diff --git a/README.md b/README.md index c5d51f499eb4d8..7ef940b6ce237f 100644 --- a/README.md +++ b/README.md @@ -148,7 +148,7 @@ Want to get paid to work on openpilot? [comma.ai is hiring](http://comma.ai/posi Licensing ------ -openpilot is released under the MIT license. +openpilot is released under the MIT license. Some parts of the software are released under other licenses as specified. Any user of this software shall indemnify and hold harmless Comma.ai, Inc. and its directors, officers, employees, agents, stockholders, affiliates, subcontractors and customers from and against all allegations, claims, actions, suits, demands, damages, liabilities, obligations, losses, settlements, judgments, costs and expenses (including without limitation attorneys’ fees and costs) which arise out of, relate to or result from any use of this software by user. diff --git a/RELEASES.md b/RELEASES.md index 34837bcc8cbbb2..fc3613c5caba5c 100644 --- a/RELEASES.md +++ b/RELEASES.md @@ -1,3 +1,11 @@ +Version 0.4.6 (2018-05-18) +========================== + * NEOSv6 required! Will autoupdate + * Stability improvements + * Fix all memory leaks + * Update C++ compiler to clang6 + * Improve front camera exposure + Version 0.4.5 (2018-04-27) ========================== * Release notes added to the update popup diff --git a/cereal/car.capnp b/cereal/car.capnp index 94ff6697ece9bc..19ab7120b5ec0c 100644 --- a/cereal/car.capnp +++ b/cereal/car.capnp @@ -57,6 +57,7 @@ struct CarEvent @0x9b1657f34caf3ad3 { plannerError @32; ipasOverride @33; debugAlert @34; + steerTempUnavailableMute @35; } } @@ -330,4 +331,10 @@ struct CarParams { stoppingControl @34 :Bool; # Does the car allows full control even at lows speeds when stopping startAccel @35 :Float32; # Required acceleraton to overcome creep braking steerRateCost @40 :Float32; # Lateral MPC cost on steering rate + steerControlType @46 :SteerControlType; + + enum SteerControlType { + torque @0; + angle @1; + } } diff --git a/common/fingerprints.py b/common/fingerprints.py index f7724312af1e88..d6941ffa4bcf22 100644 --- a/common/fingerprints.py +++ b/common/fingerprints.py @@ -17,6 +17,10 @@ class TOYOTA: class GM: VOLT = "CHEVROLET VOLT PREMIER 2017" + CADILLAC_CT6 = "CADILLAC CT6 SUPERCRUISE 2018" + +class FORD: + FUSION = "FORD FUSION 2018" _DEBUG_ADDRESS = {1880: 8} # reserved for debug purposes @@ -82,6 +86,12 @@ class GM: GM.VOLT: [{ 170: 8, 171: 8, 189: 7, 190: 6, 193: 8, 197: 8, 199: 4, 201: 8, 209: 7, 211: 2, 241: 6, 288: 5, 289: 8, 298: 8, 304: 1, 308: 4, 309: 8, 311: 8, 313: 8, 320: 3, 328: 1, 352: 5, 381: 6, 386: 8, 388: 8, 389: 2, 390: 7, 417: 7, 419: 1, 426: 7, 451: 8, 452: 8, 453: 6, 454: 8, 456: 8, 479: 3, 481: 7, 485: 8, 489: 8, 493: 8, 495: 4, 497: 8, 499: 3, 500: 6, 501: 8, 508: 8, 528: 4, 532: 6, 546: 7, 550: 8, 554: 3, 558: 8, 560: 8, 562: 8, 563: 5, 564: 5, 565: 5, 566: 5, 567: 3, 568: 1, 573: 1, 577: 8, 647: 3, 707: 8, 711: 6, 761: 7, 810: 8, 840: 5, 842: 5, 844: 8, 866: 4, 961: 8, 969: 8, 977: 8, 979: 7, 988: 6, 989: 8, 995: 7, 1001: 8, 1005: 6, 1009: 8, 1017: 8, 1019: 2, 1020: 8, 1105: 6, 1187: 4, 1217: 8, 1221: 5, 1223: 3, 1225: 7, 1227: 4, 1233: 8, 1249: 8, 1257: 6, 1265: 8, 1267: 1, 1273: 3, 1275: 3, 1280: 4, 1300: 8, 1322: 6, 1323: 4, 1328: 4, 1417: 8, 1601: 8, 1905: 7, 1906: 7, 1907: 7, 1910: 7, 1912: 7, 1922: 7, 1927: 7, 1928: 7, 2016: 8, 2020: 8, 2024: 8, 2028: 8 }], + GM.CADILLAC_CT6: [{ + 190: 6, 193: 8, 197: 8, 199: 4, 201: 8, 209: 7, 211: 2, 241: 6, 249: 8, 288: 5, 298: 8, 304: 1, 309: 8, 313: 8, 320: 3, 322: 7, 328: 1, 336: 1, 338: 6, 340: 6, 352: 5, 354: 5, 356: 8, 368: 3, 372: 5, 381: 8, 386: 8, 393: 7, 398: 8, 407: 7, 413: 8, 417: 7, 419: 1, 422: 4, 426: 7, 431: 8, 442: 8, 451: 8, 452: 8, 453: 6, 455: 7, 456: 8, 458: 5, 460: 5, 462: 4, 463: 3, 479: 3, 481: 7, 485: 8, 487: 8, 489: 8, 495: 4, 497: 8, 499: 3, 500: 6, 501: 8, 508: 8, 528: 5, 532: 6, 534: 2, 554: 3, 560: 8, 562: 8, 563: 5, 564: 5, 565: 5, 567: 5, 569: 3, 573: 1, 577: 8, 608: 8, 609: 6, 610: 6, 611: 6, 612: 8, 613: 8, 647: 6, 707: 8, 715: 8, 717: 5, 719: 5, 723: 2, 753: 5, 761: 7, 800: 6, 801: 8, 804: 3, 810: 8, 832: 8, 833: 8, 834: 8, 835: 6, 836: 5, 837: 8, 838: 8, 839: 8, 840: 5, 842: 5, 844: 8, 866: 4, 869: 4, 880: 6, 884: 8, 961: 8, 969: 8, 977: 8, 979: 8, 985: 5, 1001: 8, 1005: 6, 1009: 8, 1011: 6, 1013: 1, 1017: 8, 1019: 2, 1020: 8, 1105: 6, 1217: 8, 1221: 5, 1223: 3, 1225: 7, 1233: 8, 1249: 8, 1257: 6, 1259: 8, 1261: 7, 1263: 4, 1265: 8, 1267: 1, 1280: 4, 1296: 4, 1300: 8, 1322: 6, 1417: 8, 1601: 8, 1906: 7, 1907: 7, 1912: 7, 1914: 7, 1918: 7, 1919: 7, 1934: 7, 2016: 8, 2024: 8 + }], + FORD.FUSION: [{ + 71: 8, 74: 8, 75: 8, 76: 8, 90: 8, 92: 8, 93: 8, 118: 8, 119: 8, 120: 8, 125: 8, 129: 8, 130: 8, 131: 8, 132: 8, 133: 8, 145: 8, 146: 8, 357: 8, 359: 8, 360: 8, 361: 8, 376: 8, 390: 8, 391: 8, 392: 8, 394: 8, 512: 8, 514: 8, 516: 8, 531: 8, 532: 8, 534: 8, 535: 8, 560: 8, 578: 8, 604: 8, 613: 8, 673: 8, 827: 8, 848: 8, 934: 8, 935: 8, 936: 8, 947: 8, 963: 8, 970: 8, 972: 8, 973: 8, 984: 8, 992: 8, 994: 8, 997: 8, 998: 8, 1003: 8, 1034: 8, 1045: 8, 1046: 8, 1053: 8, 1054: 8, 1058: 8, 1059: 8, 1068: 8, 1072: 8, 1073: 8, 1082: 8, 1107: 8, 1108: 8, 1109: 8, 1110: 8, 1200: 8, 1427: 8, 1430: 8, 1438: 8, 1459: 8 + }], } # support additional internal only fingerprints diff --git a/common/logging_extra.py b/common/logging_extra.py index 359b3e09146b1c..bad9ad51653403 100644 --- a/common/logging_extra.py +++ b/common/logging_extra.py @@ -18,7 +18,7 @@ def json_robust_dumps(obj): class NiceOrderedDict(OrderedDict): def __str__(self): - return '{'+', '.join("%r: %r" % p for p in self.iteritems())+'}' + return json_robust_dumps(self) class SwagFormatter(logging.Formatter): def __init__(self, swaglogger): @@ -62,6 +62,10 @@ def format_dict(self, record): def format(self, record): return json_robust_dumps(self.format_dict(record)) +class SwagErrorFilter(logging.Filter): + def filter(self, record): + return record.levelno < logging.ERROR + _tmpfunc = lambda: 0 _srcfile = os.path.normcase(_tmpfunc.__code__.co_filename) @@ -128,15 +132,40 @@ def event(self, event_name, *args, **kwargs): if args: evt['args'] = args evt.update(kwargs) - self.info(evt) + if 'error' in kwargs: + self.error(evt) + else: + self.info(evt) if __name__ == "__main__": log = SwagLogger() + stdout_handler = logging.StreamHandler(sys.stdout) + stdout_handler.setLevel(logging.INFO) + stdout_handler.addFilter(SwagErrorFilter()) + log.addHandler(stdout_handler) + + stderr_handler = logging.StreamHandler(sys.stderr) + stderr_handler.setLevel(logging.ERROR) + log.addHandler(stderr_handler) + log.info("asdasd %s", "a") log.info({'wut': 1}) + log.warning("warning") + log.error("error") + log.critical("critical") + log.event("test", x="y") with log.ctx(): + stdout_handler.setFormatter(SwagFormatter(log)) + stderr_handler.setFormatter(SwagFormatter(log)) log.bind(user="some user") log.info("in req") - log.event("do_req") + print("") + log.warning("warning") + print("") + log.error("error") + print("") + log.critical("critical") + print("") + log.event("do_req", a=1, b="c") diff --git a/installer/updater/updater b/installer/updater/updater new file mode 100755 index 00000000000000..a5defb4108b556 Binary files /dev/null and b/installer/updater/updater differ diff --git a/launch_chffrplus.sh b/launch_chffrplus.sh index 3362e8252849af..00e126c58beee8 100755 --- a/launch_chffrplus.sh +++ b/launch_chffrplus.sh @@ -22,18 +22,6 @@ function launch { echo 0-3 > /dev/cpuset/foreground/cpus echo 0-3 > /dev/cpuset/android/cpus - # check if NEOS update is required - while [ "$(cat /VERSION)" -lt 4 ] && [ ! -e /data/media/0/noupdate ]; do - # wait for network - (cd selfdrive/ui/spinner && exec ./spinner 'waiting for network...') & spin_pid=$! - until ping -W 1 -c 1 8.8.8.8; do sleep 1; done - kill $spin_pid - - # update NEOS - curl -o /tmp/updater https://neos.comma.ai/updater && chmod +x /tmp/updater && /tmp/updater - sleep 10 - done - export PYTHONPATH="$PWD" # start manager diff --git a/phonelibs/capnp-cpp/aarch64/bin/capnp b/phonelibs/capnp-cpp/aarch64/bin/capnp new file mode 100755 index 00000000000000..e60fe7fe3c1ba0 Binary files /dev/null and b/phonelibs/capnp-cpp/aarch64/bin/capnp differ diff --git a/phonelibs/capnp-cpp/aarch64/bin/capnpc b/phonelibs/capnp-cpp/aarch64/bin/capnpc new file mode 120000 index 00000000000000..5668473f09dafe --- /dev/null +++ b/phonelibs/capnp-cpp/aarch64/bin/capnpc @@ -0,0 +1 @@ +capnp \ No newline at end of file diff --git a/phonelibs/capnp-cpp/aarch64/bin/capnpc-c++ b/phonelibs/capnp-cpp/aarch64/bin/capnpc-c++ new file mode 100755 index 00000000000000..d3090911446257 Binary files /dev/null and b/phonelibs/capnp-cpp/aarch64/bin/capnpc-c++ differ diff --git a/phonelibs/capnp-cpp/aarch64/bin/capnpc-capnp b/phonelibs/capnp-cpp/aarch64/bin/capnpc-capnp new file mode 100755 index 00000000000000..b1c7a9a9b818b6 Binary files /dev/null and b/phonelibs/capnp-cpp/aarch64/bin/capnpc-capnp differ diff --git a/phonelibs/capnp-cpp/aarch64/lib/libcapnp.a b/phonelibs/capnp-cpp/aarch64/lib/libcapnp.a new file mode 100644 index 00000000000000..a997023caa4e1b Binary files /dev/null and b/phonelibs/capnp-cpp/aarch64/lib/libcapnp.a differ diff --git a/phonelibs/capnp-cpp/aarch64/lib/libcapnpc.a b/phonelibs/capnp-cpp/aarch64/lib/libcapnpc.a new file mode 100644 index 00000000000000..2ede39fb910a33 Binary files /dev/null and b/phonelibs/capnp-cpp/aarch64/lib/libcapnpc.a differ diff --git a/phonelibs/capnp-cpp/aarch64/lib/libkj.a b/phonelibs/capnp-cpp/aarch64/lib/libkj.a new file mode 100644 index 00000000000000..58cf096637f027 Binary files /dev/null and b/phonelibs/capnp-cpp/aarch64/lib/libkj.a differ diff --git a/phonelibs/capnp-cpp/include/capnp/any.h b/phonelibs/capnp-cpp/include/capnp/any.h new file mode 100644 index 00000000000000..6df9dc8dc2dcea --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/any.h @@ -0,0 +1,1073 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_ANY_H_ +#define CAPNP_ANY_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "layout.h" +#include "pointer-helpers.h" +#include "orphan.h" +#include "list.h" + +namespace capnp { + +class StructSchema; +class ListSchema; +class InterfaceSchema; +class Orphanage; +class ClientHook; +class PipelineHook; +struct PipelineOp; +struct AnyPointer; + +struct AnyList { + AnyList() = delete; + + class Reader; + class Builder; +}; + +struct AnyStruct { + AnyStruct() = delete; + + class Reader; + class Builder; + class Pipeline; +}; + +template<> +struct List { + List() = delete; + + class Reader; + class Builder; +}; + +namespace _ { // private +template <> struct Kind_ { static constexpr Kind kind = Kind::OTHER; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::OTHER; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::OTHER; }; +} // namespace _ (private) + +// ======================================================================================= +// AnyPointer! + +enum class Equality { + NOT_EQUAL, + EQUAL, + UNKNOWN_CONTAINS_CAPS +}; + +kj::StringPtr KJ_STRINGIFY(Equality res); + +struct AnyPointer { + // Reader/Builder for the `AnyPointer` field type, i.e. a pointer that can point to an arbitrary + // object. + + AnyPointer() = delete; + + class Reader { + public: + typedef AnyPointer Reads; + + Reader() = default; + inline Reader(_::PointerReader reader): reader(reader) {} + + inline MessageSize targetSize() const; + // Get the total size of the target object and all its children. + + inline PointerType getPointerType() const; + + inline bool isNull() const { return getPointerType() == PointerType::NULL_; } + inline bool isStruct() const { return getPointerType() == PointerType::STRUCT; } + inline bool isList() const { return getPointerType() == PointerType::LIST; } + inline bool isCapability() const { return getPointerType() == PointerType::CAPABILITY; } + + Equality equals(AnyPointer::Reader right); + bool operator==(AnyPointer::Reader right); + inline bool operator!=(AnyPointer::Reader right) { + return !(*this == right); + } + + template + inline ReaderFor getAs() const; + // Valid for T = any generated struct type, interface type, List, Text, or Data. + + template + inline ReaderFor getAs(StructSchema schema) const; + // Only valid for T = DynamicStruct. Requires `#include `. + + template + inline ReaderFor getAs(ListSchema schema) const; + // Only valid for T = DynamicList. Requires `#include `. + + template + inline ReaderFor getAs(InterfaceSchema schema) const; + // Only valid for T = DynamicCapability. Requires `#include `. + +#if !CAPNP_LITE + kj::Own getPipelinedCap(kj::ArrayPtr ops) const; + // Used by RPC system to implement pipelining. Applications generally shouldn't use this + // directly. +#endif // !CAPNP_LITE + + private: + _::PointerReader reader; + friend struct AnyPointer; + friend class Orphanage; + friend class CapReaderContext; + friend struct _::PointerHelpers; + }; + + class Builder { + public: + typedef AnyPointer Builds; + + Builder() = delete; + inline Builder(decltype(nullptr)) {} + inline Builder(_::PointerBuilder builder): builder(builder) {} + + inline MessageSize targetSize() const; + // Get the total size of the target object and all its children. + + inline PointerType getPointerType(); + + inline bool isNull() { return getPointerType() == PointerType::NULL_; } + inline bool isStruct() { return getPointerType() == PointerType::STRUCT; } + inline bool isList() { return getPointerType() == PointerType::LIST; } + inline bool isCapability() { return getPointerType() == PointerType::CAPABILITY; } + + inline Equality equals(AnyPointer::Reader right) { + return asReader().equals(right); + } + inline bool operator==(AnyPointer::Reader right) { + return asReader() == right; + } + inline bool operator!=(AnyPointer::Reader right) { + return !(*this == right); + } + + inline void clear(); + // Set to null. + + template + inline BuilderFor getAs(); + // Valid for T = any generated struct type, List, Text, or Data. + + template + inline BuilderFor getAs(StructSchema schema); + // Only valid for T = DynamicStruct. Requires `#include `. + + template + inline BuilderFor getAs(ListSchema schema); + // Only valid for T = DynamicList. Requires `#include `. + + template + inline BuilderFor getAs(InterfaceSchema schema); + // Only valid for T = DynamicCapability. Requires `#include `. + + template + inline BuilderFor initAs(); + // Valid for T = any generated struct type. + + template + inline BuilderFor initAs(uint elementCount); + // Valid for T = List, Text, or Data. + + template + inline BuilderFor initAs(StructSchema schema); + // Only valid for T = DynamicStruct. Requires `#include `. + + template + inline BuilderFor initAs(ListSchema schema, uint elementCount); + // Only valid for T = DynamicList. Requires `#include `. + + inline AnyList::Builder initAsAnyList(ElementSize elementSize, uint elementCount); + // Note: Does not accept INLINE_COMPOSITE for elementSize. + + inline List::Builder initAsListOfAnyStruct( + uint16_t dataWordCount, uint16_t pointerCount, uint elementCount); + + inline AnyStruct::Builder initAsAnyStruct(uint16_t dataWordCount, uint16_t pointerCount); + + template + inline void setAs(ReaderFor value); + // Valid for ReaderType = T::Reader for T = any generated struct type, List, Text, Data, + // DynamicStruct, or DynamicList (the dynamic types require `#include `). + + template + inline void setAs(std::initializer_list>> list); + // Valid for T = List. + + template + inline void setCanonicalAs(ReaderFor value); + + inline void set(Reader value) { builder.copyFrom(value.reader); } + // Set to a copy of another AnyPointer. + + inline void setCanonical(Reader value) { builder.copyFrom(value.reader, true); } + + template + inline void adopt(Orphan&& orphan); + // Valid for T = any generated struct type, List, Text, Data, DynamicList, DynamicStruct, + // or DynamicValue (the dynamic types require `#include `). + + template + inline Orphan disownAs(); + // Valid for T = any generated struct type, List, Text, Data. + + template + inline Orphan disownAs(StructSchema schema); + // Only valid for T = DynamicStruct. Requires `#include `. + + template + inline Orphan disownAs(ListSchema schema); + // Only valid for T = DynamicList. Requires `#include `. + + template + inline Orphan disownAs(InterfaceSchema schema); + // Only valid for T = DynamicCapability. Requires `#include `. + + inline Orphan disown(); + // Disown without a type. + + inline Reader asReader() const { return Reader(builder.asReader()); } + inline operator Reader() const { return Reader(builder.asReader()); } + + private: + _::PointerBuilder builder; + friend class Orphanage; + friend class CapBuilderContext; + friend struct _::PointerHelpers; + }; + +#if !CAPNP_LITE + class Pipeline { + public: + typedef AnyPointer Pipelines; + + inline Pipeline(decltype(nullptr)) {} + inline explicit Pipeline(kj::Own&& hook): hook(kj::mv(hook)) {} + + Pipeline noop(); + // Just make a copy. + + Pipeline getPointerField(uint16_t pointerIndex); + // Deprecated. In the future, we should use .asAnyStruct.getPointerField. + + inline AnyStruct::Pipeline asAnyStruct(); + + kj::Own asCap(); + // Expect that the result is a capability and construct a pipelined version of it now. + + inline kj::Own releasePipelineHook() { return kj::mv(hook); } + // For use by RPC implementations. + + template ) == Kind::INTERFACE>> + inline operator T() { return T(asCap()); } + + private: + kj::Own hook; + kj::Array ops; + + inline Pipeline(kj::Own&& hook, kj::Array&& ops) + : hook(kj::mv(hook)), ops(kj::mv(ops)) {} + + friend class LocalClient; + friend class PipelineHook; + friend class AnyStruct::Pipeline; + }; +#endif // !CAPNP_LITE +}; + +template <> +class Orphan { + // An orphaned object of unknown type. + +public: + Orphan() = default; + KJ_DISALLOW_COPY(Orphan); + Orphan(Orphan&&) = default; + inline Orphan(_::OrphanBuilder&& builder) + : builder(kj::mv(builder)) {} + + Orphan& operator=(Orphan&&) = default; + + template + inline Orphan(Orphan&& other): builder(kj::mv(other.builder)) {} + template + inline Orphan& operator=(Orphan&& other) { builder = kj::mv(other.builder); return *this; } + // Cast from typed orphan. + + // It's not possible to get an AnyPointer::{Reader,Builder} directly since there is no + // underlying pointer (the pointer would normally live in the parent, but this object is + // orphaned). It is possible, however, to request typed readers/builders. + + template + inline BuilderFor getAs(); + template + inline BuilderFor getAs(StructSchema schema); + template + inline BuilderFor getAs(ListSchema schema); + template + inline typename T::Client getAs(InterfaceSchema schema); + template + inline ReaderFor getAsReader() const; + template + inline ReaderFor getAsReader(StructSchema schema) const; + template + inline ReaderFor getAsReader(ListSchema schema) const; + template + inline typename T::Client getAsReader(InterfaceSchema schema) const; + + template + inline Orphan releaseAs(); + template + inline Orphan releaseAs(StructSchema schema); + template + inline Orphan releaseAs(ListSchema schema); + template + inline Orphan releaseAs(InterfaceSchema schema); + // Down-cast the orphan to a specific type. + + inline bool operator==(decltype(nullptr)) const { return builder == nullptr; } + inline bool operator!=(decltype(nullptr)) const { return builder != nullptr; } + +private: + _::OrphanBuilder builder; + + template + friend struct _::PointerHelpers; + friend class Orphanage; + template + friend class Orphan; + friend class AnyPointer::Builder; +}; + +template struct AnyTypeFor_; +template <> struct AnyTypeFor_ { typedef AnyStruct Type; }; +template <> struct AnyTypeFor_ { typedef AnyList Type; }; + +template +using AnyTypeFor = typename AnyTypeFor_::Type; + +template +inline ReaderFor>> toAny(T&& value) { + return ReaderFor>>( + _::PointerHelpers>::getInternalReader(value)); +} +template +inline BuilderFor>> toAny(T&& value) { + return BuilderFor>>( + _::PointerHelpers>::getInternalBuilder(kj::mv(value))); +} + +template <> +struct List { + // Note: This cannot be used for a list of structs, since such lists are not encoded as pointer + // lists! Use List. + + List() = delete; + + class Reader { + public: + typedef List Reads; + + inline Reader(): reader(ElementSize::POINTER) {} + inline explicit Reader(_::ListReader reader): reader(reader) {} + + inline uint size() const { return unbound(reader.size() / ELEMENTS); } + inline AnyPointer::Reader operator[](uint index) const { + KJ_IREQUIRE(index < size()); + return AnyPointer::Reader(reader.getPointerElement(bounded(index) * ELEMENTS)); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + + private: + _::ListReader reader; + template + friend struct _::PointerHelpers; + template + friend struct List; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Builder { + public: + typedef List Builds; + + Builder() = delete; + inline Builder(decltype(nullptr)): builder(ElementSize::POINTER) {} + inline explicit Builder(_::ListBuilder builder): builder(builder) {} + + inline operator Reader() const { return Reader(builder.asReader()); } + inline Reader asReader() const { return Reader(builder.asReader()); } + + inline uint size() const { return unbound(builder.size() / ELEMENTS); } + inline AnyPointer::Builder operator[](uint index) { + KJ_IREQUIRE(index < size()); + return AnyPointer::Builder(builder.getPointerElement(bounded(index) * ELEMENTS)); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() { return Iterator(this, 0); } + inline Iterator end() { return Iterator(this, size()); } + + private: + _::ListBuilder builder; + template + friend struct _::PointerHelpers; + friend class Orphanage; + template + friend struct ToDynamic_; + }; +}; + +class AnyStruct::Reader { +public: + typedef AnyStruct Reads; + + Reader() = default; + inline Reader(_::StructReader reader): _reader(reader) {} + + template ) == Kind::STRUCT>> + inline Reader(T&& value) + : _reader(_::PointerHelpers>::getInternalReader(kj::fwd(value))) {} + + kj::ArrayPtr getDataSection() { + return _reader.getDataSectionAsBlob(); + } + List::Reader getPointerSection() { + return List::Reader(_reader.getPointerSectionAsList()); + } + + kj::Array canonicalize() { + return _reader.canonicalize(); + } + + Equality equals(AnyStruct::Reader right); + bool operator==(AnyStruct::Reader right); + inline bool operator!=(AnyStruct::Reader right) { + return !(*this == right); + } + + template + ReaderFor as() const { + // T must be a struct type. + return typename T::Reader(_reader); + } +private: + _::StructReader _reader; + + template + friend struct _::PointerHelpers; + friend class Orphanage; +}; + +class AnyStruct::Builder { +public: + typedef AnyStruct Builds; + + inline Builder(decltype(nullptr)) {} + inline Builder(_::StructBuilder builder): _builder(builder) {} + +#if !_MSC_VER // TODO(msvc): MSVC ICEs on this. Try restoring when compiler improves. + template ) == Kind::STRUCT>> + inline Builder(T&& value) + : _builder(_::PointerHelpers>::getInternalBuilder(kj::fwd(value))) {} +#endif + + inline kj::ArrayPtr getDataSection() { + return _builder.getDataSectionAsBlob(); + } + List::Builder getPointerSection() { + return List::Builder(_builder.getPointerSectionAsList()); + } + + inline Equality equals(AnyStruct::Reader right) { + return asReader().equals(right); + } + inline bool operator==(AnyStruct::Reader right) { + return asReader() == right; + } + inline bool operator!=(AnyStruct::Reader right) { + return !(*this == right); + } + + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return Reader(_builder.asReader()); } + + template + BuilderFor as() { + // T must be a struct type. + return typename T::Builder(_builder); + } +private: + _::StructBuilder _builder; + friend class Orphanage; + friend class CapBuilderContext; +}; + +#if !CAPNP_LITE +class AnyStruct::Pipeline { +public: + inline Pipeline(decltype(nullptr)): typeless(nullptr) {} + inline explicit Pipeline(AnyPointer::Pipeline&& typeless) + : typeless(kj::mv(typeless)) {} + + inline AnyPointer::Pipeline getPointerField(uint16_t pointerIndex) { + // Return a new Promise representing a sub-object of the result. `pointerIndex` is the index + // of the sub-object within the pointer section of the result (the result must be a struct). + // + // TODO(perf): On GCC 4.8 / Clang 3.3, use rvalue qualifiers to avoid the need for copies. + // Also make `ops` into a Vector to optimize this. + return typeless.getPointerField(pointerIndex); + } + +private: + AnyPointer::Pipeline typeless; +}; +#endif // !CAPNP_LITE + +class List::Reader { +public: + typedef List Reads; + + inline Reader(): reader(ElementSize::INLINE_COMPOSITE) {} + inline explicit Reader(_::ListReader reader): reader(reader) {} + + inline uint size() const { return unbound(reader.size() / ELEMENTS); } + inline AnyStruct::Reader operator[](uint index) const { + KJ_IREQUIRE(index < size()); + return AnyStruct::Reader(reader.getStructElement(bounded(index) * ELEMENTS)); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + +private: + _::ListReader reader; + template + friend struct _::PointerHelpers; + template + friend struct List; + friend class Orphanage; + template + friend struct ToDynamic_; +}; + +class List::Builder { +public: + typedef List Builds; + + Builder() = delete; + inline Builder(decltype(nullptr)): builder(ElementSize::INLINE_COMPOSITE) {} + inline explicit Builder(_::ListBuilder builder): builder(builder) {} + + inline operator Reader() const { return Reader(builder.asReader()); } + inline Reader asReader() const { return Reader(builder.asReader()); } + + inline uint size() const { return unbound(builder.size() / ELEMENTS); } + inline AnyStruct::Builder operator[](uint index) { + KJ_IREQUIRE(index < size()); + return AnyStruct::Builder(builder.getStructElement(bounded(index) * ELEMENTS)); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() { return Iterator(this, 0); } + inline Iterator end() { return Iterator(this, size()); } + +private: + _::ListBuilder builder; + template + friend struct _::PointerHelpers; + friend class Orphanage; + template + friend struct ToDynamic_; +}; + +class AnyList::Reader { +public: + typedef AnyList Reads; + + inline Reader(): _reader(ElementSize::VOID) {} + inline Reader(_::ListReader reader): _reader(reader) {} + +#if !_MSC_VER // TODO(msvc): MSVC ICEs on this. Try restoring when compiler improves. + template ) == Kind::LIST>> + inline Reader(T&& value) + : _reader(_::PointerHelpers>::getInternalReader(kj::fwd(value))) {} +#endif + + inline ElementSize getElementSize() { return _reader.getElementSize(); } + inline uint size() { return unbound(_reader.size() / ELEMENTS); } + + inline kj::ArrayPtr getRawBytes() { return _reader.asRawBytes(); } + + Equality equals(AnyList::Reader right); + bool operator==(AnyList::Reader right); + inline bool operator!=(AnyList::Reader right) { + return !(*this == right); + } + + template ReaderFor as() { + // T must be List. + return ReaderFor(_reader); + } +private: + _::ListReader _reader; + + template + friend struct _::PointerHelpers; + friend class Orphanage; +}; + +class AnyList::Builder { +public: + typedef AnyList Builds; + + inline Builder(decltype(nullptr)): _builder(ElementSize::VOID) {} + inline Builder(_::ListBuilder builder): _builder(builder) {} + +#if !_MSC_VER // TODO(msvc): MSVC ICEs on this. Try restoring when compiler improves. + template ) == Kind::LIST>> + inline Builder(T&& value) + : _builder(_::PointerHelpers>::getInternalBuilder(kj::fwd(value))) {} +#endif + + inline ElementSize getElementSize() { return _builder.getElementSize(); } + inline uint size() { return unbound(_builder.size() / ELEMENTS); } + + Equality equals(AnyList::Reader right); + inline bool operator==(AnyList::Reader right) { + return asReader() == right; + } + inline bool operator!=(AnyList::Reader right) { + return !(*this == right); + } + + template BuilderFor as() { + // T must be List. + return BuilderFor(_builder); + } + + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return Reader(_builder.asReader()); } + +private: + _::ListBuilder _builder; + + friend class Orphanage; +}; + +// ======================================================================================= +// Pipeline helpers +// +// These relate to capabilities, but we don't declare them in capability.h because generated code +// for structs needs to know about these, even in files that contain no interfaces. + +#if !CAPNP_LITE + +struct PipelineOp { + // Corresponds to rpc.capnp's PromisedAnswer.Op. + + enum Type { + NOOP, // for convenience + + GET_POINTER_FIELD + + // There may be other types in the future... + }; + + Type type; + union { + uint16_t pointerIndex; // for GET_POINTER_FIELD + }; +}; + +class PipelineHook { + // Represents a currently-running call, and implements pipelined requests on its result. + +public: + virtual kj::Own addRef() = 0; + // Increment this object's reference count. + + virtual kj::Own getPipelinedCap(kj::ArrayPtr ops) = 0; + // Extract a promised Capability from the results. + + virtual kj::Own getPipelinedCap(kj::Array&& ops); + // Version of getPipelinedCap() passing the array by move. May avoid a copy in some cases. + // Default implementation just calls the other version. + + template > + static inline kj::Own from(Pipeline&& pipeline); + +private: + template struct FromImpl; +}; + +#endif // !CAPNP_LITE + +// ======================================================================================= +// Inline implementation details + +inline MessageSize AnyPointer::Reader::targetSize() const { + return reader.targetSize().asPublic(); +} + +inline PointerType AnyPointer::Reader::getPointerType() const { + return reader.getPointerType(); +} + +template +inline ReaderFor AnyPointer::Reader::getAs() const { + return _::PointerHelpers::get(reader); +} + +inline MessageSize AnyPointer::Builder::targetSize() const { + return asReader().targetSize(); +} + +inline PointerType AnyPointer::Builder::getPointerType() { + return builder.getPointerType(); +} + +inline void AnyPointer::Builder::clear() { + return builder.clear(); +} + +template +inline BuilderFor AnyPointer::Builder::getAs() { + return _::PointerHelpers::get(builder); +} + +template +inline BuilderFor AnyPointer::Builder::initAs() { + return _::PointerHelpers::init(builder); +} + +template +inline BuilderFor AnyPointer::Builder::initAs(uint elementCount) { + return _::PointerHelpers::init(builder, elementCount); +} + +inline AnyList::Builder AnyPointer::Builder::initAsAnyList( + ElementSize elementSize, uint elementCount) { + return AnyList::Builder(builder.initList(elementSize, bounded(elementCount) * ELEMENTS)); +} + +inline List::Builder AnyPointer::Builder::initAsListOfAnyStruct( + uint16_t dataWordCount, uint16_t pointerCount, uint elementCount) { + return List::Builder(builder.initStructList(bounded(elementCount) * ELEMENTS, + _::StructSize(bounded(dataWordCount) * WORDS, + bounded(pointerCount) * POINTERS))); +} + +inline AnyStruct::Builder AnyPointer::Builder::initAsAnyStruct( + uint16_t dataWordCount, uint16_t pointerCount) { + return AnyStruct::Builder(builder.initStruct( + _::StructSize(bounded(dataWordCount) * WORDS, + bounded(pointerCount) * POINTERS))); +} + +template +inline void AnyPointer::Builder::setAs(ReaderFor value) { + return _::PointerHelpers::set(builder, value); +} + +template +inline void AnyPointer::Builder::setCanonicalAs(ReaderFor value) { + return _::PointerHelpers::setCanonical(builder, value); +} + +template +inline void AnyPointer::Builder::setAs( + std::initializer_list>> list) { + return _::PointerHelpers::set(builder, list); +} + +template +inline void AnyPointer::Builder::adopt(Orphan&& orphan) { + _::PointerHelpers::adopt(builder, kj::mv(orphan)); +} + +template +inline Orphan AnyPointer::Builder::disownAs() { + return _::PointerHelpers::disown(builder); +} + +inline Orphan AnyPointer::Builder::disown() { + return Orphan(builder.disown()); +} + +template <> struct ReaderFor_ { typedef AnyPointer::Reader Type; }; +template <> struct BuilderFor_ { typedef AnyPointer::Builder Type; }; +template <> struct ReaderFor_ { typedef AnyStruct::Reader Type; }; +template <> struct BuilderFor_ { typedef AnyStruct::Builder Type; }; + +template <> +struct Orphanage::GetInnerReader { + static inline _::PointerReader apply(const AnyPointer::Reader& t) { + return t.reader; + } +}; + +template <> +struct Orphanage::GetInnerBuilder { + static inline _::PointerBuilder apply(AnyPointer::Builder& t) { + return t.builder; + } +}; + +template <> +struct Orphanage::GetInnerReader { + static inline _::StructReader apply(const AnyStruct::Reader& t) { + return t._reader; + } +}; + +template <> +struct Orphanage::GetInnerBuilder { + static inline _::StructBuilder apply(AnyStruct::Builder& t) { + return t._builder; + } +}; + +template <> +struct Orphanage::GetInnerReader { + static inline _::ListReader apply(const AnyList::Reader& t) { + return t._reader; + } +}; + +template <> +struct Orphanage::GetInnerBuilder { + static inline _::ListBuilder apply(AnyList::Builder& t) { + return t._builder; + } +}; + +template +inline BuilderFor Orphan::getAs() { + return _::OrphanGetImpl::apply(builder); +} +template +inline ReaderFor Orphan::getAsReader() const { + return _::OrphanGetImpl::applyReader(builder); +} +template +inline Orphan Orphan::releaseAs() { + return Orphan(kj::mv(builder)); +} + +// Using AnyPointer as the template type should work... + +template <> +inline typename AnyPointer::Reader AnyPointer::Reader::getAs() const { + return *this; +} +template <> +inline typename AnyPointer::Builder AnyPointer::Builder::getAs() { + return *this; +} +template <> +inline typename AnyPointer::Builder AnyPointer::Builder::initAs() { + clear(); + return *this; +} +template <> +inline void AnyPointer::Builder::setAs(AnyPointer::Reader value) { + return builder.copyFrom(value.reader); +} +template <> +inline void AnyPointer::Builder::adopt(Orphan&& orphan) { + builder.adopt(kj::mv(orphan.builder)); +} +template <> +inline Orphan AnyPointer::Builder::disownAs() { + return Orphan(builder.disown()); +} +template <> +inline Orphan Orphan::releaseAs() { + return kj::mv(*this); +} + +namespace _ { // private + +// Specialize PointerHelpers for AnyPointer. + +template <> +struct PointerHelpers { + static inline AnyPointer::Reader get(PointerReader reader, + const void* defaultValue = nullptr, + uint defaultBytes = 0) { + return AnyPointer::Reader(reader); + } + static inline AnyPointer::Builder get(PointerBuilder builder, + const void* defaultValue = nullptr, + uint defaultBytes = 0) { + return AnyPointer::Builder(builder); + } + static inline void set(PointerBuilder builder, AnyPointer::Reader value) { + AnyPointer::Builder(builder).set(value); + } + static inline void adopt(PointerBuilder builder, Orphan&& value) { + builder.adopt(kj::mv(value.builder)); + } + static inline Orphan disown(PointerBuilder builder) { + return Orphan(builder.disown()); + } + static inline _::PointerReader getInternalReader(const AnyPointer::Reader& reader) { + return reader.reader; + } + static inline _::PointerBuilder getInternalBuilder(AnyPointer::Builder&& builder) { + return builder.builder; + } +}; + +template <> +struct PointerHelpers { + static inline AnyStruct::Reader get( + PointerReader reader, const word* defaultValue = nullptr) { + return AnyStruct::Reader(reader.getStruct(defaultValue)); + } + static inline AnyStruct::Builder get( + PointerBuilder builder, const word* defaultValue = nullptr) { + // TODO(someday): Allow specifying the size somehow? + return AnyStruct::Builder(builder.getStruct( + _::StructSize(ZERO * WORDS, ZERO * POINTERS), defaultValue)); + } + static inline void set(PointerBuilder builder, AnyStruct::Reader value) { + builder.setStruct(value._reader); + } + static inline AnyStruct::Builder init( + PointerBuilder builder, uint16_t dataWordCount, uint16_t pointerCount) { + return AnyStruct::Builder(builder.initStruct( + StructSize(bounded(dataWordCount) * WORDS, + bounded(pointerCount) * POINTERS))); + } + + static void adopt(PointerBuilder builder, Orphan&& value) { + builder.adopt(kj::mv(value.builder)); + } + static Orphan disown(PointerBuilder builder) { + return Orphan(builder.disown()); + } +}; + +template <> +struct PointerHelpers { + static inline AnyList::Reader get( + PointerReader reader, const word* defaultValue = nullptr) { + return AnyList::Reader(reader.getListAnySize(defaultValue)); + } + static inline AnyList::Builder get( + PointerBuilder builder, const word* defaultValue = nullptr) { + return AnyList::Builder(builder.getListAnySize(defaultValue)); + } + static inline void set(PointerBuilder builder, AnyList::Reader value) { + builder.setList(value._reader); + } + static inline AnyList::Builder init( + PointerBuilder builder, ElementSize elementSize, uint elementCount) { + return AnyList::Builder(builder.initList( + elementSize, bounded(elementCount) * ELEMENTS)); + } + static inline AnyList::Builder init( + PointerBuilder builder, uint16_t dataWordCount, uint16_t pointerCount, uint elementCount) { + return AnyList::Builder(builder.initStructList( + bounded(elementCount) * ELEMENTS, + StructSize(bounded(dataWordCount) * WORDS, + bounded(pointerCount) * POINTERS))); + } + + static void adopt(PointerBuilder builder, Orphan&& value) { + builder.adopt(kj::mv(value.builder)); + } + static Orphan disown(PointerBuilder builder) { + return Orphan(builder.disown()); + } +}; + +template <> +struct OrphanGetImpl { + static inline AnyStruct::Builder apply(_::OrphanBuilder& builder) { + return AnyStruct::Builder(builder.asStruct(_::StructSize(ZERO * WORDS, ZERO * POINTERS))); + } + static inline AnyStruct::Reader applyReader(const _::OrphanBuilder& builder) { + return AnyStruct::Reader(builder.asStructReader(_::StructSize(ZERO * WORDS, ZERO * POINTERS))); + } + static inline void truncateListOf(_::OrphanBuilder& builder, ElementCount size) { + builder.truncate(size, _::StructSize(ZERO * WORDS, ZERO * POINTERS)); + } +}; + +template <> +struct OrphanGetImpl { + static inline AnyList::Builder apply(_::OrphanBuilder& builder) { + return AnyList::Builder(builder.asListAnySize()); + } + static inline AnyList::Reader applyReader(const _::OrphanBuilder& builder) { + return AnyList::Reader(builder.asListReaderAnySize()); + } + static inline void truncateListOf(_::OrphanBuilder& builder, ElementCount size) { + builder.truncate(size, ElementSize::POINTER); + } +}; + +} // namespace _ (private) + +#if !CAPNP_LITE + +template +struct PipelineHook::FromImpl { + static inline kj::Own apply(typename T::Pipeline&& pipeline) { + return from(kj::mv(pipeline._typeless)); + } +}; + +template <> +struct PipelineHook::FromImpl { + static inline kj::Own apply(AnyPointer::Pipeline&& pipeline) { + return kj::mv(pipeline.hook); + } +}; + +template +inline kj::Own PipelineHook::from(Pipeline&& pipeline) { + return FromImpl::apply(kj::fwd(pipeline)); +} + +#endif // !CAPNP_LITE + +} // namespace capnp + +#endif // CAPNP_ANY_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/blob.h b/phonelibs/capnp-cpp/include/capnp/blob.h new file mode 100644 index 00000000000000..d11f101a5ad378 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/blob.h @@ -0,0 +1,220 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_BLOB_H_ +#define CAPNP_BLOB_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include +#include +#include "common.h" +#include + +namespace capnp { + +struct Data { + Data() = delete; + class Reader; + class Builder; + class Pipeline {}; +}; + +struct Text { + Text() = delete; + class Reader; + class Builder; + class Pipeline {}; +}; + +class Data::Reader: public kj::ArrayPtr { + // Points to a blob of bytes. The usual Reader rules apply -- Data::Reader behaves like a simple + // pointer which does not own its target, can be passed by value, etc. + +public: + typedef Data Reads; + + Reader() = default; + inline Reader(decltype(nullptr)): ArrayPtr(nullptr) {} + inline Reader(const byte* value, size_t size): ArrayPtr(value, size) {} + inline Reader(const kj::Array& value): ArrayPtr(value) {} + inline Reader(const ArrayPtr& value): ArrayPtr(value) {} + inline Reader(const kj::Array& value): ArrayPtr(value) {} + inline Reader(const ArrayPtr& value): ArrayPtr(value) {} +}; + +class Text::Reader: public kj::StringPtr { + // Like Data::Reader, but points at NUL-terminated UTF-8 text. The NUL terminator is not counted + // in the size but must be present immediately after the last byte. + // + // Text::Reader's interface contract is that its data MUST be NUL-terminated. The producer of + // the Text::Reader must guarantee this, so that the consumer need not check. The data SHOULD + // also be valid UTF-8, but this is NOT guaranteed -- the consumer must verify if it cares. + +public: + typedef Text Reads; + + Reader() = default; + inline Reader(decltype(nullptr)): StringPtr(nullptr) {} + inline Reader(const char* value): StringPtr(value) {} + inline Reader(const char* value, size_t size): StringPtr(value, size) {} + inline Reader(const kj::String& value): StringPtr(value) {} + inline Reader(const StringPtr& value): StringPtr(value) {} + +#if KJ_COMPILER_SUPPORTS_STL_STRING_INTEROP + template ().c_str())> + inline Reader(const T& t): StringPtr(t) {} + // Allow implicit conversion from any class that has a c_str() method (namely, std::string). + // We use a template trick to detect std::string in order to avoid including the header for + // those who don't want it. +#endif +}; + +class Data::Builder: public kj::ArrayPtr { + // Like Data::Reader except the pointers aren't const. + +public: + typedef Data Builds; + + Builder() = default; + inline Builder(decltype(nullptr)): ArrayPtr(nullptr) {} + inline Builder(byte* value, size_t size): ArrayPtr(value, size) {} + inline Builder(kj::Array& value): ArrayPtr(value) {} + inline Builder(ArrayPtr value): ArrayPtr(value) {} + + inline Data::Reader asReader() const { return Data::Reader(*this); } + inline operator Reader() const { return asReader(); } +}; + +class Text::Builder: public kj::DisallowConstCopy { + // Basically identical to kj::StringPtr, except that the contents are non-const. + +public: + inline Builder(): content(nulstr, 1) {} + inline Builder(decltype(nullptr)): content(nulstr, 1) {} + inline Builder(char* value): content(value, strlen(value) + 1) {} + inline Builder(char* value, size_t size): content(value, size + 1) { + KJ_IREQUIRE(value[size] == '\0', "StringPtr must be NUL-terminated."); + } + + inline Reader asReader() const { return Reader(content.begin(), content.size() - 1); } + inline operator Reader() const { return asReader(); } + + inline operator kj::ArrayPtr(); + inline kj::ArrayPtr asArray(); + inline operator kj::ArrayPtr() const; + inline kj::ArrayPtr asArray() const; + inline kj::ArrayPtr asBytes() { return asArray().asBytes(); } + inline kj::ArrayPtr asBytes() const { return asArray().asBytes(); } + // Result does not include NUL terminator. + + inline operator kj::StringPtr() const; + inline kj::StringPtr asString() const; + + inline const char* cStr() const { return content.begin(); } + // Returns NUL-terminated string. + + inline size_t size() const { return content.size() - 1; } + // Result does not include NUL terminator. + + inline char operator[](size_t index) const { return content[index]; } + inline char& operator[](size_t index) { return content[index]; } + + inline char* begin() { return content.begin(); } + inline char* end() { return content.end() - 1; } + inline const char* begin() const { return content.begin(); } + inline const char* end() const { return content.end() - 1; } + + inline bool operator==(decltype(nullptr)) const { return content.size() <= 1; } + inline bool operator!=(decltype(nullptr)) const { return content.size() > 1; } + + inline bool operator==(Builder other) const { return asString() == other.asString(); } + inline bool operator!=(Builder other) const { return asString() != other.asString(); } + inline bool operator< (Builder other) const { return asString() < other.asString(); } + inline bool operator> (Builder other) const { return asString() > other.asString(); } + inline bool operator<=(Builder other) const { return asString() <= other.asString(); } + inline bool operator>=(Builder other) const { return asString() >= other.asString(); } + + inline kj::StringPtr slice(size_t start) const; + inline kj::ArrayPtr slice(size_t start, size_t end) const; + inline Builder slice(size_t start); + inline kj::ArrayPtr slice(size_t start, size_t end); + // A string slice is only NUL-terminated if it is a suffix, so slice() has a one-parameter + // version that assumes end = size(). + +private: + inline explicit Builder(kj::ArrayPtr content): content(content) {} + + kj::ArrayPtr content; + + static char nulstr[1]; +}; + +inline kj::StringPtr KJ_STRINGIFY(Text::Builder builder) { + return builder.asString(); +} + +inline bool operator==(const char* a, const Text::Builder& b) { return a == b.asString(); } +inline bool operator!=(const char* a, const Text::Builder& b) { return a != b.asString(); } + +inline Text::Builder::operator kj::StringPtr() const { + return kj::StringPtr(content.begin(), content.size() - 1); +} + +inline kj::StringPtr Text::Builder::asString() const { + return kj::StringPtr(content.begin(), content.size() - 1); +} + +inline Text::Builder::operator kj::ArrayPtr() { + return content.slice(0, content.size() - 1); +} + +inline kj::ArrayPtr Text::Builder::asArray() { + return content.slice(0, content.size() - 1); +} + +inline Text::Builder::operator kj::ArrayPtr() const { + return content.slice(0, content.size() - 1); +} + +inline kj::ArrayPtr Text::Builder::asArray() const { + return content.slice(0, content.size() - 1); +} + +inline kj::StringPtr Text::Builder::slice(size_t start) const { + return asReader().slice(start); +} +inline kj::ArrayPtr Text::Builder::slice(size_t start, size_t end) const { + return content.slice(start, end); +} + +inline Text::Builder Text::Builder::slice(size_t start) { + return Text::Builder(content.slice(start, content.size())); +} +inline kj::ArrayPtr Text::Builder::slice(size_t start, size_t end) { + return content.slice(start, end); +} + +} // namespace capnp + +#endif // CAPNP_BLOB_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/c++.capnp b/phonelibs/capnp-cpp/include/capnp/c++.capnp new file mode 100644 index 00000000000000..2bda54717920ab --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/c++.capnp @@ -0,0 +1,26 @@ +# Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +# Licensed under the MIT License: +# +# Permission is hereby granted, free of charge, to any person obtaining a copy +# of this software and associated documentation files (the "Software"), to deal +# in the Software without restriction, including without limitation the rights +# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +# copies of the Software, and to permit persons to whom the Software is +# furnished to do so, subject to the following conditions: +# +# The above copyright notice and this permission notice shall be included in +# all copies or substantial portions of the Software. +# +# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +# THE SOFTWARE. + +@0xbdf87d7bb8304e81; +$namespace("capnp::annotations"); + +annotation namespace(file): Text; +annotation name(field, enumerant, struct, enum, interface, method, param, group, union): Text; diff --git a/phonelibs/capnp-cpp/include/capnp/c++.capnp.h b/phonelibs/capnp-cpp/include/capnp/c++.capnp.h new file mode 100644 index 00000000000000..6d9817fbded116 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/c++.capnp.h @@ -0,0 +1,33 @@ +// Generated by Cap'n Proto compiler, DO NOT EDIT +// source: c++.capnp + +#ifndef CAPNP_INCLUDED_bdf87d7bb8304e81_ +#define CAPNP_INCLUDED_bdf87d7bb8304e81_ + +#include + +#if CAPNP_VERSION != 6001 +#error "Version mismatch between generated code and library headers. You must use the same version of the Cap'n Proto compiler and library." +#endif + + +namespace capnp { +namespace schemas { + +CAPNP_DECLARE_SCHEMA(b9c6f99ebf805f2c); +CAPNP_DECLARE_SCHEMA(f264a779fef191ce); + +} // namespace schemas +} // namespace capnp + +namespace capnp { +namespace annotations { + +// ======================================================================================= + +// ======================================================================================= + +} // namespace +} // namespace + +#endif // CAPNP_INCLUDED_bdf87d7bb8304e81_ diff --git a/phonelibs/capnp-cpp/include/capnp/c.capnp b/phonelibs/capnp-cpp/include/capnp/c.capnp new file mode 100644 index 00000000000000..5de7e7363afcc0 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/c.capnp @@ -0,0 +1,37 @@ +# Copyright (c) 2016 NetDEF, Inc. and contributors +# Licensed under the MIT License: +# +# Permission is hereby granted, free of charge, to any person obtaining a copy +# of this software and associated documentation files (the "Software"), to deal +# in the Software without restriction, including without limitation the rights +# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +# copies of the Software, and to permit persons to whom the Software is +# furnished to do so, subject to the following conditions: +# +# The above copyright notice and this permission notice shall be included in +# all copies or substantial portions of the Software. +# +# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +# THE SOFTWARE. + +@0xc0183dd65ffef0f3; + +annotation nameinfix @0x85a8d86d736ba637 (file): Text; +# add an infix (middle insert) for output file names +# +# "make" generally has implicit rules for compiling "foo.c" => "foo". This +# is very annoying with capnp since the rule will be "foo" => "foo.c", leading +# to a loop. $nameinfix (recommended parameter: "-gen") inserts its parameter +# before the ".c", so the filename becomes "foo-gen.c" +# +# ("foo" is really "foo.capnp", so it's foo.capnp-gen.c) + +annotation fieldgetset @0xf72bc690355d66de (file): Void; +# generate getter & setter functions for accessing fields +# +# allows grabbing/putting values without de-/encoding the entire struct. diff --git a/phonelibs/capnp-cpp/include/capnp/capability.h b/phonelibs/capnp-cpp/include/capnp/capability.h new file mode 100644 index 00000000000000..56a5e6f6de2d38 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/capability.h @@ -0,0 +1,884 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_CAPABILITY_H_ +#define CAPNP_CAPABILITY_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#if CAPNP_LITE +#error "RPC APIs, including this header, are not available in lite mode." +#endif + +#include +#include +#include "raw-schema.h" +#include "any.h" +#include "pointer-helpers.h" + +namespace capnp { + +template +class Response; + +template +class RemotePromise: public kj::Promise>, public T::Pipeline { + // A Promise which supports pipelined calls. T is typically a struct type. T must declare + // an inner "mix-in" type "Pipeline" which implements pipelining; RemotePromise simply + // multiply-inherits that type along with Promise>. T::Pipeline must be movable, + // but does not need to be copyable (i.e. just like Promise). + // + // The promise is for an owned pointer so that the RPC system can allocate the MessageReader + // itself. + +public: + inline RemotePromise(kj::Promise>&& promise, typename T::Pipeline&& pipeline) + : kj::Promise>(kj::mv(promise)), + T::Pipeline(kj::mv(pipeline)) {} + inline RemotePromise(decltype(nullptr)) + : kj::Promise>(nullptr), + T::Pipeline(nullptr) {} + KJ_DISALLOW_COPY(RemotePromise); + RemotePromise(RemotePromise&& other) = default; + RemotePromise& operator=(RemotePromise&& other) = default; +}; + +class LocalClient; +namespace _ { // private +extern const RawSchema NULL_INTERFACE_SCHEMA; // defined in schema.c++ +class CapabilityServerSetBase; +} // namespace _ (private) + +struct Capability { + // A capability without type-safe methods. Typed capability clients wrap `Client` and typed + // capability servers subclass `Server` to dispatch to the regular, typed methods. + + class Client; + class Server; + + struct _capnpPrivate { + struct IsInterface; + static constexpr uint64_t typeId = 0x3; + static constexpr Kind kind = Kind::INTERFACE; + static constexpr _::RawSchema const* schema = &_::NULL_INTERFACE_SCHEMA; + + static const _::RawBrandedSchema* brand() { + return &_::NULL_INTERFACE_SCHEMA.defaultBrand; + } + }; +}; + +// ======================================================================================= +// Capability clients + +class RequestHook; +class ResponseHook; +class PipelineHook; +class ClientHook; + +template +class Request: public Params::Builder { + // A call that hasn't been sent yet. This class extends a Builder for the call's "Params" + // structure with a method send() that actually sends it. + // + // Given a Cap'n Proto method `foo(a :A, b :B): C`, the generated client interface will have + // a method `Request fooRequest()` (as well as a convenience method + // `RemotePromise foo(A::Reader a, B::Reader b)`). + +public: + inline Request(typename Params::Builder builder, kj::Own&& hook) + : Params::Builder(builder), hook(kj::mv(hook)) {} + inline Request(decltype(nullptr)): Params::Builder(nullptr) {} + + RemotePromise send() KJ_WARN_UNUSED_RESULT; + // Send the call and return a promise for the results. + +private: + kj::Own hook; + + friend class Capability::Client; + friend struct DynamicCapability; + template + friend class CallContext; + friend class RequestHook; +}; + +template +class Response: public Results::Reader { + // A completed call. This class extends a Reader for the call's answer structure. The Response + // is move-only -- once it goes out-of-scope, the underlying message will be freed. + +public: + inline Response(typename Results::Reader reader, kj::Own&& hook) + : Results::Reader(reader), hook(kj::mv(hook)) {} + +private: + kj::Own hook; + + template + friend class Request; + friend class ResponseHook; +}; + +class Capability::Client { + // Base type for capability clients. + +public: + typedef Capability Reads; + typedef Capability Calls; + + Client(decltype(nullptr)); + // If you need to declare a Client before you have anything to assign to it (perhaps because + // the assignment is going to occur in an if/else scope), you can start by initializing it to + // `nullptr`. The resulting client is not meant to be called and throws exceptions from all + // methods. + + template ()>> + Client(kj::Own&& server); + // Make a client capability that wraps the given server capability. The server's methods will + // only be executed in the given EventLoop, regardless of what thread calls the client's methods. + + template ()>> + Client(kj::Promise&& promise); + // Make a client from a promise for a future client. The resulting client queues calls until the + // promise resolves. + + Client(kj::Exception&& exception); + // Make a broken client that throws the given exception from all calls. + + Client(Client& other); + Client& operator=(Client& other); + // Copies by reference counting. Warning: This refcounting is not thread-safe. All copies of + // the client must remain in one thread. + + Client(Client&&) = default; + Client& operator=(Client&&) = default; + // Move constructor avoids reference counting. + + explicit Client(kj::Own&& hook); + // For use by the RPC implementation: Wrap a ClientHook. + + template + typename T::Client castAs(); + // Reinterpret the capability as implementing the given interface. Note that no error will occur + // here if the capability does not actually implement this interface, but later method calls will + // fail. It's up to the application to decide how indicate that additional interfaces are + // supported. + // + // TODO(perf): GCC 4.8 / Clang 3.3: rvalue-qualified version for better performance. + + template + typename T::Client castAs(InterfaceSchema schema); + // Dynamic version. `T` must be `DynamicCapability`, and you must `#include `. + + kj::Promise whenResolved(); + // If the capability is actually only a promise, the returned promise resolves once the + // capability itself has resolved to its final destination (or propagates the exception if + // the capability promise is rejected). This is mainly useful for error-checking in the case + // where no calls are being made. There is no reason to wait for this before making calls; if + // the capability does not resolve, the call results will propagate the error. + + Request typelessRequest( + uint64_t interfaceId, uint16_t methodId, + kj::Maybe sizeHint); + // Make a request without knowing the types of the params or results. You specify the type ID + // and method number manually. + + // TODO(someday): method(s) for Join + +protected: + Client() = default; + + template + Request newCall(uint64_t interfaceId, uint16_t methodId, + kj::Maybe sizeHint); + +private: + kj::Own hook; + + static kj::Own makeLocalClient(kj::Own&& server); + + template + friend struct _::PointerHelpers; + friend struct DynamicCapability; + friend class Orphanage; + friend struct DynamicStruct; + friend struct DynamicList; + template + friend struct List; + friend class _::CapabilityServerSetBase; + friend class ClientHook; +}; + +// ======================================================================================= +// Capability servers + +class CallContextHook; + +template +class CallContext: public kj::DisallowConstCopy { + // Wrapper around CallContextHook with a specific return type. + // + // Methods of this class may only be called from within the server's event loop, not from other + // threads. + // + // The CallContext becomes invalid as soon as the call reports completion. + +public: + explicit CallContext(CallContextHook& hook); + + typename Params::Reader getParams(); + // Get the params payload. + + void releaseParams(); + // Release the params payload. getParams() will throw an exception after this is called. + // Releasing the params may allow the RPC system to free up buffer space to handle other + // requests. Long-running asynchronous methods should try to call this as early as is + // convenient. + + typename Results::Builder getResults(kj::Maybe sizeHint = nullptr); + typename Results::Builder initResults(kj::Maybe sizeHint = nullptr); + void setResults(typename Results::Reader value); + void adoptResults(Orphan&& value); + Orphanage getResultsOrphanage(kj::Maybe sizeHint = nullptr); + // Manipulate the results payload. The "Return" message (part of the RPC protocol) will + // typically be allocated the first time one of these is called. Some RPC systems may + // allocate these messages in a limited space (such as a shared memory segment), therefore the + // application should delay calling these as long as is convenient to do so (but don't delay + // if doing so would require extra copies later). + // + // `sizeHint` indicates a guess at the message size. This will usually be used to decide how + // much space to allocate for the first message segment (don't worry: only space that is actually + // used will be sent on the wire). If omitted, the system decides. The message root pointer + // should not be included in the size. So, if you are simply going to copy some existing message + // directly into the results, just call `.totalSize()` and pass that in. + + template + kj::Promise tailCall(Request&& tailRequest); + // Resolve the call by making a tail call. `tailRequest` is a request that has been filled in + // but not yet sent. The context will send the call, then fill in the results with the result + // of the call. If tailCall() is used, {get,init,set,adopt}Results (above) *must not* be called. + // + // The RPC implementation may be able to optimize a tail call to another machine such that the + // results never actually pass through this machine. Even if no such optimization is possible, + // `tailCall()` may allow pipelined calls to be forwarded optimistically to the new call site. + // + // In general, this should be the last thing a method implementation calls, and the promise + // returned from `tailCall()` should then be returned by the method implementation. + + void allowCancellation(); + // Indicate that it is OK for the RPC system to discard its Promise for this call's result if + // the caller cancels the call, thereby transitively canceling any asynchronous operations the + // call implementation was performing. This is not done by default because it could represent a + // security risk: applications must be carefully written to ensure that they do not end up in + // a bad state if an operation is canceled at an arbitrary point. However, for long-running + // method calls that hold significant resources, prompt cancellation is often useful. + // + // Keep in mind that asynchronous cancellation cannot occur while the method is synchronously + // executing on a local thread. The method must perform an asynchronous operation or call + // `EventLoop::current().evalLater()` to yield control. + // + // Note: You might think that we should offer `onCancel()` and/or `isCanceled()` methods that + // provide notification when the caller cancels the request without forcefully killing off the + // promise chain. Unfortunately, this composes poorly with promise forking: the canceled + // path may be just one branch of a fork of the result promise. The other branches still want + // the call to continue. Promise forking is used within the Cap'n Proto implementation -- in + // particular each pipelined call forks the result promise. So, if a caller made a pipelined + // call and then dropped the original object, the call should not be canceled, but it would be + // excessively complicated for the framework to avoid notififying of cancellation as long as + // pipelined calls still exist. + +private: + CallContextHook* hook; + + friend class Capability::Server; + friend struct DynamicCapability; +}; + +class Capability::Server { + // Objects implementing a Cap'n Proto interface must subclass this. Typically, such objects + // will instead subclass a typed Server interface which will take care of implementing + // dispatchCall(). + +public: + typedef Capability Serves; + + virtual kj::Promise dispatchCall(uint64_t interfaceId, uint16_t methodId, + CallContext context) = 0; + // Call the given method. `params` is the input struct, and should be released as soon as it + // is no longer needed. `context` may be used to allocate the output struct and deal with + // cancellation. + + // TODO(someday): Method which can optionally be overridden to implement Join when the object is + // a proxy. + +protected: + inline Capability::Client thisCap(); + // Get a capability pointing to this object, much like the `this` keyword. + // + // The effect of this method is undefined if: + // - No capability client has been created pointing to this object. (This is always the case in + // the server's constructor.) + // - The capability client pointing at this object has been destroyed. (This is always the case + // in the server's destructor.) + // - Multiple capability clients have been created around the same server (possible if the server + // is refcounted, which is not recommended since the client itself provides refcounting). + + template + CallContext internalGetTypedContext( + CallContext typeless); + kj::Promise internalUnimplemented(const char* actualInterfaceName, + uint64_t requestedTypeId); + kj::Promise internalUnimplemented(const char* interfaceName, + uint64_t typeId, uint16_t methodId); + kj::Promise internalUnimplemented(const char* interfaceName, const char* methodName, + uint64_t typeId, uint16_t methodId); + +private: + ClientHook* thisHook = nullptr; + friend class LocalClient; +}; + +// ======================================================================================= + +class ReaderCapabilityTable: private _::CapTableReader { + // Class which imbues Readers with the ability to read capabilities. + // + // In Cap'n Proto format, the encoding of a capability pointer is simply an integer index into + // an external table. Since these pointers fundamentally point outside the message, a + // MessageReader by default has no idea what they point at, and therefore reading capabilities + // from such a reader will throw exceptions. + // + // In order to be able to read capabilities, you must first attach a capability table, using + // this class. By "imbuing" a Reader, you get a new Reader which will interpret capability + // pointers by treating them as indexes into the ReaderCapabilityTable. + // + // Note that when using Cap'n Proto's RPC system, this is handled automatically. + +public: + explicit ReaderCapabilityTable(kj::Array>> table); + KJ_DISALLOW_COPY(ReaderCapabilityTable); + + template + T imbue(T reader); + // Return a reader equivalent to `reader` except that when reading capability-valued fields, + // the capabilities are looked up in this table. + +private: + kj::Array>> table; + + kj::Maybe> extractCap(uint index) override; +}; + +class BuilderCapabilityTable: private _::CapTableBuilder { + // Class which imbues Builders with the ability to read and write capabilities. + // + // This is much like ReaderCapabilityTable, except for builders. The table starts out empty, + // but capabilities can be added to it over time. + +public: + BuilderCapabilityTable(); + KJ_DISALLOW_COPY(BuilderCapabilityTable); + + inline kj::ArrayPtr>> getTable() { return table; } + + template + T imbue(T builder); + // Return a builder equivalent to `builder` except that when reading capability-valued fields, + // the capabilities are looked up in this table. + +private: + kj::Vector>> table; + + kj::Maybe> extractCap(uint index) override; + uint injectCap(kj::Own&& cap) override; + void dropCap(uint index) override; +}; + +// ======================================================================================= + +namespace _ { // private + +class CapabilityServerSetBase { +public: + Capability::Client addInternal(kj::Own&& server, void* ptr); + kj::Promise getLocalServerInternal(Capability::Client& client); +}; + +} // namespace _ (private) + +template +class CapabilityServerSet: private _::CapabilityServerSetBase { + // Allows a server to recognize its own capabilities when passed back to it, and obtain the + // underlying Server objects associated with them. + // + // All objects in the set must have the same interface type T. The objects may implement various + // interfaces derived from T (and in fact T can be `capnp::Capability` to accept all objects), + // but note that if you compile with RTTI disabled then you will not be able to down-cast through + // virtual inheritance, and all inheritance between server interfaces is virtual. So, with RTTI + // disabled, you will likely need to set T to be the most-derived Cap'n Proto interface type, + // and you server class will need to be directly derived from that, so that you can use + // static_cast (or kj::downcast) to cast to it after calling getLocalServer(). (If you compile + // with RTTI, then you can freely dynamic_cast and ignore this issue!) + +public: + CapabilityServerSet() = default; + KJ_DISALLOW_COPY(CapabilityServerSet); + + typename T::Client add(kj::Own&& server); + // Create a new capability Client for the given Server and also add this server to the set. + + kj::Promise> getLocalServer(typename T::Client& client); + // Given a Client pointing to a server previously passed to add(), return the corresponding + // Server. This returns a promise because if the input client is itself a promise, this must + // wait for it to resolve. Keep in mind that the server will be deleted when all clients are + // gone, so the caller should make sure to keep the client alive (hence why this method only + // accepts an lvalue input). +}; + +// ======================================================================================= +// Hook interfaces which must be implemented by the RPC system. Applications never call these +// directly; the RPC system implements them and the types defined earlier in this file wrap them. + +class RequestHook { + // Hook interface implemented by RPC system representing a request being built. + +public: + virtual RemotePromise send() = 0; + // Send the call and return a promise for the result. + + virtual const void* getBrand() = 0; + // Returns a void* that identifies who made this request. This can be used by an RPC adapter to + // discover when tail call is going to be sent over its own connection and therefore can be + // optimized into a remote tail call. + + template + inline static kj::Own from(Request&& request) { + return kj::mv(request.hook); + } +}; + +class ResponseHook { + // Hook interface implemented by RPC system representing a response. + // + // At present this class has no methods. It exists only for garbage collection -- when the + // ResponseHook is destroyed, the results can be freed. + +public: + virtual ~ResponseHook() noexcept(false); + // Just here to make sure the type is dynamic. + + template + inline static kj::Own from(Response&& response) { + return kj::mv(response.hook); + } +}; + +// class PipelineHook is declared in any.h because it is needed there. + +class ClientHook { +public: + ClientHook(); + + virtual Request newCall( + uint64_t interfaceId, uint16_t methodId, kj::Maybe sizeHint) = 0; + // Start a new call, allowing the client to allocate request/response objects as it sees fit. + // This version is used when calls are made from application code in the local process. + + struct VoidPromiseAndPipeline { + kj::Promise promise; + kj::Own pipeline; + }; + + virtual VoidPromiseAndPipeline call(uint64_t interfaceId, uint16_t methodId, + kj::Own&& context) = 0; + // Call the object, but the caller controls allocation of the request/response objects. If the + // callee insists on allocating these objects itself, it must make a copy. This version is used + // when calls come in over the network via an RPC system. Note that even if the returned + // `Promise` is discarded, the call may continue executing if any pipelined calls are + // waiting for it. + // + // Since the caller of this method chooses the CallContext implementation, it is the caller's + // responsibility to ensure that the returned promise is not canceled unless allowed via + // the context's `allowCancellation()`. + // + // The call must not begin synchronously; the callee must arrange for the call to begin in a + // later turn of the event loop. Otherwise, application code may call back and affect the + // callee's state in an unexpected way. + + virtual kj::Maybe getResolved() = 0; + // If this ClientHook is a promise that has already resolved, returns the inner, resolved version + // of the capability. The caller may permanently replace this client with the resolved one if + // desired. Returns null if the client isn't a promise or hasn't resolved yet -- use + // `whenMoreResolved()` to distinguish between them. + + virtual kj::Maybe>> whenMoreResolved() = 0; + // If this client is a settled reference (not a promise), return nullptr. Otherwise, return a + // promise that eventually resolves to a new client that is closer to being the final, settled + // client (i.e. the value eventually returned by `getResolved()`). Calling this repeatedly + // should eventually produce a settled client. + + kj::Promise whenResolved(); + // Repeatedly calls whenMoreResolved() until it returns nullptr. + + virtual kj::Own addRef() = 0; + // Return a new reference to the same capability. + + virtual const void* getBrand() = 0; + // Returns a void* that identifies who made this client. This can be used by an RPC adapter to + // discover when a capability it needs to marshal is one that it created in the first place, and + // therefore it can transfer the capability without proxying. + + static const uint NULL_CAPABILITY_BRAND; + // Value is irrelevant; used for pointer. + + inline bool isNull() { return getBrand() == &NULL_CAPABILITY_BRAND; } + // Returns true if the capability was created as a result of assigning a Client to null or by + // reading a null pointer out of a Cap'n Proto message. + + virtual void* getLocalServer(_::CapabilityServerSetBase& capServerSet); + // If this is a local capability created through `capServerSet`, return the underlying Server. + // Otherwise, return nullptr. Default implementation (which everyone except LocalClient should + // use) always returns nullptr. + + static kj::Own from(Capability::Client client) { return kj::mv(client.hook); } +}; + +class CallContextHook { + // Hook interface implemented by RPC system to manage a call on the server side. See + // CallContext. + +public: + virtual AnyPointer::Reader getParams() = 0; + virtual void releaseParams() = 0; + virtual AnyPointer::Builder getResults(kj::Maybe sizeHint) = 0; + virtual kj::Promise tailCall(kj::Own&& request) = 0; + virtual void allowCancellation() = 0; + + virtual kj::Promise onTailCall() = 0; + // If `tailCall()` is called, resolves to the PipelineHook from the tail call. An + // implementation of `ClientHook::call()` is allowed to call this at most once. + + virtual ClientHook::VoidPromiseAndPipeline directTailCall(kj::Own&& request) = 0; + // Call this when you would otherwise call onTailCall() immediately followed by tailCall(). + // Implementations of tailCall() should typically call directTailCall() and then fulfill the + // promise fulfiller for onTailCall() with the returned pipeline. + + virtual kj::Own addRef() = 0; +}; + +kj::Own newLocalPromiseClient(kj::Promise>&& promise); +// Returns a ClientHook that queues up calls until `promise` resolves, then forwards them to +// the new client. This hook's `getResolved()` and `whenMoreResolved()` methods will reflect the +// redirection to the eventual replacement client. + +kj::Own newLocalPromisePipeline(kj::Promise>&& promise); +// Returns a PipelineHook that queues up calls until `promise` resolves, then forwards them to +// the new pipeline. + +kj::Own newBrokenCap(kj::StringPtr reason); +kj::Own newBrokenCap(kj::Exception&& reason); +// Helper function that creates a capability which simply throws exceptions when called. + +kj::Own newBrokenPipeline(kj::Exception&& reason); +// Helper function that creates a pipeline which simply throws exceptions when called. + +Request newBrokenRequest( + kj::Exception&& reason, kj::Maybe sizeHint); +// Helper function that creates a Request object that simply throws exceptions when sent. + +// ======================================================================================= +// Extend PointerHelpers for interfaces + +namespace _ { // private + +template +struct PointerHelpers { + static inline typename T::Client get(PointerReader reader) { + return typename T::Client(reader.getCapability()); + } + static inline typename T::Client get(PointerBuilder builder) { + return typename T::Client(builder.getCapability()); + } + static inline void set(PointerBuilder builder, typename T::Client&& value) { + builder.setCapability(kj::mv(value.Capability::Client::hook)); + } + static inline void set(PointerBuilder builder, typename T::Client& value) { + builder.setCapability(value.Capability::Client::hook->addRef()); + } + static inline void adopt(PointerBuilder builder, Orphan&& value) { + builder.adopt(kj::mv(value.builder)); + } + static inline Orphan disown(PointerBuilder builder) { + return Orphan(builder.disown()); + } +}; + +} // namespace _ (private) + +// ======================================================================================= +// Extend List for interfaces + +template +struct List { + List() = delete; + + class Reader { + public: + typedef List Reads; + + Reader() = default; + inline explicit Reader(_::ListReader reader): reader(reader) {} + + inline uint size() const { return unbound(reader.size() / ELEMENTS); } + inline typename T::Client operator[](uint index) const { + KJ_IREQUIRE(index < size()); + return typename T::Client(reader.getPointerElement( + bounded(index) * ELEMENTS).getCapability()); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + + private: + _::ListReader reader; + template + friend struct _::PointerHelpers; + template + friend struct List; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Builder { + public: + typedef List Builds; + + Builder() = delete; + inline Builder(decltype(nullptr)) {} + inline explicit Builder(_::ListBuilder builder): builder(builder) {} + + inline operator Reader() const { return Reader(builder.asReader()); } + inline Reader asReader() const { return Reader(builder.asReader()); } + + inline uint size() const { return unbound(builder.size() / ELEMENTS); } + inline typename T::Client operator[](uint index) { + KJ_IREQUIRE(index < size()); + return typename T::Client(builder.getPointerElement( + bounded(index) * ELEMENTS).getCapability()); + } + inline void set(uint index, typename T::Client value) { + KJ_IREQUIRE(index < size()); + builder.getPointerElement(bounded(index) * ELEMENTS).setCapability(kj::mv(value.hook)); + } + inline void adopt(uint index, Orphan&& value) { + KJ_IREQUIRE(index < size()); + builder.getPointerElement(bounded(index) * ELEMENTS).adopt(kj::mv(value)); + } + inline Orphan disown(uint index) { + KJ_IREQUIRE(index < size()); + return Orphan(builder.getPointerElement(bounded(index) * ELEMENTS).disown()); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() { return Iterator(this, 0); } + inline Iterator end() { return Iterator(this, size()); } + + private: + _::ListBuilder builder; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + +private: + inline static _::ListBuilder initPointer(_::PointerBuilder builder, uint size) { + return builder.initList(ElementSize::POINTER, bounded(size) * ELEMENTS); + } + inline static _::ListBuilder getFromPointer(_::PointerBuilder builder, const word* defaultValue) { + return builder.getList(ElementSize::POINTER, defaultValue); + } + inline static _::ListReader getFromPointer( + const _::PointerReader& reader, const word* defaultValue) { + return reader.getList(ElementSize::POINTER, defaultValue); + } + + template + friend struct List; + template + friend struct _::PointerHelpers; +}; + +// ======================================================================================= +// Inline implementation details + +template +RemotePromise Request::send() { + auto typelessPromise = hook->send(); + hook = nullptr; // prevent reuse + + // Convert the Promise to return the correct response type. + // Explicitly upcast to kj::Promise to make clear that calling .then() doesn't invalidate the + // Pipeline part of the RemotePromise. + auto typedPromise = kj::implicitCast>&>(typelessPromise) + .then([](Response&& response) -> Response { + return Response(response.getAs(), kj::mv(response.hook)); + }); + + // Wrap the typeless pipeline in a typed wrapper. + typename Results::Pipeline typedPipeline( + kj::mv(kj::implicitCast(typelessPromise))); + + return RemotePromise(kj::mv(typedPromise), kj::mv(typedPipeline)); +} + +inline Capability::Client::Client(kj::Own&& hook): hook(kj::mv(hook)) {} +template +inline Capability::Client::Client(kj::Own&& server) + : hook(makeLocalClient(kj::mv(server))) {} +template +inline Capability::Client::Client(kj::Promise&& promise) + : hook(newLocalPromiseClient(promise.then([](T&& t) { return kj::mv(t.hook); }))) {} +inline Capability::Client::Client(Client& other): hook(other.hook->addRef()) {} +inline Capability::Client& Capability::Client::operator=(Client& other) { + hook = other.hook->addRef(); + return *this; +} +template +inline typename T::Client Capability::Client::castAs() { + return typename T::Client(hook->addRef()); +} +inline kj::Promise Capability::Client::whenResolved() { + return hook->whenResolved(); +} +inline Request Capability::Client::typelessRequest( + uint64_t interfaceId, uint16_t methodId, + kj::Maybe sizeHint) { + return newCall(interfaceId, methodId, sizeHint); +} +template +inline Request Capability::Client::newCall( + uint64_t interfaceId, uint16_t methodId, kj::Maybe sizeHint) { + auto typeless = hook->newCall(interfaceId, methodId, sizeHint); + return Request(typeless.template getAs(), kj::mv(typeless.hook)); +} + +template +inline CallContext::CallContext(CallContextHook& hook): hook(&hook) {} +template +inline typename Params::Reader CallContext::getParams() { + return hook->getParams().template getAs(); +} +template +inline void CallContext::releaseParams() { + hook->releaseParams(); +} +template +inline typename Results::Builder CallContext::getResults( + kj::Maybe sizeHint) { + // `template` keyword needed due to: http://llvm.org/bugs/show_bug.cgi?id=17401 + return hook->getResults(sizeHint).template getAs(); +} +template +inline typename Results::Builder CallContext::initResults( + kj::Maybe sizeHint) { + // `template` keyword needed due to: http://llvm.org/bugs/show_bug.cgi?id=17401 + return hook->getResults(sizeHint).template initAs(); +} +template +inline void CallContext::setResults(typename Results::Reader value) { + hook->getResults(value.totalSize()).template setAs(value); +} +template +inline void CallContext::adoptResults(Orphan&& value) { + hook->getResults(nullptr).adopt(kj::mv(value)); +} +template +inline Orphanage CallContext::getResultsOrphanage( + kj::Maybe sizeHint) { + return Orphanage::getForMessageContaining(hook->getResults(sizeHint)); +} +template +template +inline kj::Promise CallContext::tailCall( + Request&& tailRequest) { + return hook->tailCall(kj::mv(tailRequest.hook)); +} +template +inline void CallContext::allowCancellation() { + hook->allowCancellation(); +} + +template +CallContext Capability::Server::internalGetTypedContext( + CallContext typeless) { + return CallContext(*typeless.hook); +} + +Capability::Client Capability::Server::thisCap() { + return Client(thisHook->addRef()); +} + +template +T ReaderCapabilityTable::imbue(T reader) { + return T(_::PointerHelpers>::getInternalReader(reader).imbue(this)); +} + +template +T BuilderCapabilityTable::imbue(T builder) { + return T(_::PointerHelpers>::getInternalBuilder(kj::mv(builder)).imbue(this)); +} + +template +typename T::Client CapabilityServerSet::add(kj::Own&& server) { + void* ptr = reinterpret_cast(server.get()); + // Clang insists that `castAs` is a template-dependent member and therefore we need the + // `template` keyword here, but AFAICT this is wrong: addImpl() is not a template. + return addInternal(kj::mv(server), ptr).template castAs(); +} + +template +kj::Promise> CapabilityServerSet::getLocalServer( + typename T::Client& client) { + return getLocalServerInternal(client) + .then([](void* server) -> kj::Maybe { + if (server == nullptr) { + return nullptr; + } else { + return *reinterpret_cast(server); + } + }); +} + +template +struct Orphanage::GetInnerReader { + static inline kj::Own apply(typename T::Client t) { + return ClientHook::from(kj::mv(t)); + } +}; + +} // namespace capnp + +#endif // CAPNP_CAPABILITY_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/common.h b/phonelibs/capnp-cpp/include/capnp/common.h new file mode 100644 index 00000000000000..3fc7a421124026 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/common.h @@ -0,0 +1,723 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file contains types which are intended to help detect incorrect usage at compile +// time, but should then be optimized down to basic primitives (usually, integers) by the +// compiler. + +#ifndef CAPNP_COMMON_H_ +#define CAPNP_COMMON_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include +#include +#include + +#if CAPNP_DEBUG_TYPES +#include +#endif + +namespace capnp { + +#define CAPNP_VERSION_MAJOR 0 +#define CAPNP_VERSION_MINOR 6 +#define CAPNP_VERSION_MICRO 1 + +#define CAPNP_VERSION \ + (CAPNP_VERSION_MAJOR * 1000000 + CAPNP_VERSION_MINOR * 1000 + CAPNP_VERSION_MICRO) + +#ifndef CAPNP_LITE +#define CAPNP_LITE 0 +#endif + +typedef unsigned int uint; + +struct Void { + // Type used for Void fields. Using C++'s "void" type creates a bunch of issues since it behaves + // differently from other types. + + inline constexpr bool operator==(Void other) const { return true; } + inline constexpr bool operator!=(Void other) const { return false; } +}; + +static constexpr Void VOID = Void(); +// Constant value for `Void`, which is an empty struct. + +inline kj::StringPtr KJ_STRINGIFY(Void) { return "void"; } + +struct Text; +struct Data; + +enum class Kind: uint8_t { + PRIMITIVE, + BLOB, + ENUM, + STRUCT, + UNION, + INTERFACE, + LIST, + + OTHER + // Some other type which is often a type parameter to Cap'n Proto templates, but which needs + // special handling. This includes types like AnyPointer, Dynamic*, etc. +}; + +enum class Style: uint8_t { + PRIMITIVE, + POINTER, // other than struct + STRUCT, + CAPABILITY +}; + +enum class ElementSize: uint8_t { + // Size of a list element. + + VOID = 0, + BIT = 1, + BYTE = 2, + TWO_BYTES = 3, + FOUR_BYTES = 4, + EIGHT_BYTES = 5, + + POINTER = 6, + + INLINE_COMPOSITE = 7 +}; + +enum class PointerType { + // Various wire types a pointer field can take + + NULL_, + // Should be NULL, but that's #defined in stddef.h + + STRUCT, + LIST, + CAPABILITY +}; + +namespace schemas { + +template +struct EnumInfo; + +} // namespace schemas + +namespace _ { // private + +template struct Kind_; + +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::PRIMITIVE; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::BLOB; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::BLOB; }; + +template struct Kind_> { + static constexpr Kind kind = Kind::STRUCT; +}; +template struct Kind_> { + static constexpr Kind kind = Kind::INTERFACE; +}; +template struct Kind_::IsEnum>> { + static constexpr Kind kind = Kind::ENUM; +}; + +} // namespace _ (private) + +template ::kind> +inline constexpr Kind kind() { + // This overload of kind() matches types which have a Kind_ specialization. + + return k; +} + +#if _MSC_VER + +#define CAPNP_KIND(T) ::capnp::_::Kind_::kind +// Avoid constexpr methods in MSVC (it remains buggy in many situations). + +#else // _MSC_VER + +#define CAPNP_KIND(T) ::capnp::kind() +// Use this macro rather than kind() in any code which must work in MSVC. + +#endif // _MSC_VER, else + +#if !CAPNP_LITE + +template ()> +inline constexpr Style style() { + return k == Kind::PRIMITIVE || k == Kind::ENUM ? Style::PRIMITIVE + : k == Kind::STRUCT ? Style::STRUCT + : k == Kind::INTERFACE ? Style::CAPABILITY : Style::POINTER; +} + +#endif // !CAPNP_LITE + +template +struct List; + +#if _MSC_VER + +template +struct List {}; +// For some reason, without this declaration, MSVC will error out on some uses of List +// claiming that "T" -- as used in the default initializer for the second template param, "k" -- +// is not defined. I do not understand this error, but adding this empty default declaration fixes +// it. + +#endif + +template struct ListElementType_; +template struct ListElementType_> { typedef T Type; }; +template using ListElementType = typename ListElementType_::Type; + +namespace _ { // private +template struct Kind_> { + static constexpr Kind kind = Kind::LIST; +}; +} // namespace _ (private) + +template struct ReaderFor_ { typedef typename T::Reader Type; }; +template struct ReaderFor_ { typedef T Type; }; +template struct ReaderFor_ { typedef T Type; }; +template struct ReaderFor_ { typedef typename T::Client Type; }; +template using ReaderFor = typename ReaderFor_::Type; +// The type returned by List::Reader::operator[]. + +template struct BuilderFor_ { typedef typename T::Builder Type; }; +template struct BuilderFor_ { typedef T Type; }; +template struct BuilderFor_ { typedef T Type; }; +template struct BuilderFor_ { typedef typename T::Client Type; }; +template using BuilderFor = typename BuilderFor_::Type; +// The type returned by List::Builder::operator[]. + +template struct PipelineFor_ { typedef typename T::Pipeline Type;}; +template struct PipelineFor_ { typedef typename T::Client Type; }; +template using PipelineFor = typename PipelineFor_::Type; + +template struct TypeIfEnum_; +template struct TypeIfEnum_ { typedef T Type; }; + +template +using TypeIfEnum = typename TypeIfEnum_>::Type; + +template +using FromReader = typename kj::Decay::Reads; +// FromReader = MyType (for any Cap'n Proto type). + +template +using FromBuilder = typename kj::Decay::Builds; +// FromBuilder = MyType (for any Cap'n Proto type). + +template +using FromPipeline = typename kj::Decay::Pipelines; +// FromBuilder = MyType (for any Cap'n Proto type). + +template +using FromClient = typename kj::Decay::Calls; +// FromReader = MyType (for any Cap'n Proto interface type). + +template +using FromServer = typename kj::Decay::Serves; +// FromBuilder = MyType (for any Cap'n Proto interface type). + +template +struct FromAny_; + +template +struct FromAny_>> { + using Type = FromReader; +}; + +template +struct FromAny_>> { + using Type = FromBuilder; +}; + +template +struct FromAny_>> { + using Type = FromPipeline; +}; + +// Note that T::Client is covered by FromReader + +template +struct FromAny_, kj::VoidSfinae>> { + using Type = FromServer; +}; + +template +struct FromAny_::kind == Kind::PRIMITIVE || _::Kind_::kind == Kind::ENUM>> { + // TODO(msvc): Ideally the EnableIf condition would be `style() == Style::PRIMITIVE`, but MSVC + // cannot yet use style() in this constexpr context. + + using Type = kj::Decay; +}; + +template +using FromAny = typename FromAny_::Type; +// Given any Cap'n Proto value type as an input, return the Cap'n Proto base type. That is: +// +// Foo::Reader -> Foo +// Foo::Builder -> Foo +// Foo::Pipeline -> Foo +// Foo::Client -> Foo +// Own -> Foo +// uint32_t -> uint32_t + +namespace _ { // private + +template +struct PointerHelpers; + +#if _MSC_VER + +template +struct PointerHelpers {}; +// For some reason, without this declaration, MSVC will error out on some uses of PointerHelpers +// claiming that "T" -- as used in the default initializer for the second template param, "k" -- +// is not defined. I do not understand this error, but adding this empty default declaration fixes +// it. + +#endif + +} // namespace _ (private) + +struct MessageSize { + // Size of a message. Every struct type has a method `.totalSize()` that returns this. + uint64_t wordCount; + uint capCount; +}; + +// ======================================================================================= +// Raw memory types and measures + +using kj::byte; + +class word { uint64_t content KJ_UNUSED_MEMBER; KJ_DISALLOW_COPY(word); public: word() = default; }; +// word is an opaque type with size of 64 bits. This type is useful only to make pointer +// arithmetic clearer. Since the contents are private, the only way to access them is to first +// reinterpret_cast to some other pointer type. +// +// Copying is disallowed because you should always use memcpy(). Otherwise, you may run afoul of +// aliasing rules. +// +// A pointer of type word* should always be word-aligned even if won't actually be dereferenced as +// that type. + +static_assert(sizeof(byte) == 1, "uint8_t is not one byte?"); +static_assert(sizeof(word) == 8, "uint64_t is not 8 bytes?"); + +#if CAPNP_DEBUG_TYPES +// Set CAPNP_DEBUG_TYPES to 1 to use kj::Quantity for "count" types. Otherwise, plain integers are +// used. All the code should still operate exactly the same, we just lose compile-time checking. +// Note that this will also change symbol names, so it's important that the library and any clients +// be compiled with the same setting here. +// +// We disable this by default to reduce symbol name size and avoid any possibility of the compiler +// failing to fully-optimize the types, but anyone modifying Cap'n Proto itself should enable this +// during development and testing. + +namespace _ { class BitLabel; class ElementLabel; struct WirePointer; } + +template +using BitCountN = kj::Quantity(), T>, _::BitLabel>; +template +using ByteCountN = kj::Quantity(), T>, byte>; +template +using WordCountN = kj::Quantity(), T>, word>; +template +using ElementCountN = kj::Quantity(), T>, _::ElementLabel>; +template +using WirePointerCountN = kj::Quantity(), T>, _::WirePointer>; + +typedef BitCountN<8, uint8_t> BitCount8; +typedef BitCountN<16, uint16_t> BitCount16; +typedef BitCountN<32, uint32_t> BitCount32; +typedef BitCountN<64, uint64_t> BitCount64; +typedef BitCountN BitCount; + +typedef ByteCountN<8, uint8_t> ByteCount8; +typedef ByteCountN<16, uint16_t> ByteCount16; +typedef ByteCountN<32, uint32_t> ByteCount32; +typedef ByteCountN<64, uint64_t> ByteCount64; +typedef ByteCountN ByteCount; + +typedef WordCountN<8, uint8_t> WordCount8; +typedef WordCountN<16, uint16_t> WordCount16; +typedef WordCountN<32, uint32_t> WordCount32; +typedef WordCountN<64, uint64_t> WordCount64; +typedef WordCountN WordCount; + +typedef ElementCountN<8, uint8_t> ElementCount8; +typedef ElementCountN<16, uint16_t> ElementCount16; +typedef ElementCountN<32, uint32_t> ElementCount32; +typedef ElementCountN<64, uint64_t> ElementCount64; +typedef ElementCountN ElementCount; + +typedef WirePointerCountN<8, uint8_t> WirePointerCount8; +typedef WirePointerCountN<16, uint16_t> WirePointerCount16; +typedef WirePointerCountN<32, uint32_t> WirePointerCount32; +typedef WirePointerCountN<64, uint64_t> WirePointerCount64; +typedef WirePointerCountN WirePointerCount; + +template +using BitsPerElementN = decltype(BitCountN() / ElementCountN()); +template +using BytesPerElementN = decltype(ByteCountN() / ElementCountN()); +template +using WordsPerElementN = decltype(WordCountN() / ElementCountN()); +template +using PointersPerElementN = decltype(WirePointerCountN() / ElementCountN()); + +using kj::bounded; +using kj::unbound; +using kj::unboundAs; +using kj::unboundMax; +using kj::unboundMaxBits; +using kj::assertMax; +using kj::assertMaxBits; +using kj::upgradeBound; +using kj::ThrowOverflow; +using kj::assumeBits; +using kj::assumeMax; +using kj::subtractChecked; +using kj::trySubtract; + +template +inline constexpr U* operator+(U* ptr, kj::Quantity offset) { + return ptr + unbound(offset / kj::unit>()); +} +template +inline constexpr const U* operator+(const U* ptr, kj::Quantity offset) { + return ptr + unbound(offset / kj::unit>()); +} +template +inline constexpr U* operator+=(U*& ptr, kj::Quantity offset) { + return ptr = ptr + unbound(offset / kj::unit>()); +} +template +inline constexpr const U* operator+=(const U*& ptr, kj::Quantity offset) { + return ptr = ptr + unbound(offset / kj::unit>()); +} + +template +inline constexpr U* operator-(U* ptr, kj::Quantity offset) { + return ptr - unbound(offset / kj::unit>()); +} +template +inline constexpr const U* operator-(const U* ptr, kj::Quantity offset) { + return ptr - unbound(offset / kj::unit>()); +} +template +inline constexpr U* operator-=(U*& ptr, kj::Quantity offset) { + return ptr = ptr - unbound(offset / kj::unit>()); +} +template +inline constexpr const U* operator-=(const U*& ptr, kj::Quantity offset) { + return ptr = ptr - unbound(offset / kj::unit>()); +} + +constexpr auto BITS = kj::unit>(); +constexpr auto BYTES = kj::unit>(); +constexpr auto WORDS = kj::unit>(); +constexpr auto ELEMENTS = kj::unit>(); +constexpr auto POINTERS = kj::unit>(); + +constexpr auto ZERO = kj::bounded<0>(); +constexpr auto ONE = kj::bounded<1>(); + +// GCC 4.7 actually gives unused warnings on these constants in opt mode... +constexpr auto BITS_PER_BYTE KJ_UNUSED = bounded<8>() * BITS / BYTES; +constexpr auto BITS_PER_WORD KJ_UNUSED = bounded<64>() * BITS / WORDS; +constexpr auto BYTES_PER_WORD KJ_UNUSED = bounded<8>() * BYTES / WORDS; + +constexpr auto BITS_PER_POINTER KJ_UNUSED = bounded<64>() * BITS / POINTERS; +constexpr auto BYTES_PER_POINTER KJ_UNUSED = bounded<8>() * BYTES / POINTERS; +constexpr auto WORDS_PER_POINTER KJ_UNUSED = ONE * WORDS / POINTERS; + +constexpr auto POINTER_SIZE_IN_WORDS = ONE * POINTERS * WORDS_PER_POINTER; + +constexpr uint SEGMENT_WORD_COUNT_BITS = 29; // Number of words in a segment. +constexpr uint LIST_ELEMENT_COUNT_BITS = 29; // Number of elements in a list. +constexpr uint STRUCT_DATA_WORD_COUNT_BITS = 16; // Number of words in a Struct data section. +constexpr uint STRUCT_POINTER_COUNT_BITS = 16; // Number of pointers in a Struct pointer section. +constexpr uint BLOB_SIZE_BITS = 29; // Number of bytes in a blob. + +typedef WordCountN SegmentWordCount; +typedef ElementCountN ListElementCount; +typedef WordCountN StructDataWordCount; +typedef WirePointerCountN StructPointerCount; +typedef ByteCountN BlobSize; + +constexpr auto MAX_SEGMENT_WORDS = + bounded()>() * WORDS; +constexpr auto MAX_LIST_ELEMENTS = + bounded()>() * ELEMENTS; +constexpr auto MAX_STUCT_DATA_WORDS = + bounded()>() * WORDS; +constexpr auto MAX_STRUCT_POINTER_COUNT = + bounded()>() * POINTERS; + +using StructDataBitCount = decltype(WordCountN() * BITS_PER_WORD); +// Number of bits in a Struct data segment (should come out to BitCountN<22>). + +using StructDataOffset = decltype(StructDataBitCount() * (ONE * ELEMENTS / BITS)); +using StructPointerOffset = StructPointerCount; +// Type of a field offset. + +inline StructDataOffset assumeDataOffset(uint32_t offset) { + return assumeMax(MAX_STUCT_DATA_WORDS * BITS_PER_WORD * (ONE * ELEMENTS / BITS), + bounded(offset) * ELEMENTS); +} + +inline StructPointerOffset assumePointerOffset(uint32_t offset) { + return assumeMax(MAX_STRUCT_POINTER_COUNT, bounded(offset) * POINTERS); +} + +constexpr uint MAX_TEXT_SIZE = kj::maxValueForBits() - 1; +typedef kj::Quantity, byte> TextSize; +// Not including NUL terminator. + +template +inline KJ_CONSTEXPR() decltype(bounded() * BYTES / ELEMENTS) bytesPerElement() { + return bounded() * BYTES / ELEMENTS; +} + +template +inline KJ_CONSTEXPR() decltype(bounded() * BITS / ELEMENTS) bitsPerElement() { + return bounded() * BITS / ELEMENTS; +} + +template +inline constexpr kj::Quantity, T> +intervalLength(const T* a, const T* b, kj::Quantity, T>) { + return kj::assumeMax(b - a) * kj::unit, T>>(); +} + +template +inline constexpr kj::ArrayPtr arrayPtr(const U* ptr, kj::Quantity size) { + return kj::ArrayPtr(ptr, unbound(size / kj::unit>())); +} +template +inline constexpr kj::ArrayPtr arrayPtr(U* ptr, kj::Quantity size) { + return kj::ArrayPtr(ptr, unbound(size / kj::unit>())); +} + +#else + +template +using BitCountN = T; +template +using ByteCountN = T; +template +using WordCountN = T; +template +using ElementCountN = T; +template +using WirePointerCountN = T; + + +// XXX +typedef BitCountN<8, uint8_t> BitCount8; +typedef BitCountN<16, uint16_t> BitCount16; +typedef BitCountN<32, uint32_t> BitCount32; +typedef BitCountN<64, uint64_t> BitCount64; +typedef BitCountN BitCount; + +typedef ByteCountN<8, uint8_t> ByteCount8; +typedef ByteCountN<16, uint16_t> ByteCount16; +typedef ByteCountN<32, uint32_t> ByteCount32; +typedef ByteCountN<64, uint64_t> ByteCount64; +typedef ByteCountN ByteCount; + +typedef WordCountN<8, uint8_t> WordCount8; +typedef WordCountN<16, uint16_t> WordCount16; +typedef WordCountN<32, uint32_t> WordCount32; +typedef WordCountN<64, uint64_t> WordCount64; +typedef WordCountN WordCount; + +typedef ElementCountN<8, uint8_t> ElementCount8; +typedef ElementCountN<16, uint16_t> ElementCount16; +typedef ElementCountN<32, uint32_t> ElementCount32; +typedef ElementCountN<64, uint64_t> ElementCount64; +typedef ElementCountN ElementCount; + +typedef WirePointerCountN<8, uint8_t> WirePointerCount8; +typedef WirePointerCountN<16, uint16_t> WirePointerCount16; +typedef WirePointerCountN<32, uint32_t> WirePointerCount32; +typedef WirePointerCountN<64, uint64_t> WirePointerCount64; +typedef WirePointerCountN WirePointerCount; + +template +using BitsPerElementN = decltype(BitCountN() / ElementCountN()); +template +using BytesPerElementN = decltype(ByteCountN() / ElementCountN()); +template +using WordsPerElementN = decltype(WordCountN() / ElementCountN()); +template +using PointersPerElementN = decltype(WirePointerCountN() / ElementCountN()); + +using kj::ThrowOverflow; +// YYY + +template inline constexpr uint bounded() { return i; } +template inline constexpr T bounded(T i) { return i; } +template inline constexpr T unbound(T i) { return i; } + +template inline constexpr T unboundAs(U i) { return i; } + +template inline constexpr uint unboundMax(T i) { return i; } +template inline constexpr uint unboundMaxBits(T i) { return i; } + +template +inline T assertMax(T value, ErrorFunc&& func) { + if (KJ_UNLIKELY(value > newMax)) func(); + return value; +} + +template +inline T assertMax(uint newMax, T value, ErrorFunc&& func) { + if (KJ_UNLIKELY(value > newMax)) func(); + return value; +} + +template +inline T assertMaxBits(T value, ErrorFunc&& func = ErrorFunc()) { + if (KJ_UNLIKELY(value > kj::maxValueForBits())) func(); + return value; +} + +template +inline T assertMaxBits(uint bits, T value, ErrorFunc&& func = ErrorFunc()) { + if (KJ_UNLIKELY(value > (1ull << bits) - 1)) func(); + return value; +} + +template inline constexpr T upgradeBound(U i) { return i; } + +template inline constexpr T assumeBits(T i) { return i; } +template inline constexpr T assumeMax(T i) { return i; } + +template +inline auto subtractChecked(T a, U b, ErrorFunc&& errorFunc = ErrorFunc()) + -> decltype(a - b) { + if (b > a) errorFunc(); + return a - b; +} + +template +inline auto trySubtract(T a, U b) -> kj::Maybe { + if (b > a) { + return nullptr; + } else { + return a - b; + } +} + +constexpr uint BITS = 1; +constexpr uint BYTES = 1; +constexpr uint WORDS = 1; +constexpr uint ELEMENTS = 1; +constexpr uint POINTERS = 1; + +constexpr uint ZERO = 0; +constexpr uint ONE = 1; + +// GCC 4.7 actually gives unused warnings on these constants in opt mode... +constexpr uint BITS_PER_BYTE KJ_UNUSED = 8; +constexpr uint BITS_PER_WORD KJ_UNUSED = 64; +constexpr uint BYTES_PER_WORD KJ_UNUSED = 8; + +constexpr uint BITS_PER_POINTER KJ_UNUSED = 64; +constexpr uint BYTES_PER_POINTER KJ_UNUSED = 8; +constexpr uint WORDS_PER_POINTER KJ_UNUSED = 1; + +// XXX +constexpr uint POINTER_SIZE_IN_WORDS = ONE * POINTERS * WORDS_PER_POINTER; + +constexpr uint SEGMENT_WORD_COUNT_BITS = 29; // Number of words in a segment. +constexpr uint LIST_ELEMENT_COUNT_BITS = 29; // Number of elements in a list. +constexpr uint STRUCT_DATA_WORD_COUNT_BITS = 16; // Number of words in a Struct data section. +constexpr uint STRUCT_POINTER_COUNT_BITS = 16; // Number of pointers in a Struct pointer section. +constexpr uint BLOB_SIZE_BITS = 29; // Number of bytes in a blob. + +typedef WordCountN SegmentWordCount; +typedef ElementCountN ListElementCount; +typedef WordCountN StructDataWordCount; +typedef WirePointerCountN StructPointerCount; +typedef ByteCountN BlobSize; +// YYY + +constexpr auto MAX_SEGMENT_WORDS = kj::maxValueForBits(); +constexpr auto MAX_LIST_ELEMENTS = kj::maxValueForBits(); +constexpr auto MAX_STUCT_DATA_WORDS = kj::maxValueForBits(); +constexpr auto MAX_STRUCT_POINTER_COUNT = kj::maxValueForBits(); + +typedef uint StructDataBitCount; +typedef uint StructDataOffset; +typedef uint StructPointerOffset; + +inline StructDataOffset assumeDataOffset(uint32_t offset) { return offset; } +inline StructPointerOffset assumePointerOffset(uint32_t offset) { return offset; } + +constexpr uint MAX_TEXT_SIZE = kj::maxValueForBits() - 1; +typedef uint TextSize; + +template +inline KJ_CONSTEXPR() size_t bytesPerElement() { return sizeof(T); } + +template +inline KJ_CONSTEXPR() size_t bitsPerElement() { return sizeof(T) * 8; } + +template +inline constexpr ptrdiff_t intervalLength(const T* a, const T* b, uint) { + return b - a; +} + +template +inline constexpr kj::ArrayPtr arrayPtr(const U* ptr, T size) { + return kj::arrayPtr(ptr, size); +} +template +inline constexpr kj::ArrayPtr arrayPtr(U* ptr, T size) { + return kj::arrayPtr(ptr, size); +} + +#endif + +} // namespace capnp + +#endif // CAPNP_COMMON_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/compat/json.capnp.h b/phonelibs/capnp-cpp/include/capnp/compat/json.capnp.h new file mode 100644 index 00000000000000..a8877e540b9f2a --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/compat/json.capnp.h @@ -0,0 +1,860 @@ +// Generated by Cap'n Proto compiler, DO NOT EDIT +// source: json.capnp + +#ifndef CAPNP_INCLUDED_8ef99297a43a5e34_ +#define CAPNP_INCLUDED_8ef99297a43a5e34_ + +#include +#if !CAPNP_LITE +#include +#endif // !CAPNP_LITE + +#if CAPNP_VERSION != 6001 +#error "Version mismatch between generated code and library headers. You must use the same version of the Cap'n Proto compiler and library." +#endif + + +namespace capnp { +namespace schemas { + +CAPNP_DECLARE_SCHEMA(8825ffaa852cda72); +CAPNP_DECLARE_SCHEMA(c27855d853a937cc); +CAPNP_DECLARE_SCHEMA(9bbf84153dd4bb60); + +} // namespace schemas +} // namespace capnp + +namespace capnp { + +struct JsonValue { + JsonValue() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + NULL_, + BOOLEAN, + NUMBER, + STRING, + ARRAY, + OBJECT, + CALL, + }; + struct Field; + struct Call; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(8825ffaa852cda72, 2, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct JsonValue::Field { + Field() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(c27855d853a937cc, 0, 2) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct JsonValue::Call { + Call() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9bbf84153dd4bb60, 0, 2) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +// ======================================================================================= + +class JsonValue::Reader { +public: + typedef JsonValue Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isNull() const; + inline ::capnp::Void getNull() const; + + inline bool isBoolean() const; + inline bool getBoolean() const; + + inline bool isNumber() const; + inline double getNumber() const; + + inline bool isString() const; + inline bool hasString() const; + inline ::capnp::Text::Reader getString() const; + + inline bool isArray() const; + inline bool hasArray() const; + inline ::capnp::List< ::capnp::JsonValue>::Reader getArray() const; + + inline bool isObject() const; + inline bool hasObject() const; + inline ::capnp::List< ::capnp::JsonValue::Field>::Reader getObject() const; + + inline bool isCall() const; + inline bool hasCall() const; + inline ::capnp::JsonValue::Call::Reader getCall() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class JsonValue::Builder { +public: + typedef JsonValue Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isNull(); + inline ::capnp::Void getNull(); + inline void setNull( ::capnp::Void value = ::capnp::VOID); + + inline bool isBoolean(); + inline bool getBoolean(); + inline void setBoolean(bool value); + + inline bool isNumber(); + inline double getNumber(); + inline void setNumber(double value); + + inline bool isString(); + inline bool hasString(); + inline ::capnp::Text::Builder getString(); + inline void setString( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initString(unsigned int size); + inline void adoptString(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownString(); + + inline bool isArray(); + inline bool hasArray(); + inline ::capnp::List< ::capnp::JsonValue>::Builder getArray(); + inline void setArray( ::capnp::List< ::capnp::JsonValue>::Reader value); + inline ::capnp::List< ::capnp::JsonValue>::Builder initArray(unsigned int size); + inline void adoptArray(::capnp::Orphan< ::capnp::List< ::capnp::JsonValue>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::JsonValue>> disownArray(); + + inline bool isObject(); + inline bool hasObject(); + inline ::capnp::List< ::capnp::JsonValue::Field>::Builder getObject(); + inline void setObject( ::capnp::List< ::capnp::JsonValue::Field>::Reader value); + inline ::capnp::List< ::capnp::JsonValue::Field>::Builder initObject(unsigned int size); + inline void adoptObject(::capnp::Orphan< ::capnp::List< ::capnp::JsonValue::Field>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::JsonValue::Field>> disownObject(); + + inline bool isCall(); + inline bool hasCall(); + inline ::capnp::JsonValue::Call::Builder getCall(); + inline void setCall( ::capnp::JsonValue::Call::Reader value); + inline ::capnp::JsonValue::Call::Builder initCall(); + inline void adoptCall(::capnp::Orphan< ::capnp::JsonValue::Call>&& value); + inline ::capnp::Orphan< ::capnp::JsonValue::Call> disownCall(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class JsonValue::Pipeline { +public: + typedef JsonValue Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class JsonValue::Field::Reader { +public: + typedef Field Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasName() const; + inline ::capnp::Text::Reader getName() const; + + inline bool hasValue() const; + inline ::capnp::JsonValue::Reader getValue() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class JsonValue::Field::Builder { +public: + typedef Field Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasName(); + inline ::capnp::Text::Builder getName(); + inline void setName( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initName(unsigned int size); + inline void adoptName(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownName(); + + inline bool hasValue(); + inline ::capnp::JsonValue::Builder getValue(); + inline void setValue( ::capnp::JsonValue::Reader value); + inline ::capnp::JsonValue::Builder initValue(); + inline void adoptValue(::capnp::Orphan< ::capnp::JsonValue>&& value); + inline ::capnp::Orphan< ::capnp::JsonValue> disownValue(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class JsonValue::Field::Pipeline { +public: + typedef Field Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::JsonValue::Pipeline getValue(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class JsonValue::Call::Reader { +public: + typedef Call Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasFunction() const; + inline ::capnp::Text::Reader getFunction() const; + + inline bool hasParams() const; + inline ::capnp::List< ::capnp::JsonValue>::Reader getParams() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class JsonValue::Call::Builder { +public: + typedef Call Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasFunction(); + inline ::capnp::Text::Builder getFunction(); + inline void setFunction( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initFunction(unsigned int size); + inline void adoptFunction(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownFunction(); + + inline bool hasParams(); + inline ::capnp::List< ::capnp::JsonValue>::Builder getParams(); + inline void setParams( ::capnp::List< ::capnp::JsonValue>::Reader value); + inline ::capnp::List< ::capnp::JsonValue>::Builder initParams(unsigned int size); + inline void adoptParams(::capnp::Orphan< ::capnp::List< ::capnp::JsonValue>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::JsonValue>> disownParams(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class JsonValue::Call::Pipeline { +public: + typedef Call Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +// ======================================================================================= + +inline ::capnp::JsonValue::Which JsonValue::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline ::capnp::JsonValue::Which JsonValue::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline bool JsonValue::Reader::isNull() const { + return which() == JsonValue::NULL_; +} +inline bool JsonValue::Builder::isNull() { + return which() == JsonValue::NULL_; +} +inline ::capnp::Void JsonValue::Reader::getNull() const { + KJ_IREQUIRE((which() == JsonValue::NULL_), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void JsonValue::Builder::getNull() { + KJ_IREQUIRE((which() == JsonValue::NULL_), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void JsonValue::Builder::setNull( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::NULL_); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool JsonValue::Reader::isBoolean() const { + return which() == JsonValue::BOOLEAN; +} +inline bool JsonValue::Builder::isBoolean() { + return which() == JsonValue::BOOLEAN; +} +inline bool JsonValue::Reader::getBoolean() const { + KJ_IREQUIRE((which() == JsonValue::BOOLEAN), + "Must check which() before get()ing a union member."); + return _reader.getDataField( + ::capnp::bounded<16>() * ::capnp::ELEMENTS); +} + +inline bool JsonValue::Builder::getBoolean() { + KJ_IREQUIRE((which() == JsonValue::BOOLEAN), + "Must check which() before get()ing a union member."); + return _builder.getDataField( + ::capnp::bounded<16>() * ::capnp::ELEMENTS); +} +inline void JsonValue::Builder::setBoolean(bool value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::BOOLEAN); + _builder.setDataField( + ::capnp::bounded<16>() * ::capnp::ELEMENTS, value); +} + +inline bool JsonValue::Reader::isNumber() const { + return which() == JsonValue::NUMBER; +} +inline bool JsonValue::Builder::isNumber() { + return which() == JsonValue::NUMBER; +} +inline double JsonValue::Reader::getNumber() const { + KJ_IREQUIRE((which() == JsonValue::NUMBER), + "Must check which() before get()ing a union member."); + return _reader.getDataField( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline double JsonValue::Builder::getNumber() { + KJ_IREQUIRE((which() == JsonValue::NUMBER), + "Must check which() before get()ing a union member."); + return _builder.getDataField( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void JsonValue::Builder::setNumber(double value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::NUMBER); + _builder.setDataField( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool JsonValue::Reader::isString() const { + return which() == JsonValue::STRING; +} +inline bool JsonValue::Builder::isString() { + return which() == JsonValue::STRING; +} +inline bool JsonValue::Reader::hasString() const { + if (which() != JsonValue::STRING) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool JsonValue::Builder::hasString() { + if (which() != JsonValue::STRING) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader JsonValue::Reader::getString() const { + KJ_IREQUIRE((which() == JsonValue::STRING), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder JsonValue::Builder::getString() { + KJ_IREQUIRE((which() == JsonValue::STRING), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void JsonValue::Builder::setString( ::capnp::Text::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::STRING); + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder JsonValue::Builder::initString(unsigned int size) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::STRING); + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void JsonValue::Builder::adoptString( + ::capnp::Orphan< ::capnp::Text>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::STRING); + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> JsonValue::Builder::disownString() { + KJ_IREQUIRE((which() == JsonValue::STRING), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool JsonValue::Reader::isArray() const { + return which() == JsonValue::ARRAY; +} +inline bool JsonValue::Builder::isArray() { + return which() == JsonValue::ARRAY; +} +inline bool JsonValue::Reader::hasArray() const { + if (which() != JsonValue::ARRAY) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool JsonValue::Builder::hasArray() { + if (which() != JsonValue::ARRAY) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::JsonValue>::Reader JsonValue::Reader::getArray() const { + KJ_IREQUIRE((which() == JsonValue::ARRAY), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::JsonValue>::Builder JsonValue::Builder::getArray() { + KJ_IREQUIRE((which() == JsonValue::ARRAY), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void JsonValue::Builder::setArray( ::capnp::List< ::capnp::JsonValue>::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::ARRAY); + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::JsonValue>::Builder JsonValue::Builder::initArray(unsigned int size) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::ARRAY); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void JsonValue::Builder::adoptArray( + ::capnp::Orphan< ::capnp::List< ::capnp::JsonValue>>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::ARRAY); + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::JsonValue>> JsonValue::Builder::disownArray() { + KJ_IREQUIRE((which() == JsonValue::ARRAY), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool JsonValue::Reader::isObject() const { + return which() == JsonValue::OBJECT; +} +inline bool JsonValue::Builder::isObject() { + return which() == JsonValue::OBJECT; +} +inline bool JsonValue::Reader::hasObject() const { + if (which() != JsonValue::OBJECT) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool JsonValue::Builder::hasObject() { + if (which() != JsonValue::OBJECT) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::JsonValue::Field>::Reader JsonValue::Reader::getObject() const { + KJ_IREQUIRE((which() == JsonValue::OBJECT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue::Field>>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::JsonValue::Field>::Builder JsonValue::Builder::getObject() { + KJ_IREQUIRE((which() == JsonValue::OBJECT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue::Field>>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void JsonValue::Builder::setObject( ::capnp::List< ::capnp::JsonValue::Field>::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::OBJECT); + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue::Field>>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::JsonValue::Field>::Builder JsonValue::Builder::initObject(unsigned int size) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::OBJECT); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue::Field>>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void JsonValue::Builder::adoptObject( + ::capnp::Orphan< ::capnp::List< ::capnp::JsonValue::Field>>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::OBJECT); + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue::Field>>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::JsonValue::Field>> JsonValue::Builder::disownObject() { + KJ_IREQUIRE((which() == JsonValue::OBJECT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue::Field>>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool JsonValue::Reader::isCall() const { + return which() == JsonValue::CALL; +} +inline bool JsonValue::Builder::isCall() { + return which() == JsonValue::CALL; +} +inline bool JsonValue::Reader::hasCall() const { + if (which() != JsonValue::CALL) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool JsonValue::Builder::hasCall() { + if (which() != JsonValue::CALL) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::JsonValue::Call::Reader JsonValue::Reader::getCall() const { + KJ_IREQUIRE((which() == JsonValue::CALL), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::JsonValue::Call>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::JsonValue::Call::Builder JsonValue::Builder::getCall() { + KJ_IREQUIRE((which() == JsonValue::CALL), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::JsonValue::Call>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void JsonValue::Builder::setCall( ::capnp::JsonValue::Call::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::CALL); + ::capnp::_::PointerHelpers< ::capnp::JsonValue::Call>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::JsonValue::Call::Builder JsonValue::Builder::initCall() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::CALL); + return ::capnp::_::PointerHelpers< ::capnp::JsonValue::Call>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void JsonValue::Builder::adoptCall( + ::capnp::Orphan< ::capnp::JsonValue::Call>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, JsonValue::CALL); + ::capnp::_::PointerHelpers< ::capnp::JsonValue::Call>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::JsonValue::Call> JsonValue::Builder::disownCall() { + KJ_IREQUIRE((which() == JsonValue::CALL), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::JsonValue::Call>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool JsonValue::Field::Reader::hasName() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool JsonValue::Field::Builder::hasName() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader JsonValue::Field::Reader::getName() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder JsonValue::Field::Builder::getName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void JsonValue::Field::Builder::setName( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder JsonValue::Field::Builder::initName(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void JsonValue::Field::Builder::adoptName( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> JsonValue::Field::Builder::disownName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool JsonValue::Field::Reader::hasValue() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool JsonValue::Field::Builder::hasValue() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::JsonValue::Reader JsonValue::Field::Reader::getValue() const { + return ::capnp::_::PointerHelpers< ::capnp::JsonValue>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::JsonValue::Builder JsonValue::Field::Builder::getValue() { + return ::capnp::_::PointerHelpers< ::capnp::JsonValue>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::JsonValue::Pipeline JsonValue::Field::Pipeline::getValue() { + return ::capnp::JsonValue::Pipeline(_typeless.getPointerField(1)); +} +#endif // !CAPNP_LITE +inline void JsonValue::Field::Builder::setValue( ::capnp::JsonValue::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::JsonValue>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::JsonValue::Builder JsonValue::Field::Builder::initValue() { + return ::capnp::_::PointerHelpers< ::capnp::JsonValue>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void JsonValue::Field::Builder::adoptValue( + ::capnp::Orphan< ::capnp::JsonValue>&& value) { + ::capnp::_::PointerHelpers< ::capnp::JsonValue>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::JsonValue> JsonValue::Field::Builder::disownValue() { + return ::capnp::_::PointerHelpers< ::capnp::JsonValue>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline bool JsonValue::Call::Reader::hasFunction() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool JsonValue::Call::Builder::hasFunction() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader JsonValue::Call::Reader::getFunction() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder JsonValue::Call::Builder::getFunction() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void JsonValue::Call::Builder::setFunction( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder JsonValue::Call::Builder::initFunction(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void JsonValue::Call::Builder::adoptFunction( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> JsonValue::Call::Builder::disownFunction() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool JsonValue::Call::Reader::hasParams() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool JsonValue::Call::Builder::hasParams() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::JsonValue>::Reader JsonValue::Call::Reader::getParams() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::JsonValue>::Builder JsonValue::Call::Builder::getParams() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void JsonValue::Call::Builder::setParams( ::capnp::List< ::capnp::JsonValue>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::JsonValue>::Builder JsonValue::Call::Builder::initParams(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), size); +} +inline void JsonValue::Call::Builder::adoptParams( + ::capnp::Orphan< ::capnp::List< ::capnp::JsonValue>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::JsonValue>> JsonValue::Call::Builder::disownParams() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::JsonValue>>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +} // namespace + +#endif // CAPNP_INCLUDED_8ef99297a43a5e34_ diff --git a/phonelibs/capnp-cpp/include/capnp/compat/json.h b/phonelibs/capnp-cpp/include/capnp/compat/json.h new file mode 100644 index 00000000000000..7fa815e0998e9e --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/compat/json.h @@ -0,0 +1,462 @@ +// Copyright (c) 2015 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_COMPAT_JSON_H_ +#define CAPNP_COMPAT_JSON_H_ + +#include +#include +#include + +namespace capnp { + +class JsonCodec { + // Flexible class for encoding Cap'n Proto types as JSON, and decoding JSON back to Cap'n Proto. + // + // Typical usage: + // + // JsonCodec json; + // + // // encode + // kj::String encoded = json.encode(someStructReader); + // + // // decode + // json.decode(encoded, someStructBuilder); + // + // Advanced users can do fancy things like override the way certain types or fields are + // represented in JSON by registering handlers. See the unit test for an example. + // + // Notes: + // - When encoding, all primitive fields are always encoded, even if default-valued. Pointer + // fields are only encoded if they are non-null. + // - 64-bit integers are encoded as strings, since JSON "numbers" are double-precision floating + // points which cannot store a 64-bit integer without losing data. + // - NaNs and infinite floating point numbers are not allowed by the JSON spec, and so are encoded + // as null. This matches the behavior of `JSON.stringify` in at least Firefox and Chrome. + // - Data is encoded as an array of numbers in the range [0,255]. You probably want to register + // a handler that does something better, like maybe base64 encoding, but there are a zillion + // different ways people do this. + // - Encoding/decoding capabilities and AnyPointers requires registering a Handler, since there's + // no obvious default behavior. + // - When decoding, unrecognized field names are ignored. Note: This means that JSON is NOT a + // good format for receiving input from a human. Consider `capnp eval` or the SchemaParser + // library for human input. + +public: + JsonCodec(); + ~JsonCodec() noexcept(false); + + // --------------------------------------------------------------------------- + // standard API + + void setPrettyPrint(bool enabled); + // Enable to insert newlines, indentation, and other extra spacing into the output. The default + // is to use minimal whitespace. + + void setMaxNestingDepth(size_t maxNestingDepth); + // Set maximum nesting depth when decoding JSON to prevent highly nested input from overflowing + // the call stack. The default is 64. + + template + kj::String encode(T&& value); + // Encode any Cap'n Proto value to JSON, including primitives and + // Dynamic{Enum,Struct,List,Capability}, but not DynamicValue (see below). + + kj::String encode(DynamicValue::Reader value, Type type) const; + // Encode a DynamicValue to JSON. `type` is needed because `DynamicValue` itself does + // not distinguish between e.g. int32 and int64, which in JSON are handled differently. Most + // of the time, though, you can use the single-argument templated version of `encode()` instead. + + void decode(kj::ArrayPtr input, DynamicStruct::Builder output) const; + // Decode JSON text directly into a struct builder. This only works for structs since lists + // need to be allocated with the correct size in advance. + // + // (Remember that any Cap'n Proto struct reader type can be implicitly cast to + // DynamicStruct::Reader.) + + template + Orphan decode(kj::ArrayPtr input, Orphanage orphanage) const; + // Decode JSON text to any Cap'n Proto object (pointer value), allocated using the given + // orphanage. T must be specified explicitly and cannot be dynamic, e.g.: + // + // Orphan orphan = json.decode(text, orphanage); + + template + ReaderFor decode(kj::ArrayPtr input) const; + // Decode JSON text into a primitive or capability value. T must be specified explicitly and + // cannot be dynamic, e.g.: + // + // uint32_t n = json.decode(text); + + Orphan decode(kj::ArrayPtr input, Type type, Orphanage orphanage) const; + Orphan decode( + kj::ArrayPtr input, ListSchema type, Orphanage orphanage) const; + Orphan decode( + kj::ArrayPtr input, StructSchema type, Orphanage orphanage) const; + DynamicCapability::Client decode(kj::ArrayPtr input, InterfaceSchema type) const; + DynamicEnum decode(kj::ArrayPtr input, EnumSchema type) const; + // Decode to a dynamic value, specifying the type schema. + + // --------------------------------------------------------------------------- + // layered API + // + // You can separate text <-> JsonValue from JsonValue <-> T. These are particularly useful + // for calling from Handler implementations. + + kj::String encodeRaw(JsonValue::Reader value) const; + void decodeRaw(kj::ArrayPtr input, JsonValue::Builder output) const; + // Translate JsonValue <-> text. + + template + void encode(T&& value, JsonValue::Builder output); + void encode(DynamicValue::Reader input, Type type, JsonValue::Builder output) const; + void decode(JsonValue::Reader input, DynamicStruct::Builder output) const; + template + Orphan decode(JsonValue::Reader input, Orphanage orphanage) const; + template + ReaderFor decode(JsonValue::Reader input) const; + + Orphan decode(JsonValue::Reader input, Type type, Orphanage orphanage) const; + Orphan decode(JsonValue::Reader input, ListSchema type, Orphanage orphanage) const; + Orphan decode( + JsonValue::Reader input, StructSchema type, Orphanage orphanage) const; + DynamicCapability::Client decode(JsonValue::Reader input, InterfaceSchema type) const; + DynamicEnum decode(JsonValue::Reader input, EnumSchema type) const; + + // --------------------------------------------------------------------------- + // specializing particular types + + template ()> + class Handler; + // Implement this interface to specify a special encoding for a particular type or field. + // + // The templates are a bit ugly, but subclasses of this type essentially implement two methods, + // one to encode values of this type and one to decode values of this type. `encode()` is simple: + // + // void encode(const JsonCodec& codec, ReaderFor input, JsonValue::Builder output) const; + // + // `decode()` is a bit trickier. When T is a struct (including DynamicStruct), it is: + // + // void decode(const JsonCodec& codec, JsonValue::Reader input, BuilderFor output) const; + // + // However, when T is a primitive, decode() is: + // + // T decode(const JsonCodec& codec, JsonValue::Reader input) const; + // + // Or when T is any non-struct object (list, blob), decode() is: + // + // Orphan decode(const JsonCodec& codec, JsonValue::Reader input, Orphanage orphanage) const; + // + // Or when T is an interface: + // + // T::Client decode(const JsonCodec& codec, JsonValue::Reader input) const; + // + // Additionally, when T is a struct you can *optionally* also implement the orphan-returning form + // of decode(), but it will only be called when the struct would be allocated as an individual + // object, not as part of a list. This allows you to return "nullptr" in these cases to say that + // the pointer value should be null. This does not apply to list elements because struct list + // elements cannot ever be null (since Cap'n Proto encodes struct lists as a flat list rather + // than list-of-pointers). + + template + void addTypeHandler(Handler& handler); + void addTypeHandler(Type type, Handler& handler); + void addTypeHandler(EnumSchema type, Handler& handler); + void addTypeHandler(StructSchema type, Handler& handler); + void addTypeHandler(ListSchema type, Handler& handler); + void addTypeHandler(InterfaceSchema type, Handler& handler); + // Arrange that whenever the type T appears in the message, your handler will be used to + // encode/decode it. + // + // Note that if you register a handler for a capability type, it will also apply to subtypes. + // Thus Handler handles all capabilities. + + template + void addFieldHandler(StructSchema::Field field, Handler& handler); + // Matches only the specific field. T can be a dynamic type. T must match the field's type. + +private: + class HandlerBase; + struct Impl; + + kj::Own impl; + + void encodeField(StructSchema::Field field, DynamicValue::Reader input, + JsonValue::Builder output) const; + void decodeArray(List::Reader input, DynamicList::Builder output) const; + void decodeObject(List::Reader input, DynamicStruct::Builder output) const; + void addTypeHandlerImpl(Type type, HandlerBase& handler); + void addFieldHandlerImpl(StructSchema::Field field, Type type, HandlerBase& handler); +}; + +// ======================================================================================= +// inline implementation details + +template +kj::String JsonCodec::encode(T&& value) { + typedef FromAny> Base; + return encode(DynamicValue::Reader(ReaderFor(kj::fwd(value))), Type::from()); +} + +template +inline Orphan JsonCodec::decode(kj::ArrayPtr input, Orphanage orphanage) const { + return decode(input, Type::from(), orphanage).template releaseAs(); +} + +template +inline ReaderFor JsonCodec::decode(kj::ArrayPtr input) const { + static_assert(style() == Style::PRIMITIVE || style() == Style::CAPABILITY, + "must specify an orphanage to decode an object type"); + return decode(input, Type::from(), Orphanage()).getReader().template as(); +} + +inline Orphan JsonCodec::decode( + kj::ArrayPtr input, ListSchema type, Orphanage orphanage) const { + return decode(input, Type(type), orphanage).releaseAs(); +} +inline Orphan JsonCodec::decode( + kj::ArrayPtr input, StructSchema type, Orphanage orphanage) const { + return decode(input, Type(type), orphanage).releaseAs(); +} +inline DynamicCapability::Client JsonCodec::decode( + kj::ArrayPtr input, InterfaceSchema type) const { + return decode(input, Type(type), Orphanage()).getReader().as(); +} +inline DynamicEnum JsonCodec::decode(kj::ArrayPtr input, EnumSchema type) const { + return decode(input, Type(type), Orphanage()).getReader().as(); +} + +// ----------------------------------------------------------------------------- + +template +void JsonCodec::encode(T&& value, JsonValue::Builder output) { + typedef FromAny> Base; + encode(DynamicValue::Reader(ReaderFor(kj::fwd(value))), Type::from(), output); +} + +template +inline Orphan JsonCodec::decode(JsonValue::Reader input, Orphanage orphanage) const { + return decode(input, Type::from(), orphanage).template releaseAs(); +} + +template +inline ReaderFor JsonCodec::decode(JsonValue::Reader input) const { + static_assert(style() == Style::PRIMITIVE || style() == Style::CAPABILITY, + "must specify an orphanage to decode an object type"); + return decode(input, Type::from(), Orphanage()).getReader().template as(); +} + +inline Orphan JsonCodec::decode( + JsonValue::Reader input, ListSchema type, Orphanage orphanage) const { + return decode(input, Type(type), orphanage).releaseAs(); +} +inline Orphan JsonCodec::decode( + JsonValue::Reader input, StructSchema type, Orphanage orphanage) const { + return decode(input, Type(type), orphanage).releaseAs(); +} +inline DynamicCapability::Client JsonCodec::decode( + JsonValue::Reader input, InterfaceSchema type) const { + return decode(input, Type(type), Orphanage()).getReader().as(); +} +inline DynamicEnum JsonCodec::decode(JsonValue::Reader input, EnumSchema type) const { + return decode(input, Type(type), Orphanage()).getReader().as(); +} + +// ----------------------------------------------------------------------------- + +class JsonCodec::HandlerBase { + // Internal helper; ignore. +public: + virtual void encodeBase(const JsonCodec& codec, DynamicValue::Reader input, + JsonValue::Builder output) const = 0; + virtual Orphan decodeBase(const JsonCodec& codec, JsonValue::Reader input, + Type type, Orphanage orphanage) const; + virtual void decodeStructBase(const JsonCodec& codec, JsonValue::Reader input, + DynamicStruct::Builder output) const; +}; + +template +class JsonCodec::Handler: private JsonCodec::HandlerBase { +public: + virtual void encode(const JsonCodec& codec, ReaderFor input, + JsonValue::Builder output) const = 0; + virtual Orphan decode(const JsonCodec& codec, JsonValue::Reader input, + Orphanage orphanage) const = 0; + +private: + void encodeBase(const JsonCodec& codec, DynamicValue::Reader input, + JsonValue::Builder output) const override final { + encode(codec, input.as(), output); + } + Orphan decodeBase(const JsonCodec& codec, JsonValue::Reader input, + Type type, Orphanage orphanage) const override final { + return decode(codec, input, orphanage); + } + friend class JsonCodec; +}; + +template +class JsonCodec::Handler: private JsonCodec::HandlerBase { +public: + virtual void encode(const JsonCodec& codec, ReaderFor input, + JsonValue::Builder output) const = 0; + virtual void decode(const JsonCodec& codec, JsonValue::Reader input, + BuilderFor output) const = 0; + virtual Orphan decode(const JsonCodec& codec, JsonValue::Reader input, + Orphanage orphanage) const { + // If subclass does not override, fall back to regular version. + auto result = orphanage.newOrphan(); + decode(codec, input, result.get()); + return result; + } + +private: + void encodeBase(const JsonCodec& codec, DynamicValue::Reader input, + JsonValue::Builder output) const override final { + encode(codec, input.as(), output); + } + Orphan decodeBase(const JsonCodec& codec, JsonValue::Reader input, + Type type, Orphanage orphanage) const override final { + return decode(codec, input, orphanage); + } + void decodeStructBase(const JsonCodec& codec, JsonValue::Reader input, + DynamicStruct::Builder output) const override final { + decode(codec, input, output.as()); + } + friend class JsonCodec; +}; + +template <> +class JsonCodec::Handler: private JsonCodec::HandlerBase { + // Almost identical to Style::STRUCT except that we pass the struct type to decode(). + +public: + virtual void encode(const JsonCodec& codec, DynamicStruct::Reader input, + JsonValue::Builder output) const = 0; + virtual void decode(const JsonCodec& codec, JsonValue::Reader input, + DynamicStruct::Builder output) const = 0; + virtual Orphan decode(const JsonCodec& codec, JsonValue::Reader input, + StructSchema type, Orphanage orphanage) const { + // If subclass does not override, fall back to regular version. + auto result = orphanage.newOrphan(type); + decode(codec, input, result.get()); + return result; + } + +private: + void encodeBase(const JsonCodec& codec, DynamicValue::Reader input, + JsonValue::Builder output) const override final { + encode(codec, input.as(), output); + } + Orphan decodeBase(const JsonCodec& codec, JsonValue::Reader input, + Type type, Orphanage orphanage) const override final { + return decode(codec, input, type.asStruct(), orphanage); + } + void decodeStructBase(const JsonCodec& codec, JsonValue::Reader input, + DynamicStruct::Builder output) const override final { + decode(codec, input, output.as()); + } + friend class JsonCodec; +}; + +template +class JsonCodec::Handler: private JsonCodec::HandlerBase { +public: + virtual void encode(const JsonCodec& codec, T input, JsonValue::Builder output) const = 0; + virtual T decode(const JsonCodec& codec, JsonValue::Reader input) const = 0; + +private: + void encodeBase(const JsonCodec& codec, DynamicValue::Reader input, + JsonValue::Builder output) const override final { + encode(codec, input.as(), output); + } + Orphan decodeBase(const JsonCodec& codec, JsonValue::Reader input, + Type type, Orphanage orphanage) const override final { + return decode(codec, input); + } + friend class JsonCodec; +}; + +template +class JsonCodec::Handler: private JsonCodec::HandlerBase { +public: + virtual void encode(const JsonCodec& codec, typename T::Client input, + JsonValue::Builder output) const = 0; + virtual typename T::Client decode(const JsonCodec& codec, JsonValue::Reader input) const = 0; + +private: + void encodeBase(const JsonCodec& codec, DynamicValue::Reader input, + JsonValue::Builder output) const override final { + encode(codec, input.as(), output); + } + Orphan decodeBase(const JsonCodec& codec, JsonValue::Reader input, + Type type, Orphanage orphanage) const override final { + return orphanage.newOrphanCopy(decode(codec, input)); + } + friend class JsonCodec; +}; + +template +inline void JsonCodec::addTypeHandler(Handler& handler) { + addTypeHandlerImpl(Type::from(), handler); +} +inline void JsonCodec::addTypeHandler(Type type, Handler& handler) { + addTypeHandlerImpl(type, handler); +} +inline void JsonCodec::addTypeHandler(EnumSchema type, Handler& handler) { + addTypeHandlerImpl(type, handler); +} +inline void JsonCodec::addTypeHandler(StructSchema type, Handler& handler) { + addTypeHandlerImpl(type, handler); +} +inline void JsonCodec::addTypeHandler(ListSchema type, Handler& handler) { + addTypeHandlerImpl(type, handler); +} +inline void JsonCodec::addTypeHandler(InterfaceSchema type, Handler& handler) { + addTypeHandlerImpl(type, handler); +} + +template +inline void JsonCodec::addFieldHandler(StructSchema::Field field, Handler& handler) { + addFieldHandlerImpl(field, Type::from(), handler); +} + +template <> void JsonCodec::addTypeHandler(Handler& handler) + KJ_UNAVAILABLE("JSON handlers for type sets (e.g. all structs, all lists) not implemented; " + "try specifying a specific type schema as the first parameter"); +template <> void JsonCodec::addTypeHandler(Handler& handler) + KJ_UNAVAILABLE("JSON handlers for type sets (e.g. all structs, all lists) not implemented; " + "try specifying a specific type schema as the first parameter"); +template <> void JsonCodec::addTypeHandler(Handler& handler) + KJ_UNAVAILABLE("JSON handlers for type sets (e.g. all structs, all lists) not implemented; " + "try specifying a specific type schema as the first parameter"); +template <> void JsonCodec::addTypeHandler(Handler& handler) + KJ_UNAVAILABLE("JSON handlers for type sets (e.g. all structs, all lists) not implemented; " + "try specifying a specific type schema as the first parameter"); +template <> void JsonCodec::addTypeHandler(Handler& handler) + KJ_UNAVAILABLE("JSON handlers for type sets (e.g. all structs, all lists) not implemented; " + "try specifying a specific type schema as the first parameter"); +// TODO(someday): Implement support for registering handlers that cover thinsg like "all structs" +// or "all lists". Currently you can only target a specific struct or list type. + +} // namespace capnp + +#endif // CAPNP_COMPAT_JSON_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/dynamic.h b/phonelibs/capnp-cpp/include/capnp/dynamic.h new file mode 100644 index 00000000000000..fcefcc3bf2fee9 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/dynamic.h @@ -0,0 +1,1643 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file defines classes that can be used to manipulate messages based on schemas that are not +// known until runtime. This is also useful for writing generic code that uses schemas to handle +// arbitrary types in a generic way. +// +// Each of the classes defined here has a to() template method which converts an instance back to a +// native type. This method will throw an exception if the requested type does not match the +// schema. To convert native types to dynamic, use DynamicFactory. +// +// As always, underlying data is validated lazily, so you have to actually traverse the whole +// message if you want to validate all content. + +#ifndef CAPNP_DYNAMIC_H_ +#define CAPNP_DYNAMIC_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "schema.h" +#include "layout.h" +#include "message.h" +#include "any.h" +#include "capability.h" + +namespace capnp { + +class MessageReader; +class MessageBuilder; + +struct DynamicValue { + DynamicValue() = delete; + + enum Type { + UNKNOWN, + // Means that the value has unknown type and content because it comes from a newer version of + // the schema, or from a newer version of Cap'n Proto that has new features that this version + // doesn't understand. + + VOID, + BOOL, + INT, + UINT, + FLOAT, + TEXT, + DATA, + LIST, + ENUM, + STRUCT, + CAPABILITY, + ANY_POINTER + }; + + class Reader; + class Builder; + class Pipeline; +}; +class DynamicEnum; +struct DynamicStruct { + DynamicStruct() = delete; + class Reader; + class Builder; + class Pipeline; +}; +struct DynamicList { + DynamicList() = delete; + class Reader; + class Builder; +}; +struct DynamicCapability { + DynamicCapability() = delete; + class Client; + class Server; +}; +template <> class Orphan; + +template struct DynamicTypeFor_; +template <> struct DynamicTypeFor_ { typedef DynamicEnum Type; }; +template <> struct DynamicTypeFor_ { typedef DynamicStruct Type; }; +template <> struct DynamicTypeFor_ { typedef DynamicList Type; }; +template <> struct DynamicTypeFor_ { typedef DynamicCapability Type; }; + +template +using DynamicTypeFor = typename DynamicTypeFor_()>::Type; + +template +ReaderFor>> toDynamic(T&& value); +template +BuilderFor>> toDynamic(T&& value); +template +DynamicTypeFor> toDynamic(T&& value); +template +typename DynamicTypeFor>::Client toDynamic(kj::Own&& value); + +namespace _ { // private + +template <> struct Kind_ { static constexpr Kind kind = Kind::OTHER; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::OTHER; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::OTHER; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::OTHER; }; +template <> struct Kind_ { static constexpr Kind kind = Kind::OTHER; }; + +} // namespace _ (private) + +template <> inline constexpr Style style() { return Style::POINTER; } +template <> inline constexpr Style style() { return Style::PRIMITIVE; } +template <> inline constexpr Style style() { return Style::STRUCT; } +template <> inline constexpr Style style() { return Style::POINTER; } +template <> inline constexpr Style style() { return Style::CAPABILITY; } + +// ------------------------------------------------------------------- + +class DynamicEnum { +public: + DynamicEnum() = default; + inline DynamicEnum(EnumSchema::Enumerant enumerant) + : schema(enumerant.getContainingEnum()), value(enumerant.getOrdinal()) {} + inline DynamicEnum(EnumSchema schema, uint16_t value) + : schema(schema), value(value) {} + + template () == Kind::ENUM>> + inline DynamicEnum(T&& value): DynamicEnum(toDynamic(value)) {} + + template + inline T as() const { return static_cast(asImpl(typeId())); } + // Cast to a native enum type. + + inline EnumSchema getSchema() const { return schema; } + + kj::Maybe getEnumerant() const; + // Get which enumerant this enum value represents. Returns nullptr if the numeric value does not + // correspond to any enumerant in the schema -- this can happen if the data was built using a + // newer schema that has more values defined. + + inline uint16_t getRaw() const { return value; } + // Returns the raw underlying enum value. + +private: + EnumSchema schema; + uint16_t value; + + uint16_t asImpl(uint64_t requestedTypeId) const; + + friend struct DynamicStruct; + friend struct DynamicList; + friend struct DynamicValue; + template + friend DynamicTypeFor> toDynamic(T&& value); +}; + +// ------------------------------------------------------------------- + +class DynamicStruct::Reader { +public: + typedef DynamicStruct Reads; + + Reader() = default; + + template >() == Kind::STRUCT>> + inline Reader(T&& value): Reader(toDynamic(value)) {} + + inline MessageSize totalSize() const { return reader.totalSize().asPublic(); } + + template + typename T::Reader as() const; + // Convert the dynamic struct to its compiled-in type. + + inline StructSchema getSchema() const { return schema; } + + DynamicValue::Reader get(StructSchema::Field field) const; + // Read the given field value. + + bool has(StructSchema::Field field) const; + // Tests whether the given field is set to its default value. For pointer values, this does + // not actually traverse the value comparing it with the default, but simply returns true if the + // pointer is non-null. For members of unions, has() returns false if the union member is not + // active, but does not necessarily return true if the member is active (depends on the field's + // value). + + kj::Maybe which() const; + // If the struct contains an (unnamed) union, and the currently-active field within that union + // is known, this returns that field. Otherwise, it returns null. In other words, this returns + // null if there is no union present _or_ if the union's discriminant is set to an unrecognized + // value. This could happen in particular when receiving a message from a sender who has a + // newer version of the protocol and is using a field of the union that you don't know about yet. + + DynamicValue::Reader get(kj::StringPtr name) const; + bool has(kj::StringPtr name) const; + // Shortcuts to access fields by name. These throw exceptions if no such field exists. + +private: + StructSchema schema; + _::StructReader reader; + + inline Reader(StructSchema schema, _::StructReader reader) + : schema(schema), reader(reader) {} + Reader(StructSchema schema, const _::OrphanBuilder& orphan); + + bool isSetInUnion(StructSchema::Field field) const; + void verifySetInUnion(StructSchema::Field field) const; + static DynamicValue::Reader getImpl(_::StructReader reader, StructSchema::Field field); + + template + friend struct _::PointerHelpers; + friend class DynamicStruct::Builder; + friend struct DynamicList; + friend class MessageReader; + friend class MessageBuilder; + template + friend struct ::capnp::ToDynamic_; + friend kj::StringTree _::structString( + _::StructReader reader, const _::RawBrandedSchema& schema); + friend class Orphanage; + friend class Orphan; + friend class Orphan; + friend class Orphan; +}; + +class DynamicStruct::Builder { +public: + typedef DynamicStruct Builds; + + Builder() = default; + inline Builder(decltype(nullptr)) {} + + template >() == Kind::STRUCT>> + inline Builder(T&& value): Builder(toDynamic(value)) {} + + inline MessageSize totalSize() const { return asReader().totalSize(); } + + template + typename T::Builder as(); + // Cast to a particular struct type. + + inline StructSchema getSchema() const { return schema; } + + DynamicValue::Builder get(StructSchema::Field field); + // Read the given field value. + + inline bool has(StructSchema::Field field) { return asReader().has(field); } + // Tests whether the given field is set to its default value. For pointer values, this does + // not actually traverse the value comparing it with the default, but simply returns true if the + // pointer is non-null. For members of unions, has() returns whether the field is currently + // active and the union as a whole is non-default -- so, the only time has() will return false + // for an active union field is if it is the default active field and it has its default value. + + kj::Maybe which(); + // If the struct contains an (unnamed) union, and the currently-active field within that union + // is known, this returns that field. Otherwise, it returns null. In other words, this returns + // null if there is no union present _or_ if the union's discriminant is set to an unrecognized + // value. This could happen in particular when receiving a message from a sender who has a + // newer version of the protocol and is using a field of the union that you don't know about yet. + + void set(StructSchema::Field field, const DynamicValue::Reader& value); + // Set the given field value. + + DynamicValue::Builder init(StructSchema::Field field); + DynamicValue::Builder init(StructSchema::Field field, uint size); + // Init a struct, list, or blob field. + + void adopt(StructSchema::Field field, Orphan&& orphan); + Orphan disown(StructSchema::Field field); + // Adopt/disown. This works even for non-pointer fields: adopt() becomes equivalent to set() + // and disown() becomes like get() followed by clear(). + + void clear(StructSchema::Field field); + // Clear a field, setting it to its default value. For pointer fields, this actually makes the + // field null. + + DynamicValue::Builder get(kj::StringPtr name); + bool has(kj::StringPtr name); + void set(kj::StringPtr name, const DynamicValue::Reader& value); + void set(kj::StringPtr name, std::initializer_list value); + DynamicValue::Builder init(kj::StringPtr name); + DynamicValue::Builder init(kj::StringPtr name, uint size); + void adopt(kj::StringPtr name, Orphan&& orphan); + Orphan disown(kj::StringPtr name); + void clear(kj::StringPtr name); + // Shortcuts to access fields by name. These throw exceptions if no such field exists. + + Reader asReader() const; + +private: + StructSchema schema; + _::StructBuilder builder; + + inline Builder(StructSchema schema, _::StructBuilder builder) + : schema(schema), builder(builder) {} + Builder(StructSchema schema, _::OrphanBuilder& orphan); + + bool isSetInUnion(StructSchema::Field field); + void verifySetInUnion(StructSchema::Field field); + void setInUnion(StructSchema::Field field); + + template + friend struct _::PointerHelpers; + friend struct DynamicList; + friend class MessageReader; + friend class MessageBuilder; + template + friend struct ::capnp::ToDynamic_; + friend class Orphanage; + friend class Orphan; + friend class Orphan; + friend class Orphan; +}; + +class DynamicStruct::Pipeline { +public: + typedef DynamicStruct Pipelines; + + inline Pipeline(decltype(nullptr)): typeless(nullptr) {} + + template + typename T::Pipeline releaseAs(); + // Convert the dynamic pipeline to its compiled-in type. + + inline StructSchema getSchema() { return schema; } + + DynamicValue::Pipeline get(StructSchema::Field field); + // Read the given field value. + + DynamicValue::Pipeline get(kj::StringPtr name); + // Get by string name. + +private: + StructSchema schema; + AnyPointer::Pipeline typeless; + + inline explicit Pipeline(StructSchema schema, AnyPointer::Pipeline&& typeless) + : schema(schema), typeless(kj::mv(typeless)) {} + + friend class Request; +}; + +// ------------------------------------------------------------------- + +class DynamicList::Reader { +public: + typedef DynamicList Reads; + + inline Reader(): reader(ElementSize::VOID) {} + + template >() == Kind::LIST>> + inline Reader(T&& value): Reader(toDynamic(value)) {} + + template + typename T::Reader as() const; + // Try to convert to any List, Data, or Text. Throws an exception if the underlying data + // can't possibly represent the requested type. + + inline ListSchema getSchema() const { return schema; } + + inline uint size() const { return unbound(reader.size() / ELEMENTS); } + DynamicValue::Reader operator[](uint index) const; + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + +private: + ListSchema schema; + _::ListReader reader; + + Reader(ListSchema schema, _::ListReader reader): schema(schema), reader(reader) {} + Reader(ListSchema schema, const _::OrphanBuilder& orphan); + + template + friend struct _::PointerHelpers; + friend struct DynamicStruct; + friend class DynamicList::Builder; + template + friend struct ::capnp::ToDynamic_; + friend class Orphanage; + friend class Orphan; + friend class Orphan; + friend class Orphan; +}; + +class DynamicList::Builder { +public: + typedef DynamicList Builds; + + inline Builder(): builder(ElementSize::VOID) {} + inline Builder(decltype(nullptr)): builder(ElementSize::VOID) {} + + template >() == Kind::LIST>> + inline Builder(T&& value): Builder(toDynamic(value)) {} + + template + typename T::Builder as(); + // Try to convert to any List, Data, or Text. Throws an exception if the underlying data + // can't possibly represent the requested type. + + inline ListSchema getSchema() const { return schema; } + + inline uint size() const { return unbound(builder.size() / ELEMENTS); } + DynamicValue::Builder operator[](uint index); + void set(uint index, const DynamicValue::Reader& value); + DynamicValue::Builder init(uint index, uint size); + void adopt(uint index, Orphan&& orphan); + Orphan disown(uint index); + + typedef _::IndexingIterator Iterator; + inline Iterator begin() { return Iterator(this, 0); } + inline Iterator end() { return Iterator(this, size()); } + + void copyFrom(std::initializer_list value); + + Reader asReader() const; + +private: + ListSchema schema; + _::ListBuilder builder; + + Builder(ListSchema schema, _::ListBuilder builder): schema(schema), builder(builder) {} + Builder(ListSchema schema, _::OrphanBuilder& orphan); + + template + friend struct _::PointerHelpers; + friend struct DynamicStruct; + template + friend struct ::capnp::ToDynamic_; + friend class Orphanage; + template + friend struct _::OrphanGetImpl; + friend class Orphan; + friend class Orphan; + friend class Orphan; +}; + +// ------------------------------------------------------------------- + +class DynamicCapability::Client: public Capability::Client { +public: + typedef DynamicCapability Calls; + typedef DynamicCapability Reads; + + Client() = default; + + template >() == Kind::INTERFACE>> + inline Client(T&& client); + + template ()>> + inline Client(kj::Own&& server); + + template () == Kind::INTERFACE>> + typename T::Client as(); + template () == Kind::INTERFACE>> + typename T::Client releaseAs(); + // Convert to any client type. + + Client upcast(InterfaceSchema requestedSchema); + // Upcast to a superclass. Throws an exception if `schema` is not a superclass. + + inline InterfaceSchema getSchema() { return schema; } + + Request newRequest( + InterfaceSchema::Method method, kj::Maybe sizeHint = nullptr); + Request newRequest( + kj::StringPtr methodName, kj::Maybe sizeHint = nullptr); + +private: + InterfaceSchema schema; + + Client(InterfaceSchema schema, kj::Own&& hook) + : Capability::Client(kj::mv(hook)), schema(schema) {} + + template + inline Client(InterfaceSchema schema, kj::Own&& server); + + friend struct Capability; + friend struct DynamicStruct; + friend struct DynamicList; + friend struct DynamicValue; + friend class Orphan; + friend class Orphan; + friend class Orphan; + template + friend struct _::PointerHelpers; +}; + +class DynamicCapability::Server: public Capability::Server { +public: + typedef DynamicCapability Serves; + + Server(InterfaceSchema schema): schema(schema) {} + + virtual kj::Promise call(InterfaceSchema::Method method, + CallContext context) = 0; + + kj::Promise dispatchCall(uint64_t interfaceId, uint16_t methodId, + CallContext context) override final; + + inline InterfaceSchema getSchema() const { return schema; } + +private: + InterfaceSchema schema; +}; + +template <> +class Request: public DynamicStruct::Builder { + // Specialization of `Request` for DynamicStruct. + +public: + inline Request(DynamicStruct::Builder builder, kj::Own&& hook, + StructSchema resultSchema) + : DynamicStruct::Builder(builder), hook(kj::mv(hook)), resultSchema(resultSchema) {} + + RemotePromise send(); + // Send the call and return a promise for the results. + +private: + kj::Own hook; + StructSchema resultSchema; + + friend class Capability::Client; + friend struct DynamicCapability; + template + friend class CallContext; + friend class RequestHook; +}; + +template <> +class CallContext: public kj::DisallowConstCopy { + // Wrapper around CallContextHook with a specific return type. + // + // Methods of this class may only be called from within the server's event loop, not from other + // threads. + +public: + explicit CallContext(CallContextHook& hook, StructSchema paramType, StructSchema resultType); + + DynamicStruct::Reader getParams(); + void releaseParams(); + DynamicStruct::Builder getResults(kj::Maybe sizeHint = nullptr); + DynamicStruct::Builder initResults(kj::Maybe sizeHint = nullptr); + void setResults(DynamicStruct::Reader value); + void adoptResults(Orphan&& value); + Orphanage getResultsOrphanage(kj::Maybe sizeHint = nullptr); + template + kj::Promise tailCall(Request&& tailRequest); + void allowCancellation(); + +private: + CallContextHook* hook; + StructSchema paramType; + StructSchema resultType; + + friend class DynamicCapability::Server; +}; + +// ------------------------------------------------------------------- + +// Make sure ReaderFor and BuilderFor work for DynamicEnum, DynamicStruct, and +// DynamicList, so that we can define DynamicValue::as(). + +template <> struct ReaderFor_ { typedef DynamicEnum Type; }; +template <> struct BuilderFor_ { typedef DynamicEnum Type; }; +template <> struct ReaderFor_ { typedef DynamicStruct::Reader Type; }; +template <> struct BuilderFor_ { typedef DynamicStruct::Builder Type; }; +template <> struct ReaderFor_ { typedef DynamicList::Reader Type; }; +template <> struct BuilderFor_ { typedef DynamicList::Builder Type; }; +template <> struct ReaderFor_ { typedef DynamicCapability::Client Type; }; +template <> struct BuilderFor_ { typedef DynamicCapability::Client Type; }; +template <> struct PipelineFor_ { typedef DynamicCapability::Client Type; }; + +class DynamicValue::Reader { +public: + typedef DynamicValue Reads; + + inline Reader(decltype(nullptr) n = nullptr); // UNKNOWN + inline Reader(Void value); + inline Reader(bool value); + inline Reader(char value); + inline Reader(signed char value); + inline Reader(short value); + inline Reader(int value); + inline Reader(long value); + inline Reader(long long value); + inline Reader(unsigned char value); + inline Reader(unsigned short value); + inline Reader(unsigned int value); + inline Reader(unsigned long value); + inline Reader(unsigned long long value); + inline Reader(float value); + inline Reader(double value); + inline Reader(const char* value); // Text + inline Reader(const Text::Reader& value); + inline Reader(const Data::Reader& value); + inline Reader(const DynamicList::Reader& value); + inline Reader(DynamicEnum value); + inline Reader(const DynamicStruct::Reader& value); + inline Reader(const AnyPointer::Reader& value); + inline Reader(DynamicCapability::Client& value); + inline Reader(DynamicCapability::Client&& value); + template ()>> + inline Reader(kj::Own&& value); + Reader(ConstSchema constant); + + template ()))> + inline Reader(T&& value): Reader(toDynamic(kj::mv(value))) {} + + Reader(const Reader& other); + Reader(Reader&& other) noexcept; + ~Reader() noexcept(false); + Reader& operator=(const Reader& other); + Reader& operator=(Reader&& other); + // Unfortunately, we cannot use the implicit definitions of these since DynamicCapability is not + // trivially copyable. + + template + inline ReaderFor as() const { return AsImpl::apply(*this); } + // Use to interpret the value as some Cap'n Proto type. Allowed types are: + // - Void, bool, [u]int{8,16,32,64}_t, float, double, any enum: Returns the raw value. + // - Text, Data, AnyPointer, any struct type: Returns the corresponding Reader. + // - List for any T listed above: Returns List::Reader. + // - DynamicEnum: Returns the corresponding type. + // - DynamicStruct, DynamicList: Returns the corresponding Reader. + // - Any capability type, including DynamicCapability: Returns the corresponding Client. + // - DynamicValue: Returns an identical Reader. Useful to avoid special-casing in generic code. + // (TODO(perf): On GCC 4.8 / Clang 3.3, provide rvalue-qualified version that avoids + // refcounting.) + // + // DynamicValue allows various implicit conversions, mostly just to make the interface friendlier. + // - Any integer can be converted to any other integer type so long as the actual value is within + // the new type's range. + // - Floating-point types can be converted to integers as long as no information would be lost + // in the conversion. + // - Integers can be converted to floating points. This may lose information, but won't throw. + // - Float32/Float64 can be converted between each other. Converting Float64 -> Float32 may lose + // information, but won't throw. + // - Text can be converted to an enum, if the Text matches one of the enumerant names (but not + // vice-versa). + // - Capabilities can be upcast (cast to a supertype), but not downcast. + // + // Any other conversion attempt will throw an exception. + + inline Type getType() const { return type; } + // Get the type of this value. + +private: + Type type; + + union { + Void voidValue; + bool boolValue; + int64_t intValue; + uint64_t uintValue; + double floatValue; + Text::Reader textValue; + Data::Reader dataValue; + DynamicList::Reader listValue; + DynamicEnum enumValue; + DynamicStruct::Reader structValue; + AnyPointer::Reader anyPointerValue; + + mutable DynamicCapability::Client capabilityValue; + // Declared mutable because `Client`s normally cannot be const. + + // Warning: Copy/move constructors assume all these types are trivially copyable except + // Capability. + }; + + template ()> struct AsImpl; + // Implementation backing the as() method. Needs to be a struct to allow partial + // specialization. Has a method apply() which does the work. + + friend class Orphanage; // to speed up newOrphanCopy(DynamicValue::Reader) +}; + +class DynamicValue::Builder { +public: + typedef DynamicValue Builds; + + inline Builder(decltype(nullptr) n = nullptr); // UNKNOWN + inline Builder(Void value); + inline Builder(bool value); + inline Builder(char value); + inline Builder(signed char value); + inline Builder(short value); + inline Builder(int value); + inline Builder(long value); + inline Builder(long long value); + inline Builder(unsigned char value); + inline Builder(unsigned short value); + inline Builder(unsigned int value); + inline Builder(unsigned long value); + inline Builder(unsigned long long value); + inline Builder(float value); + inline Builder(double value); + inline Builder(Text::Builder value); + inline Builder(Data::Builder value); + inline Builder(DynamicList::Builder value); + inline Builder(DynamicEnum value); + inline Builder(DynamicStruct::Builder value); + inline Builder(AnyPointer::Builder value); + inline Builder(DynamicCapability::Client& value); + inline Builder(DynamicCapability::Client&& value); + + template ()))> + inline Builder(T value): Builder(toDynamic(value)) {} + + Builder(Builder& other); + Builder(Builder&& other) noexcept; + ~Builder() noexcept(false); + Builder& operator=(Builder& other); + Builder& operator=(Builder&& other); + // Unfortunately, we cannot use the implicit definitions of these since DynamicCapability is not + // trivially copyable. + + template + inline BuilderFor as() { return AsImpl::apply(*this); } + // See DynamicValue::Reader::as(). + + inline Type getType() { return type; } + // Get the type of this value. + + Reader asReader() const; + +private: + Type type; + + union { + Void voidValue; + bool boolValue; + int64_t intValue; + uint64_t uintValue; + double floatValue; + Text::Builder textValue; + Data::Builder dataValue; + DynamicList::Builder listValue; + DynamicEnum enumValue; + DynamicStruct::Builder structValue; + AnyPointer::Builder anyPointerValue; + + mutable DynamicCapability::Client capabilityValue; + // Declared mutable because `Client`s normally cannot be const. + }; + + template ()> struct AsImpl; + // Implementation backing the as() method. Needs to be a struct to allow partial + // specialization. Has a method apply() which does the work. + + friend class Orphan; +}; + +class DynamicValue::Pipeline { +public: + typedef DynamicValue Pipelines; + + inline Pipeline(decltype(nullptr) n = nullptr); + inline Pipeline(DynamicStruct::Pipeline&& value); + inline Pipeline(DynamicCapability::Client&& value); + + Pipeline(Pipeline&& other) noexcept; + Pipeline& operator=(Pipeline&& other); + ~Pipeline() noexcept(false); + + template + inline PipelineFor releaseAs() { return AsImpl::apply(*this); } + + inline Type getType() { return type; } + // Get the type of this value. + +private: + Type type; + union { + DynamicStruct::Pipeline structValue; + DynamicCapability::Client capabilityValue; + }; + + template ()> struct AsImpl; + // Implementation backing the releaseAs() method. Needs to be a struct to allow partial + // specialization. Has a method apply() which does the work. +}; + +kj::StringTree KJ_STRINGIFY(const DynamicValue::Reader& value); +kj::StringTree KJ_STRINGIFY(const DynamicValue::Builder& value); +kj::StringTree KJ_STRINGIFY(DynamicEnum value); +kj::StringTree KJ_STRINGIFY(const DynamicStruct::Reader& value); +kj::StringTree KJ_STRINGIFY(const DynamicStruct::Builder& value); +kj::StringTree KJ_STRINGIFY(const DynamicList::Reader& value); +kj::StringTree KJ_STRINGIFY(const DynamicList::Builder& value); + +// ------------------------------------------------------------------- +// Orphan <-> Dynamic glue + +template <> +class Orphan { +public: + Orphan() = default; + KJ_DISALLOW_COPY(Orphan); + Orphan(Orphan&&) = default; + Orphan& operator=(Orphan&&) = default; + + template () == Kind::STRUCT>> + inline Orphan(Orphan&& other): schema(Schema::from()), builder(kj::mv(other.builder)) {} + + DynamicStruct::Builder get(); + DynamicStruct::Reader getReader() const; + + template + Orphan releaseAs(); + // Like DynamicStruct::Builder::as(), but coerces the Orphan type. Since Orphans are move-only, + // the original Orphan is no longer valid after this call; ownership is + // transferred to the returned Orphan. + + inline bool operator==(decltype(nullptr)) const { return builder == nullptr; } + inline bool operator!=(decltype(nullptr)) const { return builder != nullptr; } + +private: + StructSchema schema; + _::OrphanBuilder builder; + + inline Orphan(StructSchema schema, _::OrphanBuilder&& builder) + : schema(schema), builder(kj::mv(builder)) {} + + template + friend struct _::PointerHelpers; + friend struct DynamicList; + friend class Orphanage; + friend class Orphan; + friend class Orphan; + friend class MessageBuilder; +}; + +template <> +class Orphan { +public: + Orphan() = default; + KJ_DISALLOW_COPY(Orphan); + Orphan(Orphan&&) = default; + Orphan& operator=(Orphan&&) = default; + + template () == Kind::LIST>> + inline Orphan(Orphan&& other): schema(Schema::from()), builder(kj::mv(other.builder)) {} + + DynamicList::Builder get(); + DynamicList::Reader getReader() const; + + template + Orphan releaseAs(); + // Like DynamicList::Builder::as(), but coerces the Orphan type. Since Orphans are move-only, + // the original Orphan is no longer valid after this call; ownership is + // transferred to the returned Orphan. + + // TODO(someday): Support truncate(). + + inline bool operator==(decltype(nullptr)) const { return builder == nullptr; } + inline bool operator!=(decltype(nullptr)) const { return builder != nullptr; } + +private: + ListSchema schema; + _::OrphanBuilder builder; + + inline Orphan(ListSchema schema, _::OrphanBuilder&& builder) + : schema(schema), builder(kj::mv(builder)) {} + + template + friend struct _::PointerHelpers; + friend struct DynamicList; + friend class Orphanage; + friend class Orphan; + friend class Orphan; +}; + +template <> +class Orphan { +public: + Orphan() = default; + KJ_DISALLOW_COPY(Orphan); + Orphan(Orphan&&) = default; + Orphan& operator=(Orphan&&) = default; + + template () == Kind::INTERFACE>> + inline Orphan(Orphan&& other): schema(Schema::from()), builder(kj::mv(other.builder)) {} + + DynamicCapability::Client get(); + DynamicCapability::Client getReader() const; + + template + Orphan releaseAs(); + // Like DynamicCapability::Client::as(), but coerces the Orphan type. Since Orphans are move-only, + // the original Orphan is no longer valid after this call; ownership is + // transferred to the returned Orphan. + + inline bool operator==(decltype(nullptr)) const { return builder == nullptr; } + inline bool operator!=(decltype(nullptr)) const { return builder != nullptr; } + +private: + InterfaceSchema schema; + _::OrphanBuilder builder; + + inline Orphan(InterfaceSchema schema, _::OrphanBuilder&& builder) + : schema(schema), builder(kj::mv(builder)) {} + + template + friend struct _::PointerHelpers; + friend struct DynamicList; + friend class Orphanage; + friend class Orphan; + friend class Orphan; +}; + +template <> +class Orphan { +public: + inline Orphan(decltype(nullptr) n = nullptr): type(DynamicValue::UNKNOWN) {} + inline Orphan(Void value); + inline Orphan(bool value); + inline Orphan(char value); + inline Orphan(signed char value); + inline Orphan(short value); + inline Orphan(int value); + inline Orphan(long value); + inline Orphan(long long value); + inline Orphan(unsigned char value); + inline Orphan(unsigned short value); + inline Orphan(unsigned int value); + inline Orphan(unsigned long value); + inline Orphan(unsigned long long value); + inline Orphan(float value); + inline Orphan(double value); + inline Orphan(DynamicEnum value); + Orphan(Orphan&&) = default; + template + Orphan(Orphan&&); + Orphan(Orphan&&); + Orphan(void*) = delete; // So Orphan(bool) doesn't accept pointers. + KJ_DISALLOW_COPY(Orphan); + + Orphan& operator=(Orphan&&) = default; + + inline DynamicValue::Type getType() { return type; } + + DynamicValue::Builder get(); + DynamicValue::Reader getReader() const; + + template + Orphan releaseAs(); + // Like DynamicValue::Builder::as(), but coerces the Orphan type. Since Orphans are move-only, + // the original Orphan is no longer valid after this call; ownership is + // transferred to the returned Orphan. + +private: + DynamicValue::Type type; + union { + Void voidValue; + bool boolValue; + int64_t intValue; + uint64_t uintValue; + double floatValue; + DynamicEnum enumValue; + StructSchema structSchema; + ListSchema listSchema; + InterfaceSchema interfaceSchema; + }; + + _::OrphanBuilder builder; + // Only used if `type` is a pointer type. + + Orphan(DynamicValue::Builder value, _::OrphanBuilder&& builder); + Orphan(DynamicValue::Type type, _::OrphanBuilder&& builder) + : type(type), builder(kj::mv(builder)) {} + Orphan(StructSchema structSchema, _::OrphanBuilder&& builder) + : type(DynamicValue::STRUCT), structSchema(structSchema), builder(kj::mv(builder)) {} + Orphan(ListSchema listSchema, _::OrphanBuilder&& builder) + : type(DynamicValue::LIST), listSchema(listSchema), builder(kj::mv(builder)) {} + + template + friend struct _::PointerHelpers; + friend struct DynamicStruct; + friend struct DynamicList; + friend struct AnyPointer; + friend class Orphanage; +}; + +template +inline Orphan::Orphan(Orphan&& other) + : Orphan(other.get(), kj::mv(other.builder)) {} + +inline Orphan::Orphan(Orphan&& other) + : type(DynamicValue::ANY_POINTER), builder(kj::mv(other.builder)) {} + +template +Orphan Orphan::releaseAs() { + get().as(); // type check + return Orphan(kj::mv(builder)); +} + +template +Orphan Orphan::releaseAs() { + get().as(); // type check + return Orphan(kj::mv(builder)); +} + +template +Orphan Orphan::releaseAs() { + get().as(); // type check + return Orphan(kj::mv(builder)); +} + +template +Orphan Orphan::releaseAs() { + get().as(); // type check + type = DynamicValue::UNKNOWN; + return Orphan(kj::mv(builder)); +} + +template <> +Orphan Orphan::releaseAs(); +template <> +Orphan Orphan::releaseAs(); +template <> +Orphan Orphan::releaseAs(); +template <> +Orphan Orphan::releaseAs(); + +template <> +struct Orphanage::GetInnerBuilder { + static inline _::StructBuilder apply(DynamicStruct::Builder& t) { + return t.builder; + } +}; + +template <> +struct Orphanage::GetInnerBuilder { + static inline _::ListBuilder apply(DynamicList::Builder& t) { + return t.builder; + } +}; + +template <> +inline Orphan Orphanage::newOrphanCopy( + DynamicStruct::Reader copyFrom) const { + return Orphan( + copyFrom.getSchema(), _::OrphanBuilder::copy(arena, capTable, copyFrom.reader)); +} + +template <> +inline Orphan Orphanage::newOrphanCopy( + DynamicList::Reader copyFrom) const { + return Orphan(copyFrom.getSchema(), + _::OrphanBuilder::copy(arena, capTable, copyFrom.reader)); +} + +template <> +inline Orphan Orphanage::newOrphanCopy( + DynamicCapability::Client copyFrom) const { + return Orphan( + copyFrom.getSchema(), _::OrphanBuilder::copy(arena, capTable, copyFrom.hook->addRef())); +} + +template <> +Orphan Orphanage::newOrphanCopy( + DynamicValue::Reader copyFrom) const; + +namespace _ { // private + +template <> +struct PointerHelpers { + // getDynamic() is used when an AnyPointer's get() accessor is passed arguments, because for + // non-dynamic types PointerHelpers::get() takes a default value as the third argument, and we + // don't want people to accidentally be able to provide their own default value. + static DynamicStruct::Reader getDynamic(PointerReader reader, StructSchema schema); + static DynamicStruct::Builder getDynamic(PointerBuilder builder, StructSchema schema); + static void set(PointerBuilder builder, const DynamicStruct::Reader& value); + static DynamicStruct::Builder init(PointerBuilder builder, StructSchema schema); + static inline void adopt(PointerBuilder builder, Orphan&& value) { + builder.adopt(kj::mv(value.builder)); + } + static inline Orphan disown(PointerBuilder builder, StructSchema schema) { + return Orphan(schema, builder.disown()); + } +}; + +template <> +struct PointerHelpers { + // getDynamic() is used when an AnyPointer's get() accessor is passed arguments, because for + // non-dynamic types PointerHelpers::get() takes a default value as the third argument, and we + // don't want people to accidentally be able to provide their own default value. + static DynamicList::Reader getDynamic(PointerReader reader, ListSchema schema); + static DynamicList::Builder getDynamic(PointerBuilder builder, ListSchema schema); + static void set(PointerBuilder builder, const DynamicList::Reader& value); + static DynamicList::Builder init(PointerBuilder builder, ListSchema schema, uint size); + static inline void adopt(PointerBuilder builder, Orphan&& value) { + builder.adopt(kj::mv(value.builder)); + } + static inline Orphan disown(PointerBuilder builder, ListSchema schema) { + return Orphan(schema, builder.disown()); + } +}; + +template <> +struct PointerHelpers { + // getDynamic() is used when an AnyPointer's get() accessor is passed arguments, because for + // non-dynamic types PointerHelpers::get() takes a default value as the third argument, and we + // don't want people to accidentally be able to provide their own default value. + static DynamicCapability::Client getDynamic(PointerReader reader, InterfaceSchema schema); + static DynamicCapability::Client getDynamic(PointerBuilder builder, InterfaceSchema schema); + static void set(PointerBuilder builder, DynamicCapability::Client& value); + static void set(PointerBuilder builder, DynamicCapability::Client&& value); + static inline void adopt(PointerBuilder builder, Orphan&& value) { + builder.adopt(kj::mv(value.builder)); + } + static inline Orphan disown(PointerBuilder builder, InterfaceSchema schema) { + return Orphan(schema, builder.disown()); + } +}; + +} // namespace _ (private) + +template +inline ReaderFor AnyPointer::Reader::getAs(StructSchema schema) const { + return _::PointerHelpers::getDynamic(reader, schema); +} +template +inline ReaderFor AnyPointer::Reader::getAs(ListSchema schema) const { + return _::PointerHelpers::getDynamic(reader, schema); +} +template +inline ReaderFor AnyPointer::Reader::getAs(InterfaceSchema schema) const { + return _::PointerHelpers::getDynamic(reader, schema); +} +template +inline BuilderFor AnyPointer::Builder::getAs(StructSchema schema) { + return _::PointerHelpers::getDynamic(builder, schema); +} +template +inline BuilderFor AnyPointer::Builder::getAs(ListSchema schema) { + return _::PointerHelpers::getDynamic(builder, schema); +} +template +inline BuilderFor AnyPointer::Builder::getAs(InterfaceSchema schema) { + return _::PointerHelpers::getDynamic(builder, schema); +} +template +inline BuilderFor AnyPointer::Builder::initAs(StructSchema schema) { + return _::PointerHelpers::init(builder, schema); +} +template +inline BuilderFor AnyPointer::Builder::initAs(ListSchema schema, uint elementCount) { + return _::PointerHelpers::init(builder, schema, elementCount); +} +template <> +inline void AnyPointer::Builder::setAs(DynamicStruct::Reader value) { + return _::PointerHelpers::set(builder, value); +} +template <> +inline void AnyPointer::Builder::setAs(DynamicList::Reader value) { + return _::PointerHelpers::set(builder, value); +} +template <> +inline void AnyPointer::Builder::setAs(DynamicCapability::Client value) { + return _::PointerHelpers::set(builder, kj::mv(value)); +} +template <> +void AnyPointer::Builder::adopt(Orphan&& orphan); +template +inline Orphan AnyPointer::Builder::disownAs(StructSchema schema) { + return _::PointerHelpers::disown(builder, schema); +} +template +inline Orphan AnyPointer::Builder::disownAs(ListSchema schema) { + return _::PointerHelpers::disown(builder, schema); +} +template +inline Orphan AnyPointer::Builder::disownAs(InterfaceSchema schema) { + return _::PointerHelpers::disown(builder, schema); +} + +// We have to declare the methods below inline because Clang and GCC disagree about how to mangle +// their symbol names. +template <> +inline DynamicStruct::Builder Orphan::getAs(StructSchema schema) { + return DynamicStruct::Builder(schema, builder); +} +template <> +inline DynamicStruct::Reader Orphan::getAsReader( + StructSchema schema) const { + return DynamicStruct::Reader(schema, builder); +} +template <> +inline Orphan Orphan::releaseAs(StructSchema schema) { + return Orphan(schema, kj::mv(builder)); +} +template <> +inline DynamicList::Builder Orphan::getAs(ListSchema schema) { + return DynamicList::Builder(schema, builder); +} +template <> +inline DynamicList::Reader Orphan::getAsReader(ListSchema schema) const { + return DynamicList::Reader(schema, builder); +} +template <> +inline Orphan Orphan::releaseAs(ListSchema schema) { + return Orphan(schema, kj::mv(builder)); +} +template <> +inline DynamicCapability::Client Orphan::getAs( + InterfaceSchema schema) { + return DynamicCapability::Client(schema, builder.asCapability()); +} +template <> +inline DynamicCapability::Client Orphan::getAsReader( + InterfaceSchema schema) const { + return DynamicCapability::Client(schema, builder.asCapability()); +} +template <> +inline Orphan Orphan::releaseAs( + InterfaceSchema schema) { + return Orphan(schema, kj::mv(builder)); +} + +// ======================================================================================= +// Inline implementation details. + +template +struct ToDynamic_ { + static inline DynamicStruct::Reader apply(const typename T::Reader& value) { + return DynamicStruct::Reader(Schema::from(), value._reader); + } + static inline DynamicStruct::Builder apply(typename T::Builder& value) { + return DynamicStruct::Builder(Schema::from(), value._builder); + } +}; + +template +struct ToDynamic_ { + static inline DynamicList::Reader apply(const typename T::Reader& value) { + return DynamicList::Reader(Schema::from(), value.reader); + } + static inline DynamicList::Builder apply(typename T::Builder& value) { + return DynamicList::Builder(Schema::from(), value.builder); + } +}; + +template +struct ToDynamic_ { + static inline DynamicCapability::Client apply(typename T::Client value) { + return DynamicCapability::Client(kj::mv(value)); + } + static inline DynamicCapability::Client apply(typename T::Client&& value) { + return DynamicCapability::Client(kj::mv(value)); + } +}; + +template +ReaderFor>> toDynamic(T&& value) { + return ToDynamic_>::apply(value); +} +template +BuilderFor>> toDynamic(T&& value) { + return ToDynamic_>::apply(value); +} +template +DynamicTypeFor> toDynamic(T&& value) { + return DynamicEnum(Schema::from>(), static_cast(value)); +} +template +typename DynamicTypeFor>::Client toDynamic(kj::Own&& value) { + return typename FromServer::Client(kj::mv(value)); +} + +inline DynamicValue::Reader::Reader(std::nullptr_t n): type(UNKNOWN) {} +inline DynamicValue::Builder::Builder(std::nullptr_t n): type(UNKNOWN) {} + +#define CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(cppType, typeTag, fieldName) \ +inline DynamicValue::Reader::Reader(cppType value) \ + : type(typeTag), fieldName##Value(value) {} \ +inline DynamicValue::Builder::Builder(cppType value) \ + : type(typeTag), fieldName##Value(value) {} \ +inline Orphan::Orphan(cppType value) \ + : type(DynamicValue::typeTag), fieldName##Value(value) {} + +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(Void, VOID, void); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(bool, BOOL, bool); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(char, INT, int); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(signed char, INT, int); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(short, INT, int); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(int, INT, int); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(long, INT, int); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(long long, INT, int); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(unsigned char, UINT, uint); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(unsigned short, UINT, uint); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(unsigned int, UINT, uint); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(unsigned long, UINT, uint); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(unsigned long long, UINT, uint); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(float, FLOAT, float); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(double, FLOAT, float); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(DynamicEnum, ENUM, enum); +#undef CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR + +#define CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(cppType, typeTag, fieldName) \ +inline DynamicValue::Reader::Reader(const cppType::Reader& value) \ + : type(typeTag), fieldName##Value(value) {} \ +inline DynamicValue::Builder::Builder(cppType::Builder value) \ + : type(typeTag), fieldName##Value(value) {} + +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(Text, TEXT, text); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(Data, DATA, data); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(DynamicList, LIST, list); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(DynamicStruct, STRUCT, struct); +CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR(AnyPointer, ANY_POINTER, anyPointer); + +#undef CAPNP_DECLARE_DYNAMIC_VALUE_CONSTRUCTOR + +inline DynamicValue::Reader::Reader(DynamicCapability::Client& value) + : type(CAPABILITY), capabilityValue(value) {} +inline DynamicValue::Reader::Reader(DynamicCapability::Client&& value) + : type(CAPABILITY), capabilityValue(kj::mv(value)) {} +template +inline DynamicValue::Reader::Reader(kj::Own&& value) + : type(CAPABILITY), capabilityValue(kj::mv(value)) {} +inline DynamicValue::Builder::Builder(DynamicCapability::Client& value) + : type(CAPABILITY), capabilityValue(value) {} +inline DynamicValue::Builder::Builder(DynamicCapability::Client&& value) + : type(CAPABILITY), capabilityValue(kj::mv(value)) {} + +inline DynamicValue::Reader::Reader(const char* value): Reader(Text::Reader(value)) {} + +#define CAPNP_DECLARE_TYPE(discrim, typeName) \ +template <> \ +struct DynamicValue::Reader::AsImpl { \ + static ReaderFor apply(const Reader& reader); \ +}; \ +template <> \ +struct DynamicValue::Builder::AsImpl { \ + static BuilderFor apply(Builder& builder); \ +}; + +//CAPNP_DECLARE_TYPE(VOID, Void) +CAPNP_DECLARE_TYPE(BOOL, bool) +CAPNP_DECLARE_TYPE(INT8, int8_t) +CAPNP_DECLARE_TYPE(INT16, int16_t) +CAPNP_DECLARE_TYPE(INT32, int32_t) +CAPNP_DECLARE_TYPE(INT64, int64_t) +CAPNP_DECLARE_TYPE(UINT8, uint8_t) +CAPNP_DECLARE_TYPE(UINT16, uint16_t) +CAPNP_DECLARE_TYPE(UINT32, uint32_t) +CAPNP_DECLARE_TYPE(UINT64, uint64_t) +CAPNP_DECLARE_TYPE(FLOAT32, float) +CAPNP_DECLARE_TYPE(FLOAT64, double) + +CAPNP_DECLARE_TYPE(TEXT, Text) +CAPNP_DECLARE_TYPE(DATA, Data) +CAPNP_DECLARE_TYPE(LIST, DynamicList) +CAPNP_DECLARE_TYPE(STRUCT, DynamicStruct) +CAPNP_DECLARE_TYPE(INTERFACE, DynamicCapability) +CAPNP_DECLARE_TYPE(ENUM, DynamicEnum) +CAPNP_DECLARE_TYPE(ANY_POINTER, AnyPointer) +#undef CAPNP_DECLARE_TYPE + +// CAPNP_DECLARE_TYPE(Void) causes gcc 4.7 to segfault. If I do it manually and remove the +// ReaderFor<> and BuilderFor<> wrappers, it works. +template <> +struct DynamicValue::Reader::AsImpl { + static Void apply(const Reader& reader); +}; +template <> +struct DynamicValue::Builder::AsImpl { + static Void apply(Builder& builder); +}; + +template +struct DynamicValue::Reader::AsImpl { + static T apply(const Reader& reader) { + return reader.as().as(); + } +}; +template +struct DynamicValue::Builder::AsImpl { + static T apply(Builder& builder) { + return builder.as().as(); + } +}; + +template +struct DynamicValue::Reader::AsImpl { + static typename T::Reader apply(const Reader& reader) { + return reader.as().as(); + } +}; +template +struct DynamicValue::Builder::AsImpl { + static typename T::Builder apply(Builder& builder) { + return builder.as().as(); + } +}; + +template +struct DynamicValue::Reader::AsImpl { + static typename T::Reader apply(const Reader& reader) { + return reader.as().as(); + } +}; +template +struct DynamicValue::Builder::AsImpl { + static typename T::Builder apply(Builder& builder) { + return builder.as().as(); + } +}; + +template +struct DynamicValue::Reader::AsImpl { + static typename T::Client apply(const Reader& reader) { + return reader.as().as(); + } +}; +template +struct DynamicValue::Builder::AsImpl { + static typename T::Client apply(Builder& builder) { + return builder.as().as(); + } +}; + +template <> +struct DynamicValue::Reader::AsImpl { + static DynamicValue::Reader apply(const Reader& reader) { + return reader; + } +}; +template <> +struct DynamicValue::Builder::AsImpl { + static DynamicValue::Builder apply(Builder& builder) { + return builder; + } +}; + +inline DynamicValue::Pipeline::Pipeline(std::nullptr_t n): type(UNKNOWN) {} +inline DynamicValue::Pipeline::Pipeline(DynamicStruct::Pipeline&& value) + : type(STRUCT), structValue(kj::mv(value)) {} +inline DynamicValue::Pipeline::Pipeline(DynamicCapability::Client&& value) + : type(CAPABILITY), capabilityValue(kj::mv(value)) {} + +template +struct DynamicValue::Pipeline::AsImpl { + static typename T::Pipeline apply(Pipeline& pipeline) { + return pipeline.releaseAs().releaseAs(); + } +}; +template +struct DynamicValue::Pipeline::AsImpl { + static typename T::Client apply(Pipeline& pipeline) { + return pipeline.releaseAs().releaseAs(); + } +}; +template <> +struct DynamicValue::Pipeline::AsImpl { + static PipelineFor apply(Pipeline& pipeline); +}; +template <> +struct DynamicValue::Pipeline::AsImpl { + static PipelineFor apply(Pipeline& pipeline); +}; + +// ------------------------------------------------------------------- + +template +typename T::Reader DynamicStruct::Reader::as() const { + static_assert(kind() == Kind::STRUCT, + "DynamicStruct::Reader::as() can only convert to struct types."); + schema.requireUsableAs(); + return typename T::Reader(reader); +} + +template +typename T::Builder DynamicStruct::Builder::as() { + static_assert(kind() == Kind::STRUCT, + "DynamicStruct::Builder::as() can only convert to struct types."); + schema.requireUsableAs(); + return typename T::Builder(builder); +} + +template <> +inline DynamicStruct::Reader DynamicStruct::Reader::as() const { + return *this; +} +template <> +inline DynamicStruct::Builder DynamicStruct::Builder::as() { + return *this; +} + +inline DynamicStruct::Reader DynamicStruct::Builder::asReader() const { + return DynamicStruct::Reader(schema, builder.asReader()); +} + +template <> +inline AnyStruct::Reader DynamicStruct::Reader::as() const { + return AnyStruct::Reader(reader); +} + +template <> +inline AnyStruct::Builder DynamicStruct::Builder::as() { + return AnyStruct::Builder(builder); +} + +template +typename T::Pipeline DynamicStruct::Pipeline::releaseAs() { + static_assert(kind() == Kind::STRUCT, + "DynamicStruct::Pipeline::releaseAs() can only convert to struct types."); + schema.requireUsableAs(); + return typename T::Pipeline(kj::mv(typeless)); +} + +// ------------------------------------------------------------------- + +template +typename T::Reader DynamicList::Reader::as() const { + static_assert(kind() == Kind::LIST, + "DynamicStruct::Reader::as() can only convert to list types."); + schema.requireUsableAs(); + return typename T::Reader(reader); +} +template +typename T::Builder DynamicList::Builder::as() { + static_assert(kind() == Kind::LIST, + "DynamicStruct::Builder::as() can only convert to list types."); + schema.requireUsableAs(); + return typename T::Builder(builder); +} + +template <> +inline DynamicList::Reader DynamicList::Reader::as() const { + return *this; +} +template <> +inline DynamicList::Builder DynamicList::Builder::as() { + return *this; +} + +template <> +inline AnyList::Reader DynamicList::Reader::as() const { + return AnyList::Reader(reader); +} + +template <> +inline AnyList::Builder DynamicList::Builder::as() { + return AnyList::Builder(builder); +} + +// ------------------------------------------------------------------- + +template +inline DynamicCapability::Client::Client(T&& client) + : Capability::Client(kj::mv(client)), schema(Schema::from>()) {} + +template +inline DynamicCapability::Client::Client(kj::Own&& server) + : Client(server->getSchema(), kj::mv(server)) {} +template +inline DynamicCapability::Client::Client(InterfaceSchema schema, kj::Own&& server) + : Capability::Client(kj::mv(server)), schema(schema) {} + +template +typename T::Client DynamicCapability::Client::as() { + static_assert(kind() == Kind::INTERFACE, + "DynamicCapability::Client::as() can only convert to interface types."); + schema.requireUsableAs(); + return typename T::Client(hook->addRef()); +} + +template +typename T::Client DynamicCapability::Client::releaseAs() { + static_assert(kind() == Kind::INTERFACE, + "DynamicCapability::Client::as() can only convert to interface types."); + schema.requireUsableAs(); + return typename T::Client(kj::mv(hook)); +} + +inline CallContext::CallContext( + CallContextHook& hook, StructSchema paramType, StructSchema resultType) + : hook(&hook), paramType(paramType), resultType(resultType) {} +inline DynamicStruct::Reader CallContext::getParams() { + return hook->getParams().getAs(paramType); +} +inline void CallContext::releaseParams() { + hook->releaseParams(); +} +inline DynamicStruct::Builder CallContext::getResults( + kj::Maybe sizeHint) { + return hook->getResults(sizeHint).getAs(resultType); +} +inline DynamicStruct::Builder CallContext::initResults( + kj::Maybe sizeHint) { + return hook->getResults(sizeHint).initAs(resultType); +} +inline void CallContext::setResults(DynamicStruct::Reader value) { + hook->getResults(value.totalSize()).setAs(value); +} +inline void CallContext::adoptResults(Orphan&& value) { + hook->getResults(MessageSize { 0, 0 }).adopt(kj::mv(value)); +} +inline Orphanage CallContext::getResultsOrphanage( + kj::Maybe sizeHint) { + return Orphanage::getForMessageContaining(hook->getResults(sizeHint)); +} +template +inline kj::Promise CallContext::tailCall( + Request&& tailRequest) { + return hook->tailCall(kj::mv(tailRequest.hook)); +} +inline void CallContext::allowCancellation() { + hook->allowCancellation(); +} + +template <> +inline DynamicCapability::Client Capability::Client::castAs( + InterfaceSchema schema) { + return DynamicCapability::Client(schema, hook->addRef()); +} + +// ------------------------------------------------------------------- + +template +ReaderFor ConstSchema::as() const { + return DynamicValue::Reader(*this).as(); +} + +} // namespace capnp + +#endif // CAPNP_DYNAMIC_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/endian.h b/phonelibs/capnp-cpp/include/capnp/endian.h new file mode 100644 index 00000000000000..c5a6e63c5a9584 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/endian.h @@ -0,0 +1,309 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_ENDIAN_H_ +#define CAPNP_ENDIAN_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "common.h" +#include +#include // memcpy + +namespace capnp { +namespace _ { // private + +// WireValue +// +// Wraps a primitive value as it appears on the wire. Namely, values are little-endian on the +// wire, because little-endian is the most common endianness in modern CPUs. +// +// Note: In general, code that depends cares about byte ordering is bad. See: +// http://commandcenter.blogspot.com/2012/04/byte-order-fallacy.html +// Cap'n Proto is special because it is essentially doing compiler-like things, fussing over +// allocation and layout of memory, in order to squeeze out every last drop of performance. + +#if _MSC_VER +// Assume Windows is little-endian. +// +// TODO(msvc): This is ugly. Maybe refactor later checks to be based on CAPNP_BYTE_ORDER or +// CAPNP_SWAP_BYTES or something, and define that in turn based on _MSC_VER or the GCC +// intrinsics. + +#ifndef __ORDER_BIG_ENDIAN__ +#define __ORDER_BIG_ENDIAN__ 4321 +#endif +#ifndef __ORDER_LITTLE_ENDIAN__ +#define __ORDER_LITTLE_ENDIAN__ 1234 +#endif +#ifndef __BYTE_ORDER__ +#define __BYTE_ORDER__ __ORDER_LITTLE_ENDIAN__ +#endif +#endif + +#if CAPNP_REVERSE_ENDIAN +#define CAPNP_WIRE_BYTE_ORDER __ORDER_BIG_ENDIAN__ +#define CAPNP_OPPOSITE_OF_WIRE_BYTE_ORDER __ORDER_LITTLE_ENDIAN__ +#else +#define CAPNP_WIRE_BYTE_ORDER __ORDER_LITTLE_ENDIAN__ +#define CAPNP_OPPOSITE_OF_WIRE_BYTE_ORDER __ORDER_BIG_ENDIAN__ +#endif + +#if defined(__BYTE_ORDER__) && \ + __BYTE_ORDER__ == CAPNP_WIRE_BYTE_ORDER && \ + !CAPNP_DISABLE_ENDIAN_DETECTION +// CPU is little-endian. We can just read/write the memory directly. + +template +class DirectWireValue { +public: + KJ_ALWAYS_INLINE(T get() const) { return value; } + KJ_ALWAYS_INLINE(void set(T newValue)) { value = newValue; } + +private: + T value; +}; + +template +using WireValue = DirectWireValue; +// To prevent ODR problems when endian-test, endian-reverse-test, and endian-fallback-test are +// linked together, we define each implementation with a different name and define an alias to the +// one we want to use. + +#elif defined(__BYTE_ORDER__) && \ + __BYTE_ORDER__ == CAPNP_OPPOSITE_OF_WIRE_BYTE_ORDER && \ + defined(__GNUC__) && !CAPNP_DISABLE_ENDIAN_DETECTION +// Big-endian, but GCC's __builtin_bswap() is available. + +// TODO(perf): Use dedicated instructions to read little-endian data on big-endian CPUs that have +// them. + +// TODO(perf): Verify that this code optimizes reasonably. In particular, ensure that the +// compiler optimizes away the memcpy()s and keeps everything in registers. + +template +class SwappingWireValue; + +template +class SwappingWireValue { +public: + KJ_ALWAYS_INLINE(T get() const) { return value; } + KJ_ALWAYS_INLINE(void set(T newValue)) { value = newValue; } + +private: + T value; +}; + +template +class SwappingWireValue { +public: + KJ_ALWAYS_INLINE(T get() const) { + // Not all platforms have __builtin_bswap16() for some reason. In particular, it is missing + // on gcc-4.7.3-cygwin32 (but present on gcc-4.8.1-cygwin64). + uint16_t swapped = (value << 8) | (value >> 8); + T result; + memcpy(&result, &swapped, sizeof(T)); + return result; + } + KJ_ALWAYS_INLINE(void set(T newValue)) { + uint16_t raw; + memcpy(&raw, &newValue, sizeof(T)); + // Not all platforms have __builtin_bswap16() for some reason. In particular, it is missing + // on gcc-4.7.3-cygwin32 (but present on gcc-4.8.1-cygwin64). + value = (raw << 8) | (raw >> 8); + } + +private: + uint16_t value; +}; + +template +class SwappingWireValue { +public: + KJ_ALWAYS_INLINE(T get() const) { + uint32_t swapped = __builtin_bswap32(value); + T result; + memcpy(&result, &swapped, sizeof(T)); + return result; + } + KJ_ALWAYS_INLINE(void set(T newValue)) { + uint32_t raw; + memcpy(&raw, &newValue, sizeof(T)); + value = __builtin_bswap32(raw); + } + +private: + uint32_t value; +}; + +template +class SwappingWireValue { +public: + KJ_ALWAYS_INLINE(T get() const) { + uint64_t swapped = __builtin_bswap64(value); + T result; + memcpy(&result, &swapped, sizeof(T)); + return result; + } + KJ_ALWAYS_INLINE(void set(T newValue)) { + uint64_t raw; + memcpy(&raw, &newValue, sizeof(T)); + value = __builtin_bswap64(raw); + } + +private: + uint64_t value; +}; + +template +using WireValue = SwappingWireValue; +// To prevent ODR problems when endian-test, endian-reverse-test, and endian-fallback-test are +// linked together, we define each implementation with a different name and define an alias to the +// one we want to use. + +#else +// Unknown endianness. Fall back to bit shifts. + +#if !CAPNP_DISABLE_ENDIAN_DETECTION +#if _MSC_VER +#pragma message("Couldn't detect endianness of your platform. Using unoptimized fallback implementation.") +#pragma message("Consider changing this code to detect your platform and send us a patch!") +#else +#warning "Couldn't detect endianness of your platform. Using unoptimized fallback implementation." +#warning "Consider changing this code to detect your platform and send us a patch!" +#endif +#endif // !CAPNP_DISABLE_ENDIAN_DETECTION + +template +class ShiftingWireValue; + +template +class ShiftingWireValue { +public: + KJ_ALWAYS_INLINE(T get() const) { return value; } + KJ_ALWAYS_INLINE(void set(T newValue)) { value = newValue; } + +private: + T value; +}; + +template +class ShiftingWireValue { +public: + KJ_ALWAYS_INLINE(T get() const) { + uint16_t raw = (static_cast(bytes[0]) ) | + (static_cast(bytes[1]) << 8); + T result; + memcpy(&result, &raw, sizeof(T)); + return result; + } + KJ_ALWAYS_INLINE(void set(T newValue)) { + uint16_t raw; + memcpy(&raw, &newValue, sizeof(T)); + bytes[0] = raw; + bytes[1] = raw >> 8; + } + +private: + union { + byte bytes[2]; + uint16_t align; + }; +}; + +template +class ShiftingWireValue { +public: + KJ_ALWAYS_INLINE(T get() const) { + uint32_t raw = (static_cast(bytes[0]) ) | + (static_cast(bytes[1]) << 8) | + (static_cast(bytes[2]) << 16) | + (static_cast(bytes[3]) << 24); + T result; + memcpy(&result, &raw, sizeof(T)); + return result; + } + KJ_ALWAYS_INLINE(void set(T newValue)) { + uint32_t raw; + memcpy(&raw, &newValue, sizeof(T)); + bytes[0] = raw; + bytes[1] = raw >> 8; + bytes[2] = raw >> 16; + bytes[3] = raw >> 24; + } + +private: + union { + byte bytes[4]; + uint32_t align; + }; +}; + +template +class ShiftingWireValue { +public: + KJ_ALWAYS_INLINE(T get() const) { + uint64_t raw = (static_cast(bytes[0]) ) | + (static_cast(bytes[1]) << 8) | + (static_cast(bytes[2]) << 16) | + (static_cast(bytes[3]) << 24) | + (static_cast(bytes[4]) << 32) | + (static_cast(bytes[5]) << 40) | + (static_cast(bytes[6]) << 48) | + (static_cast(bytes[7]) << 56); + T result; + memcpy(&result, &raw, sizeof(T)); + return result; + } + KJ_ALWAYS_INLINE(void set(T newValue)) { + uint64_t raw; + memcpy(&raw, &newValue, sizeof(T)); + bytes[0] = raw; + bytes[1] = raw >> 8; + bytes[2] = raw >> 16; + bytes[3] = raw >> 24; + bytes[4] = raw >> 32; + bytes[5] = raw >> 40; + bytes[6] = raw >> 48; + bytes[7] = raw >> 56; + } + +private: + union { + byte bytes[8]; + uint64_t align; + }; +}; + +template +using WireValue = ShiftingWireValue; +// To prevent ODR problems when endian-test, endian-reverse-test, and endian-fallback-test are +// linked together, we define each implementation with a different name and define an alias to the +// one we want to use. + +#endif + +} // namespace _ (private) +} // namespace capnp + +#endif // CAPNP_ENDIAN_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/ez-rpc.h b/phonelibs/capnp-cpp/include/capnp/ez-rpc.h new file mode 100644 index 00000000000000..fba5ace5820255 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/ez-rpc.h @@ -0,0 +1,254 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_EZ_RPC_H_ +#define CAPNP_EZ_RPC_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "rpc.h" +#include "message.h" + +struct sockaddr; + +namespace kj { class AsyncIoProvider; class LowLevelAsyncIoProvider; } + +namespace capnp { + +class EzRpcContext; + +class EzRpcClient { + // Super-simple interface for setting up a Cap'n Proto RPC client. Example: + // + // # Cap'n Proto schema + // interface Adder { + // add @0 (left :Int32, right :Int32) -> (value :Int32); + // } + // + // // C++ client + // int main() { + // capnp::EzRpcClient client("localhost:3456"); + // Adder::Client adder = client.getMain(); + // auto request = adder.addRequest(); + // request.setLeft(12); + // request.setRight(34); + // auto response = request.send().wait(client.getWaitScope()); + // assert(response.getValue() == 46); + // return 0; + // } + // + // // C++ server + // class AdderImpl final: public Adder::Server { + // public: + // kj::Promise add(AddContext context) override { + // auto params = context.getParams(); + // context.getResults().setValue(params.getLeft() + params.getRight()); + // return kj::READY_NOW; + // } + // }; + // + // int main() { + // capnp::EzRpcServer server(kj::heap(), "*:3456"); + // kj::NEVER_DONE.wait(server.getWaitScope()); + // } + // + // This interface is easy, but it hides a lot of useful features available from the lower-level + // classes: + // - The server can only export a small set of public, singleton capabilities under well-known + // string names. This is fine for transient services where no state needs to be kept between + // connections, but hides the power of Cap'n Proto when it comes to long-lived resources. + // - EzRpcClient/EzRpcServer automatically set up a `kj::EventLoop` and make it current for the + // thread. Only one `kj::EventLoop` can exist per thread, so you cannot use these interfaces + // if you wish to set up your own event loop. (However, you can safely create multiple + // EzRpcClient / EzRpcServer objects in a single thread; they will make sure to make no more + // than one EventLoop.) + // - These classes only support simple two-party connections, not multilateral VatNetworks. + // - These classes only support communication over a raw, unencrypted socket. If you want to + // build on an abstract stream (perhaps one which supports encryption), you must use the + // lower-level interfaces. + // + // Some of these restrictions will probably be lifted in future versions, but some things will + // always require using the low-level interfaces directly. If you are interested in working + // at a lower level, start by looking at these interfaces: + // - `kj::setupAsyncIo()` in `kj/async-io.h`. + // - `RpcSystem` in `capnp/rpc.h`. + // - `TwoPartyVatNetwork` in `capnp/rpc-twoparty.h`. + +public: + explicit EzRpcClient(kj::StringPtr serverAddress, uint defaultPort = 0, + ReaderOptions readerOpts = ReaderOptions()); + // Construct a new EzRpcClient and connect to the given address. The connection is formed in + // the background -- if it fails, calls to capabilities returned by importCap() will fail with an + // appropriate exception. + // + // `defaultPort` is the IP port number to use if `serverAddress` does not include it explicitly. + // If unspecified, the port is required in `serverAddress`. + // + // The address is parsed by `kj::Network` in `kj/async-io.h`. See that interface for more info + // on the address format, but basically it's what you'd expect. + // + // `readerOpts` is the ReaderOptions structure used to read each incoming message on the + // connection. Setting this may be necessary if you need to receive very large individual + // messages or messages. However, it is recommended that you instead think about how to change + // your protocol to send large data blobs in multiple small chunks -- this is much better for + // both security and performance. See `ReaderOptions` in `message.h` for more details. + + EzRpcClient(const struct sockaddr* serverAddress, uint addrSize, + ReaderOptions readerOpts = ReaderOptions()); + // Like the above constructor, but connects to an already-resolved socket address. Any address + // format supported by `kj::Network` in `kj/async-io.h` is accepted. + + explicit EzRpcClient(int socketFd, ReaderOptions readerOpts = ReaderOptions()); + // Create a client on top of an already-connected socket. + // `readerOpts` acts as in the first constructor. + + ~EzRpcClient() noexcept(false); + + template + typename Type::Client getMain(); + Capability::Client getMain(); + // Get the server's main (aka "bootstrap") interface. + + template + typename Type::Client importCap(kj::StringPtr name) + KJ_DEPRECATED("Change your server to export a main interface, then use getMain() instead."); + Capability::Client importCap(kj::StringPtr name) + KJ_DEPRECATED("Change your server to export a main interface, then use getMain() instead."); + // ** DEPRECATED ** + // + // Ask the sever for the capability with the given name. You may specify a type to automatically + // down-cast to that type. It is up to you to specify the correct expected type. + // + // Named interfaces are deprecated. The new preferred usage pattern is for the server to export + // a "main" interface which itself has methods for getting any other interfaces. + + kj::WaitScope& getWaitScope(); + // Get the `WaitScope` for the client's `EventLoop`, which allows you to synchronously wait on + // promises. + + kj::AsyncIoProvider& getIoProvider(); + // Get the underlying AsyncIoProvider set up by the RPC system. This is useful if you want + // to do some non-RPC I/O in asynchronous fashion. + + kj::LowLevelAsyncIoProvider& getLowLevelIoProvider(); + // Get the underlying LowLevelAsyncIoProvider set up by the RPC system. This is useful if you + // want to do some non-RPC I/O in asynchronous fashion. + +private: + struct Impl; + kj::Own impl; +}; + +class EzRpcServer { + // The server counterpart to `EzRpcClient`. See `EzRpcClient` for an example. + +public: + explicit EzRpcServer(Capability::Client mainInterface, kj::StringPtr bindAddress, + uint defaultPort = 0, ReaderOptions readerOpts = ReaderOptions()); + // Construct a new `EzRpcServer` that binds to the given address. An address of "*" means to + // bind to all local addresses. + // + // `defaultPort` is the IP port number to use if `serverAddress` does not include it explicitly. + // If unspecified, a port is chosen automatically, and you must call getPort() to find out what + // it is. + // + // The address is parsed by `kj::Network` in `kj/async-io.h`. See that interface for more info + // on the address format, but basically it's what you'd expect. + // + // The server might not begin listening immediately, especially if `bindAddress` needs to be + // resolved. If you need to wait until the server is definitely up, wait on the promise returned + // by `getPort()`. + // + // `readerOpts` is the ReaderOptions structure used to read each incoming message on the + // connection. Setting this may be necessary if you need to receive very large individual + // messages or messages. However, it is recommended that you instead think about how to change + // your protocol to send large data blobs in multiple small chunks -- this is much better for + // both security and performance. See `ReaderOptions` in `message.h` for more details. + + EzRpcServer(Capability::Client mainInterface, struct sockaddr* bindAddress, uint addrSize, + ReaderOptions readerOpts = ReaderOptions()); + // Like the above constructor, but binds to an already-resolved socket address. Any address + // format supported by `kj::Network` in `kj/async-io.h` is accepted. + + EzRpcServer(Capability::Client mainInterface, int socketFd, uint port, + ReaderOptions readerOpts = ReaderOptions()); + // Create a server on top of an already-listening socket (i.e. one on which accept() may be + // called). `port` is returned by `getPort()` -- it serves no other purpose. + // `readerOpts` acts as in the other two above constructors. + + explicit EzRpcServer(kj::StringPtr bindAddress, uint defaultPort = 0, + ReaderOptions readerOpts = ReaderOptions()) + KJ_DEPRECATED("Please specify a main interface for your server."); + EzRpcServer(struct sockaddr* bindAddress, uint addrSize, + ReaderOptions readerOpts = ReaderOptions()) + KJ_DEPRECATED("Please specify a main interface for your server."); + EzRpcServer(int socketFd, uint port, ReaderOptions readerOpts = ReaderOptions()) + KJ_DEPRECATED("Please specify a main interface for your server."); + + ~EzRpcServer() noexcept(false); + + void exportCap(kj::StringPtr name, Capability::Client cap); + // Export a capability publicly under the given name, so that clients can import it. + // + // Keep in mind that you can implicitly convert `kj::Own&&` to + // `Capability::Client`, so it's typical to pass something like + // `kj::heap()` as the second parameter. + + kj::Promise getPort(); + // Get the IP port number on which this server is listening. This promise won't resolve until + // the server is actually listening. If the address was not an IP address (e.g. it was a Unix + // domain socket) then getPort() resolves to zero. + + kj::WaitScope& getWaitScope(); + // Get the `WaitScope` for the client's `EventLoop`, which allows you to synchronously wait on + // promises. + + kj::AsyncIoProvider& getIoProvider(); + // Get the underlying AsyncIoProvider set up by the RPC system. This is useful if you want + // to do some non-RPC I/O in asynchronous fashion. + + kj::LowLevelAsyncIoProvider& getLowLevelIoProvider(); + // Get the underlying LowLevelAsyncIoProvider set up by the RPC system. This is useful if you + // want to do some non-RPC I/O in asynchronous fashion. + +private: + struct Impl; + kj::Own impl; +}; + +// ======================================================================================= +// inline implementation details + +template +inline typename Type::Client EzRpcClient::getMain() { + return getMain().castAs(); +} + +template +inline typename Type::Client EzRpcClient::importCap(kj::StringPtr name) { + return importCap(name).castAs(); +} + +} // namespace capnp + +#endif // CAPNP_EZ_RPC_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/generated-header-support.h b/phonelibs/capnp-cpp/include/capnp/generated-header-support.h new file mode 100644 index 00000000000000..51b6dd7c113c63 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/generated-header-support.h @@ -0,0 +1,407 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file is included from all generated headers. + +#ifndef CAPNP_GENERATED_HEADER_SUPPORT_H_ +#define CAPNP_GENERATED_HEADER_SUPPORT_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "raw-schema.h" +#include "layout.h" +#include "list.h" +#include "orphan.h" +#include "pointer-helpers.h" +#include "any.h" +#include +#include + +namespace capnp { + +class MessageBuilder; // So that it can be declared a friend. + +template +struct ToDynamic_; // Defined in dynamic.h, needs to be declared as everyone's friend. + +struct DynamicStruct; // So that it can be declared a friend. + +struct Capability; // To declare brandBindingFor() + +namespace _ { // private + +#if !CAPNP_LITE + +template +inline const RawSchema& rawSchema() { + return *CapnpPrivate::schema; +} +template ::typeId> +inline const RawSchema& rawSchema() { + return *schemas::EnumInfo::schema; +} + +template +inline const RawBrandedSchema& rawBrandedSchema() { + return *CapnpPrivate::brand(); +} +template ::typeId> +inline const RawBrandedSchema& rawBrandedSchema() { + return schemas::EnumInfo::schema->defaultBrand; +} + +template +struct ChooseBrand; +// If all of `Params` are `AnyPointer`, return the type's default brand. Otherwise, return a +// specific brand instance. TypeTag is the _capnpPrivate struct for the type in question. + +template +struct ChooseBrand { + // All params were AnyPointer. No specific brand needed. + static constexpr _::RawBrandedSchema const* brand() { return &TypeTag::schema->defaultBrand; } +}; + +template +struct ChooseBrand: public ChooseBrand {}; +// The first parameter is AnyPointer, so recurse to check the rest. + +template +struct ChooseBrand { + // At least one parameter is not AnyPointer, so use the specificBrand constant. + static constexpr _::RawBrandedSchema const* brand() { return &TypeTag::specificBrand; } +}; + +template ()> +struct BrandBindingFor_; + +#define HANDLE_TYPE(Type, which) \ + template <> \ + struct BrandBindingFor_ { \ + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { \ + return { which, listDepth, nullptr }; \ + } \ + } +HANDLE_TYPE(Void, 0); +HANDLE_TYPE(bool, 1); +HANDLE_TYPE(int8_t, 2); +HANDLE_TYPE(int16_t, 3); +HANDLE_TYPE(int32_t, 4); +HANDLE_TYPE(int64_t, 5); +HANDLE_TYPE(uint8_t, 6); +HANDLE_TYPE(uint16_t, 7); +HANDLE_TYPE(uint32_t, 8); +HANDLE_TYPE(uint64_t, 9); +HANDLE_TYPE(float, 10); +HANDLE_TYPE(double, 11); +#undef HANDLE_TYPE + +template <> +struct BrandBindingFor_ { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return { 12, listDepth, nullptr }; + } +}; + +template <> +struct BrandBindingFor_ { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return { 13, listDepth, nullptr }; + } +}; + +template +struct BrandBindingFor_, Kind::LIST> { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return BrandBindingFor_::get(listDepth + 1); + } +}; + +template +struct BrandBindingFor_ { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return { 15, listDepth, nullptr }; + } +}; + +template +struct BrandBindingFor_ { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return { 16, listDepth, T::_capnpPrivate::brand() }; + } +}; + +template +struct BrandBindingFor_ { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return { 17, listDepth, T::_capnpPrivate::brand() }; + } +}; + +template <> +struct BrandBindingFor_ { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return { 18, listDepth, 0, 0 }; + } +}; + +template <> +struct BrandBindingFor_ { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return { 18, listDepth, 0, 1 }; + } +}; + +template <> +struct BrandBindingFor_ { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return { 18, listDepth, 0, 2 }; + } +}; + +template <> +struct BrandBindingFor_ { + static constexpr RawBrandedSchema::Binding get(uint16_t listDepth) { + return { 18, listDepth, 0, 3 }; + } +}; + +template +constexpr RawBrandedSchema::Binding brandBindingFor() { + return BrandBindingFor_::get(0); +} + +kj::StringTree structString(StructReader reader, const RawBrandedSchema& schema); +kj::String enumString(uint16_t value, const RawBrandedSchema& schema); +// Declared here so that we can declare inline stringify methods on generated types. +// Defined in stringify.c++, which depends on dynamic.c++, which is allowed not to be linked in. + +template +inline kj::StringTree structString(StructReader reader) { + return structString(reader, rawBrandedSchema()); +} +template +inline kj::String enumString(T value) { + return enumString(static_cast(value), rawBrandedSchema()); +} + +#endif // !CAPNP_LITE + +// TODO(cleanup): Unify ConstStruct and ConstList. +template +class ConstStruct { +public: + ConstStruct() = delete; + KJ_DISALLOW_COPY(ConstStruct); + inline explicit constexpr ConstStruct(const word* ptr): ptr(ptr) {} + + inline typename T::Reader get() const { + return AnyPointer::Reader(PointerReader::getRootUnchecked(ptr)).getAs(); + } + + inline operator typename T::Reader() const { return get(); } + inline typename T::Reader operator*() const { return get(); } + inline TemporaryPointer operator->() const { return get(); } + +private: + const word* ptr; +}; + +template +class ConstList { +public: + ConstList() = delete; + KJ_DISALLOW_COPY(ConstList); + inline explicit constexpr ConstList(const word* ptr): ptr(ptr) {} + + inline typename List::Reader get() const { + return AnyPointer::Reader(PointerReader::getRootUnchecked(ptr)).getAs>(); + } + + inline operator typename List::Reader() const { return get(); } + inline typename List::Reader operator*() const { return get(); } + inline TemporaryPointer::Reader> operator->() const { return get(); } + +private: + const word* ptr; +}; + +template +class ConstText { +public: + ConstText() = delete; + KJ_DISALLOW_COPY(ConstText); + inline explicit constexpr ConstText(const word* ptr): ptr(ptr) {} + + inline Text::Reader get() const { + return Text::Reader(reinterpret_cast(ptr), size); + } + + inline operator Text::Reader() const { return get(); } + inline Text::Reader operator*() const { return get(); } + inline TemporaryPointer operator->() const { return get(); } + + inline kj::StringPtr toString() const { + return get(); + } + +private: + const word* ptr; +}; + +template +inline kj::StringPtr KJ_STRINGIFY(const ConstText& s) { + return s.get(); +} + +template +class ConstData { +public: + ConstData() = delete; + KJ_DISALLOW_COPY(ConstData); + inline explicit constexpr ConstData(const word* ptr): ptr(ptr) {} + + inline Data::Reader get() const { + return Data::Reader(reinterpret_cast(ptr), size); + } + + inline operator Data::Reader() const { return get(); } + inline Data::Reader operator*() const { return get(); } + inline TemporaryPointer operator->() const { return get(); } + +private: + const word* ptr; +}; + +template +inline auto KJ_STRINGIFY(const ConstData& s) -> decltype(kj::toCharSequence(s.get())) { + return kj::toCharSequence(s.get()); +} + +} // namespace _ (private) + +template +inline constexpr uint64_t typeId() { return CapnpPrivate::typeId; } +template ::typeId> +inline constexpr uint64_t typeId() { return id; } +// typeId() returns the type ID as defined in the schema. Works with structs, enums, and +// interfaces. + +template +inline constexpr uint sizeInWords() { + // Return the size, in words, of a Struct type, if allocated free-standing (not in a list). + // May be useful for pre-computing space needed in order to precisely allocate messages. + + return unbound((upgradeBound(_::structSize().data) + + _::structSize().pointers * WORDS_PER_POINTER) / WORDS); +} + +} // namespace capnp + +#if _MSC_VER +// MSVC doesn't understand floating-point constexpr yet. +// +// TODO(msvc): Remove this hack when MSVC is fixed. +#define CAPNP_NON_INT_CONSTEXPR_DECL_INIT(value) +#define CAPNP_NON_INT_CONSTEXPR_DEF_INIT(value) = value +#else +#define CAPNP_NON_INT_CONSTEXPR_DECL_INIT(value) = value +#define CAPNP_NON_INT_CONSTEXPR_DEF_INIT(value) +#endif + +#if _MSC_VER +// TODO(msvc): A little hack to allow MSVC to use C++14 return type deduction in cases where the +// explicit type exposes bugs in the compiler. +#define CAPNP_AUTO_IF_MSVC(...) auto +#else +#define CAPNP_AUTO_IF_MSVC(...) __VA_ARGS__ +#endif + +#if CAPNP_LITE + +#define CAPNP_DECLARE_SCHEMA(id) \ + extern ::capnp::word const* const bp_##id + +#define CAPNP_DECLARE_ENUM(type, id) \ + inline ::kj::String KJ_STRINGIFY(type##_##id value) { \ + return ::kj::str(static_cast(value)); \ + } \ + template <> struct EnumInfo { \ + struct IsEnum; \ + static constexpr uint64_t typeId = 0x##id; \ + static inline ::capnp::word const* encodedSchema() { return bp_##id; } \ + } + +#if _MSC_VER +// TODO(msvc): MSVC dosen't expect constexprs to have definitions. +#define CAPNP_DEFINE_ENUM(type, id) +#else +#define CAPNP_DEFINE_ENUM(type, id) \ + constexpr uint64_t EnumInfo::typeId +#endif + +#define CAPNP_DECLARE_STRUCT_HEADER(id, dataWordSize_, pointerCount_) \ + struct IsStruct; \ + static constexpr uint64_t typeId = 0x##id; \ + static constexpr uint16_t dataWordSize = dataWordSize_; \ + static constexpr uint16_t pointerCount = pointerCount_; \ + static inline ::capnp::word const* encodedSchema() { return ::capnp::schemas::bp_##id; } + +#else // CAPNP_LITE + +#define CAPNP_DECLARE_SCHEMA(id) \ + extern ::capnp::word const* const bp_##id; \ + extern const ::capnp::_::RawSchema s_##id + +#define CAPNP_DECLARE_ENUM(type, id) \ + inline ::kj::String KJ_STRINGIFY(type##_##id value) { \ + return ::capnp::_::enumString(value); \ + } \ + template <> struct EnumInfo { \ + struct IsEnum; \ + static constexpr uint64_t typeId = 0x##id; \ + static inline ::capnp::word const* encodedSchema() { return bp_##id; } \ + static constexpr ::capnp::_::RawSchema const* schema = &s_##id; \ + } +#define CAPNP_DEFINE_ENUM(type, id) \ + constexpr uint64_t EnumInfo::typeId; \ + constexpr ::capnp::_::RawSchema const* EnumInfo::schema + +#define CAPNP_DECLARE_STRUCT_HEADER(id, dataWordSize_, pointerCount_) \ + struct IsStruct; \ + static constexpr uint64_t typeId = 0x##id; \ + static constexpr ::capnp::Kind kind = ::capnp::Kind::STRUCT; \ + static constexpr uint16_t dataWordSize = dataWordSize_; \ + static constexpr uint16_t pointerCount = pointerCount_; \ + static inline ::capnp::word const* encodedSchema() { return ::capnp::schemas::bp_##id; } \ + static constexpr ::capnp::_::RawSchema const* schema = &::capnp::schemas::s_##id; + +#define CAPNP_DECLARE_INTERFACE_HEADER(id) \ + struct IsInterface; \ + static constexpr uint64_t typeId = 0x##id; \ + static constexpr ::capnp::Kind kind = ::capnp::Kind::INTERFACE; \ + static inline ::capnp::word const* encodedSchema() { return ::capnp::schemas::bp_##id; } \ + static constexpr ::capnp::_::RawSchema const* schema = &::capnp::schemas::s_##id; + +#endif // CAPNP_LITE, else + +#endif // CAPNP_GENERATED_HEADER_SUPPORT_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/json.capnp b/phonelibs/capnp-cpp/include/capnp/json.capnp new file mode 100644 index 00000000000000..55188736f8bdb2 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/json.capnp @@ -0,0 +1,58 @@ +# Copyright (c) 2015 Sandstorm Development Group, Inc. and contributors +# Licensed under the MIT License: +# +# Permission is hereby granted, free of charge, to any person obtaining a copy +# of this software and associated documentation files (the "Software"), to deal +# in the Software without restriction, including without limitation the rights +# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +# copies of the Software, and to permit persons to whom the Software is +# furnished to do so, subject to the following conditions: +# +# The above copyright notice and this permission notice shall be included in +# all copies or substantial portions of the Software. +# +# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +# THE SOFTWARE. + +@0x8ef99297a43a5e34; + +$import "/capnp/c++.capnp".namespace("capnp"); + +struct JsonValue { + union { + null @0 :Void; + boolean @1 :Bool; + number @2 :Float64; + string @3 :Text; + array @4 :List(JsonValue); + object @5 :List(Field); + # Standard JSON values. + + call @6 :Call; + # Non-standard: A "function call", applying a named function (named by a single identifier) + # to a parameter list. Examples: + # + # BinData(0, "Zm9vCg==") + # ISODate("2015-04-15T08:44:50.218Z") + # + # Mongo DB users will recognize the above as exactly the syntax Mongo uses to represent BSON + # "binary" and "date" types in text, since JSON has no analog of these. This is basically the + # reason this extension exists. We do NOT recommend using `call` unless you specifically need + # to be compatible with some silly format that uses this syntax. + } + + struct Field { + name @0 :Text; + value @1 :JsonValue; + } + + struct Call { + function @0 :Text; + params @1 :List(JsonValue); + } +} diff --git a/phonelibs/capnp-cpp/include/capnp/layout.h b/phonelibs/capnp-cpp/include/capnp/layout.h new file mode 100644 index 00000000000000..99dc533b2bf157 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/layout.h @@ -0,0 +1,1274 @@ +// Copyright (c) 2013-2016 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file is NOT intended for use by clients, except in generated code. +// +// This file defines low-level, non-type-safe classes for traversing the Cap'n Proto memory layout +// (which is also its wire format). Code generated by the Cap'n Proto compiler uses these classes, +// as does other parts of the Cap'n proto library which provide a higher-level interface for +// dynamic introspection. + +#ifndef CAPNP_LAYOUT_H_ +#define CAPNP_LAYOUT_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include +#include +#include "common.h" +#include "blob.h" +#include "endian.h" + +#if (defined(__mips__) || defined(__hppa__)) && !defined(CAPNP_CANONICALIZE_NAN) +#define CAPNP_CANONICALIZE_NAN 1 +// Explicitly detect NaNs and canonicalize them to the quiet NaN value as would be returned by +// __builtin_nan("") on systems implementing the IEEE-754 recommended (but not required) NaN +// signalling/quiet differentiation (such as x86). Unfortunately, some architectures -- in +// particular, MIPS -- represent quiet vs. signalling nans differently than the rest of the world. +// Canonicalizing them makes output consistent (which is important!), but hurts performance +// slightly. +// +// Note that trying to convert MIPS NaNs to standard NaNs without losing data doesn't work. +// Signaling vs. quiet is indicated by a bit, with the meaning being the opposite on MIPS vs. +// everyone else. It would be great if we could just flip that bit, but we can't, because if the +// significand is all-zero, then the value is infinity rather than NaN. This means that on most +// machines, where the bit indicates quietness, there is one more quiet NaN value than signalling +// NaN value, whereas on MIPS there is one more sNaN than qNaN, and thus there is no isomorphic +// mapping that properly preserves quietness. Instead of doing something hacky, we just give up +// and blow away NaN payloads, because no one uses them anyway. +#endif + +namespace capnp { + +#if !CAPNP_LITE +class ClientHook; +#endif // !CAPNP_LITE + +namespace _ { // private + +class PointerBuilder; +class PointerReader; +class StructBuilder; +class StructReader; +class ListBuilder; +class ListReader; +class OrphanBuilder; +struct WirePointer; +struct WireHelpers; +class SegmentReader; +class SegmentBuilder; +class Arena; +class BuilderArena; + +// ============================================================================= + +#if CAPNP_DEBUG_TYPES +typedef kj::UnitRatio, BitLabel, ElementLabel> BitsPerElementTableType; +#else +typedef uint BitsPerElementTableType; +#endif + +static constexpr BitsPerElementTableType BITS_PER_ELEMENT_TABLE[8] = { + bounded< 0>() * BITS / ELEMENTS, + bounded< 1>() * BITS / ELEMENTS, + bounded< 8>() * BITS / ELEMENTS, + bounded<16>() * BITS / ELEMENTS, + bounded<32>() * BITS / ELEMENTS, + bounded<64>() * BITS / ELEMENTS, + bounded< 0>() * BITS / ELEMENTS, + bounded< 0>() * BITS / ELEMENTS +}; + +inline KJ_CONSTEXPR() BitsPerElementTableType dataBitsPerElement(ElementSize size) { + return _::BITS_PER_ELEMENT_TABLE[static_cast(size)]; +} + +inline constexpr PointersPerElementN<1> pointersPerElement(ElementSize size) { + return size == ElementSize::POINTER + ? PointersPerElementN<1>(ONE * POINTERS / ELEMENTS) + : PointersPerElementN<1>(ZERO * POINTERS / ELEMENTS); +} + +static constexpr BitsPerElementTableType BITS_PER_ELEMENT_INCLUDING_PONITERS_TABLE[8] = { + bounded< 0>() * BITS / ELEMENTS, + bounded< 1>() * BITS / ELEMENTS, + bounded< 8>() * BITS / ELEMENTS, + bounded<16>() * BITS / ELEMENTS, + bounded<32>() * BITS / ELEMENTS, + bounded<64>() * BITS / ELEMENTS, + bounded<64>() * BITS / ELEMENTS, + bounded< 0>() * BITS / ELEMENTS +}; + +inline KJ_CONSTEXPR() BitsPerElementTableType bitsPerElementIncludingPointers(ElementSize size) { + return _::BITS_PER_ELEMENT_INCLUDING_PONITERS_TABLE[static_cast(size)]; +} + +template struct ElementSizeForByteSize; +template <> struct ElementSizeForByteSize<1> { static constexpr ElementSize value = ElementSize::BYTE; }; +template <> struct ElementSizeForByteSize<2> { static constexpr ElementSize value = ElementSize::TWO_BYTES; }; +template <> struct ElementSizeForByteSize<4> { static constexpr ElementSize value = ElementSize::FOUR_BYTES; }; +template <> struct ElementSizeForByteSize<8> { static constexpr ElementSize value = ElementSize::EIGHT_BYTES; }; + +template struct ElementSizeForType { + static constexpr ElementSize value = + // Primitive types that aren't special-cased below can be determined from sizeof(). + CAPNP_KIND(T) == Kind::PRIMITIVE ? ElementSizeForByteSize::value : + CAPNP_KIND(T) == Kind::ENUM ? ElementSize::TWO_BYTES : + CAPNP_KIND(T) == Kind::STRUCT ? ElementSize::INLINE_COMPOSITE : + + // Everything else is a pointer. + ElementSize::POINTER; +}; + +// Void and bool are special. +template <> struct ElementSizeForType { static constexpr ElementSize value = ElementSize::VOID; }; +template <> struct ElementSizeForType { static constexpr ElementSize value = ElementSize::BIT; }; + +// Lists and blobs are pointers, not structs. +template struct ElementSizeForType> { + static constexpr ElementSize value = ElementSize::POINTER; +}; +template <> struct ElementSizeForType { + static constexpr ElementSize value = ElementSize::POINTER; +}; +template <> struct ElementSizeForType { + static constexpr ElementSize value = ElementSize::POINTER; +}; + +template +inline constexpr ElementSize elementSizeForType() { + return ElementSizeForType::value; +} + +struct MessageSizeCounts { + WordCountN<61, uint64_t> wordCount; // 2^64 bytes + uint capCount; + + MessageSizeCounts& operator+=(const MessageSizeCounts& other) { + // OK to truncate unchecked because this class is used to count actual stuff in memory, and + // we couldn't possibly have anywhere near 2^61 words. + wordCount = assumeBits<61>(wordCount + other.wordCount); + capCount += other.capCount; + return *this; + } + + void addWords(WordCountN<61, uint64_t> other) { + wordCount = assumeBits<61>(wordCount + other); + } + + MessageSize asPublic() { + return MessageSize { unbound(wordCount / WORDS), capCount }; + } +}; + +// ============================================================================= + +template +union AlignedData { + // Useful for declaring static constant data blobs as an array of bytes, but forcing those + // bytes to be word-aligned. + + uint8_t bytes[wordCount * sizeof(word)]; + word words[wordCount]; +}; + +struct StructSize { + StructDataWordCount data; + StructPointerCount pointers; + + inline constexpr WordCountN<17> total() const { return data + pointers * WORDS_PER_POINTER; } + + StructSize() = default; + inline constexpr StructSize(StructDataWordCount data, StructPointerCount pointers) + : data(data), pointers(pointers) {} +}; + +template +inline constexpr StructSize structSize() { + return StructSize(bounded(CapnpPrivate::dataWordSize) * WORDS, + bounded(CapnpPrivate::pointerCount) * POINTERS); +} + +template > +inline constexpr StructSize minStructSizeForElement() { + // If T is a struct, return its struct size. Otherwise return the minimum struct size big enough + // to hold a T. + + return StructSize(bounded(CapnpPrivate::dataWordSize) * WORDS, + bounded(CapnpPrivate::pointerCount) * POINTERS); +} + +template > +inline constexpr StructSize minStructSizeForElement() { + // If T is a struct, return its struct size. Otherwise return the minimum struct size big enough + // to hold a T. + + return StructSize( + dataBitsPerElement(elementSizeForType()) * ELEMENTS > ZERO * BITS + ? StructDataWordCount(ONE * WORDS) : StructDataWordCount(ZERO * WORDS), + pointersPerElement(elementSizeForType()) * ELEMENTS); +} + +// ------------------------------------------------------------------- +// Masking of default values + +template struct Mask_; +template struct Mask_ { typedef T Type; }; +template struct Mask_ { typedef uint16_t Type; }; +template <> struct Mask_ { typedef uint32_t Type; }; +template <> struct Mask_ { typedef uint64_t Type; }; + +template struct Mask_ { + // Union discriminants end up here. + static_assert(sizeof(T) == 2, "Don't know how to mask this type."); + typedef uint16_t Type; +}; + +template +using Mask = typename Mask_::Type; + +template +KJ_ALWAYS_INLINE(Mask mask(T value, Mask mask)); +template +KJ_ALWAYS_INLINE(T unmask(Mask value, Mask mask)); + +template +inline Mask mask(T value, Mask mask) { + return static_cast >(value) ^ mask; +} + +template <> +inline uint32_t mask(float value, uint32_t mask) { +#if CAPNP_CANONICALIZE_NAN + if (value != value) { + return 0x7fc00000u ^ mask; + } +#endif + + uint32_t i; + static_assert(sizeof(i) == sizeof(value), "float is not 32 bits?"); + memcpy(&i, &value, sizeof(value)); + return i ^ mask; +} + +template <> +inline uint64_t mask(double value, uint64_t mask) { +#if CAPNP_CANONICALIZE_NAN + if (value != value) { + return 0x7ff8000000000000ull ^ mask; + } +#endif + + uint64_t i; + static_assert(sizeof(i) == sizeof(value), "double is not 64 bits?"); + memcpy(&i, &value, sizeof(value)); + return i ^ mask; +} + +template +inline T unmask(Mask value, Mask mask) { + return static_cast(value ^ mask); +} + +template <> +inline float unmask(uint32_t value, uint32_t mask) { + value ^= mask; + float result; + static_assert(sizeof(result) == sizeof(value), "float is not 32 bits?"); + memcpy(&result, &value, sizeof(value)); + return result; +} + +template <> +inline double unmask(uint64_t value, uint64_t mask) { + value ^= mask; + double result; + static_assert(sizeof(result) == sizeof(value), "double is not 64 bits?"); + memcpy(&result, &value, sizeof(value)); + return result; +} + +// ------------------------------------------------------------------- + +class CapTableReader { +public: +#if !CAPNP_LITE + virtual kj::Maybe> extractCap(uint index) = 0; + // Extract the capability at the given index. If the index is invalid, returns null. +#endif // !CAPNP_LITE +}; + +class CapTableBuilder: public CapTableReader { +public: +#if !CAPNP_LITE + virtual uint injectCap(kj::Own&& cap) = 0; + // Add the capability to the message and return its index. If the same ClientHook is injected + // twice, this may return the same index both times, but in this case dropCap() needs to be + // called an equal number of times to actually remove the cap. + + virtual void dropCap(uint index) = 0; + // Remove a capability injected earlier. Called when the pointer is overwritten or zero'd out. +#endif // !CAPNP_LITE +}; + +// ------------------------------------------------------------------- + +class PointerBuilder: public kj::DisallowConstCopy { + // Represents a single pointer, usually embedded in a struct or a list. + +public: + inline PointerBuilder(): segment(nullptr), capTable(nullptr), pointer(nullptr) {} + + static inline PointerBuilder getRoot( + SegmentBuilder* segment, CapTableBuilder* capTable, word* location); + // Get a PointerBuilder representing a message root located in the given segment at the given + // location. + + inline bool isNull() { return getPointerType() == PointerType::NULL_; } + PointerType getPointerType() const; + + StructBuilder getStruct(StructSize size, const word* defaultValue); + ListBuilder getList(ElementSize elementSize, const word* defaultValue); + ListBuilder getStructList(StructSize elementSize, const word* defaultValue); + ListBuilder getListAnySize(const word* defaultValue); + template typename T::Builder getBlob( + const void* defaultValue, ByteCount defaultSize); +#if !CAPNP_LITE + kj::Own getCapability(); +#endif // !CAPNP_LITE + // Get methods: Get the value. If it is null, initialize it to a copy of the default value. + // The default value is encoded as an "unchecked message" for structs, lists, and objects, or a + // simple byte array for blobs. + + StructBuilder initStruct(StructSize size); + ListBuilder initList(ElementSize elementSize, ElementCount elementCount); + ListBuilder initStructList(ElementCount elementCount, StructSize size); + template typename T::Builder initBlob(ByteCount size); + // Init methods: Initialize the pointer to a newly-allocated object, discarding the existing + // object. + + void setStruct(const StructReader& value, bool canonical = false); + void setList(const ListReader& value, bool canonical = false); + template void setBlob(typename T::Reader value); +#if !CAPNP_LITE + void setCapability(kj::Own&& cap); +#endif // !CAPNP_LITE + // Set methods: Initialize the pointer to a newly-allocated copy of the given value, discarding + // the existing object. + + void adopt(OrphanBuilder&& orphan); + // Set the pointer to point at the given orphaned value. + + OrphanBuilder disown(); + // Set the pointer to null and return its previous value as an orphan. + + void clear(); + // Clear the pointer to null, discarding its previous value. + + void transferFrom(PointerBuilder other); + // Equivalent to `adopt(other.disown())`. + + void copyFrom(PointerReader other, bool canonical = false); + // Equivalent to `set(other.get())`. + // If you set the canonical flag, it will attempt to lay the target out + // canonically, provided enough space is available. + + PointerReader asReader() const; + + BuilderArena* getArena() const; + // Get the arena containing this pointer. + + CapTableBuilder* getCapTable(); + // Gets the capability context in which this object is operating. + + PointerBuilder imbue(CapTableBuilder* capTable); + // Return a copy of this builder except using the given capability context. + +private: + SegmentBuilder* segment; // Memory segment in which the pointer resides. + CapTableBuilder* capTable; // Table of capability indexes. + WirePointer* pointer; // Pointer to the pointer. + + inline PointerBuilder(SegmentBuilder* segment, CapTableBuilder* capTable, WirePointer* pointer) + : segment(segment), capTable(capTable), pointer(pointer) {} + + friend class StructBuilder; + friend class ListBuilder; + friend class OrphanBuilder; +}; + +class PointerReader { +public: + inline PointerReader() + : segment(nullptr), capTable(nullptr), pointer(nullptr), nestingLimit(0x7fffffff) {} + + static PointerReader getRoot(SegmentReader* segment, CapTableReader* capTable, + const word* location, int nestingLimit); + // Get a PointerReader representing a message root located in the given segment at the given + // location. + + static inline PointerReader getRootUnchecked(const word* location); + // Get a PointerReader for an unchecked message. + + MessageSizeCounts targetSize() const; + // Return the total size of the target object and everything to which it points. Does not count + // far pointer overhead. This is useful for deciding how much space is needed to copy the object + // into a flat array. However, the caller is advised NOT to treat this value as secure. Instead, + // use the result as a hint for allocating the first segment, do the copy, and then throw an + // exception if it overruns. + + inline bool isNull() const { return getPointerType() == PointerType::NULL_; } + PointerType getPointerType() const; + + StructReader getStruct(const word* defaultValue) const; + ListReader getList(ElementSize expectedElementSize, const word* defaultValue) const; + ListReader getListAnySize(const word* defaultValue) const; + template + typename T::Reader getBlob(const void* defaultValue, ByteCount defaultSize) const; +#if !CAPNP_LITE + kj::Own getCapability() const; +#endif // !CAPNP_LITE + // Get methods: Get the value. If it is null, return the default value instead. + // The default value is encoded as an "unchecked message" for structs, lists, and objects, or a + // simple byte array for blobs. + + const word* getUnchecked() const; + // If this is an unchecked message, get a word* pointing at the location of the pointer. This + // word* can actually be passed to readUnchecked() to read the designated sub-object later. If + // this isn't an unchecked message, throws an exception. + + kj::Maybe getArena() const; + // Get the arena containing this pointer. + + CapTableReader* getCapTable(); + // Gets the capability context in which this object is operating. + + PointerReader imbue(CapTableReader* capTable) const; + // Return a copy of this reader except using the given capability context. + + bool isCanonical(const word **readHead); + // Validate this pointer's canonicity, subject to the conditions: + // * All data to the left of readHead has been read thus far (for pointer + // ordering) + // * All pointers in preorder have already been checked + // * This pointer is in the first and only segment of the message + +private: + SegmentReader* segment; // Memory segment in which the pointer resides. + CapTableReader* capTable; // Table of capability indexes. + const WirePointer* pointer; // Pointer to the pointer. null = treat as null pointer. + + int nestingLimit; + // Limits the depth of message structures to guard against stack-overflow-based DoS attacks. + // Once this reaches zero, further pointers will be pruned. + + inline PointerReader(SegmentReader* segment, CapTableReader* capTable, + const WirePointer* pointer, int nestingLimit) + : segment(segment), capTable(capTable), pointer(pointer), nestingLimit(nestingLimit) {} + + friend class StructReader; + friend class ListReader; + friend class PointerBuilder; + friend class OrphanBuilder; +}; + +// ------------------------------------------------------------------- + +class StructBuilder: public kj::DisallowConstCopy { +public: + inline StructBuilder(): segment(nullptr), capTable(nullptr), data(nullptr), pointers(nullptr) {} + + inline word* getLocation() { return reinterpret_cast(data); } + // Get the object's location. Only valid for independently-allocated objects (i.e. not list + // elements). + + inline StructDataBitCount getDataSectionSize() const { return dataSize; } + inline StructPointerCount getPointerSectionSize() const { return pointerCount; } + inline kj::ArrayPtr getDataSectionAsBlob(); + inline _::ListBuilder getPointerSectionAsList(); + + template + KJ_ALWAYS_INLINE(bool hasDataField(StructDataOffset offset)); + // Return true if the field is set to something other than its default value. + + template + KJ_ALWAYS_INLINE(T getDataField(StructDataOffset offset)); + // Gets the data field value of the given type at the given offset. The offset is measured in + // multiples of the field size, determined by the type. + + template + KJ_ALWAYS_INLINE(T getDataField(StructDataOffset offset, Mask mask)); + // Like getDataField() but applies the given XOR mask to the data on load. Used for reading + // fields with non-zero default values. + + template + KJ_ALWAYS_INLINE(void setDataField(StructDataOffset offset, kj::NoInfer value)); + // Sets the data field value at the given offset. + + template + KJ_ALWAYS_INLINE(void setDataField(StructDataOffset offset, + kj::NoInfer value, Mask mask)); + // Like setDataField() but applies the given XOR mask before storing. Used for writing fields + // with non-zero default values. + + KJ_ALWAYS_INLINE(PointerBuilder getPointerField(StructPointerOffset ptrIndex)); + // Get a builder for a pointer field given the index within the pointer section. + + void clearAll(); + // Clear all pointers and data. + + void transferContentFrom(StructBuilder other); + // Adopt all pointers from `other`, and also copy all data. If `other`'s sections are larger + // than this, the extra data is not transferred, meaning there is a risk of data loss when + // transferring from messages built with future versions of the protocol. + + void copyContentFrom(StructReader other); + // Copy content from `other`. If `other`'s sections are larger than this, the extra data is not + // copied, meaning there is a risk of data loss when copying from messages built with future + // versions of the protocol. + + StructReader asReader() const; + // Gets a StructReader pointing at the same memory. + + BuilderArena* getArena(); + // Gets the arena in which this object is allocated. + + CapTableBuilder* getCapTable(); + // Gets the capability context in which this object is operating. + + StructBuilder imbue(CapTableBuilder* capTable); + // Return a copy of this builder except using the given capability context. + +private: + SegmentBuilder* segment; // Memory segment in which the struct resides. + CapTableBuilder* capTable; // Table of capability indexes. + void* data; // Pointer to the encoded data. + WirePointer* pointers; // Pointer to the encoded pointers. + + StructDataBitCount dataSize; + // Size of data section. We use a bit count rather than a word count to more easily handle the + // case of struct lists encoded with less than a word per element. + + StructPointerCount pointerCount; // Size of the pointer section. + + inline StructBuilder(SegmentBuilder* segment, CapTableBuilder* capTable, + void* data, WirePointer* pointers, + StructDataBitCount dataSize, StructPointerCount pointerCount) + : segment(segment), capTable(capTable), data(data), pointers(pointers), + dataSize(dataSize), pointerCount(pointerCount) {} + + friend class ListBuilder; + friend struct WireHelpers; + friend class OrphanBuilder; +}; + +class StructReader { +public: + inline StructReader() + : segment(nullptr), capTable(nullptr), data(nullptr), pointers(nullptr), + dataSize(ZERO * BITS), pointerCount(ZERO * POINTERS), nestingLimit(0x7fffffff) {} + inline StructReader(kj::ArrayPtr data) + : segment(nullptr), capTable(nullptr), data(data.begin()), pointers(nullptr), + dataSize(assumeBits(data.size()) * WORDS * BITS_PER_WORD), + pointerCount(ZERO * POINTERS), nestingLimit(0x7fffffff) {} + + const void* getLocation() const { return data; } + + inline StructDataBitCount getDataSectionSize() const { return dataSize; } + inline StructPointerCount getPointerSectionSize() const { return pointerCount; } + inline kj::ArrayPtr getDataSectionAsBlob(); + inline _::ListReader getPointerSectionAsList(); + + kj::Array canonicalize(); + + template + KJ_ALWAYS_INLINE(bool hasDataField(StructDataOffset offset) const); + // Return true if the field is set to something other than its default value. + + template + KJ_ALWAYS_INLINE(T getDataField(StructDataOffset offset) const); + // Get the data field value of the given type at the given offset. The offset is measured in + // multiples of the field size, determined by the type. Returns zero if the offset is past the + // end of the struct's data section. + + template + KJ_ALWAYS_INLINE(T getDataField(StructDataOffset offset, Mask mask) const); + // Like getDataField(offset), but applies the given XOR mask to the result. Used for reading + // fields with non-zero default values. + + KJ_ALWAYS_INLINE(PointerReader getPointerField(StructPointerOffset ptrIndex) const); + // Get a reader for a pointer field given the index within the pointer section. If the index + // is out-of-bounds, returns a null pointer. + + MessageSizeCounts totalSize() const; + // Return the total size of the struct and everything to which it points. Does not count far + // pointer overhead. This is useful for deciding how much space is needed to copy the struct + // into a flat array. However, the caller is advised NOT to treat this value as secure. Instead, + // use the result as a hint for allocating the first segment, do the copy, and then throw an + // exception if it overruns. + + CapTableReader* getCapTable(); + // Gets the capability context in which this object is operating. + + StructReader imbue(CapTableReader* capTable) const; + // Return a copy of this reader except using the given capability context. + + bool isCanonical(const word **readHead, const word **ptrHead, + bool *dataTrunc, bool *ptrTrunc); + // Validate this pointer's canonicity, subject to the conditions: + // * All data to the left of readHead has been read thus far (for pointer + // ordering) + // * All pointers in preorder have already been checked + // * This pointer is in the first and only segment of the message + // + // If this function returns false, the struct is non-canonical. If it + // returns true, then: + // * If it is a composite in a list, it is canonical if at least one struct + // in the list outputs dataTrunc = 1, and at least one outputs ptrTrunc = 1 + // * If it is derived from a struct pointer, it is canonical if + // dataTrunc = 1 AND ptrTrunc = 1 + +private: + SegmentReader* segment; // Memory segment in which the struct resides. + CapTableReader* capTable; // Table of capability indexes. + + const void* data; + const WirePointer* pointers; + + StructDataBitCount dataSize; + // Size of data section. We use a bit count rather than a word count to more easily handle the + // case of struct lists encoded with less than a word per element. + + StructPointerCount pointerCount; // Size of the pointer section. + + int nestingLimit; + // Limits the depth of message structures to guard against stack-overflow-based DoS attacks. + // Once this reaches zero, further pointers will be pruned. + // TODO(perf): Limit to 16 bits for better packing? + + inline StructReader(SegmentReader* segment, CapTableReader* capTable, + const void* data, const WirePointer* pointers, + StructDataBitCount dataSize, StructPointerCount pointerCount, + int nestingLimit) + : segment(segment), capTable(capTable), data(data), pointers(pointers), + dataSize(dataSize), pointerCount(pointerCount), + nestingLimit(nestingLimit) {} + + friend class ListReader; + friend class StructBuilder; + friend struct WireHelpers; +}; + +// ------------------------------------------------------------------- + +class ListBuilder: public kj::DisallowConstCopy { +public: + inline explicit ListBuilder(ElementSize elementSize) + : segment(nullptr), capTable(nullptr), ptr(nullptr), elementCount(ZERO * ELEMENTS), + step(ZERO * BITS / ELEMENTS), structDataSize(ZERO * BITS), + structPointerCount(ZERO * POINTERS), elementSize(elementSize) {} + + inline word* getLocation() { + // Get the object's location. + + if (elementSize == ElementSize::INLINE_COMPOSITE && ptr != nullptr) { + return reinterpret_cast(ptr) - POINTER_SIZE_IN_WORDS; + } else { + return reinterpret_cast(ptr); + } + } + + inline ElementSize getElementSize() const { return elementSize; } + + inline ListElementCount size() const; + // The number of elements in the list. + + Text::Builder asText(); + Data::Builder asData(); + // Reinterpret the list as a blob. Throws an exception if the elements are not byte-sized. + + template + KJ_ALWAYS_INLINE(T getDataElement(ElementCount index)); + // Get the element of the given type at the given index. + + template + KJ_ALWAYS_INLINE(void setDataElement(ElementCount index, kj::NoInfer value)); + // Set the element at the given index. + + KJ_ALWAYS_INLINE(PointerBuilder getPointerElement(ElementCount index)); + + StructBuilder getStructElement(ElementCount index); + + ListReader asReader() const; + // Get a ListReader pointing at the same memory. + + BuilderArena* getArena(); + // Gets the arena in which this object is allocated. + + CapTableBuilder* getCapTable(); + // Gets the capability context in which this object is operating. + + ListBuilder imbue(CapTableBuilder* capTable); + // Return a copy of this builder except using the given capability context. + +private: + SegmentBuilder* segment; // Memory segment in which the list resides. + CapTableBuilder* capTable; // Table of capability indexes. + + byte* ptr; // Pointer to list content. + + ListElementCount elementCount; // Number of elements in the list. + + BitsPerElementN<23> step; + // The distance between elements. The maximum value occurs when a struct contains 2^16-1 data + // words and 2^16-1 pointers, i.e. 2^17 - 2 words, or 2^23 - 128 bits. + + StructDataBitCount structDataSize; + StructPointerCount structPointerCount; + // The struct properties to use when interpreting the elements as structs. All lists can be + // interpreted as struct lists, so these are always filled in. + + ElementSize elementSize; + // The element size as a ElementSize. This is only really needed to disambiguate INLINE_COMPOSITE + // from other types when the overall size is exactly zero or one words. + + inline ListBuilder(SegmentBuilder* segment, CapTableBuilder* capTable, void* ptr, + BitsPerElementN<23> step, ListElementCount size, + StructDataBitCount structDataSize, StructPointerCount structPointerCount, + ElementSize elementSize) + : segment(segment), capTable(capTable), ptr(reinterpret_cast(ptr)), + elementCount(size), step(step), structDataSize(structDataSize), + structPointerCount(structPointerCount), elementSize(elementSize) {} + + friend class StructBuilder; + friend struct WireHelpers; + friend class OrphanBuilder; +}; + +class ListReader { +public: + inline explicit ListReader(ElementSize elementSize) + : segment(nullptr), capTable(nullptr), ptr(nullptr), elementCount(ZERO * ELEMENTS), + step(ZERO * BITS / ELEMENTS), structDataSize(ZERO * BITS), + structPointerCount(ZERO * POINTERS), elementSize(elementSize), nestingLimit(0x7fffffff) {} + + inline ListElementCount size() const; + // The number of elements in the list. + + inline ElementSize getElementSize() const { return elementSize; } + + Text::Reader asText(); + Data::Reader asData(); + // Reinterpret the list as a blob. Throws an exception if the elements are not byte-sized. + + kj::ArrayPtr asRawBytes(); + + template + KJ_ALWAYS_INLINE(T getDataElement(ElementCount index) const); + // Get the element of the given type at the given index. + + KJ_ALWAYS_INLINE(PointerReader getPointerElement(ElementCount index) const); + + StructReader getStructElement(ElementCount index) const; + + CapTableReader* getCapTable(); + // Gets the capability context in which this object is operating. + + ListReader imbue(CapTableReader* capTable) const; + // Return a copy of this reader except using the given capability context. + + bool isCanonical(const word **readHead, const WirePointer* ref); + // Validate this pointer's canonicity, subject to the conditions: + // * All data to the left of readHead has been read thus far (for pointer + // ordering) + // * All pointers in preorder have already been checked + // * This pointer is in the first and only segment of the message + +private: + SegmentReader* segment; // Memory segment in which the list resides. + CapTableReader* capTable; // Table of capability indexes. + + const byte* ptr; // Pointer to list content. + + ListElementCount elementCount; // Number of elements in the list. + + BitsPerElementN<23> step; + // The distance between elements. The maximum value occurs when a struct contains 2^16-1 data + // words and 2^16-1 pointers, i.e. 2^17 - 2 words, or 2^23 - 2 bits. + + StructDataBitCount structDataSize; + StructPointerCount structPointerCount; + // The struct properties to use when interpreting the elements as structs. All lists can be + // interpreted as struct lists, so these are always filled in. + + ElementSize elementSize; + // The element size as a ElementSize. This is only really needed to disambiguate INLINE_COMPOSITE + // from other types when the overall size is exactly zero or one words. + + int nestingLimit; + // Limits the depth of message structures to guard against stack-overflow-based DoS attacks. + // Once this reaches zero, further pointers will be pruned. + + inline ListReader(SegmentReader* segment, CapTableReader* capTable, const void* ptr, + ListElementCount elementCount, BitsPerElementN<23> step, + StructDataBitCount structDataSize, StructPointerCount structPointerCount, + ElementSize elementSize, int nestingLimit) + : segment(segment), capTable(capTable), ptr(reinterpret_cast(ptr)), + elementCount(elementCount), step(step), structDataSize(structDataSize), + structPointerCount(structPointerCount), elementSize(elementSize), + nestingLimit(nestingLimit) {} + + friend class StructReader; + friend class ListBuilder; + friend struct WireHelpers; + friend class OrphanBuilder; +}; + +// ------------------------------------------------------------------- + +class OrphanBuilder { +public: + inline OrphanBuilder(): segment(nullptr), capTable(nullptr), location(nullptr) { + memset(&tag, 0, sizeof(tag)); + } + OrphanBuilder(const OrphanBuilder& other) = delete; + inline OrphanBuilder(OrphanBuilder&& other) noexcept; + inline ~OrphanBuilder() noexcept(false); + + static OrphanBuilder initStruct(BuilderArena* arena, CapTableBuilder* capTable, StructSize size); + static OrphanBuilder initList(BuilderArena* arena, CapTableBuilder* capTable, + ElementCount elementCount, ElementSize elementSize); + static OrphanBuilder initStructList(BuilderArena* arena, CapTableBuilder* capTable, + ElementCount elementCount, StructSize elementSize); + static OrphanBuilder initText(BuilderArena* arena, CapTableBuilder* capTable, ByteCount size); + static OrphanBuilder initData(BuilderArena* arena, CapTableBuilder* capTable, ByteCount size); + + static OrphanBuilder copy(BuilderArena* arena, CapTableBuilder* capTable, StructReader copyFrom); + static OrphanBuilder copy(BuilderArena* arena, CapTableBuilder* capTable, ListReader copyFrom); + static OrphanBuilder copy(BuilderArena* arena, CapTableBuilder* capTable, PointerReader copyFrom); + static OrphanBuilder copy(BuilderArena* arena, CapTableBuilder* capTable, Text::Reader copyFrom); + static OrphanBuilder copy(BuilderArena* arena, CapTableBuilder* capTable, Data::Reader copyFrom); +#if !CAPNP_LITE + static OrphanBuilder copy(BuilderArena* arena, CapTableBuilder* capTable, + kj::Own copyFrom); +#endif // !CAPNP_LITE + + static OrphanBuilder concat(BuilderArena* arena, CapTableBuilder* capTable, + ElementSize expectedElementSize, StructSize expectedStructSize, + kj::ArrayPtr lists); + + static OrphanBuilder referenceExternalData(BuilderArena* arena, Data::Reader data); + + OrphanBuilder& operator=(const OrphanBuilder& other) = delete; + inline OrphanBuilder& operator=(OrphanBuilder&& other); + + inline bool operator==(decltype(nullptr)) const { return location == nullptr; } + inline bool operator!=(decltype(nullptr)) const { return location != nullptr; } + + StructBuilder asStruct(StructSize size); + // Interpret as a struct, or throw an exception if not a struct. + + ListBuilder asList(ElementSize elementSize); + // Interpret as a list, or throw an exception if not a list. elementSize cannot be + // INLINE_COMPOSITE -- use asStructList() instead. + + ListBuilder asStructList(StructSize elementSize); + // Interpret as a struct list, or throw an exception if not a list. + + ListBuilder asListAnySize(); + // For AnyList. + + Text::Builder asText(); + Data::Builder asData(); + // Interpret as a blob, or throw an exception if not a blob. + + StructReader asStructReader(StructSize size) const; + ListReader asListReader(ElementSize elementSize) const; + ListReader asListReaderAnySize() const; +#if !CAPNP_LITE + kj::Own asCapability() const; +#endif // !CAPNP_LITE + Text::Reader asTextReader() const; + Data::Reader asDataReader() const; + + bool truncate(ElementCount size, bool isText) KJ_WARN_UNUSED_RESULT; + // Resize the orphan list to the given size. Returns false if the list is currently empty but + // the requested size is non-zero, in which case the caller will need to allocate a new list. + + void truncate(ElementCount size, ElementSize elementSize); + void truncate(ElementCount size, StructSize elementSize); + void truncateText(ElementCount size); + // Versions of truncate() that know how to allocate a new list if needed. + +private: + static_assert(ONE * POINTERS * WORDS_PER_POINTER == ONE * WORDS, + "This struct assumes a pointer is one word."); + word tag; + // Contains an encoded WirePointer representing this object. WirePointer is defined in + // layout.c++, but fits in a word. + // + // This may be a FAR pointer. Even in that case, `location` points to the eventual destination + // of that far pointer. The reason we keep the far pointer around rather than just making `tag` + // represent the final destination is because if the eventual adopter of the pointer is not in + // the target's segment then it may be useful to reuse the far pointer landing pad. + // + // If `tag` is not a far pointer, its offset is garbage; only `location` points to the actual + // target. + + SegmentBuilder* segment; + // Segment in which the object resides. + + CapTableBuilder* capTable; + // Table of capability indexes. + + word* location; + // Pointer to the object, or nullptr if the pointer is null. For capabilities, we make this + // 0x1 just so that it is non-null for operator==, but it is never used. + + inline OrphanBuilder(const void* tagPtr, SegmentBuilder* segment, + CapTableBuilder* capTable, word* location) + : segment(segment), capTable(capTable), location(location) { + memcpy(&tag, tagPtr, sizeof(tag)); + } + + inline WirePointer* tagAsPtr() { return reinterpret_cast(&tag); } + inline const WirePointer* tagAsPtr() const { return reinterpret_cast(&tag); } + + void euthanize(); + // Erase the target object, zeroing it out and possibly reclaiming the memory. Called when + // the OrphanBuilder is being destroyed or overwritten and it is non-null. + + friend struct WireHelpers; +}; + +// ======================================================================================= +// Internal implementation details... + +// These are defined in the source file. +template <> typename Text::Builder PointerBuilder::initBlob(ByteCount size); +template <> void PointerBuilder::setBlob(typename Text::Reader value); +template <> typename Text::Builder PointerBuilder::getBlob( + const void* defaultValue, ByteCount defaultSize); +template <> typename Text::Reader PointerReader::getBlob( + const void* defaultValue, ByteCount defaultSize) const; + +template <> typename Data::Builder PointerBuilder::initBlob(ByteCount size); +template <> void PointerBuilder::setBlob(typename Data::Reader value); +template <> typename Data::Builder PointerBuilder::getBlob( + const void* defaultValue, ByteCount defaultSize); +template <> typename Data::Reader PointerReader::getBlob( + const void* defaultValue, ByteCount defaultSize) const; + +inline PointerBuilder PointerBuilder::getRoot( + SegmentBuilder* segment, CapTableBuilder* capTable, word* location) { + return PointerBuilder(segment, capTable, reinterpret_cast(location)); +} + +inline PointerReader PointerReader::getRootUnchecked(const word* location) { + return PointerReader(nullptr, nullptr, + reinterpret_cast(location), 0x7fffffff); +} + +// ------------------------------------------------------------------- + +inline kj::ArrayPtr StructBuilder::getDataSectionAsBlob() { + return kj::ArrayPtr(reinterpret_cast(data), + unbound(dataSize / BITS_PER_BYTE / BYTES)); +} + +inline _::ListBuilder StructBuilder::getPointerSectionAsList() { + return _::ListBuilder(segment, capTable, pointers, ONE * POINTERS * BITS_PER_POINTER / ELEMENTS, + pointerCount * (ONE * ELEMENTS / POINTERS), + ZERO * BITS, ONE * POINTERS, ElementSize::POINTER); +} + +template +inline bool StructBuilder::hasDataField(StructDataOffset offset) { + return getDataField>(offset) != 0; +} + +template <> +inline bool StructBuilder::hasDataField(StructDataOffset offset) { + return false; +} + +template +inline T StructBuilder::getDataField(StructDataOffset offset) { + return reinterpret_cast*>(data)[unbound(offset / ELEMENTS)].get(); +} + +template <> +inline bool StructBuilder::getDataField(StructDataOffset offset) { + BitCount32 boffset = offset * (ONE * BITS / ELEMENTS); + byte* b = reinterpret_cast(data) + boffset / BITS_PER_BYTE; + return (*reinterpret_cast(b) & + unbound(ONE << (boffset % BITS_PER_BYTE / BITS))) != 0; +} + +template <> +inline Void StructBuilder::getDataField(StructDataOffset offset) { + return VOID; +} + +template +inline T StructBuilder::getDataField(StructDataOffset offset, Mask mask) { + return unmask(getDataField >(offset), mask); +} + +template +inline void StructBuilder::setDataField(StructDataOffset offset, kj::NoInfer value) { + reinterpret_cast*>(data)[unbound(offset / ELEMENTS)].set(value); +} + +#if CAPNP_CANONICALIZE_NAN +// Use mask() on floats and doubles to make sure we canonicalize NaNs. +template <> +inline void StructBuilder::setDataField(StructDataOffset offset, float value) { + setDataField(offset, mask(value, 0)); +} +template <> +inline void StructBuilder::setDataField(StructDataOffset offset, double value) { + setDataField(offset, mask(value, 0)); +} +#endif + +template <> +inline void StructBuilder::setDataField(StructDataOffset offset, bool value) { + auto boffset = offset * (ONE * BITS / ELEMENTS); + byte* b = reinterpret_cast(data) + boffset / BITS_PER_BYTE; + uint bitnum = unboundMaxBits<3>(boffset % BITS_PER_BYTE / BITS); + *reinterpret_cast(b) = (*reinterpret_cast(b) & ~(1 << bitnum)) + | (static_cast(value) << bitnum); +} + +template <> +inline void StructBuilder::setDataField(StructDataOffset offset, Void value) {} + +template +inline void StructBuilder::setDataField(StructDataOffset offset, + kj::NoInfer value, Mask m) { + setDataField >(offset, mask(value, m)); +} + +inline PointerBuilder StructBuilder::getPointerField(StructPointerOffset ptrIndex) { + // Hacky because WirePointer is defined in the .c++ file (so is incomplete here). + return PointerBuilder(segment, capTable, reinterpret_cast( + reinterpret_cast(pointers) + ptrIndex * WORDS_PER_POINTER)); +} + +// ------------------------------------------------------------------- + +inline kj::ArrayPtr StructReader::getDataSectionAsBlob() { + return kj::ArrayPtr(reinterpret_cast(data), + unbound(dataSize / BITS_PER_BYTE / BYTES)); +} + +inline _::ListReader StructReader::getPointerSectionAsList() { + return _::ListReader(segment, capTable, pointers, pointerCount * (ONE * ELEMENTS / POINTERS), + ONE * POINTERS * BITS_PER_POINTER / ELEMENTS, ZERO * BITS, ONE * POINTERS, + ElementSize::POINTER, nestingLimit); +} + +template +inline bool StructReader::hasDataField(StructDataOffset offset) const { + return getDataField>(offset) != 0; +} + +template <> +inline bool StructReader::hasDataField(StructDataOffset offset) const { + return false; +} + +template +inline T StructReader::getDataField(StructDataOffset offset) const { + if ((offset + ONE * ELEMENTS) * capnp::bitsPerElement() <= dataSize) { + return reinterpret_cast*>(data)[unbound(offset / ELEMENTS)].get(); + } else { + return static_cast(0); + } +} + +template <> +inline bool StructReader::getDataField(StructDataOffset offset) const { + auto boffset = offset * (ONE * BITS / ELEMENTS); + if (boffset < dataSize) { + const byte* b = reinterpret_cast(data) + boffset / BITS_PER_BYTE; + return (*reinterpret_cast(b) & + unbound(ONE << (boffset % BITS_PER_BYTE / BITS))) != 0; + } else { + return false; + } +} + +template <> +inline Void StructReader::getDataField(StructDataOffset offset) const { + return VOID; +} + +template +T StructReader::getDataField(StructDataOffset offset, Mask mask) const { + return unmask(getDataField >(offset), mask); +} + +inline PointerReader StructReader::getPointerField(StructPointerOffset ptrIndex) const { + if (ptrIndex < pointerCount) { + // Hacky because WirePointer is defined in the .c++ file (so is incomplete here). + return PointerReader(segment, capTable, reinterpret_cast( + reinterpret_cast(pointers) + ptrIndex * WORDS_PER_POINTER), nestingLimit); + } else{ + return PointerReader(); + } +} + +// ------------------------------------------------------------------- + +inline ListElementCount ListBuilder::size() const { return elementCount; } + +template +inline T ListBuilder::getDataElement(ElementCount index) { + return reinterpret_cast*>( + ptr + upgradeBound(index) * step / BITS_PER_BYTE)->get(); + + // TODO(perf): Benchmark this alternate implementation, which I suspect may make better use of + // the x86 SIB byte. Also use it for all the other getData/setData implementations below, and + // the various non-inline methods that look up pointers. + // Also if using this, consider changing ptr back to void* instead of byte*. +// return reinterpret_cast*>(ptr)[ +// index / ELEMENTS * (step / capnp::bitsPerElement())].get(); +} + +template <> +inline bool ListBuilder::getDataElement(ElementCount index) { + // Ignore step for bit lists because bit lists cannot be upgraded to struct lists. + auto bindex = index * (ONE * BITS / ELEMENTS); + byte* b = ptr + bindex / BITS_PER_BYTE; + return (*reinterpret_cast(b) & + unbound(ONE << (bindex % BITS_PER_BYTE / BITS))) != 0; +} + +template <> +inline Void ListBuilder::getDataElement(ElementCount index) { + return VOID; +} + +template +inline void ListBuilder::setDataElement(ElementCount index, kj::NoInfer value) { + reinterpret_cast*>( + ptr + upgradeBound(index) * step / BITS_PER_BYTE)->set(value); +} + +#if CAPNP_CANONICALIZE_NAN +// Use mask() on floats and doubles to make sure we canonicalize NaNs. +template <> +inline void ListBuilder::setDataElement(ElementCount index, float value) { + setDataElement(index, mask(value, 0)); +} +template <> +inline void ListBuilder::setDataElement(ElementCount index, double value) { + setDataElement(index, mask(value, 0)); +} +#endif + +template <> +inline void ListBuilder::setDataElement(ElementCount index, bool value) { + // Ignore stepBytes for bit lists because bit lists cannot be upgraded to struct lists. + auto bindex = index * (ONE * BITS / ELEMENTS); + byte* b = ptr + bindex / BITS_PER_BYTE; + auto bitnum = bindex % BITS_PER_BYTE / BITS; + *reinterpret_cast(b) = (*reinterpret_cast(b) & ~(1 << unbound(bitnum))) + | (static_cast(value) << unbound(bitnum)); +} + +template <> +inline void ListBuilder::setDataElement(ElementCount index, Void value) {} + +inline PointerBuilder ListBuilder::getPointerElement(ElementCount index) { + return PointerBuilder(segment, capTable, reinterpret_cast(ptr + + upgradeBound(index) * step / BITS_PER_BYTE)); +} + +// ------------------------------------------------------------------- + +inline ListElementCount ListReader::size() const { return elementCount; } + +template +inline T ListReader::getDataElement(ElementCount index) const { + return reinterpret_cast*>( + ptr + upgradeBound(index) * step / BITS_PER_BYTE)->get(); +} + +template <> +inline bool ListReader::getDataElement(ElementCount index) const { + // Ignore step for bit lists because bit lists cannot be upgraded to struct lists. + auto bindex = index * (ONE * BITS / ELEMENTS); + const byte* b = ptr + bindex / BITS_PER_BYTE; + return (*reinterpret_cast(b) & + unbound(ONE << (bindex % BITS_PER_BYTE / BITS))) != 0; +} + +template <> +inline Void ListReader::getDataElement(ElementCount index) const { + return VOID; +} + +inline PointerReader ListReader::getPointerElement(ElementCount index) const { + return PointerReader(segment, capTable, reinterpret_cast( + ptr + upgradeBound(index) * step / BITS_PER_BYTE), nestingLimit); +} + +// ------------------------------------------------------------------- + +inline OrphanBuilder::OrphanBuilder(OrphanBuilder&& other) noexcept + : segment(other.segment), capTable(other.capTable), location(other.location) { + memcpy(&tag, &other.tag, sizeof(tag)); // Needs memcpy to comply with aliasing rules. + other.segment = nullptr; + other.location = nullptr; +} + +inline OrphanBuilder::~OrphanBuilder() noexcept(false) { + if (segment != nullptr) euthanize(); +} + +inline OrphanBuilder& OrphanBuilder::operator=(OrphanBuilder&& other) { + // With normal smart pointers, it's important to handle the case where the incoming pointer + // is actually transitively owned by this one. In this case, euthanize() would destroy `other` + // before we copied it. This isn't possible in the case of `OrphanBuilder` because it only + // owns message objects, and `other` is not itself a message object, therefore cannot possibly + // be transitively owned by `this`. + + if (segment != nullptr) euthanize(); + segment = other.segment; + capTable = other.capTable; + location = other.location; + memcpy(&tag, &other.tag, sizeof(tag)); // Needs memcpy to comply with aliasing rules. + other.segment = nullptr; + other.location = nullptr; + return *this; +} + +} // namespace _ (private) +} // namespace capnp + +#endif // CAPNP_LAYOUT_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/list.h b/phonelibs/capnp-cpp/include/capnp/list.h new file mode 100644 index 00000000000000..23e5e6c10e661f --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/list.h @@ -0,0 +1,546 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_LIST_H_ +#define CAPNP_LIST_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "layout.h" +#include "orphan.h" +#include +#ifdef KJ_STD_COMPAT +#include +#endif // KJ_STD_COMPAT + +namespace capnp { +namespace _ { // private + +template +class TemporaryPointer { + // This class is a little hack which lets us define operator->() in cases where it needs to + // return a pointer to a temporary value. We instead construct a TemporaryPointer and return that + // (by value). The compiler then invokes operator->() on the TemporaryPointer, which itself is + // able to return a real pointer to its member. + +public: + TemporaryPointer(T&& value): value(kj::mv(value)) {} + TemporaryPointer(const T& value): value(value) {} + + inline T* operator->() { return &value; } +private: + T value; +}; + +template +class IndexingIterator { +public: + IndexingIterator() = default; + + inline Element operator*() const { return (*container)[index]; } + inline TemporaryPointer operator->() const { + return TemporaryPointer((*container)[index]); + } + inline Element operator[]( int off) const { return (*container)[index]; } + inline Element operator[](uint off) const { return (*container)[index]; } + + inline IndexingIterator& operator++() { ++index; return *this; } + inline IndexingIterator operator++(int) { IndexingIterator other = *this; ++index; return other; } + inline IndexingIterator& operator--() { --index; return *this; } + inline IndexingIterator operator--(int) { IndexingIterator other = *this; --index; return other; } + + inline IndexingIterator operator+(uint amount) const { return IndexingIterator(container, index + amount); } + inline IndexingIterator operator-(uint amount) const { return IndexingIterator(container, index - amount); } + inline IndexingIterator operator+( int amount) const { return IndexingIterator(container, index + amount); } + inline IndexingIterator operator-( int amount) const { return IndexingIterator(container, index - amount); } + + inline int operator-(const IndexingIterator& other) const { return index - other.index; } + + inline IndexingIterator& operator+=(uint amount) { index += amount; return *this; } + inline IndexingIterator& operator-=(uint amount) { index -= amount; return *this; } + inline IndexingIterator& operator+=( int amount) { index += amount; return *this; } + inline IndexingIterator& operator-=( int amount) { index -= amount; return *this; } + + // STL says comparing iterators of different containers is not allowed, so we only compare + // indices here. + inline bool operator==(const IndexingIterator& other) const { return index == other.index; } + inline bool operator!=(const IndexingIterator& other) const { return index != other.index; } + inline bool operator<=(const IndexingIterator& other) const { return index <= other.index; } + inline bool operator>=(const IndexingIterator& other) const { return index >= other.index; } + inline bool operator< (const IndexingIterator& other) const { return index < other.index; } + inline bool operator> (const IndexingIterator& other) const { return index > other.index; } + +private: + Container* container; + uint index; + + friend Container; + inline IndexingIterator(Container* container, uint index) + : container(container), index(index) {} +}; + +} // namespace _ (private) + +template +struct List { + // List of primitives. + + List() = delete; + + class Reader { + public: + typedef List Reads; + + inline Reader(): reader(_::elementSizeForType()) {} + inline explicit Reader(_::ListReader reader): reader(reader) {} + + inline uint size() const { return unbound(reader.size() / ELEMENTS); } + inline T operator[](uint index) const { + KJ_IREQUIRE(index < size()); + return reader.template getDataElement(bounded(index) * ELEMENTS); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + + private: + _::ListReader reader; + template + friend struct _::PointerHelpers; + template + friend struct List; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Builder { + public: + typedef List Builds; + + inline Builder(): builder(_::elementSizeForType()) {} + inline Builder(decltype(nullptr)): Builder() {} + inline explicit Builder(_::ListBuilder builder): builder(builder) {} + + inline operator Reader() const { return Reader(builder.asReader()); } + inline Reader asReader() const { return Reader(builder.asReader()); } + + inline uint size() const { return unbound(builder.size() / ELEMENTS); } + inline T operator[](uint index) { + KJ_IREQUIRE(index < size()); + return builder.template getDataElement(bounded(index) * ELEMENTS); + } + inline void set(uint index, T value) { + // Alas, it is not possible to make operator[] return a reference to which you can assign, + // since the encoded representation does not necessarily match the compiler's representation + // of the type. We can't even return a clever class that implements operator T() and + // operator=() because it will lead to surprising behavior when using type inference (e.g. + // calling a template function with inferred argument types, or using "auto" or "decltype"). + + builder.template setDataElement(bounded(index) * ELEMENTS, value); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() { return Iterator(this, 0); } + inline Iterator end() { return Iterator(this, size()); } + + private: + _::ListBuilder builder; + template + friend struct _::PointerHelpers; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Pipeline {}; + +private: + inline static _::ListBuilder initPointer(_::PointerBuilder builder, uint size) { + return builder.initList(_::elementSizeForType(), bounded(size) * ELEMENTS); + } + inline static _::ListBuilder getFromPointer(_::PointerBuilder builder, const word* defaultValue) { + return builder.getList(_::elementSizeForType(), defaultValue); + } + inline static _::ListReader getFromPointer( + const _::PointerReader& reader, const word* defaultValue) { + return reader.getList(_::elementSizeForType(), defaultValue); + } + + template + friend struct List; + template + friend struct _::PointerHelpers; +}; + +template +struct List: public List {}; + +template +struct List { + // List of structs. + + List() = delete; + + class Reader { + public: + typedef List Reads; + + inline Reader(): reader(ElementSize::INLINE_COMPOSITE) {} + inline explicit Reader(_::ListReader reader): reader(reader) {} + + inline uint size() const { return unbound(reader.size() / ELEMENTS); } + inline typename T::Reader operator[](uint index) const { + KJ_IREQUIRE(index < size()); + return typename T::Reader(reader.getStructElement(bounded(index) * ELEMENTS)); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + + private: + _::ListReader reader; + template + friend struct _::PointerHelpers; + template + friend struct List; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Builder { + public: + typedef List Builds; + + inline Builder(): builder(ElementSize::INLINE_COMPOSITE) {} + inline Builder(decltype(nullptr)): Builder() {} + inline explicit Builder(_::ListBuilder builder): builder(builder) {} + + inline operator Reader() const { return Reader(builder.asReader()); } + inline Reader asReader() const { return Reader(builder.asReader()); } + + inline uint size() const { return unbound(builder.size() / ELEMENTS); } + inline typename T::Builder operator[](uint index) { + KJ_IREQUIRE(index < size()); + return typename T::Builder(builder.getStructElement(bounded(index) * ELEMENTS)); + } + + inline void adoptWithCaveats(uint index, Orphan&& orphan) { + // Mostly behaves like you'd expect `adopt` to behave, but with two caveats originating from + // the fact that structs in a struct list are allocated inline rather than by pointer: + // * This actually performs a shallow copy, effectively adopting each of the orphan's + // children rather than adopting the orphan itself. The orphan ends up being discarded, + // possibly wasting space in the message object. + // * If the orphan is larger than the target struct -- say, because the orphan was built + // using a newer version of the schema that has additional fields -- it will be truncated, + // losing data. + + KJ_IREQUIRE(index < size()); + + // We pass a zero-valued StructSize to asStruct() because we do not want the struct to be + // expanded under any circumstances. We're just going to throw it away anyway, and + // transferContentFrom() already carefully compares the struct sizes before transferring. + builder.getStructElement(bounded(index) * ELEMENTS).transferContentFrom( + orphan.builder.asStruct(_::StructSize(ZERO * WORDS, ZERO * POINTERS))); + } + inline void setWithCaveats(uint index, const typename T::Reader& reader) { + // Mostly behaves like you'd expect `set` to behave, but with a caveat originating from + // the fact that structs in a struct list are allocated inline rather than by pointer: + // If the source struct is larger than the target struct -- say, because the source was built + // using a newer version of the schema that has additional fields -- it will be truncated, + // losing data. + // + // Note: If you are trying to concatenate some lists, use Orphanage::newOrphanConcat() to + // do it without losing any data in case the source lists come from a newer version of the + // protocol. (Plus, it's easier to use anyhow.) + + KJ_IREQUIRE(index < size()); + builder.getStructElement(bounded(index) * ELEMENTS).copyContentFrom(reader._reader); + } + + // There are no init(), set(), adopt(), or disown() methods for lists of structs because the + // elements of the list are inlined and are initialized when the list is initialized. This + // means that init() would be redundant, and set() would risk data loss if the input struct + // were from a newer version of the protocol. + + typedef _::IndexingIterator Iterator; + inline Iterator begin() { return Iterator(this, 0); } + inline Iterator end() { return Iterator(this, size()); } + + private: + _::ListBuilder builder; + template + friend struct _::PointerHelpers; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Pipeline {}; + +private: + inline static _::ListBuilder initPointer(_::PointerBuilder builder, uint size) { + return builder.initStructList(bounded(size) * ELEMENTS, _::structSize()); + } + inline static _::ListBuilder getFromPointer(_::PointerBuilder builder, const word* defaultValue) { + return builder.getStructList(_::structSize(), defaultValue); + } + inline static _::ListReader getFromPointer( + const _::PointerReader& reader, const word* defaultValue) { + return reader.getList(ElementSize::INLINE_COMPOSITE, defaultValue); + } + + template + friend struct List; + template + friend struct _::PointerHelpers; +}; + +template +struct List, Kind::LIST> { + // List of lists. + + List() = delete; + + class Reader { + public: + typedef List> Reads; + + inline Reader(): reader(ElementSize::POINTER) {} + inline explicit Reader(_::ListReader reader): reader(reader) {} + + inline uint size() const { return unbound(reader.size() / ELEMENTS); } + inline typename List::Reader operator[](uint index) const { + KJ_IREQUIRE(index < size()); + return typename List::Reader(_::PointerHelpers>::get( + reader.getPointerElement(bounded(index) * ELEMENTS))); + } + + typedef _::IndexingIterator::Reader> Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + + private: + _::ListReader reader; + template + friend struct _::PointerHelpers; + template + friend struct List; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Builder { + public: + typedef List> Builds; + + inline Builder(): builder(ElementSize::POINTER) {} + inline Builder(decltype(nullptr)): Builder() {} + inline explicit Builder(_::ListBuilder builder): builder(builder) {} + + inline operator Reader() const { return Reader(builder.asReader()); } + inline Reader asReader() const { return Reader(builder.asReader()); } + + inline uint size() const { return unbound(builder.size() / ELEMENTS); } + inline typename List::Builder operator[](uint index) { + KJ_IREQUIRE(index < size()); + return typename List::Builder(_::PointerHelpers>::get( + builder.getPointerElement(bounded(index) * ELEMENTS))); + } + inline typename List::Builder init(uint index, uint size) { + KJ_IREQUIRE(index < this->size()); + return typename List::Builder(_::PointerHelpers>::init( + builder.getPointerElement(bounded(index) * ELEMENTS), size)); + } + inline void set(uint index, typename List::Reader value) { + KJ_IREQUIRE(index < size()); + builder.getPointerElement(bounded(index) * ELEMENTS).setList(value.reader); + } + void set(uint index, std::initializer_list> value) { + KJ_IREQUIRE(index < size()); + auto l = init(index, value.size()); + uint i = 0; + for (auto& element: value) { + l.set(i++, element); + } + } + inline void adopt(uint index, Orphan&& value) { + KJ_IREQUIRE(index < size()); + builder.getPointerElement(bounded(index) * ELEMENTS).adopt(kj::mv(value.builder)); + } + inline Orphan disown(uint index) { + KJ_IREQUIRE(index < size()); + return Orphan(builder.getPointerElement(bounded(index) * ELEMENTS).disown()); + } + + typedef _::IndexingIterator::Builder> Iterator; + inline Iterator begin() { return Iterator(this, 0); } + inline Iterator end() { return Iterator(this, size()); } + + private: + _::ListBuilder builder; + template + friend struct _::PointerHelpers; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Pipeline {}; + +private: + inline static _::ListBuilder initPointer(_::PointerBuilder builder, uint size) { + return builder.initList(ElementSize::POINTER, bounded(size) * ELEMENTS); + } + inline static _::ListBuilder getFromPointer(_::PointerBuilder builder, const word* defaultValue) { + return builder.getList(ElementSize::POINTER, defaultValue); + } + inline static _::ListReader getFromPointer( + const _::PointerReader& reader, const word* defaultValue) { + return reader.getList(ElementSize::POINTER, defaultValue); + } + + template + friend struct List; + template + friend struct _::PointerHelpers; +}; + +template +struct List { + List() = delete; + + class Reader { + public: + typedef List Reads; + + inline Reader(): reader(ElementSize::POINTER) {} + inline explicit Reader(_::ListReader reader): reader(reader) {} + + inline uint size() const { return unbound(reader.size() / ELEMENTS); } + inline typename T::Reader operator[](uint index) const { + KJ_IREQUIRE(index < size()); + return reader.getPointerElement(bounded(index) * ELEMENTS) + .template getBlob(nullptr, ZERO * BYTES); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + + private: + _::ListReader reader; + template + friend struct _::PointerHelpers; + template + friend struct List; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Builder { + public: + typedef List Builds; + + inline Builder(): builder(ElementSize::POINTER) {} + inline Builder(decltype(nullptr)): Builder() {} + inline explicit Builder(_::ListBuilder builder): builder(builder) {} + + inline operator Reader() const { return Reader(builder.asReader()); } + inline Reader asReader() const { return Reader(builder.asReader()); } + + inline uint size() const { return unbound(builder.size() / ELEMENTS); } + inline typename T::Builder operator[](uint index) { + KJ_IREQUIRE(index < size()); + return builder.getPointerElement(bounded(index) * ELEMENTS) + .template getBlob(nullptr, ZERO * BYTES); + } + inline void set(uint index, typename T::Reader value) { + KJ_IREQUIRE(index < size()); + builder.getPointerElement(bounded(index) * ELEMENTS).template setBlob(value); + } + inline typename T::Builder init(uint index, uint size) { + KJ_IREQUIRE(index < this->size()); + return builder.getPointerElement(bounded(index) * ELEMENTS) + .template initBlob(bounded(size) * BYTES); + } + inline void adopt(uint index, Orphan&& value) { + KJ_IREQUIRE(index < size()); + builder.getPointerElement(bounded(index) * ELEMENTS).adopt(kj::mv(value.builder)); + } + inline Orphan disown(uint index) { + KJ_IREQUIRE(index < size()); + return Orphan(builder.getPointerElement(bounded(index) * ELEMENTS).disown()); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() { return Iterator(this, 0); } + inline Iterator end() { return Iterator(this, size()); } + + private: + _::ListBuilder builder; + template + friend struct _::PointerHelpers; + friend class Orphanage; + template + friend struct ToDynamic_; + }; + + class Pipeline {}; + +private: + inline static _::ListBuilder initPointer(_::PointerBuilder builder, uint size) { + return builder.initList(ElementSize::POINTER, bounded(size) * ELEMENTS); + } + inline static _::ListBuilder getFromPointer(_::PointerBuilder builder, const word* defaultValue) { + return builder.getList(ElementSize::POINTER, defaultValue); + } + inline static _::ListReader getFromPointer( + const _::PointerReader& reader, const word* defaultValue) { + return reader.getList(ElementSize::POINTER, defaultValue); + } + + template + friend struct List; + template + friend struct _::PointerHelpers; +}; + +} // namespace capnp + +#ifdef KJ_STD_COMPAT +namespace std { + +template +struct iterator_traits> + : public std::iterator {}; + +} // namespace std +#endif // KJ_STD_COMPAT + +#endif // CAPNP_LIST_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/membrane.h b/phonelibs/capnp-cpp/include/capnp/membrane.h new file mode 100644 index 00000000000000..6fa8a1335d9418 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/membrane.h @@ -0,0 +1,202 @@ +// Copyright (c) 2015 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_MEMBRANE_H_ +#define CAPNP_MEMBRANE_H_ +// In capability theory, a "membrane" is a wrapper around a capability which (usually) forwards +// calls but recursively wraps capabilities in those calls in the same membrane. The purpose of a +// membrane is to enforce a barrier between two capabilities that cannot be bypassed by merely +// introducing new objects. +// +// The most common use case for a membrane is revocation: Say Alice wants to give Bob a capability +// to access Carol, but wants to be able to revoke this capability later. Alice can accomplish this +// by wrapping Carol in a revokable wrapper which passes through calls until such a time as Alice +// indicates it should be revoked, after which all calls through the wrapper will throw exceptions. +// However, a naive wrapper approach has a problem: if Bob makes a call to Carol and sends a new +// capability in that call, or if Carol returns a capability to Bob in the response to a call, then +// the two are now able to communicate using this new capability, which Alice cannot revoke. In +// order to avoid this problem, Alice must use not just a wrapper but a "membrane", which +// recursively wraps all objects that pass through it in either direction. Thus, all connections +// formed between Bob and Carol (originating from Alice's original introduction) can be revoked +// together by revoking the membrane. +// +// Note that when a capability is passed into a membrane and then passed back out, the result is +// the original capability, not a double-membraned capability. This means that in our revocation +// example, if Bob uses his capability to Carol to obtain another capability from her, then send +// it back to her, the capability Carol receives back will NOT be revoked when Bob's access to +// Carol is revoked. Thus Bob can create long-term irrevocable connections. In most practical use +// cases, this is what you want. APIs commonly rely on the fact that a capability obtained and then +// passed back can be recognized as the original capability. +// +// Mark Miller on membranes: http://www.eros-os.org/pipermail/e-lang/2003-January/008434.html + +#include "capability.h" + +namespace capnp { + +class MembranePolicy { + // Applications may implement this interface to define a membrane policy, which allows some + // calls crossing the membrane to be blocked or redirected. + +public: + virtual kj::Maybe inboundCall( + uint64_t interfaceId, uint16_t methodId, Capability::Client target) = 0; + // Given an inbound call (a call originating "outside" the membrane destined for an object + // "inside" the membrane), decides what to do with it. The policy may: + // + // - Return null to indicate that the call should proceed to the destination. All capabilities + // in the parameters or result will be properly wrapped in the same membrane. + // - Return a capability to have the call redirected to that capability. Note that the redirect + // capability will be treated as outside the membrane, so the params and results will not be + // auto-wrapped; however, the callee can easily wrap the returned capability in the membrane + // itself before returning to achieve this effect. + // - Throw an exception to cause the call to fail with that exception. + // + // `target` is the underlying capability (*inside* the membrane) for which the call is destined. + // Generally, the only way you should use `target` is to wrap it in some capability which you + // return as a redirect. The redirect capability may modify the call in some way and send it to + // `target`. Be careful to use `copyIntoMembrane()` and `copyOutOfMembrane()` as appropriate when + // copying parameters or results across the membrane. + // + // Note that since `target` is inside the capability, if you were to directly return it (rather + // than return null), the effect would be that the membrane would be broken: the call would + // proceed directly and any new capabilities introduced through it would not be membraned. You + // generally should not do that. + + virtual kj::Maybe outboundCall( + uint64_t interfaceId, uint16_t methodId, Capability::Client target) = 0; + // Like `inboundCall()`, but applies to calls originating *inside* the membrane and terminating + // outside. + // + // Note: It is strongly recommended that `outboundCall()` returns null in exactly the same cases + // that `inboundCall()` return null. Conversely, for any case where `inboundCall()` would + // redirect or throw, `outboundCall()` should also redirect or throw. Otherwise, you can run + // into inconsistent behavion when a promise is returned across a membrane, and that promise + // later resolves to a capability on the other side of the membrane: calls on the promise + // will enter and then exit the membrane, but calls on the eventual resolution will not cross + // the membrane at all, so it is important that these two cases behave the same. + + virtual kj::Own addRef() = 0; + // Return a new owned pointer to the same policy. + // + // Typically an implementation of MembranePolicy should also inherit kj::Refcounted and implement + // `addRef()` as `return kj::addRef(*this);`. + // + // Note that the membraning system considers two membranes created with the same MembranePolicy + // object actually to be the *same* membrane. This is relevant when an object passes into the + // membrane and then back out (or out and then back in): instead of double-wrapping the object, + // the wrapping will be removed. +}; + +Capability::Client membrane(Capability::Client inner, kj::Own policy); +// Wrap `inner` in a membrane specified by `policy`. `inner` is considered "inside" the membrane, +// while the returned capability should only be called from outside the membrane. + +Capability::Client reverseMembrane(Capability::Client outer, kj::Own policy); +// Like `membrane` but treat the input capability as "outside" the membrane, and return a +// capability appropriate for use inside. +// +// Applications typically won't use this directly; the membraning code automatically sets up +// reverse membranes where needed. + +template +ClientType membrane(ClientType inner, kj::Own policy); +template +ClientType reverseMembrane(ClientType inner, kj::Own policy); +// Convenience templates which return the same interface type as the input. + +template +typename ServerType::Serves::Client membrane( + kj::Own inner, kj::Own policy); +template +typename ServerType::Serves::Client reverseMembrane( + kj::Own inner, kj::Own policy); +// Convenience templates which input a capability server type and return the appropriate client +// type. + +template +Orphan::Reads> copyIntoMembrane( + Reader&& from, Orphanage to, kj::Own policy); +// Copy a Cap'n Proto object (e.g. struct or list), adding the given membrane to any capabilities +// found within it. `from` is interpreted as "outside" the membrane while `to` is "inside". + +template +Orphan::Reads> copyOutOfMembrane( + Reader&& from, Orphanage to, kj::Own policy); +// Like copyIntoMembrane() except that `from` is "inside" the membrane and `to` is "outside". + +// ======================================================================================= +// inline implementation details + +template +ClientType membrane(ClientType inner, kj::Own policy) { + return membrane(Capability::Client(kj::mv(inner)), kj::mv(policy)) + .castAs(); +} +template +ClientType reverseMembrane(ClientType inner, kj::Own policy) { + return reverseMembrane(Capability::Client(kj::mv(inner)), kj::mv(policy)) + .castAs(); +} + +template +typename ServerType::Serves::Client membrane( + kj::Own inner, kj::Own policy) { + return membrane(Capability::Client(kj::mv(inner)), kj::mv(policy)) + .castAs(); +} +template +typename ServerType::Serves::Client reverseMembrane( + kj::Own inner, kj::Own policy) { + return reverseMembrane(Capability::Client(kj::mv(inner)), kj::mv(policy)) + .castAs(); +} + +namespace _ { // private + +OrphanBuilder copyOutOfMembrane(PointerReader from, Orphanage to, + kj::Own policy, bool reverse); +OrphanBuilder copyOutOfMembrane(StructReader from, Orphanage to, + kj::Own policy, bool reverse); +OrphanBuilder copyOutOfMembrane(ListReader from, Orphanage to, + kj::Own policy, bool reverse); + +} // namespace _ (private) + +template +Orphan::Reads> copyIntoMembrane( + Reader&& from, Orphanage to, kj::Own policy) { + return _::copyOutOfMembrane( + _::PointerHelpers::Reads>::getInternalReader(from), + to, kj::mv(policy), true); +} + +template +Orphan::Reads> copyOutOfMembrane( + Reader&& from, Orphanage to, kj::Own policy) { + return _::copyOutOfMembrane( + _::PointerHelpers::Reads>::getInternalReader(from), + to, kj::mv(policy), false); +} + +} // namespace capnp + +#endif // CAPNP_MEMBRANE_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/message.h b/phonelibs/capnp-cpp/include/capnp/message.h new file mode 100644 index 00000000000000..b4d5e9fc82230d --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/message.h @@ -0,0 +1,508 @@ +// Copyright (c) 2013-2016 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#include +#include +#include +#include +#include "common.h" +#include "layout.h" +#include "any.h" + +#ifndef CAPNP_MESSAGE_H_ +#define CAPNP_MESSAGE_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +namespace capnp { + +namespace _ { // private + class ReaderArena; + class BuilderArena; +} + +class StructSchema; +class Orphanage; +template +class Orphan; + +// ======================================================================================= + +struct ReaderOptions { + // Options controlling how data is read. + + uint64_t traversalLimitInWords = 8 * 1024 * 1024; + // Limits how many total words of data are allowed to be traversed. Traversal is counted when + // a new struct or list builder is obtained, e.g. from a get() accessor. This means that calling + // the getter for the same sub-struct multiple times will cause it to be double-counted. Once + // the traversal limit is reached, an error will be reported. + // + // This limit exists for security reasons. It is possible for an attacker to construct a message + // in which multiple pointers point at the same location. This is technically invalid, but hard + // to detect. Using such a message, an attacker could cause a message which is small on the wire + // to appear much larger when actually traversed, possibly exhausting server resources leading to + // denial-of-service. + // + // It makes sense to set a traversal limit that is much larger than the underlying message. + // Together with sensible coding practices (e.g. trying to avoid calling sub-object getters + // multiple times, which is expensive anyway), this should provide adequate protection without + // inconvenience. + // + // The default limit is 64 MiB. This may or may not be a sensible number for any given use case, + // but probably at least prevents easy exploitation while also avoiding causing problems in most + // typical cases. + + int nestingLimit = 64; + // Limits how deeply-nested a message structure can be, e.g. structs containing other structs or + // lists of structs. + // + // Like the traversal limit, this limit exists for security reasons. Since it is common to use + // recursive code to traverse recursive data structures, an attacker could easily cause a stack + // overflow by sending a very-deeply-nested (or even cyclic) message, without the message even + // being very large. The default limit of 64 is probably low enough to prevent any chance of + // stack overflow, yet high enough that it is never a problem in practice. +}; + +class MessageReader { + // Abstract interface for an object used to read a Cap'n Proto message. Subclasses of + // MessageReader are responsible for reading the raw, flat message content. Callers should + // usually call `messageReader.getRoot()` to get a `MyStructType::Reader` + // representing the root of the message, then use that to traverse the message content. + // + // Some common subclasses of `MessageReader` include `SegmentArrayMessageReader`, whose + // constructor accepts pointers to the raw data, and `StreamFdMessageReader` (from + // `serialize.h`), which reads the message from a file descriptor. One might implement other + // subclasses to handle things like reading from shared memory segments, mmap()ed files, etc. + +public: + MessageReader(ReaderOptions options); + // It is suggested that subclasses take ReaderOptions as a constructor parameter, but give it a + // default value of "ReaderOptions()". The base class constructor doesn't have a default value + // in order to remind subclasses that they really need to give the user a way to provide this. + + virtual ~MessageReader() noexcept(false); + + virtual kj::ArrayPtr getSegment(uint id) = 0; + // Gets the segment with the given ID, or returns null if no such segment exists. This method + // will be called at most once for each segment ID. + + inline const ReaderOptions& getOptions(); + // Get the options passed to the constructor. + + template + typename RootType::Reader getRoot(); + // Get the root struct of the message, interpreting it as the given struct type. + + template + typename RootType::Reader getRoot(SchemaType schema); + // Dynamically interpret the root struct of the message using the given schema (a StructSchema). + // RootType in this case must be DynamicStruct, and you must #include to + // use this. + + bool isCanonical(); + // Returns whether the message encoded in the reader is in canonical form. + +private: + ReaderOptions options; + + // Space in which we can construct a ReaderArena. We don't use ReaderArena directly here + // because we don't want clients to have to #include arena.h, which itself includes a bunch of + // big STL headers. We don't use a pointer to a ReaderArena because that would require an + // extra malloc on every message which could be expensive when processing small messages. + void* arenaSpace[15 + sizeof(kj::MutexGuarded) / sizeof(void*)]; + bool allocatedArena; + + _::ReaderArena* arena() { return reinterpret_cast<_::ReaderArena*>(arenaSpace); } + AnyPointer::Reader getRootInternal(); +}; + +class MessageBuilder { + // Abstract interface for an object used to allocate and build a message. Subclasses of + // MessageBuilder are responsible for allocating the space in which the message will be written. + // The most common subclass is `MallocMessageBuilder`, but other subclasses may be used to do + // tricky things like allocate messages in shared memory or mmap()ed files. + // + // Creating a new message ususually means allocating a new MessageBuilder (ideally on the stack) + // and then calling `messageBuilder.initRoot()` to get a `MyStructType::Builder`. + // That, in turn, can be used to fill in the message content. When done, you can call + // `messageBuilder.getSegmentsForOutput()` to get a list of flat data arrays containing the + // message. + +public: + MessageBuilder(); + virtual ~MessageBuilder() noexcept(false); + KJ_DISALLOW_COPY(MessageBuilder); + + struct SegmentInit { + kj::ArrayPtr space; + + size_t wordsUsed; + // Number of words in `space` which are used; the rest are free space in which additional + // objects may be allocated. + }; + + explicit MessageBuilder(kj::ArrayPtr segments); + // Create a MessageBuilder backed by existing memory. This is an advanced interface that most + // people should not use. THIS METHOD IS INSECURE; see below. + // + // This allows a MessageBuilder to be constructed to modify an in-memory message without first + // making a copy of the content. This is especially useful in conjunction with mmap(). + // + // The contents of each segment must outlive the MessageBuilder, but the SegmentInit array itself + // only need outlive the constructor. + // + // SECURITY: Do not use this in conjunction with untrusted data. This constructor assumes that + // the input message is valid. This constructor is designed to be used with data you control, + // e.g. an mmap'd file which is owned and accessed by only one program. When reading data you + // do not trust, you *must* load it into a Reader and then copy into a Builder as a means of + // validating the content. + // + // WARNING: It is NOT safe to initialize a MessageBuilder in this way from memory that is + // currently in use by another MessageBuilder or MessageReader. Other readers/builders will + // not observe changes to the segment sizes nor newly-allocated segments caused by allocating + // new objects in this message. + + virtual kj::ArrayPtr allocateSegment(uint minimumSize) = 0; + // Allocates an array of at least the given number of words, throwing an exception or crashing if + // this is not possible. It is expected that this method will usually return more space than + // requested, and the caller should use that extra space as much as possible before allocating + // more. The returned space remains valid at least until the MessageBuilder is destroyed. + // + // Cap'n Proto will only call this once at a time, so the subclass need not worry about + // thread-safety. + + template + typename RootType::Builder initRoot(); + // Initialize the root struct of the message as the given struct type. + + template + void setRoot(Reader&& value); + // Set the root struct to a deep copy of the given struct. + + template + typename RootType::Builder getRoot(); + // Get the root struct of the message, interpreting it as the given struct type. + + template + typename RootType::Builder getRoot(SchemaType schema); + // Dynamically interpret the root struct of the message using the given schema (a StructSchema). + // RootType in this case must be DynamicStruct, and you must #include to + // use this. + + template + typename RootType::Builder initRoot(SchemaType schema); + // Dynamically init the root struct of the message using the given schema (a StructSchema). + // RootType in this case must be DynamicStruct, and you must #include to + // use this. + + template + void adoptRoot(Orphan&& orphan); + // Like setRoot() but adopts the orphan without copying. + + kj::ArrayPtr> getSegmentsForOutput(); + // Get the raw data that makes up the message. + + Orphanage getOrphanage(); + + bool isCanonical(); + // Check whether the message builder is in canonical form + +private: + void* arenaSpace[22]; + // Space in which we can construct a BuilderArena. We don't use BuilderArena directly here + // because we don't want clients to have to #include arena.h, which itself includes a bunch of + // big STL headers. We don't use a pointer to a BuilderArena because that would require an + // extra malloc on every message which could be expensive when processing small messages. + + bool allocatedArena = false; + // We have to initialize the arena lazily because when we do so we want to allocate the root + // pointer immediately, and this will allocate a segment, which requires a virtual function + // call on the MessageBuilder. We can't do such a call in the constructor since the subclass + // isn't constructed yet. This is kind of annoying because it means that getOrphanage() is + // not thread-safe, but that shouldn't be a huge deal... + + _::BuilderArena* arena() { return reinterpret_cast<_::BuilderArena*>(arenaSpace); } + _::SegmentBuilder* getRootSegment(); + AnyPointer::Builder getRootInternal(); +}; + +template +typename RootType::Reader readMessageUnchecked(const word* data); +// IF THE INPUT IS INVALID, THIS MAY CRASH, CORRUPT MEMORY, CREATE A SECURITY HOLE IN YOUR APP, +// MURDER YOUR FIRST-BORN CHILD, AND/OR BRING ABOUT ETERNAL DAMNATION ON ALL OF HUMANITY. DO NOT +// USE UNLESS YOU UNDERSTAND THE CONSEQUENCES. +// +// Given a pointer to a known-valid message located in a single contiguous memory segment, +// returns a reader for that message. No bounds-checking will be done while traversing this +// message. Use this only if you have already verified that all pointers are valid and in-bounds, +// and there are no far pointers in the message. +// +// To create a message that can be passed to this function, build a message using a MallocAllocator +// whose preferred segment size is larger than the message size. This guarantees that the message +// will be allocated as a single segment, meaning getSegmentsForOutput() returns a single word +// array. That word array is your message; you may pass a pointer to its first word into +// readMessageUnchecked() to read the message. +// +// This can be particularly handy for embedding messages in generated code: you can +// embed the raw bytes (using AlignedData) then make a Reader for it using this. This is the way +// default values are embedded in code generated by the Cap'n Proto compiler. E.g., if you have +// a message MyMessage, you can read its default value like so: +// MyMessage::Reader reader = Message::readMessageUnchecked(MyMessage::DEFAULT.words); +// +// To sanitize a message from an untrusted source such that it can be safely passed to +// readMessageUnchecked(), use copyToUnchecked(). + +template +void copyToUnchecked(Reader&& reader, kj::ArrayPtr uncheckedBuffer); +// Copy the content of the given reader into the given buffer, such that it can safely be passed to +// readMessageUnchecked(). The buffer's size must be exactly reader.totalSizeInWords() + 1, +// otherwise an exception will be thrown. The buffer must be zero'd before calling. + +template +typename RootType::Reader readDataStruct(kj::ArrayPtr data); +// Interprets the given data as a single, data-only struct. Only primitive fields (booleans, +// numbers, and enums) will be readable; all pointers will be null. This is useful if you want +// to use Cap'n Proto as a language/platform-neutral way to pack some bits. +// +// The input is a word array rather than a byte array to enforce alignment. If you have a byte +// array which you know is word-aligned (or if your platform supports unaligned reads and you don't +// mind the performance penalty), then you can use `reinterpret_cast` to convert a byte array into +// a word array: +// +// kj::arrayPtr(reinterpret_cast(bytes.begin()), +// reinterpret_cast(bytes.end())) + +template +typename kj::ArrayPtr writeDataStruct(BuilderType builder); +// Given a struct builder, get the underlying data section as a word array, suitable for passing +// to `readDataStruct()`. +// +// Note that you may call `.toBytes()` on the returned value to convert to `ArrayPtr`. + +template +static typename Type::Reader defaultValue(); +// Get a default instance of the given struct or list type. +// +// TODO(cleanup): Find a better home for this function? + +// ======================================================================================= + +class SegmentArrayMessageReader: public MessageReader { + // A simple MessageReader that reads from an array of word arrays representing all segments. + // In particular you can read directly from the output of MessageBuilder::getSegmentsForOutput() + // (although it would probably make more sense to call builder.getRoot().asReader() in that case). + +public: + SegmentArrayMessageReader(kj::ArrayPtr> segments, + ReaderOptions options = ReaderOptions()); + // Creates a message pointing at the given segment array, without taking ownership of the + // segments. All arrays passed in must remain valid until the MessageReader is destroyed. + + KJ_DISALLOW_COPY(SegmentArrayMessageReader); + ~SegmentArrayMessageReader() noexcept(false); + + virtual kj::ArrayPtr getSegment(uint id) override; + +private: + kj::ArrayPtr> segments; +}; + +enum class AllocationStrategy: uint8_t { + FIXED_SIZE, + // The builder will prefer to allocate the same amount of space for each segment with no + // heuristic growth. It will still allocate larger segments when the preferred size is too small + // for some single object. This mode is generally not recommended, but can be particularly useful + // for testing in order to force a message to allocate a predictable number of segments. Note + // that you can force every single object in the message to be located in a separate segment by + // using this mode with firstSegmentWords = 0. + + GROW_HEURISTICALLY + // The builder will heuristically decide how much space to allocate for each segment. Each + // allocated segment will be progressively larger than the previous segments on the assumption + // that message sizes are exponentially distributed. The total number of segments that will be + // allocated for a message of size n is O(log n). +}; + +constexpr uint SUGGESTED_FIRST_SEGMENT_WORDS = 1024; +constexpr AllocationStrategy SUGGESTED_ALLOCATION_STRATEGY = AllocationStrategy::GROW_HEURISTICALLY; + +class MallocMessageBuilder: public MessageBuilder { + // A simple MessageBuilder that uses malloc() (actually, calloc()) to allocate segments. This + // implementation should be reasonable for any case that doesn't require writing the message to + // a specific location in memory. + +public: + explicit MallocMessageBuilder(uint firstSegmentWords = SUGGESTED_FIRST_SEGMENT_WORDS, + AllocationStrategy allocationStrategy = SUGGESTED_ALLOCATION_STRATEGY); + // Creates a BuilderContext which allocates at least the given number of words for the first + // segment, and then uses the given strategy to decide how much to allocate for subsequent + // segments. When choosing a value for firstSegmentWords, consider that: + // 1) Reading and writing messages gets slower when multiple segments are involved, so it's good + // if most messages fit in a single segment. + // 2) Unused bytes will not be written to the wire, so generally it is not a big deal to allocate + // more space than you need. It only becomes problematic if you are allocating many messages + // in parallel and thus use lots of memory, or if you allocate so much extra space that just + // zeroing it out becomes a bottleneck. + // The defaults have been chosen to be reasonable for most people, so don't change them unless you + // have reason to believe you need to. + + explicit MallocMessageBuilder(kj::ArrayPtr firstSegment, + AllocationStrategy allocationStrategy = SUGGESTED_ALLOCATION_STRATEGY); + // This version always returns the given array for the first segment, and then proceeds with the + // allocation strategy. This is useful for optimization when building lots of small messages in + // a tight loop: you can reuse the space for the first segment. + // + // firstSegment MUST be zero-initialized. MallocMessageBuilder's destructor will write new zeros + // over any space that was used so that it can be reused. + + KJ_DISALLOW_COPY(MallocMessageBuilder); + virtual ~MallocMessageBuilder() noexcept(false); + + virtual kj::ArrayPtr allocateSegment(uint minimumSize) override; + +private: + uint nextSize; + AllocationStrategy allocationStrategy; + + bool ownFirstSegment; + bool returnedFirstSegment; + + void* firstSegment; + + struct MoreSegments; + kj::Maybe> moreSegments; +}; + +class FlatMessageBuilder: public MessageBuilder { + // THIS IS NOT THE CLASS YOU'RE LOOKING FOR. + // + // If you want to write a message into already-existing scratch space, use `MallocMessageBuilder` + // and pass the scratch space to its constructor. It will then only fall back to malloc() if + // the scratch space is not large enough. + // + // Do NOT use this class unless you really know what you're doing. This class is problematic + // because it requires advance knowledge of the size of your message, which is usually impossible + // to determine without actually building the message. The class was created primarily to + // implement `copyToUnchecked()`, which itself exists only to support other internal parts of + // the Cap'n Proto implementation. + +public: + explicit FlatMessageBuilder(kj::ArrayPtr array); + KJ_DISALLOW_COPY(FlatMessageBuilder); + virtual ~FlatMessageBuilder() noexcept(false); + + void requireFilled(); + // Throws an exception if the flat array is not exactly full. + + virtual kj::ArrayPtr allocateSegment(uint minimumSize) override; + +private: + kj::ArrayPtr array; + bool allocated; +}; + +// ======================================================================================= +// implementation details + +inline const ReaderOptions& MessageReader::getOptions() { + return options; +} + +template +inline typename RootType::Reader MessageReader::getRoot() { + return getRootInternal().getAs(); +} + +template +inline typename RootType::Builder MessageBuilder::initRoot() { + return getRootInternal().initAs(); +} + +template +inline void MessageBuilder::setRoot(Reader&& value) { + getRootInternal().setAs>(value); +} + +template +inline typename RootType::Builder MessageBuilder::getRoot() { + return getRootInternal().getAs(); +} + +template +void MessageBuilder::adoptRoot(Orphan&& orphan) { + return getRootInternal().adopt(kj::mv(orphan)); +} + +template +typename RootType::Reader MessageReader::getRoot(SchemaType schema) { + return getRootInternal().getAs(schema); +} + +template +typename RootType::Builder MessageBuilder::getRoot(SchemaType schema) { + return getRootInternal().getAs(schema); +} + +template +typename RootType::Builder MessageBuilder::initRoot(SchemaType schema) { + return getRootInternal().initAs(schema); +} + +template +typename RootType::Reader readMessageUnchecked(const word* data) { + return AnyPointer::Reader(_::PointerReader::getRootUnchecked(data)).getAs(); +} + +template +void copyToUnchecked(Reader&& reader, kj::ArrayPtr uncheckedBuffer) { + FlatMessageBuilder builder(uncheckedBuffer); + builder.setRoot(kj::fwd(reader)); + builder.requireFilled(); +} + +template +typename RootType::Reader readDataStruct(kj::ArrayPtr data) { + return typename RootType::Reader(_::StructReader(data)); +} + +template +typename kj::ArrayPtr writeDataStruct(BuilderType builder) { + auto bytes = _::PointerHelpers>::getInternalBuilder(kj::mv(builder)) + .getDataSectionAsBlob(); + return kj::arrayPtr(reinterpret_cast(bytes.begin()), + reinterpret_cast(bytes.end())); +} + +template +static typename Type::Reader defaultValue() { + return typename Type::Reader(_::StructReader()); +} + +template +kj::Array canonicalize(T&& reader) { + return _::PointerHelpers>::getInternalReader(reader).canonicalize(); +} + +} // namespace capnp + +#endif // CAPNP_MESSAGE_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/orphan.h b/phonelibs/capnp-cpp/include/capnp/orphan.h new file mode 100644 index 00000000000000..8c8b9a6054c885 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/orphan.h @@ -0,0 +1,440 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_ORPHAN_H_ +#define CAPNP_ORPHAN_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "layout.h" + +namespace capnp { + +class StructSchema; +class ListSchema; +struct DynamicStruct; +struct DynamicList; +namespace _ { struct OrphanageInternal; } + +template +class Orphan { + // Represents an object which is allocated within some message builder but has no pointers + // pointing at it. An Orphan can later be "adopted" by some other object as one of that object's + // fields, without having to copy the orphan. For a field `foo` of pointer type, the generated + // code will define builder methods `void adoptFoo(Orphan)` and `Orphan disownFoo()`. + // Orphans can also be created independently of any parent using an Orphanage. + // + // `Orphan` can be moved but not copied, like `Own`, so that it is impossible for one + // orphan to be adopted multiple times. If an orphan is destroyed without being adopted, its + // contents are zero'd out (and possibly reused, if we ever implement the ability to reuse space + // in a message arena). + +public: + Orphan() = default; + KJ_DISALLOW_COPY(Orphan); + Orphan(Orphan&&) = default; + Orphan& operator=(Orphan&&) = default; + inline Orphan(_::OrphanBuilder&& builder): builder(kj::mv(builder)) {} + + inline BuilderFor get(); + // Get the underlying builder. If the orphan is null, this will allocate and return a default + // object rather than crash. This is done for security -- otherwise, you might enable a DoS + // attack any time you disown a field and fail to check if it is null. In the case of structs, + // this means that the orphan is no longer null after get() returns. In the case of lists, + // no actual object is allocated since a simple empty ListBuilder can be returned. + + inline ReaderFor getReader() const; + + inline bool operator==(decltype(nullptr)) const { return builder == nullptr; } + inline bool operator!=(decltype(nullptr)) const { return builder != nullptr; } + + inline void truncate(uint size); + // Resize an object (which must be a list or a blob) to the given size. + // + // If the new size is less than the original, the remaining elements will be discarded. The + // list is never moved in this case. If the list happens to be located at the end of its segment + // (which is always true if the list was the last thing allocated), the removed memory will be + // reclaimed (reducing the messag size), otherwise it is simply zeroed. The reclaiming behavior + // is particularly useful for allocating buffer space when you aren't sure how much space you + // actually need: you can pre-allocate, say, a 4k byte array, read() from a file into it, and + // then truncate it back to the amount of space actually used. + // + // If the new size is greater than the original, the list is extended with default values. If + // the list is the last object in its segment *and* there is enough space left in the segment to + // extend it to cover the new values, then the list is extended in-place. Otherwise, it must be + // moved to a new location, leaving a zero'd hole in the previous space that won't be filled. + // This copy is shallow; sub-objects will simply be reparented, not copied. + // + // Any existing readers or builders pointing at the object are invalidated by this call (even if + // it doesn't move). You must call `get()` or `getReader()` again to get the new, valid pointer. + +private: + _::OrphanBuilder builder; + + template + friend struct _::PointerHelpers; + template + friend struct List; + template + friend class Orphan; + friend class Orphanage; + friend class MessageBuilder; +}; + +class Orphanage: private kj::DisallowConstCopy { + // Use to directly allocate Orphan objects, without having a parent object allocate and then + // disown the object. + +public: + inline Orphanage(): arena(nullptr) {} + + template + static Orphanage getForMessageContaining(BuilderType builder); + // Construct an Orphanage that allocates within the message containing the given Builder. This + // allows the constructed Orphans to be adopted by objects within said message. + // + // This constructor takes the builder rather than having the builder have a getOrphanage() method + // because this is an advanced feature and we don't want to pollute the builder APIs with it. + // + // Note that if you have a direct pointer to the `MessageBuilder`, you can simply call its + // `getOrphanage()` method. + + template + Orphan newOrphan() const; + // Allocate a new orphaned struct. + + template + Orphan newOrphan(uint size) const; + // Allocate a new orphaned list or blob. + + Orphan newOrphan(StructSchema schema) const; + // Dynamically create an orphan struct with the given schema. You must + // #include to use this. + + Orphan newOrphan(ListSchema schema, uint size) const; + // Dynamically create an orphan list with the given schema. You must #include + // to use this. + + template + Orphan> newOrphanCopy(Reader copyFrom) const; + // Allocate a new orphaned object (struct, list, or blob) and initialize it as a copy of the + // given object. + + template + Orphan>>> newOrphanConcat(kj::ArrayPtr lists) const; + template + Orphan>>> newOrphanConcat(kj::ArrayPtr lists) const; + // Given an array of List readers, copy and concatenate the lists, creating a new Orphan. + // + // Note that compared to allocating the list yourself and using `setWithCaveats()` to set each + // item, this method avoids the "caveats": the new list will be allocated with the element size + // being the maximum of that from all the input lists. This is particularly important when + // concatenating struct lists: if the lists were created using a newer version of the protocol + // in which some new fields had been added to the struct, using `setWithCaveats()` would + // truncate off those new fields. + + Orphan referenceExternalData(Data::Reader data) const; + // Creates an Orphan that points at an existing region of memory (e.g. from another message) + // without copying it. There are some SEVERE restrictions on how this can be used: + // - The memory must remain valid until the `MessageBuilder` is destroyed (even if the orphan is + // abandoned). + // - Because the data is const, you will not be allowed to obtain a `Data::Builder` + // for this blob. Any call which would return such a builder will throw an exception. You + // can, however, obtain a Reader, e.g. via orphan.getReader() or from a parent Reader (once + // the orphan is adopted). It is your responsibility to make sure your code can deal with + // these problems when using this optimization; if you can't, allocate a copy instead. + // - `data.begin()` must be aligned to a machine word boundary (32-bit or 64-bit depending on + // the CPU). Any pointer returned by malloc() as well as any data blob obtained from another + // Cap'n Proto message satisfies this. + // - If `data.size()` is not a multiple of 8, extra bytes past data.end() up until the next 8-byte + // boundary will be visible in the raw message when it is written out. Thus, there must be no + // secrets in these bytes. Data blobs obtained from other Cap'n Proto messages should be safe + // as these bytes should be zero (unless the sender had the same problem). + // + // The array will actually become one of the message's segments. The data can thus be adopted + // into the message tree without copying it. This is particularly useful when referencing very + // large blobs, such as whole mmap'd files. + +private: + _::BuilderArena* arena; + _::CapTableBuilder* capTable; + + inline explicit Orphanage(_::BuilderArena* arena, _::CapTableBuilder* capTable) + : arena(arena), capTable(capTable) {} + + template + struct GetInnerBuilder; + template + struct GetInnerReader; + template + struct NewOrphanListImpl; + + friend class MessageBuilder; + friend struct _::OrphanageInternal; +}; + +// ======================================================================================= +// Inline implementation details. + +namespace _ { // private + +template +struct OrphanGetImpl; + +template +struct OrphanGetImpl { + static inline void truncateListOf(_::OrphanBuilder& builder, ElementCount size) { + builder.truncate(size, _::elementSizeForType()); + } +}; + +template +struct OrphanGetImpl { + static inline typename T::Builder apply(_::OrphanBuilder& builder) { + return typename T::Builder(builder.asStruct(_::structSize())); + } + static inline typename T::Reader applyReader(const _::OrphanBuilder& builder) { + return typename T::Reader(builder.asStructReader(_::structSize())); + } + static inline void truncateListOf(_::OrphanBuilder& builder, ElementCount size) { + builder.truncate(size, _::structSize()); + } +}; + +#if !CAPNP_LITE +template +struct OrphanGetImpl { + static inline typename T::Client apply(_::OrphanBuilder& builder) { + return typename T::Client(builder.asCapability()); + } + static inline typename T::Client applyReader(const _::OrphanBuilder& builder) { + return typename T::Client(builder.asCapability()); + } + static inline void truncateListOf(_::OrphanBuilder& builder, ElementCount size) { + builder.truncate(size, ElementSize::POINTER); + } +}; +#endif // !CAPNP_LITE + +template +struct OrphanGetImpl, Kind::LIST> { + static inline typename List::Builder apply(_::OrphanBuilder& builder) { + return typename List::Builder(builder.asList(_::ElementSizeForType::value)); + } + static inline typename List::Reader applyReader(const _::OrphanBuilder& builder) { + return typename List::Reader(builder.asListReader(_::ElementSizeForType::value)); + } + static inline void truncateListOf(_::OrphanBuilder& builder, ElementCount size) { + builder.truncate(size, ElementSize::POINTER); + } +}; + +template +struct OrphanGetImpl, Kind::LIST> { + static inline typename List::Builder apply(_::OrphanBuilder& builder) { + return typename List::Builder(builder.asStructList(_::structSize())); + } + static inline typename List::Reader applyReader(const _::OrphanBuilder& builder) { + return typename List::Reader(builder.asListReader(_::ElementSizeForType::value)); + } + static inline void truncateListOf(_::OrphanBuilder& builder, ElementCount size) { + builder.truncate(size, ElementSize::POINTER); + } +}; + +template <> +struct OrphanGetImpl { + static inline Text::Builder apply(_::OrphanBuilder& builder) { + return Text::Builder(builder.asText()); + } + static inline Text::Reader applyReader(const _::OrphanBuilder& builder) { + return Text::Reader(builder.asTextReader()); + } + static inline void truncateListOf(_::OrphanBuilder& builder, ElementCount size) { + builder.truncate(size, ElementSize::POINTER); + } +}; + +template <> +struct OrphanGetImpl { + static inline Data::Builder apply(_::OrphanBuilder& builder) { + return Data::Builder(builder.asData()); + } + static inline Data::Reader applyReader(const _::OrphanBuilder& builder) { + return Data::Reader(builder.asDataReader()); + } + static inline void truncateListOf(_::OrphanBuilder& builder, ElementCount size) { + builder.truncate(size, ElementSize::POINTER); + } +}; + +struct OrphanageInternal { + static inline _::BuilderArena* getArena(Orphanage orphanage) { return orphanage.arena; } + static inline _::CapTableBuilder* getCapTable(Orphanage orphanage) { return orphanage.capTable; } +}; + +} // namespace _ (private) + +template +inline BuilderFor Orphan::get() { + return _::OrphanGetImpl::apply(builder); +} + +template +inline ReaderFor Orphan::getReader() const { + return _::OrphanGetImpl::applyReader(builder); +} + +template +inline void Orphan::truncate(uint size) { + _::OrphanGetImpl>::truncateListOf(builder, bounded(size) * ELEMENTS); +} + +template <> +inline void Orphan::truncate(uint size) { + builder.truncateText(bounded(size) * ELEMENTS); +} + +template <> +inline void Orphan::truncate(uint size) { + builder.truncate(bounded(size) * ELEMENTS, ElementSize::BYTE); +} + +template +struct Orphanage::GetInnerBuilder { + static inline _::StructBuilder apply(typename T::Builder& t) { + return t._builder; + } +}; + +template +struct Orphanage::GetInnerBuilder { + static inline _::ListBuilder apply(typename T::Builder& t) { + return t.builder; + } +}; + +template +Orphanage Orphanage::getForMessageContaining(BuilderType builder) { + auto inner = GetInnerBuilder>::apply(builder); + return Orphanage(inner.getArena(), inner.getCapTable()); +} + +template +Orphan Orphanage::newOrphan() const { + return Orphan(_::OrphanBuilder::initStruct(arena, capTable, _::structSize())); +} + +template +struct Orphanage::NewOrphanListImpl> { + static inline _::OrphanBuilder apply( + _::BuilderArena* arena, _::CapTableBuilder* capTable, uint size) { + return _::OrphanBuilder::initList( + arena, capTable, bounded(size) * ELEMENTS, _::ElementSizeForType::value); + } +}; + +template +struct Orphanage::NewOrphanListImpl> { + static inline _::OrphanBuilder apply( + _::BuilderArena* arena, _::CapTableBuilder* capTable, uint size) { + return _::OrphanBuilder::initStructList( + arena, capTable, bounded(size) * ELEMENTS, _::structSize()); + } +}; + +template <> +struct Orphanage::NewOrphanListImpl { + static inline _::OrphanBuilder apply( + _::BuilderArena* arena, _::CapTableBuilder* capTable, uint size) { + return _::OrphanBuilder::initText(arena, capTable, bounded(size) * BYTES); + } +}; + +template <> +struct Orphanage::NewOrphanListImpl { + static inline _::OrphanBuilder apply( + _::BuilderArena* arena, _::CapTableBuilder* capTable, uint size) { + return _::OrphanBuilder::initData(arena, capTable, bounded(size) * BYTES); + } +}; + +template +Orphan Orphanage::newOrphan(uint size) const { + return Orphan(NewOrphanListImpl::apply(arena, capTable, size)); +} + +template +struct Orphanage::GetInnerReader { + static inline _::StructReader apply(const typename T::Reader& t) { + return t._reader; + } +}; + +template +struct Orphanage::GetInnerReader { + static inline _::ListReader apply(const typename T::Reader& t) { + return t.reader; + } +}; + +template +struct Orphanage::GetInnerReader { + static inline const typename T::Reader& apply(const typename T::Reader& t) { + return t; + } +}; + +template +inline Orphan> Orphanage::newOrphanCopy(Reader copyFrom) const { + return Orphan>(_::OrphanBuilder::copy( + arena, capTable, GetInnerReader>::apply(copyFrom))); +} + +template +inline Orphan>>> +Orphanage::newOrphanConcat(kj::ArrayPtr lists) const { + return newOrphanConcat(kj::implicitCast>(lists)); +} +template +inline Orphan>>> +Orphanage::newOrphanConcat(kj::ArrayPtr lists) const { + // Optimization / simplification: Rely on List::Reader containing nothing except a + // _::ListReader. + static_assert(sizeof(T) == sizeof(_::ListReader), "lists are not bare readers?"); + kj::ArrayPtr raw( + reinterpret_cast(lists.begin()), lists.size()); + typedef ListElementType> Element; + return Orphan>( + _::OrphanBuilder::concat(arena, capTable, + _::elementSizeForType(), + _::minStructSizeForElement(), raw)); +} + +inline Orphan Orphanage::referenceExternalData(Data::Reader data) const { + return Orphan(_::OrphanBuilder::referenceExternalData(arena, data)); +} + +} // namespace capnp + +#endif // CAPNP_ORPHAN_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/persistent.capnp b/phonelibs/capnp-cpp/include/capnp/persistent.capnp new file mode 100644 index 00000000000000..a13b47168a4cc8 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/persistent.capnp @@ -0,0 +1,139 @@ +# Copyright (c) 2014 Sandstorm Development Group, Inc. and contributors +# Licensed under the MIT License: +# +# Permission is hereby granted, free of charge, to any person obtaining a copy +# of this software and associated documentation files (the "Software"), to deal +# in the Software without restriction, including without limitation the rights +# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +# copies of the Software, and to permit persons to whom the Software is +# furnished to do so, subject to the following conditions: +# +# The above copyright notice and this permission notice shall be included in +# all copies or substantial portions of the Software. +# +# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +# THE SOFTWARE. + +@0xb8630836983feed7; + +$import "/capnp/c++.capnp".namespace("capnp"); + +interface Persistent@0xc8cb212fcd9f5691(SturdyRef, Owner) { + # Interface implemented by capabilities that outlive a single connection. A client may save() + # the capability, producing a SturdyRef. The SturdyRef can be stored to disk, then later used to + # obtain a new reference to the capability on a future connection. + # + # The exact format of SturdyRef depends on the "realm" in which the SturdyRef appears. A "realm" + # is an abstract space in which all SturdyRefs have the same format and refer to the same set of + # resources. Every vat is in exactly one realm. All capability clients within that vat must + # produce SturdyRefs of the format appropriate for the realm. + # + # Similarly, every VatNetwork also resides in a particular realm. Usually, a vat's "realm" + # corresponds to the realm of its main VatNetwork. However, a Vat can in fact communicate over + # a VatNetwork in a different realm -- in this case, all SturdyRefs need to be transformed when + # coming or going through said VatNetwork. The RPC system has hooks for registering + # transformation callbacks for this purpose. + # + # Since the format of SturdyRef is realm-dependent, it is not defined here. An application should + # choose an appropriate realm for itself as part of its design. Note that under Sandstorm, every + # application exists in its own realm and is therefore free to define its own SturdyRef format; + # the Sandstorm platform handles translating between realms. + # + # Note that whether a capability is persistent is often orthogonal to its type. In these cases, + # the capability's interface should NOT inherit `Persistent`; instead, just perform a cast at + # runtime. It's not type-safe, but trying to be type-safe in these cases will likely lead to + # tears. In cases where a particular interface only makes sense on persistent capabilities, it + # still should not explicitly inherit Persistent because the `SturdyRef` and `Owner` types will + # vary between realms (they may even be different at the call site than they are on the + # implementation). Instead, mark persistent interfaces with the $persistent annotation (defined + # below). + # + # Sealing + # ------- + # + # As an added security measure, SturdyRefs may be "sealed" to a particular owner, such that + # if the SturdyRef itself leaks to a third party, that party cannot actually restore it because + # they are not the owner. To restore a sealed capability, you must first prove to its host that + # you are the rightful owner. The precise mechanism for this authentication is defined by the + # realm. + # + # Sealing is a defense-in-depth mechanism meant to mitigate damage in the case of catastrophic + # attacks. For example, say an attacker temporarily gains read access to a database full of + # SturdyRefs: it would be unfortunate if it were then necessary to revoke every single reference + # in the database to prevent the attacker from using them. + # + # In general, an "owner" is a course-grained identity. Because capability-based security is still + # the primary mechanism of security, it is not necessary nor desirable to have a separate "owner" + # identity for every single process or object; that is exactly what capabilities are supposed to + # avoid! Instead, it makes sense for an "owner" to literally identify the owner of the machines + # where the capability is stored. If untrusted third parties are able to run arbitrary code on + # said machines, then the sandbox for that code should be designed using Distributed Confinement + # such that the third-party code never sees the bits of the SturdyRefs and cannot directly + # exercise the owner's power to restore refs. See: + # + # http://www.erights.org/elib/capability/dist-confine.html + # + # Resist the urge to represent an Owner as a simple public key. The whole point of sealing is to + # defend against leaked-storage attacks. Such attacks can easily result in the owner's private + # key being stolen as well. A better solution is for `Owner` to contain a simple globally unique + # identifier for the owner, and for everyone to separately maintain a mapping of owner IDs to + # public keys. If an owner's private key is compromised, then humans will need to communicate + # and agree on a replacement public key, then update the mapping. + # + # As a concrete example, an `Owner` could simply contain a domain name, and restoring a SturdyRef + # would require signing a request using the domain's private key. Authenticating this key could + # be accomplished through certificate authorities or web-of-trust techniques. + + save @0 SaveParams -> SaveResults; + # Save a capability persistently so that it can be restored by a future connection. Not all + # capabilities can be saved -- application interfaces should define which capabilities support + # this and which do not. + + struct SaveParams { + sealFor @0 :Owner; + # Seal the SturdyRef so that it can only be restored by the specified Owner. This is meant + # to mitigate damage when a SturdyRef is leaked. See comments above. + # + # Leaving this value null may or may not be allowed; it is up to the realm to decide. If a + # realm does allow a null owner, this should indicate that anyone is allowed to restore the + # ref. + } + struct SaveResults { + sturdyRef @0 :SturdyRef; + } +} + +interface RealmGateway(InternalRef, ExternalRef, InternalOwner, ExternalOwner) { + # Interface invoked when a SturdyRef is about to cross realms. The RPC system supports providing + # a RealmGateway as a callback hook when setting up RPC over some VatNetwork. + + import @0 (cap :Persistent(ExternalRef, ExternalOwner), + params :Persistent(InternalRef, InternalOwner).SaveParams) + -> Persistent(InternalRef, InternalOwner).SaveResults; + # Given an external capability, save it and return an internal reference. Used when someone + # inside the realm tries to save a capability from outside the realm. + + export @1 (cap :Persistent(InternalRef, InternalOwner), + params :Persistent(ExternalRef, ExternalOwner).SaveParams) + -> Persistent(ExternalRef, ExternalOwner).SaveResults; + # Given an internal capability, save it and return an external reference. Used when someone + # outside the realm tries to save a capability from inside the realm. +} + +annotation persistent(interface, field) :Void; +# Apply this annotation to interfaces for objects that will always be persistent, instead of +# extending the Persistent capability, since the correct type parameters to Persistent depend on +# the realm, which is orthogonal to the interface type and therefore should not be defined +# along-side it. +# +# You may also apply this annotation to a capability-typed field which will always contain a +# persistent capability, but where the capability's interface itself is not already marked +# persistent. +# +# Note that absence of the $persistent annotation doesn't mean a capability of that type isn't +# persistent; it just means not *all* such capabilities are persistent. diff --git a/phonelibs/capnp-cpp/include/capnp/persistent.capnp.h b/phonelibs/capnp-cpp/include/capnp/persistent.capnp.h new file mode 100644 index 00000000000000..f9b443220a9584 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/persistent.capnp.h @@ -0,0 +1,1328 @@ +// Generated by Cap'n Proto compiler, DO NOT EDIT +// source: persistent.capnp + +#ifndef CAPNP_INCLUDED_b8630836983feed7_ +#define CAPNP_INCLUDED_b8630836983feed7_ + +#include +#if !CAPNP_LITE +#include +#endif // !CAPNP_LITE + +#if CAPNP_VERSION != 6001 +#error "Version mismatch between generated code and library headers. You must use the same version of the Cap'n Proto compiler and library." +#endif + + +namespace capnp { +namespace schemas { + +CAPNP_DECLARE_SCHEMA(c8cb212fcd9f5691); +CAPNP_DECLARE_SCHEMA(f76fba59183073a5); +CAPNP_DECLARE_SCHEMA(b76848c18c40efbf); +CAPNP_DECLARE_SCHEMA(84ff286cd00a3ed4); +CAPNP_DECLARE_SCHEMA(f0c2cc1d3909574d); +CAPNP_DECLARE_SCHEMA(ecafa18b482da3aa); +CAPNP_DECLARE_SCHEMA(f622595091cafb67); + +} // namespace schemas +} // namespace capnp + +namespace capnp { + +template +struct Persistent { + Persistent() = delete; + +#if !CAPNP_LITE + class Client; + class Server; +#endif // !CAPNP_LITE + + struct SaveParams; + struct SaveResults; + + #if !CAPNP_LITE + struct _capnpPrivate { + CAPNP_DECLARE_INTERFACE_HEADER(c8cb212fcd9f5691) + static const ::capnp::_::RawBrandedSchema::Scope brandScopes[]; + static const ::capnp::_::RawBrandedSchema::Binding brandBindings[]; + static const ::capnp::_::RawBrandedSchema::Dependency brandDependencies[]; + static const ::capnp::_::RawBrandedSchema specificBrand; + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return ::capnp::_::ChooseBrand<_capnpPrivate, SturdyRef, Owner>::brand(); } + }; + #endif // !CAPNP_LITE +}; + +template +struct Persistent::SaveParams { + SaveParams() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(f76fba59183073a5, 0, 1) + #if !CAPNP_LITE + static const ::capnp::_::RawBrandedSchema::Scope brandScopes[]; + static const ::capnp::_::RawBrandedSchema::Binding brandBindings[]; + static const ::capnp::_::RawBrandedSchema specificBrand; + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return ::capnp::_::ChooseBrand<_capnpPrivate, SturdyRef, Owner>::brand(); } + #endif // !CAPNP_LITE + }; +}; + +template +struct Persistent::SaveResults { + SaveResults() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(b76848c18c40efbf, 0, 1) + #if !CAPNP_LITE + static const ::capnp::_::RawBrandedSchema::Scope brandScopes[]; + static const ::capnp::_::RawBrandedSchema::Binding brandBindings[]; + static const ::capnp::_::RawBrandedSchema specificBrand; + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return ::capnp::_::ChooseBrand<_capnpPrivate, SturdyRef, Owner>::brand(); } + #endif // !CAPNP_LITE + }; +}; + +template +struct RealmGateway { + RealmGateway() = delete; + +#if !CAPNP_LITE + class Client; + class Server; +#endif // !CAPNP_LITE + + struct ImportParams; + struct ExportParams; + + #if !CAPNP_LITE + struct _capnpPrivate { + CAPNP_DECLARE_INTERFACE_HEADER(84ff286cd00a3ed4) + static const ::capnp::_::RawBrandedSchema::Scope brandScopes[]; + static const ::capnp::_::RawBrandedSchema::Binding brandBindings[]; + static const ::capnp::_::RawBrandedSchema::Dependency brandDependencies[]; + static const ::capnp::_::RawBrandedSchema specificBrand; + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return ::capnp::_::ChooseBrand<_capnpPrivate, InternalRef, ExternalRef, InternalOwner, ExternalOwner>::brand(); } + }; + #endif // !CAPNP_LITE +}; + +template +struct RealmGateway::ImportParams { + ImportParams() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(f0c2cc1d3909574d, 0, 2) + #if !CAPNP_LITE + static const ::capnp::_::RawBrandedSchema::Scope brandScopes[]; + static const ::capnp::_::RawBrandedSchema::Binding brandBindings[]; + static const ::capnp::_::RawBrandedSchema::Dependency brandDependencies[]; + static const ::capnp::_::RawBrandedSchema specificBrand; + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return ::capnp::_::ChooseBrand<_capnpPrivate, InternalRef, ExternalRef, InternalOwner, ExternalOwner>::brand(); } + #endif // !CAPNP_LITE + }; +}; + +template +struct RealmGateway::ExportParams { + ExportParams() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(ecafa18b482da3aa, 0, 2) + #if !CAPNP_LITE + static const ::capnp::_::RawBrandedSchema::Scope brandScopes[]; + static const ::capnp::_::RawBrandedSchema::Binding brandBindings[]; + static const ::capnp::_::RawBrandedSchema::Dependency brandDependencies[]; + static const ::capnp::_::RawBrandedSchema specificBrand; + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return ::capnp::_::ChooseBrand<_capnpPrivate, InternalRef, ExternalRef, InternalOwner, ExternalOwner>::brand(); } + #endif // !CAPNP_LITE + }; +}; + +// ======================================================================================= + +#if !CAPNP_LITE +template +class Persistent::Client + : public virtual ::capnp::Capability::Client { +public: + typedef Persistent Calls; + typedef Persistent Reads; + + Client(decltype(nullptr)); + explicit Client(::kj::Own< ::capnp::ClientHook>&& hook); + template ()>> + Client(::kj::Own<_t>&& server); + template ()>> + Client(::kj::Promise<_t>&& promise); + Client(::kj::Exception&& exception); + Client(Client&) = default; + Client(Client&&) = default; + Client& operator=(Client& other); + Client& operator=(Client&& other); + + template + typename Persistent::Client asGeneric() { + return castAs>(); + } + + CAPNP_AUTO_IF_MSVC(::capnp::Request::SaveParams, typename ::capnp::Persistent::SaveResults>) saveRequest( + ::kj::Maybe< ::capnp::MessageSize> sizeHint = nullptr); + +protected: + Client() = default; +}; + +template +class Persistent::Server + : public virtual ::capnp::Capability::Server { +public: + typedef Persistent Serves; + + ::kj::Promise dispatchCall(uint64_t interfaceId, uint16_t methodId, + ::capnp::CallContext< ::capnp::AnyPointer, ::capnp::AnyPointer> context) + override; + +protected: + typedef ::capnp::CallContext::SaveParams, typename ::capnp::Persistent::SaveResults> SaveContext; + virtual ::kj::Promise save(SaveContext context); + + inline typename ::capnp::Persistent::Client thisCap() { + return ::capnp::Capability::Server::thisCap() + .template castAs< ::capnp::Persistent>(); + } + + ::kj::Promise dispatchCallInternal(uint16_t methodId, + ::capnp::CallContext< ::capnp::AnyPointer, ::capnp::AnyPointer> context); +}; +#endif // !CAPNP_LITE + +template +class Persistent::SaveParams::Reader { +public: + typedef SaveParams Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + template + typename Persistent::SaveParams::Reader asPersistentGeneric() { + return typename Persistent::SaveParams::Reader(_reader); + } + + inline bool hasSealFor() const; + inline ::capnp::ReaderFor getSealFor() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +template +class Persistent::SaveParams::Builder { +public: + typedef SaveParams Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + template + typename Persistent::SaveParams::Builder asPersistentGeneric() { + return typename Persistent::SaveParams::Builder(_builder); + } + + inline bool hasSealFor(); + inline ::capnp::BuilderFor getSealFor(); + inline void setSealFor( ::capnp::ReaderFor value); + inline ::capnp::BuilderFor initSealFor(); + inline ::capnp::BuilderFor initSealFor(unsigned int size); + inline void adoptSealFor(::capnp::Orphan&& value); + inline ::capnp::Orphan disownSealFor(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +template +class Persistent::SaveParams::Pipeline { +public: + typedef SaveParams Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::PipelineFor getSealFor(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +template +class Persistent::SaveResults::Reader { +public: + typedef SaveResults Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + template + typename Persistent::SaveResults::Reader asPersistentGeneric() { + return typename Persistent::SaveResults::Reader(_reader); + } + + inline bool hasSturdyRef() const; + inline ::capnp::ReaderFor getSturdyRef() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +template +class Persistent::SaveResults::Builder { +public: + typedef SaveResults Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + template + typename Persistent::SaveResults::Builder asPersistentGeneric() { + return typename Persistent::SaveResults::Builder(_builder); + } + + inline bool hasSturdyRef(); + inline ::capnp::BuilderFor getSturdyRef(); + inline void setSturdyRef( ::capnp::ReaderFor value); + inline ::capnp::BuilderFor initSturdyRef(); + inline ::capnp::BuilderFor initSturdyRef(unsigned int size); + inline void adoptSturdyRef(::capnp::Orphan&& value); + inline ::capnp::Orphan disownSturdyRef(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +template +class Persistent::SaveResults::Pipeline { +public: + typedef SaveResults Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::PipelineFor getSturdyRef(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +#if !CAPNP_LITE +template +class RealmGateway::Client + : public virtual ::capnp::Capability::Client { +public: + typedef RealmGateway Calls; + typedef RealmGateway Reads; + + Client(decltype(nullptr)); + explicit Client(::kj::Own< ::capnp::ClientHook>&& hook); + template ()>> + Client(::kj::Own<_t>&& server); + template ()>> + Client(::kj::Promise<_t>&& promise); + Client(::kj::Exception&& exception); + Client(Client&) = default; + Client(Client&&) = default; + Client& operator=(Client& other); + Client& operator=(Client&& other); + + template + typename RealmGateway::Client asGeneric() { + return castAs>(); + } + + CAPNP_AUTO_IF_MSVC(::capnp::Request::ImportParams, typename ::capnp::Persistent::SaveResults>) importRequest( + ::kj::Maybe< ::capnp::MessageSize> sizeHint = nullptr); + CAPNP_AUTO_IF_MSVC(::capnp::Request::ExportParams, typename ::capnp::Persistent::SaveResults>) exportRequest( + ::kj::Maybe< ::capnp::MessageSize> sizeHint = nullptr); + +protected: + Client() = default; +}; + +template +class RealmGateway::Server + : public virtual ::capnp::Capability::Server { +public: + typedef RealmGateway Serves; + + ::kj::Promise dispatchCall(uint64_t interfaceId, uint16_t methodId, + ::capnp::CallContext< ::capnp::AnyPointer, ::capnp::AnyPointer> context) + override; + +protected: + typedef typename ::capnp::RealmGateway::ImportParams ImportParams; + typedef ::capnp::CallContext::SaveResults> ImportContext; + virtual ::kj::Promise import(ImportContext context); + typedef typename ::capnp::RealmGateway::ExportParams ExportParams; + typedef ::capnp::CallContext::SaveResults> ExportContext; + virtual ::kj::Promise export_(ExportContext context); + + inline typename ::capnp::RealmGateway::Client thisCap() { + return ::capnp::Capability::Server::thisCap() + .template castAs< ::capnp::RealmGateway>(); + } + + ::kj::Promise dispatchCallInternal(uint16_t methodId, + ::capnp::CallContext< ::capnp::AnyPointer, ::capnp::AnyPointer> context); +}; +#endif // !CAPNP_LITE + +template +class RealmGateway::ImportParams::Reader { +public: + typedef ImportParams Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + template + typename RealmGateway::ImportParams::Reader asRealmGatewayGeneric() { + return typename RealmGateway::ImportParams::Reader(_reader); + } + + inline bool hasCap() const; +#if !CAPNP_LITE + inline typename ::capnp::Persistent::Client getCap() const; +#endif // !CAPNP_LITE + + inline bool hasParams() const; + inline typename ::capnp::Persistent::SaveParams::Reader getParams() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +template +class RealmGateway::ImportParams::Builder { +public: + typedef ImportParams Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + template + typename RealmGateway::ImportParams::Builder asRealmGatewayGeneric() { + return typename RealmGateway::ImportParams::Builder(_builder); + } + + inline bool hasCap(); +#if !CAPNP_LITE + inline typename ::capnp::Persistent::Client getCap(); + inline void setCap(typename ::capnp::Persistent::Client&& value); + inline void setCap(typename ::capnp::Persistent::Client& value); + inline void adoptCap(::capnp::Orphan< ::capnp::Persistent>&& value); + inline ::capnp::Orphan< ::capnp::Persistent> disownCap(); +#endif // !CAPNP_LITE + + inline bool hasParams(); + inline typename ::capnp::Persistent::SaveParams::Builder getParams(); + inline void setParams(typename ::capnp::Persistent::SaveParams::Reader value); + inline typename ::capnp::Persistent::SaveParams::Builder initParams(); + inline void adoptParams(::capnp::Orphan::SaveParams>&& value); + inline ::capnp::Orphan::SaveParams> disownParams(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +template +class RealmGateway::ImportParams::Pipeline { +public: + typedef ImportParams Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline typename ::capnp::Persistent::Client getCap(); + inline typename ::capnp::Persistent::SaveParams::Pipeline getParams(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +template +class RealmGateway::ExportParams::Reader { +public: + typedef ExportParams Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + template + typename RealmGateway::ExportParams::Reader asRealmGatewayGeneric() { + return typename RealmGateway::ExportParams::Reader(_reader); + } + + inline bool hasCap() const; +#if !CAPNP_LITE + inline typename ::capnp::Persistent::Client getCap() const; +#endif // !CAPNP_LITE + + inline bool hasParams() const; + inline typename ::capnp::Persistent::SaveParams::Reader getParams() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +template +class RealmGateway::ExportParams::Builder { +public: + typedef ExportParams Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + template + typename RealmGateway::ExportParams::Builder asRealmGatewayGeneric() { + return typename RealmGateway::ExportParams::Builder(_builder); + } + + inline bool hasCap(); +#if !CAPNP_LITE + inline typename ::capnp::Persistent::Client getCap(); + inline void setCap(typename ::capnp::Persistent::Client&& value); + inline void setCap(typename ::capnp::Persistent::Client& value); + inline void adoptCap(::capnp::Orphan< ::capnp::Persistent>&& value); + inline ::capnp::Orphan< ::capnp::Persistent> disownCap(); +#endif // !CAPNP_LITE + + inline bool hasParams(); + inline typename ::capnp::Persistent::SaveParams::Builder getParams(); + inline void setParams(typename ::capnp::Persistent::SaveParams::Reader value); + inline typename ::capnp::Persistent::SaveParams::Builder initParams(); + inline void adoptParams(::capnp::Orphan::SaveParams>&& value); + inline ::capnp::Orphan::SaveParams> disownParams(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +template +class RealmGateway::ExportParams::Pipeline { +public: + typedef ExportParams Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline typename ::capnp::Persistent::Client getCap(); + inline typename ::capnp::Persistent::SaveParams::Pipeline getParams(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +// ======================================================================================= + +#if !CAPNP_LITE +template +inline Persistent::Client::Client(decltype(nullptr)) + : ::capnp::Capability::Client(nullptr) {} +template +inline Persistent::Client::Client( + ::kj::Own< ::capnp::ClientHook>&& hook) + : ::capnp::Capability::Client(::kj::mv(hook)) {} +template +template +inline Persistent::Client::Client(::kj::Own<_t>&& server) + : ::capnp::Capability::Client(::kj::mv(server)) {} +template +template +inline Persistent::Client::Client(::kj::Promise<_t>&& promise) + : ::capnp::Capability::Client(::kj::mv(promise)) {} +template +inline Persistent::Client::Client(::kj::Exception&& exception) + : ::capnp::Capability::Client(::kj::mv(exception)) {} +template +inline typename ::capnp::Persistent::Client& Persistent::Client::operator=(Client& other) { + ::capnp::Capability::Client::operator=(other); + return *this; +} +template +inline typename ::capnp::Persistent::Client& Persistent::Client::operator=(Client&& other) { + ::capnp::Capability::Client::operator=(kj::mv(other)); + return *this; +} + +#endif // !CAPNP_LITE +template +inline bool Persistent::SaveParams::Reader::hasSealFor() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +template +inline bool Persistent::SaveParams::Builder::hasSealFor() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +template +inline ::capnp::ReaderFor Persistent::SaveParams::Reader::getSealFor() const { + return ::capnp::_::PointerHelpers::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +template +inline ::capnp::BuilderFor Persistent::SaveParams::Builder::getSealFor() { + return ::capnp::_::PointerHelpers::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +template +inline ::capnp::PipelineFor Persistent::SaveParams::Pipeline::getSealFor() { + return ::capnp::PipelineFor(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +template +inline void Persistent::SaveParams::Builder::setSealFor( ::capnp::ReaderFor value) { + ::capnp::_::PointerHelpers::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +template +inline ::capnp::BuilderFor Persistent::SaveParams::Builder::initSealFor() { + return ::capnp::_::PointerHelpers::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +template +inline ::capnp::BuilderFor Persistent::SaveParams::Builder::initSealFor(unsigned int size) { + return ::capnp::_::PointerHelpers::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +template +inline void Persistent::SaveParams::Builder::adoptSealFor( + ::capnp::Orphan&& value) { + ::capnp::_::PointerHelpers::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +template +inline ::capnp::Orphan Persistent::SaveParams::Builder::disownSealFor() { + return ::capnp::_::PointerHelpers::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +// Persistent::SaveParams +template +constexpr uint16_t Persistent::SaveParams::_capnpPrivate::dataWordSize; +template +constexpr uint16_t Persistent::SaveParams::_capnpPrivate::pointerCount; +#if !CAPNP_LITE +template +constexpr ::capnp::Kind Persistent::SaveParams::_capnpPrivate::kind; +template +constexpr ::capnp::_::RawSchema const* Persistent::SaveParams::_capnpPrivate::schema; +template +const ::capnp::_::RawBrandedSchema::Scope Persistent::SaveParams::_capnpPrivate::brandScopes[] = { + { 0xc8cb212fcd9f5691, brandBindings + 0, 2, false}, +}; +template +const ::capnp::_::RawBrandedSchema::Binding Persistent::SaveParams::_capnpPrivate::brandBindings[] = { + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), +}; +template +const ::capnp::_::RawBrandedSchema Persistent::SaveParams::_capnpPrivate::specificBrand = { + &::capnp::schemas::s_f76fba59183073a5, brandScopes, nullptr, + 1, 0, nullptr +}; +#endif // !CAPNP_LITE + +template +inline bool Persistent::SaveResults::Reader::hasSturdyRef() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +template +inline bool Persistent::SaveResults::Builder::hasSturdyRef() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +template +inline ::capnp::ReaderFor Persistent::SaveResults::Reader::getSturdyRef() const { + return ::capnp::_::PointerHelpers::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +template +inline ::capnp::BuilderFor Persistent::SaveResults::Builder::getSturdyRef() { + return ::capnp::_::PointerHelpers::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +template +inline ::capnp::PipelineFor Persistent::SaveResults::Pipeline::getSturdyRef() { + return ::capnp::PipelineFor(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +template +inline void Persistent::SaveResults::Builder::setSturdyRef( ::capnp::ReaderFor value) { + ::capnp::_::PointerHelpers::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +template +inline ::capnp::BuilderFor Persistent::SaveResults::Builder::initSturdyRef() { + return ::capnp::_::PointerHelpers::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +template +inline ::capnp::BuilderFor Persistent::SaveResults::Builder::initSturdyRef(unsigned int size) { + return ::capnp::_::PointerHelpers::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +template +inline void Persistent::SaveResults::Builder::adoptSturdyRef( + ::capnp::Orphan&& value) { + ::capnp::_::PointerHelpers::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +template +inline ::capnp::Orphan Persistent::SaveResults::Builder::disownSturdyRef() { + return ::capnp::_::PointerHelpers::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +// Persistent::SaveResults +template +constexpr uint16_t Persistent::SaveResults::_capnpPrivate::dataWordSize; +template +constexpr uint16_t Persistent::SaveResults::_capnpPrivate::pointerCount; +#if !CAPNP_LITE +template +constexpr ::capnp::Kind Persistent::SaveResults::_capnpPrivate::kind; +template +constexpr ::capnp::_::RawSchema const* Persistent::SaveResults::_capnpPrivate::schema; +template +const ::capnp::_::RawBrandedSchema::Scope Persistent::SaveResults::_capnpPrivate::brandScopes[] = { + { 0xc8cb212fcd9f5691, brandBindings + 0, 2, false}, +}; +template +const ::capnp::_::RawBrandedSchema::Binding Persistent::SaveResults::_capnpPrivate::brandBindings[] = { + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), +}; +template +const ::capnp::_::RawBrandedSchema Persistent::SaveResults::_capnpPrivate::specificBrand = { + &::capnp::schemas::s_b76848c18c40efbf, brandScopes, nullptr, + 1, 0, nullptr +}; +#endif // !CAPNP_LITE + +#if !CAPNP_LITE +template +CAPNP_AUTO_IF_MSVC(::capnp::Request::SaveParams, typename ::capnp::Persistent::SaveResults>) +Persistent::Client::saveRequest(::kj::Maybe< ::capnp::MessageSize> sizeHint) { + return newCall::SaveParams, typename ::capnp::Persistent::SaveResults>( + 0xc8cb212fcd9f5691ull, 0, sizeHint); +} +template +::kj::Promise Persistent::Server::save(SaveContext) { + return ::capnp::Capability::Server::internalUnimplemented( + "capnp/persistent.capnp:Persistent", "save", + 0xc8cb212fcd9f5691ull, 0); +} +template +::kj::Promise Persistent::Server::dispatchCall( + uint64_t interfaceId, uint16_t methodId, + ::capnp::CallContext< ::capnp::AnyPointer, ::capnp::AnyPointer> context) { + switch (interfaceId) { + case 0xc8cb212fcd9f5691ull: + return dispatchCallInternal(methodId, context); + default: + return internalUnimplemented("capnp/persistent.capnp:Persistent", interfaceId); + } +} +template +::kj::Promise Persistent::Server::dispatchCallInternal( + uint16_t methodId, + ::capnp::CallContext< ::capnp::AnyPointer, ::capnp::AnyPointer> context) { + switch (methodId) { + case 0: + return save(::capnp::Capability::Server::internalGetTypedContext< + typename ::capnp::Persistent::SaveParams, typename ::capnp::Persistent::SaveResults>(context)); + default: + (void)context; + return ::capnp::Capability::Server::internalUnimplemented( + "capnp/persistent.capnp:Persistent", + 0xc8cb212fcd9f5691ull, methodId); + } +} +#endif // !CAPNP_LITE + +// Persistent +#if !CAPNP_LITE +template +constexpr ::capnp::Kind Persistent::_capnpPrivate::kind; +template +constexpr ::capnp::_::RawSchema const* Persistent::_capnpPrivate::schema; +template +const ::capnp::_::RawBrandedSchema::Scope Persistent::_capnpPrivate::brandScopes[] = { + { 0xc8cb212fcd9f5691, brandBindings + 0, 2, false}, +}; +template +const ::capnp::_::RawBrandedSchema::Binding Persistent::_capnpPrivate::brandBindings[] = { + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), +}; +template +const ::capnp::_::RawBrandedSchema::Dependency Persistent::_capnpPrivate::brandDependencies[] = { + { 33554432, ::capnp::Persistent::SaveParams::_capnpPrivate::brand() }, + { 50331648, ::capnp::Persistent::SaveResults::_capnpPrivate::brand() }, +}; +template +const ::capnp::_::RawBrandedSchema Persistent::_capnpPrivate::specificBrand = { + &::capnp::schemas::s_c8cb212fcd9f5691, brandScopes, brandDependencies, + 1, 2, nullptr +}; +#endif // !CAPNP_LITE + +#if !CAPNP_LITE +template +inline RealmGateway::Client::Client(decltype(nullptr)) + : ::capnp::Capability::Client(nullptr) {} +template +inline RealmGateway::Client::Client( + ::kj::Own< ::capnp::ClientHook>&& hook) + : ::capnp::Capability::Client(::kj::mv(hook)) {} +template +template +inline RealmGateway::Client::Client(::kj::Own<_t>&& server) + : ::capnp::Capability::Client(::kj::mv(server)) {} +template +template +inline RealmGateway::Client::Client(::kj::Promise<_t>&& promise) + : ::capnp::Capability::Client(::kj::mv(promise)) {} +template +inline RealmGateway::Client::Client(::kj::Exception&& exception) + : ::capnp::Capability::Client(::kj::mv(exception)) {} +template +inline typename ::capnp::RealmGateway::Client& RealmGateway::Client::operator=(Client& other) { + ::capnp::Capability::Client::operator=(other); + return *this; +} +template +inline typename ::capnp::RealmGateway::Client& RealmGateway::Client::operator=(Client&& other) { + ::capnp::Capability::Client::operator=(kj::mv(other)); + return *this; +} + +#endif // !CAPNP_LITE +template +inline bool RealmGateway::ImportParams::Reader::hasCap() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +template +inline bool RealmGateway::ImportParams::Builder::hasCap() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +#if !CAPNP_LITE +template +inline typename ::capnp::Persistent::Client RealmGateway::ImportParams::Reader::getCap() const { + return ::capnp::_::PointerHelpers< ::capnp::Persistent>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +template +inline typename ::capnp::Persistent::Client RealmGateway::ImportParams::Builder::getCap() { + return ::capnp::_::PointerHelpers< ::capnp::Persistent>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +template +inline typename ::capnp::Persistent::Client RealmGateway::ImportParams::Pipeline::getCap() { + return typename ::capnp::Persistent::Client(_typeless.getPointerField(0).asCap()); +} +template +inline void RealmGateway::ImportParams::Builder::setCap(typename ::capnp::Persistent::Client&& cap) { + ::capnp::_::PointerHelpers< ::capnp::Persistent>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(cap)); +} +template +inline void RealmGateway::ImportParams::Builder::setCap(typename ::capnp::Persistent::Client& cap) { + ::capnp::_::PointerHelpers< ::capnp::Persistent>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), cap); +} +template +inline void RealmGateway::ImportParams::Builder::adoptCap( + ::capnp::Orphan< ::capnp::Persistent>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Persistent>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +template +inline ::capnp::Orphan< ::capnp::Persistent> RealmGateway::ImportParams::Builder::disownCap() { + return ::capnp::_::PointerHelpers< ::capnp::Persistent>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#endif // !CAPNP_LITE + +template +inline bool RealmGateway::ImportParams::Reader::hasParams() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +template +inline bool RealmGateway::ImportParams::Builder::hasParams() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +template +inline typename ::capnp::Persistent::SaveParams::Reader RealmGateway::ImportParams::Reader::getParams() const { + return ::capnp::_::PointerHelpers::SaveParams>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +template +inline typename ::capnp::Persistent::SaveParams::Builder RealmGateway::ImportParams::Builder::getParams() { + return ::capnp::_::PointerHelpers::SaveParams>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +template +inline typename ::capnp::Persistent::SaveParams::Pipeline RealmGateway::ImportParams::Pipeline::getParams() { + return typename ::capnp::Persistent::SaveParams::Pipeline(_typeless.getPointerField(1)); +} +#endif // !CAPNP_LITE +template +inline void RealmGateway::ImportParams::Builder::setParams(typename ::capnp::Persistent::SaveParams::Reader value) { + ::capnp::_::PointerHelpers::SaveParams>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +template +inline typename ::capnp::Persistent::SaveParams::Builder RealmGateway::ImportParams::Builder::initParams() { + return ::capnp::_::PointerHelpers::SaveParams>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +template +inline void RealmGateway::ImportParams::Builder::adoptParams( + ::capnp::Orphan::SaveParams>&& value) { + ::capnp::_::PointerHelpers::SaveParams>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +template +inline ::capnp::Orphan::SaveParams> RealmGateway::ImportParams::Builder::disownParams() { + return ::capnp::_::PointerHelpers::SaveParams>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +// RealmGateway::ImportParams +template +constexpr uint16_t RealmGateway::ImportParams::_capnpPrivate::dataWordSize; +template +constexpr uint16_t RealmGateway::ImportParams::_capnpPrivate::pointerCount; +#if !CAPNP_LITE +template +constexpr ::capnp::Kind RealmGateway::ImportParams::_capnpPrivate::kind; +template +constexpr ::capnp::_::RawSchema const* RealmGateway::ImportParams::_capnpPrivate::schema; +template +const ::capnp::_::RawBrandedSchema::Scope RealmGateway::ImportParams::_capnpPrivate::brandScopes[] = { + { 0x84ff286cd00a3ed4, brandBindings + 0, 4, false}, +}; +template +const ::capnp::_::RawBrandedSchema::Binding RealmGateway::ImportParams::_capnpPrivate::brandBindings[] = { + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), +}; +template +const ::capnp::_::RawBrandedSchema::Dependency RealmGateway::ImportParams::_capnpPrivate::brandDependencies[] = { + { 16777216, ::capnp::Persistent::_capnpPrivate::brand() }, + { 16777217, ::capnp::Persistent::SaveParams::_capnpPrivate::brand() }, +}; +template +const ::capnp::_::RawBrandedSchema RealmGateway::ImportParams::_capnpPrivate::specificBrand = { + &::capnp::schemas::s_f0c2cc1d3909574d, brandScopes, brandDependencies, + 1, 2, nullptr +}; +#endif // !CAPNP_LITE + +template +inline bool RealmGateway::ExportParams::Reader::hasCap() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +template +inline bool RealmGateway::ExportParams::Builder::hasCap() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +#if !CAPNP_LITE +template +inline typename ::capnp::Persistent::Client RealmGateway::ExportParams::Reader::getCap() const { + return ::capnp::_::PointerHelpers< ::capnp::Persistent>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +template +inline typename ::capnp::Persistent::Client RealmGateway::ExportParams::Builder::getCap() { + return ::capnp::_::PointerHelpers< ::capnp::Persistent>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +template +inline typename ::capnp::Persistent::Client RealmGateway::ExportParams::Pipeline::getCap() { + return typename ::capnp::Persistent::Client(_typeless.getPointerField(0).asCap()); +} +template +inline void RealmGateway::ExportParams::Builder::setCap(typename ::capnp::Persistent::Client&& cap) { + ::capnp::_::PointerHelpers< ::capnp::Persistent>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(cap)); +} +template +inline void RealmGateway::ExportParams::Builder::setCap(typename ::capnp::Persistent::Client& cap) { + ::capnp::_::PointerHelpers< ::capnp::Persistent>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), cap); +} +template +inline void RealmGateway::ExportParams::Builder::adoptCap( + ::capnp::Orphan< ::capnp::Persistent>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Persistent>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +template +inline ::capnp::Orphan< ::capnp::Persistent> RealmGateway::ExportParams::Builder::disownCap() { + return ::capnp::_::PointerHelpers< ::capnp::Persistent>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#endif // !CAPNP_LITE + +template +inline bool RealmGateway::ExportParams::Reader::hasParams() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +template +inline bool RealmGateway::ExportParams::Builder::hasParams() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +template +inline typename ::capnp::Persistent::SaveParams::Reader RealmGateway::ExportParams::Reader::getParams() const { + return ::capnp::_::PointerHelpers::SaveParams>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +template +inline typename ::capnp::Persistent::SaveParams::Builder RealmGateway::ExportParams::Builder::getParams() { + return ::capnp::_::PointerHelpers::SaveParams>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +template +inline typename ::capnp::Persistent::SaveParams::Pipeline RealmGateway::ExportParams::Pipeline::getParams() { + return typename ::capnp::Persistent::SaveParams::Pipeline(_typeless.getPointerField(1)); +} +#endif // !CAPNP_LITE +template +inline void RealmGateway::ExportParams::Builder::setParams(typename ::capnp::Persistent::SaveParams::Reader value) { + ::capnp::_::PointerHelpers::SaveParams>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +template +inline typename ::capnp::Persistent::SaveParams::Builder RealmGateway::ExportParams::Builder::initParams() { + return ::capnp::_::PointerHelpers::SaveParams>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +template +inline void RealmGateway::ExportParams::Builder::adoptParams( + ::capnp::Orphan::SaveParams>&& value) { + ::capnp::_::PointerHelpers::SaveParams>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +template +inline ::capnp::Orphan::SaveParams> RealmGateway::ExportParams::Builder::disownParams() { + return ::capnp::_::PointerHelpers::SaveParams>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +// RealmGateway::ExportParams +template +constexpr uint16_t RealmGateway::ExportParams::_capnpPrivate::dataWordSize; +template +constexpr uint16_t RealmGateway::ExportParams::_capnpPrivate::pointerCount; +#if !CAPNP_LITE +template +constexpr ::capnp::Kind RealmGateway::ExportParams::_capnpPrivate::kind; +template +constexpr ::capnp::_::RawSchema const* RealmGateway::ExportParams::_capnpPrivate::schema; +template +const ::capnp::_::RawBrandedSchema::Scope RealmGateway::ExportParams::_capnpPrivate::brandScopes[] = { + { 0x84ff286cd00a3ed4, brandBindings + 0, 4, false}, +}; +template +const ::capnp::_::RawBrandedSchema::Binding RealmGateway::ExportParams::_capnpPrivate::brandBindings[] = { + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), +}; +template +const ::capnp::_::RawBrandedSchema::Dependency RealmGateway::ExportParams::_capnpPrivate::brandDependencies[] = { + { 16777216, ::capnp::Persistent::_capnpPrivate::brand() }, + { 16777217, ::capnp::Persistent::SaveParams::_capnpPrivate::brand() }, +}; +template +const ::capnp::_::RawBrandedSchema RealmGateway::ExportParams::_capnpPrivate::specificBrand = { + &::capnp::schemas::s_ecafa18b482da3aa, brandScopes, brandDependencies, + 1, 2, nullptr +}; +#endif // !CAPNP_LITE + +#if !CAPNP_LITE +template +CAPNP_AUTO_IF_MSVC(::capnp::Request::ImportParams, typename ::capnp::Persistent::SaveResults>) +RealmGateway::Client::importRequest(::kj::Maybe< ::capnp::MessageSize> sizeHint) { + return newCall::ImportParams, typename ::capnp::Persistent::SaveResults>( + 0x84ff286cd00a3ed4ull, 0, sizeHint); +} +template +::kj::Promise RealmGateway::Server::import(ImportContext) { + return ::capnp::Capability::Server::internalUnimplemented( + "capnp/persistent.capnp:RealmGateway", "import", + 0x84ff286cd00a3ed4ull, 0); +} +template +CAPNP_AUTO_IF_MSVC(::capnp::Request::ExportParams, typename ::capnp::Persistent::SaveResults>) +RealmGateway::Client::exportRequest(::kj::Maybe< ::capnp::MessageSize> sizeHint) { + return newCall::ExportParams, typename ::capnp::Persistent::SaveResults>( + 0x84ff286cd00a3ed4ull, 1, sizeHint); +} +template +::kj::Promise RealmGateway::Server::export_(ExportContext) { + return ::capnp::Capability::Server::internalUnimplemented( + "capnp/persistent.capnp:RealmGateway", "export", + 0x84ff286cd00a3ed4ull, 1); +} +template +::kj::Promise RealmGateway::Server::dispatchCall( + uint64_t interfaceId, uint16_t methodId, + ::capnp::CallContext< ::capnp::AnyPointer, ::capnp::AnyPointer> context) { + switch (interfaceId) { + case 0x84ff286cd00a3ed4ull: + return dispatchCallInternal(methodId, context); + default: + return internalUnimplemented("capnp/persistent.capnp:RealmGateway", interfaceId); + } +} +template +::kj::Promise RealmGateway::Server::dispatchCallInternal( + uint16_t methodId, + ::capnp::CallContext< ::capnp::AnyPointer, ::capnp::AnyPointer> context) { + switch (methodId) { + case 0: + return import(::capnp::Capability::Server::internalGetTypedContext< + typename ::capnp::RealmGateway::ImportParams, typename ::capnp::Persistent::SaveResults>(context)); + case 1: + return export_(::capnp::Capability::Server::internalGetTypedContext< + typename ::capnp::RealmGateway::ExportParams, typename ::capnp::Persistent::SaveResults>(context)); + default: + (void)context; + return ::capnp::Capability::Server::internalUnimplemented( + "capnp/persistent.capnp:RealmGateway", + 0x84ff286cd00a3ed4ull, methodId); + } +} +#endif // !CAPNP_LITE + +// RealmGateway +#if !CAPNP_LITE +template +constexpr ::capnp::Kind RealmGateway::_capnpPrivate::kind; +template +constexpr ::capnp::_::RawSchema const* RealmGateway::_capnpPrivate::schema; +template +const ::capnp::_::RawBrandedSchema::Scope RealmGateway::_capnpPrivate::brandScopes[] = { + { 0x84ff286cd00a3ed4, brandBindings + 0, 4, false}, +}; +template +const ::capnp::_::RawBrandedSchema::Binding RealmGateway::_capnpPrivate::brandBindings[] = { + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), + ::capnp::_::brandBindingFor(), +}; +template +const ::capnp::_::RawBrandedSchema::Dependency RealmGateway::_capnpPrivate::brandDependencies[] = { + { 33554432, ::capnp::RealmGateway::ImportParams::_capnpPrivate::brand() }, + { 33554433, ::capnp::RealmGateway::ExportParams::_capnpPrivate::brand() }, + { 50331648, ::capnp::Persistent::SaveResults::_capnpPrivate::brand() }, + { 50331649, ::capnp::Persistent::SaveResults::_capnpPrivate::brand() }, +}; +template +const ::capnp::_::RawBrandedSchema RealmGateway::_capnpPrivate::specificBrand = { + &::capnp::schemas::s_84ff286cd00a3ed4, brandScopes, brandDependencies, + 1, 4, nullptr +}; +#endif // !CAPNP_LITE + +} // namespace + +#endif // CAPNP_INCLUDED_b8630836983feed7_ diff --git a/phonelibs/capnp-cpp/include/capnp/pointer-helpers.h b/phonelibs/capnp-cpp/include/capnp/pointer-helpers.h new file mode 100644 index 00000000000000..fe70e5036ff221 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/pointer-helpers.h @@ -0,0 +1,160 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_POINTER_HELPERS_H_ +#define CAPNP_POINTER_HELPERS_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "layout.h" +#include "list.h" + +namespace capnp { +namespace _ { // private + +// PointerHelpers is a template class that assists in wrapping/unwrapping the low-level types in +// layout.h with the high-level public API and generated types. This way, the code generator +// and other templates do not have to specialize on each kind of pointer. + +template +struct PointerHelpers { + static inline typename T::Reader get(PointerReader reader, const word* defaultValue = nullptr) { + return typename T::Reader(reader.getStruct(defaultValue)); + } + static inline typename T::Builder get(PointerBuilder builder, + const word* defaultValue = nullptr) { + return typename T::Builder(builder.getStruct(structSize(), defaultValue)); + } + static inline void set(PointerBuilder builder, typename T::Reader value) { + builder.setStruct(value._reader); + } + static inline void setCanonical(PointerBuilder builder, typename T::Reader value) { + builder.setStruct(value._reader, true); + } + static inline typename T::Builder init(PointerBuilder builder) { + return typename T::Builder(builder.initStruct(structSize())); + } + static inline void adopt(PointerBuilder builder, Orphan&& value) { + builder.adopt(kj::mv(value.builder)); + } + static inline Orphan disown(PointerBuilder builder) { + return Orphan(builder.disown()); + } + static inline _::StructReader getInternalReader(const typename T::Reader& reader) { + return reader._reader; + } + static inline _::StructBuilder getInternalBuilder(typename T::Builder&& builder) { + return builder._builder; + } +}; + +template +struct PointerHelpers, Kind::LIST> { + static inline typename List::Reader get(PointerReader reader, + const word* defaultValue = nullptr) { + return typename List::Reader(List::getFromPointer(reader, defaultValue)); + } + static inline typename List::Builder get(PointerBuilder builder, + const word* defaultValue = nullptr) { + return typename List::Builder(List::getFromPointer(builder, defaultValue)); + } + static inline void set(PointerBuilder builder, typename List::Reader value) { + builder.setList(value.reader); + } + static inline void setCanonical(PointerBuilder builder, typename List::Reader value) { + builder.setList(value.reader, true); + } + static void set(PointerBuilder builder, kj::ArrayPtr> value) { + auto l = init(builder, value.size()); + uint i = 0; + for (auto& element: value) { + l.set(i++, element); + } + } + static inline typename List::Builder init(PointerBuilder builder, uint size) { + return typename List::Builder(List::initPointer(builder, size)); + } + static inline void adopt(PointerBuilder builder, Orphan>&& value) { + builder.adopt(kj::mv(value.builder)); + } + static inline Orphan> disown(PointerBuilder builder) { + return Orphan>(builder.disown()); + } + static inline _::ListReader getInternalReader(const typename List::Reader& reader) { + return reader.reader; + } + static inline _::ListBuilder getInternalBuilder(typename List::Builder&& builder) { + return builder.builder; + } +}; + +template +struct PointerHelpers { + static inline typename T::Reader get(PointerReader reader, + const void* defaultValue = nullptr, + uint defaultBytes = 0) { + return reader.getBlob(defaultValue, bounded(defaultBytes) * BYTES); + } + static inline typename T::Builder get(PointerBuilder builder, + const void* defaultValue = nullptr, + uint defaultBytes = 0) { + return builder.getBlob(defaultValue, bounded(defaultBytes) * BYTES); + } + static inline void set(PointerBuilder builder, typename T::Reader value) { + builder.setBlob(value); + } + static inline void setCanonical(PointerBuilder builder, typename T::Reader value) { + builder.setBlob(value); + } + static inline typename T::Builder init(PointerBuilder builder, uint size) { + return builder.initBlob(bounded(size) * BYTES); + } + static inline void adopt(PointerBuilder builder, Orphan&& value) { + builder.adopt(kj::mv(value.builder)); + } + static inline Orphan disown(PointerBuilder builder) { + return Orphan(builder.disown()); + } +}; + +struct UncheckedMessage { + typedef const word* Reader; +}; + +template <> struct Kind_ { static constexpr Kind kind = Kind::OTHER; }; + +template <> +struct PointerHelpers { + // Reads an AnyPointer field as an unchecked message pointer. Requires that the containing + // message is itself unchecked. This hack is currently private. It is used to locate default + // values within encoded schemas. + + static inline const word* get(PointerReader reader) { + return reader.getUnchecked(); + } +}; + +} // namespace _ (private) +} // namespace capnp + +#endif // CAPNP_POINTER_HELPERS_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/pretty-print.h b/phonelibs/capnp-cpp/include/capnp/pretty-print.h new file mode 100644 index 00000000000000..e6458bca496b5e --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/pretty-print.h @@ -0,0 +1,47 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_PRETTY_PRINT_H_ +#define CAPNP_PRETTY_PRINT_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "dynamic.h" +#include + +namespace capnp { + +kj::StringTree prettyPrint(DynamicStruct::Reader value); +kj::StringTree prettyPrint(DynamicStruct::Builder value); +kj::StringTree prettyPrint(DynamicList::Reader value); +kj::StringTree prettyPrint(DynamicList::Builder value); +// Print the given Cap'n Proto struct or list with nice indentation. Note that you can pass any +// struct or list reader or builder type to this method, since they can be implicitly converted +// to one of the dynamic types. +// +// If you don't want indentation, just use the value's KJ stringifier (e.g. pass it to kj::str(), +// any of the KJ debug macros, etc.). + +} // namespace capnp + +#endif // PRETTY_PRINT_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/raw-schema.h b/phonelibs/capnp-cpp/include/capnp/raw-schema.h new file mode 100644 index 00000000000000..ed9425a6241b19 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/raw-schema.h @@ -0,0 +1,242 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_RAW_SCHEMA_H_ +#define CAPNP_RAW_SCHEMA_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "common.h" // for uint and friends + +#if _MSC_VER +#include +#endif + +namespace capnp { +namespace _ { // private + +struct RawSchema; + +struct RawBrandedSchema { + // Represents a combination of a schema and bindings for its generic parameters. + // + // Note that while we generate one `RawSchema` per type, we generate a `RawBrandedSchema` for + // every _instance_ of a generic type -- or, at least, every instance that is actually used. For + // generated-code types, we use template magic to initialize these. + + const RawSchema* generic; + // Generic type which we're branding. + + struct Binding { + uint8_t which; // Numeric value of one of schema::Type::Which. + + bool isImplicitParameter; + // For AnyPointer, true if it's an implicit method parameter. + + uint16_t listDepth; // Number of times to wrap the base type in List(). + + uint16_t paramIndex; + // For AnyPointer. If it's a type parameter (scopeId is non-zero) or it's an implicit parameter + // (isImplicitParameter is true), then this is the parameter index. Otherwise this is a numeric + // value of one of schema::Type::AnyPointer::Unconstrained::Which. + + union { + const RawBrandedSchema* schema; // for struct, enum, interface + uint64_t scopeId; // for AnyPointer, if it's a type parameter + }; + + Binding() = default; + inline constexpr Binding(uint8_t which, uint16_t listDepth, const RawBrandedSchema* schema) + : which(which), isImplicitParameter(false), listDepth(listDepth), paramIndex(0), + schema(schema) {} + inline constexpr Binding(uint8_t which, uint16_t listDepth, + uint64_t scopeId, uint16_t paramIndex) + : which(which), isImplicitParameter(false), listDepth(listDepth), paramIndex(paramIndex), + scopeId(scopeId) {} + inline constexpr Binding(uint8_t which, uint16_t listDepth, uint16_t implicitParamIndex) + : which(which), isImplicitParameter(true), listDepth(listDepth), + paramIndex(implicitParamIndex), scopeId(0) {} + }; + + struct Scope { + uint64_t typeId; + // Type ID whose parameters are being bound. + + const Binding* bindings; + uint bindingCount; + // Bindings for those parameters. + + bool isUnbound; + // This scope is unbound, in the sense of SchemaLoader::getUnbound(). + }; + + const Scope* scopes; + // Array of enclosing scopes for which generic variables have been bound, sorted by type ID. + + struct Dependency { + uint location; + const RawBrandedSchema* schema; + }; + + const Dependency* dependencies; + // Map of branded schemas for dependencies of this type, given our brand. Only dependencies that + // are branded are included in this map; if a dependency is missing, use its `defaultBrand`. + + uint32_t scopeCount; + uint32_t dependencyCount; + + enum class DepKind { + // Component of a Dependency::location. Specifies what sort of dependency this is. + + INVALID, + // Mostly defined to ensure that zero is not a valid location. + + FIELD, + // Binding needed for a field's type. The index is the field index (NOT ordinal!). + + METHOD_PARAMS, + // Bindings needed for a method's params type. The index is the method number. + + METHOD_RESULTS, + // Bindings needed for a method's results type. The index is the method ordinal. + + SUPERCLASS, + // Bindings needed for a superclass type. The index is the superclass's index in the + // "extends" list. + + CONST_TYPE + // Bindings needed for the type of a constant. The index is zero. + }; + + static inline uint makeDepLocation(DepKind kind, uint index) { + // Make a number representing the location of a particular dependency within its parent + // schema. + + return (static_cast(kind) << 24) | index; + } + + class Initializer { + public: + virtual void init(const RawBrandedSchema* generic) const = 0; + }; + + const Initializer* lazyInitializer; + // Lazy initializer, invoked by ensureInitialized(). + + inline void ensureInitialized() const { + // Lazy initialization support. Invoke to ensure that initialization has taken place. This + // is required in particular when traversing the dependency list. RawSchemas for compiled-in + // types are always initialized; only dynamically-loaded schemas may be lazy. + +#if __GNUC__ + const Initializer* i = __atomic_load_n(&lazyInitializer, __ATOMIC_ACQUIRE); +#elif _MSC_VER + const Initializer* i = *static_cast(&lazyInitializer); + std::atomic_thread_fence(std::memory_order_acquire); +#else +#error "Platform not supported" +#endif + if (i != nullptr) i->init(this); + } + + inline bool isUnbound() const; + // Checks if this schema is the result of calling SchemaLoader::getUnbound(), in which case + // binding lookups need to be handled specially. +}; + +struct RawSchema { + // The generated code defines a constant RawSchema for every compiled declaration. + // + // This is an internal structure which could change in the future. + + uint64_t id; + + const word* encodedNode; + // Encoded SchemaNode, readable via readMessageUnchecked(encodedNode). + + uint32_t encodedSize; + // Size of encodedNode, in words. + + const RawSchema* const* dependencies; + // Pointers to other types on which this one depends, sorted by ID. The schemas in this table + // may be uninitialized -- you must call ensureInitialized() on the one you wish to use before + // using it. + // + // TODO(someday): Make this a hashtable. + + const uint16_t* membersByName; + // Indexes of members sorted by name. Used to implement name lookup. + // TODO(someday): Make this a hashtable. + + uint32_t dependencyCount; + uint32_t memberCount; + // Sizes of above tables. + + const uint16_t* membersByDiscriminant; + // List of all member indexes ordered by discriminant value. Those which don't have a + // discriminant value are listed at the end, in order by ordinal. + + const RawSchema* canCastTo; + // Points to the RawSchema of a compiled-in type to which it is safe to cast any DynamicValue + // with this schema. This is null for all compiled-in types; it is only set by SchemaLoader on + // dynamically-loaded types. + + class Initializer { + public: + virtual void init(const RawSchema* schema) const = 0; + }; + + const Initializer* lazyInitializer; + // Lazy initializer, invoked by ensureInitialized(). + + inline void ensureInitialized() const { + // Lazy initialization support. Invoke to ensure that initialization has taken place. This + // is required in particular when traversing the dependency list. RawSchemas for compiled-in + // types are always initialized; only dynamically-loaded schemas may be lazy. + +#if __GNUC__ + const Initializer* i = __atomic_load_n(&lazyInitializer, __ATOMIC_ACQUIRE); +#elif _MSC_VER + const Initializer* i = *static_cast(&lazyInitializer); + std::atomic_thread_fence(std::memory_order_acquire); +#else +#error "Platform not supported" +#endif + if (i != nullptr) i->init(this); + } + + RawBrandedSchema defaultBrand; + // Specifies the brand to use for this schema if no generic parameters have been bound to + // anything. Generally, in the default brand, all generic parameters are treated as if they were + // bound to `AnyPointer`. +}; + +inline bool RawBrandedSchema::isUnbound() const { + // The unbound schema is the only one that has no scopes but is not the default schema. + return scopeCount == 0 && this != &generic->defaultBrand; +} + +} // namespace _ (private) +} // namespace capnp + +#endif // CAPNP_RAW_SCHEMA_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/rpc-prelude.h b/phonelibs/capnp-cpp/include/capnp/rpc-prelude.h new file mode 100644 index 00000000000000..7d26e39de8a68e --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/rpc-prelude.h @@ -0,0 +1,130 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file contains a bunch of internal declarations that must appear before rpc.h can start. +// We don't define these directly in rpc.h because it makes the file hard to read. + +#ifndef CAPNP_RPC_PRELUDE_H_ +#define CAPNP_RPC_PRELUDE_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "capability.h" +#include "persistent.capnp.h" + +namespace capnp { + +class OutgoingRpcMessage; +class IncomingRpcMessage; + +template +class RpcSystem; + +namespace _ { // private + +class VatNetworkBase { + // Non-template version of VatNetwork. Ignore this class; see VatNetwork in rpc.h. + +public: + class Connection; + + struct ConnectionAndProvisionId { + kj::Own connection; + kj::Own firstMessage; + Orphan provisionId; + }; + + class Connection { + public: + virtual kj::Own newOutgoingMessage(uint firstSegmentWordSize) = 0; + virtual kj::Promise>> receiveIncomingMessage() = 0; + virtual kj::Promise shutdown() = 0; + virtual AnyStruct::Reader baseGetPeerVatId() = 0; + }; + virtual kj::Maybe> baseConnect(AnyStruct::Reader vatId) = 0; + virtual kj::Promise> baseAccept() = 0; +}; + +class SturdyRefRestorerBase { +public: + virtual Capability::Client baseRestore(AnyPointer::Reader ref) = 0; +}; + +class BootstrapFactoryBase { + // Non-template version of BootstrapFactory. Ignore this class; see BootstrapFactory in rpc.h. +public: + virtual Capability::Client baseCreateFor(AnyStruct::Reader clientId) = 0; +}; + +class RpcSystemBase { + // Non-template version of RpcSystem. Ignore this class; see RpcSystem in rpc.h. + +public: + RpcSystemBase(VatNetworkBase& network, kj::Maybe bootstrapInterface, + kj::Maybe::Client> gateway); + RpcSystemBase(VatNetworkBase& network, BootstrapFactoryBase& bootstrapFactory, + kj::Maybe::Client> gateway); + RpcSystemBase(VatNetworkBase& network, SturdyRefRestorerBase& restorer); + RpcSystemBase(RpcSystemBase&& other) noexcept; + ~RpcSystemBase() noexcept(false); + +private: + class Impl; + kj::Own impl; + + Capability::Client baseBootstrap(AnyStruct::Reader vatId); + Capability::Client baseRestore(AnyStruct::Reader vatId, AnyPointer::Reader objectId); + void baseSetFlowLimit(size_t words); + + template + friend class capnp::RpcSystem; +}; + +template struct InternalRefFromRealmGateway_; +template +struct InternalRefFromRealmGateway_> { + typedef InternalRef Type; +}; +template +using InternalRefFromRealmGateway = typename InternalRefFromRealmGateway_::Type; +template +using InternalRefFromRealmGatewayClient = InternalRefFromRealmGateway; + +template struct ExternalRefFromRealmGateway_; +template +struct ExternalRefFromRealmGateway_> { + typedef ExternalRef Type; +}; +template +using ExternalRefFromRealmGateway = typename ExternalRefFromRealmGateway_::Type; +template +using ExternalRefFromRealmGatewayClient = ExternalRefFromRealmGateway; + +} // namespace _ (private) +} // namespace capnp + +#endif // CAPNP_RPC_PRELUDE_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/rpc-twoparty.capnp b/phonelibs/capnp-cpp/include/capnp/rpc-twoparty.capnp new file mode 100644 index 00000000000000..0b670e8ac3fc24 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/rpc-twoparty.capnp @@ -0,0 +1,169 @@ +# Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +# Licensed under the MIT License: +# +# Permission is hereby granted, free of charge, to any person obtaining a copy +# of this software and associated documentation files (the "Software"), to deal +# in the Software without restriction, including without limitation the rights +# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +# copies of the Software, and to permit persons to whom the Software is +# furnished to do so, subject to the following conditions: +# +# The above copyright notice and this permission notice shall be included in +# all copies or substantial portions of the Software. +# +# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +# THE SOFTWARE. + +@0xa184c7885cdaf2a1; +# This file defines the "network-specific parameters" in rpc.capnp to support a network consisting +# of two vats. Each of these vats may in fact be in communication with other vats, but any +# capabilities they forward must be proxied. Thus, to each end of the connection, all capabilities +# received from the other end appear to live in a single vat. +# +# Two notable use cases for this model include: +# - Regular client-server communications, where a remote client machine (perhaps living on an end +# user's personal device) connects to a server. The server may be part of a cluster, and may +# call on other servers in the cluster to help service the user's request. It may even obtain +# capabilities from these other servers which it passes on to the user. To simplify network +# common traversal problems (e.g. if the user is behind a firewall), it is probably desirable to +# multiplex all communications between the server cluster and the client over the original +# connection rather than form new ones. This connection should use the two-party protocol, as +# the client has no interest in knowing about additional servers. +# - Applications running in a sandbox. A supervisor process may execute a confined application +# such that all of the confined app's communications with the outside world must pass through +# the supervisor. In this case, the connection between the confined app and the supervisor might +# as well use the two-party protocol, because the confined app is intentionally prevented from +# talking to any other vat anyway. Any external resources will be proxied through the supervisor, +# and so to the contained app will appear as if they were hosted by the supervisor itself. +# +# Since there are only two vats in this network, there is never a need for three-way introductions, +# so level 3 is free. Moreover, because it is never necessary to form new connections, the +# two-party protocol can be used easily anywhere where a two-way byte stream exists, without regard +# to where that byte stream goes or how it was initiated. This makes the two-party runtime library +# highly reusable. +# +# Joins (level 4) _could_ be needed in cases where one or both vats are participating in other +# networks that use joins. For instance, if Alice and Bob are speaking through the two-party +# protocol, and Bob is also participating on another network, Bob may send Alice two or more +# proxied capabilities which, unbeknownst to Bob at the time, are in fact pointing at the same +# remote object. Alice may then request to join these capabilities, at which point Bob will have +# to forward the join to the other network. Note, however, that if Alice is _not_ participating on +# any other network, then Alice will never need to _receive_ a Join, because Alice would always +# know when two locally-hosted capabilities are the same and would never export a redundant alias +# to Bob. So, Alice can respond to all incoming joins with an error, and only needs to implement +# outgoing joins if she herself desires to use this feature. Also, outgoing joins are relatively +# easy to implement in this scenario. +# +# What all this means is that a level 4 implementation of the confined network is barely more +# complicated than a level 2 implementation. However, such an implementation allows the "client" +# or "confined" app to access the server's/supervisor's network with equal functionality to any +# native participant. In other words, an application which implements only the two-party protocol +# can be paired with a proxy app in order to participate in any network. +# +# So, when implementing Cap'n Proto in a new language, it makes sense to implement only the +# two-party protocol initially, and then pair applications with an appropriate proxy written in +# C++, rather than implement other parameterizations of the RPC protocol directly. + +using Cxx = import "/capnp/c++.capnp"; +$Cxx.namespace("capnp::rpc::twoparty"); + +# Note: SturdyRef is not specified here. It is up to the application to define semantics of +# SturdyRefs if desired. + +enum Side { + server @0; + # The object lives on the "server" or "supervisor" end of the connection. Only the + # server/supervisor knows how to interpret the ref; to the client, it is opaque. + # + # Note that containers intending to implement strong confinement should rewrite SturdyRefs + # received from the external network before passing them on to the confined app. The confined + # app thus does not ever receive the raw bits of the SturdyRef (which it could perhaps + # maliciously leak), but instead receives only a thing that it can pass back to the container + # later to restore the ref. See: + # http://www.erights.org/elib/capability/dist-confine.html + + client @1; + # The object lives on the "client" or "confined app" end of the connection. Only the client + # knows how to interpret the ref; to the server/supervisor, it is opaque. Most clients do not + # actually know how to persist capabilities at all, so use of this is unusual. +} + +struct VatId { + side @0 :Side; +} + +struct ProvisionId { + # Only used for joins, since three-way introductions never happen on a two-party network. + + joinId @0 :UInt32; + # The ID from `JoinKeyPart`. +} + +struct RecipientId {} +# Never used, because there are only two parties. + +struct ThirdPartyCapId {} +# Never used, because there is no third party. + +struct JoinKeyPart { + # Joins in the two-party case are simplified by a few observations. + # + # First, on a two-party network, a Join only ever makes sense if the receiving end is also + # connected to other networks. A vat which is not connected to any other network can safely + # reject all joins. + # + # Second, since a two-party connection bisects the network -- there can be no other connections + # between the networks at either end of the connection -- if one part of a join crosses the + # connection, then _all_ parts must cross it. Therefore, a vat which is receiving a Join request + # off some other network which needs to be forwarded across the two-party connection can + # collect all the parts on its end and only forward them across the two-party connection when all + # have been received. + # + # For example, imagine that Alice and Bob are vats connected over a two-party connection, and + # each is also connected to other networks. At some point, Alice receives one part of a Join + # request off her network. The request is addressed to a capability that Alice received from + # Bob and is proxying to her other network. Alice goes ahead and responds to the Join part as + # if she hosted the capability locally (this is important so that if not all the Join parts end + # up at Alice, the original sender can detect the failed Join without hanging). As other parts + # trickle in, Alice verifies that each part is addressed to a capability from Bob and continues + # to respond to each one. Once the complete set of join parts is received, Alice checks if they + # were all for the exact same capability. If so, she doesn't need to send anything to Bob at + # all. Otherwise, she collects the set of capabilities (from Bob) to which the join parts were + # addressed and essentially initiates a _new_ Join request on those capabilities to Bob. Alice + # does not forward the Join parts she received herself, but essentially forwards the Join as a + # whole. + # + # On Bob's end, since he knows that Alice will always send all parts of a Join together, he + # simply waits until he's received them all, then performs a join on the respective capabilities + # as if it had been requested locally. + + joinId @0 :UInt32; + # A number identifying this join, chosen by the sender. May be reused once `Finish` messages are + # sent corresponding to all of the `Join` messages. + + partCount @1 :UInt16; + # The number of capabilities to be joined. + + partNum @2 :UInt16; + # Which part this request targets -- a number in the range [0, partCount). +} + +struct JoinResult { + joinId @0 :UInt32; + # Matches `JoinKeyPart`. + + succeeded @1 :Bool; + # All JoinResults in the set will have the same value for `succeeded`. The receiver actually + # implements the join by waiting for all the `JoinKeyParts` and then performing its own join on + # them, then going back and answering all the join requests afterwards. + + cap @2 :AnyPointer; + # One of the JoinResults will have a non-null `cap` which is the joined capability. + # + # TODO(cleanup): Change `AnyPointer` to `Capability` when that is supported. +} diff --git a/phonelibs/capnp-cpp/include/capnp/rpc-twoparty.capnp.h b/phonelibs/capnp-cpp/include/capnp/rpc-twoparty.capnp.h new file mode 100644 index 00000000000000..9d7820646a75ec --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/rpc-twoparty.capnp.h @@ -0,0 +1,726 @@ +// Generated by Cap'n Proto compiler, DO NOT EDIT +// source: rpc-twoparty.capnp + +#ifndef CAPNP_INCLUDED_a184c7885cdaf2a1_ +#define CAPNP_INCLUDED_a184c7885cdaf2a1_ + +#include + +#if CAPNP_VERSION != 6001 +#error "Version mismatch between generated code and library headers. You must use the same version of the Cap'n Proto compiler and library." +#endif + + +namespace capnp { +namespace schemas { + +CAPNP_DECLARE_SCHEMA(9fd69ebc87b9719c); +enum class Side_9fd69ebc87b9719c: uint16_t { + SERVER, + CLIENT, +}; +CAPNP_DECLARE_ENUM(Side, 9fd69ebc87b9719c); +CAPNP_DECLARE_SCHEMA(d20b909fee733a8e); +CAPNP_DECLARE_SCHEMA(b88d09a9c5f39817); +CAPNP_DECLARE_SCHEMA(89f389b6fd4082c1); +CAPNP_DECLARE_SCHEMA(b47f4979672cb59d); +CAPNP_DECLARE_SCHEMA(95b29059097fca83); +CAPNP_DECLARE_SCHEMA(9d263a3630b7ebee); + +} // namespace schemas +} // namespace capnp + +namespace capnp { +namespace rpc { +namespace twoparty { + +typedef ::capnp::schemas::Side_9fd69ebc87b9719c Side; + +struct VatId { + VatId() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(d20b909fee733a8e, 1, 0) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct ProvisionId { + ProvisionId() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(b88d09a9c5f39817, 1, 0) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct RecipientId { + RecipientId() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(89f389b6fd4082c1, 0, 0) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct ThirdPartyCapId { + ThirdPartyCapId() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(b47f4979672cb59d, 0, 0) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct JoinKeyPart { + JoinKeyPart() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(95b29059097fca83, 1, 0) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct JoinResult { + JoinResult() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9d263a3630b7ebee, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +// ======================================================================================= + +class VatId::Reader { +public: + typedef VatId Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::capnp::rpc::twoparty::Side getSide() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class VatId::Builder { +public: + typedef VatId Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::capnp::rpc::twoparty::Side getSide(); + inline void setSide( ::capnp::rpc::twoparty::Side value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class VatId::Pipeline { +public: + typedef VatId Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class ProvisionId::Reader { +public: + typedef ProvisionId Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getJoinId() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class ProvisionId::Builder { +public: + typedef ProvisionId Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getJoinId(); + inline void setJoinId( ::uint32_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class ProvisionId::Pipeline { +public: + typedef ProvisionId Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class RecipientId::Reader { +public: + typedef RecipientId Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class RecipientId::Builder { +public: + typedef RecipientId Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class RecipientId::Pipeline { +public: + typedef RecipientId Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class ThirdPartyCapId::Reader { +public: + typedef ThirdPartyCapId Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class ThirdPartyCapId::Builder { +public: + typedef ThirdPartyCapId Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class ThirdPartyCapId::Pipeline { +public: + typedef ThirdPartyCapId Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class JoinKeyPart::Reader { +public: + typedef JoinKeyPart Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getJoinId() const; + + inline ::uint16_t getPartCount() const; + + inline ::uint16_t getPartNum() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class JoinKeyPart::Builder { +public: + typedef JoinKeyPart Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getJoinId(); + inline void setJoinId( ::uint32_t value); + + inline ::uint16_t getPartCount(); + inline void setPartCount( ::uint16_t value); + + inline ::uint16_t getPartNum(); + inline void setPartNum( ::uint16_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class JoinKeyPart::Pipeline { +public: + typedef JoinKeyPart Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class JoinResult::Reader { +public: + typedef JoinResult Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getJoinId() const; + + inline bool getSucceeded() const; + + inline bool hasCap() const; + inline ::capnp::AnyPointer::Reader getCap() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class JoinResult::Builder { +public: + typedef JoinResult Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getJoinId(); + inline void setJoinId( ::uint32_t value); + + inline bool getSucceeded(); + inline void setSucceeded(bool value); + + inline bool hasCap(); + inline ::capnp::AnyPointer::Builder getCap(); + inline ::capnp::AnyPointer::Builder initCap(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class JoinResult::Pipeline { +public: + typedef JoinResult Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +// ======================================================================================= + +inline ::capnp::rpc::twoparty::Side VatId::Reader::getSide() const { + return _reader.getDataField< ::capnp::rpc::twoparty::Side>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::rpc::twoparty::Side VatId::Builder::getSide() { + return _builder.getDataField< ::capnp::rpc::twoparty::Side>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void VatId::Builder::setSide( ::capnp::rpc::twoparty::Side value) { + _builder.setDataField< ::capnp::rpc::twoparty::Side>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint32_t ProvisionId::Reader::getJoinId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t ProvisionId::Builder::getJoinId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void ProvisionId::Builder::setJoinId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint32_t JoinKeyPart::Reader::getJoinId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t JoinKeyPart::Builder::getJoinId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void JoinKeyPart::Builder::setJoinId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint16_t JoinKeyPart::Reader::getPartCount() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t JoinKeyPart::Builder::getPartCount() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void JoinKeyPart::Builder::setPartCount( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline ::uint16_t JoinKeyPart::Reader::getPartNum() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<3>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t JoinKeyPart::Builder::getPartNum() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<3>() * ::capnp::ELEMENTS); +} +inline void JoinKeyPart::Builder::setPartNum( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, value); +} + +inline ::uint32_t JoinResult::Reader::getJoinId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t JoinResult::Builder::getJoinId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void JoinResult::Builder::setJoinId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool JoinResult::Reader::getSucceeded() const { + return _reader.getDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS); +} + +inline bool JoinResult::Builder::getSucceeded() { + return _builder.getDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS); +} +inline void JoinResult::Builder::setSucceeded(bool value) { + _builder.setDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS, value); +} + +inline bool JoinResult::Reader::hasCap() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool JoinResult::Builder::hasCap() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader JoinResult::Reader::getCap() const { + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder JoinResult::Builder::getCap() { + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder JoinResult::Builder::initCap() { + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +} // namespace +} // namespace +} // namespace + +#endif // CAPNP_INCLUDED_a184c7885cdaf2a1_ diff --git a/phonelibs/capnp-cpp/include/capnp/rpc-twoparty.h b/phonelibs/capnp-cpp/include/capnp/rpc-twoparty.h new file mode 100644 index 00000000000000..093c1fecdf9f35 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/rpc-twoparty.h @@ -0,0 +1,160 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_RPC_TWOPARTY_H_ +#define CAPNP_RPC_TWOPARTY_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "rpc.h" +#include "message.h" +#include +#include + +namespace capnp { + +namespace rpc { + namespace twoparty { + typedef VatId SturdyRefHostId; // For backwards-compatibility with version 0.4. + } +} + +typedef VatNetwork + TwoPartyVatNetworkBase; + +class TwoPartyVatNetwork: public TwoPartyVatNetworkBase, + private TwoPartyVatNetworkBase::Connection { + // A `VatNetwork` that consists of exactly two parties communicating over an arbitrary byte + // stream. This is used to implement the common case of a client/server network. + // + // See `ez-rpc.h` for a simple interface for setting up two-party clients and servers. + // Use `TwoPartyVatNetwork` only if you need the advanced features. + +public: + TwoPartyVatNetwork(kj::AsyncIoStream& stream, rpc::twoparty::Side side, + ReaderOptions receiveOptions = ReaderOptions()); + KJ_DISALLOW_COPY(TwoPartyVatNetwork); + + kj::Promise onDisconnect() { return disconnectPromise.addBranch(); } + // Returns a promise that resolves when the peer disconnects. + + rpc::twoparty::Side getSide() { return side; } + + // implements VatNetwork ----------------------------------------------------- + + kj::Maybe> connect( + rpc::twoparty::VatId::Reader ref) override; + kj::Promise> accept() override; + +private: + class OutgoingMessageImpl; + class IncomingMessageImpl; + + kj::AsyncIoStream& stream; + rpc::twoparty::Side side; + MallocMessageBuilder peerVatId; + ReaderOptions receiveOptions; + bool accepted = false; + + kj::Maybe> previousWrite; + // Resolves when the previous write completes. This effectively serves as the write queue. + // Becomes null when shutdown() is called. + + kj::Own>> acceptFulfiller; + // Fulfiller for the promise returned by acceptConnectionAsRefHost() on the client side, or the + // second call on the server side. Never fulfilled, because there is only one connection. + + kj::ForkedPromise disconnectPromise = nullptr; + + class FulfillerDisposer: public kj::Disposer { + // Hack: TwoPartyVatNetwork is both a VatNetwork and a VatNetwork::Connection. When the RPC + // system detects (or initiates) a disconnection, it drops its reference to the Connection. + // When all references have been dropped, then we want disconnectPromise to be fulfilled. + // So we hand out Owns with this disposer attached, so that we can detect when + // they are dropped. + + public: + mutable kj::Own> fulfiller; + mutable uint refcount = 0; + + void disposeImpl(void* pointer) const override; + }; + FulfillerDisposer disconnectFulfiller; + + kj::Own asConnection(); + // Returns a pointer to this with the disposer set to disconnectFulfiller. + + // implements Connection ----------------------------------------------------- + + rpc::twoparty::VatId::Reader getPeerVatId() override; + kj::Own newOutgoingMessage(uint firstSegmentWordSize) override; + kj::Promise>> receiveIncomingMessage() override; + kj::Promise shutdown() override; +}; + +class TwoPartyServer: private kj::TaskSet::ErrorHandler { + // Convenience class which implements a simple server which accepts connections on a listener + // socket and serices them as two-party connections. + +public: + explicit TwoPartyServer(Capability::Client bootstrapInterface); + + void accept(kj::Own&& connection); + // Accepts the connection for servicing. + + kj::Promise listen(kj::ConnectionReceiver& listener); + // Listens for connections on the given listener. The returned promise never resolves unless an + // exception is thrown while trying to accept. You may discard the returned promise to cancel + // listening. + +private: + Capability::Client bootstrapInterface; + kj::TaskSet tasks; + + struct AcceptedConnection; + + void taskFailed(kj::Exception&& exception) override; +}; + +class TwoPartyClient { + // Convenience class which implements a simple client. + +public: + explicit TwoPartyClient(kj::AsyncIoStream& connection); + TwoPartyClient(kj::AsyncIoStream& connection, Capability::Client bootstrapInterface, + rpc::twoparty::Side side = rpc::twoparty::Side::CLIENT); + + Capability::Client bootstrap(); + // Get the server's bootstrap interface. + + inline kj::Promise onDisconnect() { return network.onDisconnect(); } + +private: + TwoPartyVatNetwork network; + RpcSystem rpcSystem; +}; + +} // namespace capnp + +#endif // CAPNP_RPC_TWOPARTY_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/rpc.capnp b/phonelibs/capnp-cpp/include/capnp/rpc.capnp new file mode 100644 index 00000000000000..cd808b39f70466 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/rpc.capnp @@ -0,0 +1,1399 @@ +# Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +# Licensed under the MIT License: +# +# Permission is hereby granted, free of charge, to any person obtaining a copy +# of this software and associated documentation files (the "Software"), to deal +# in the Software without restriction, including without limitation the rights +# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +# copies of the Software, and to permit persons to whom the Software is +# furnished to do so, subject to the following conditions: +# +# The above copyright notice and this permission notice shall be included in +# all copies or substantial portions of the Software. +# +# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +# THE SOFTWARE. + +@0xb312981b2552a250; +# Recall that Cap'n Proto RPC allows messages to contain references to remote objects that +# implement interfaces. These references are called "capabilities", because they both designate +# the remote object to use and confer permission to use it. +# +# Recall also that Cap'n Proto RPC has the feature that when a method call itself returns a +# capability, the caller can begin calling methods on that capability _before the first call has +# returned_. The caller essentially sends a message saying "Hey server, as soon as you finish +# that previous call, do this with the result!". Cap'n Proto's RPC protocol makes this possible. +# +# The protocol is significantly more complicated than most RPC protocols. However, this is +# implementation complexity that underlies an easy-to-grasp higher-level model of object oriented +# programming. That is, just like TCP is a surprisingly complicated protocol that implements a +# conceptually-simple byte stream abstraction, Cap'n Proto is a surprisingly complicated protocol +# that implements a conceptually-simple object abstraction. +# +# Cap'n Proto RPC is based heavily on CapTP, the object-capability protocol used by the E +# programming language: +# http://www.erights.org/elib/distrib/captp/index.html +# +# Cap'n Proto RPC takes place between "vats". A vat hosts some set of objects and talks to other +# vats through direct bilateral connections. Typically, there is a 1:1 correspondence between vats +# and processes (in the unix sense of the word), although this is not strictly always true (one +# process could run multiple vats, or a distributed virtual vat might live across many processes). +# +# Cap'n Proto does not distinguish between "clients" and "servers" -- this is up to the application. +# Either end of any connection can potentially hold capabilities pointing to the other end, and +# can call methods on those capabilities. In the doc comments below, we use the words "sender" +# and "receiver". These refer to the sender and receiver of an instance of the struct or field +# being documented. Sometimes we refer to a "third-party" that is neither the sender nor the +# receiver. Documentation is generally written from the point of view of the sender. +# +# It is generally up to the vat network implementation to securely verify that connections are made +# to the intended vat as well as to encrypt transmitted data for privacy and integrity. See the +# `VatNetwork` example interface near the end of this file. +# +# When a new connection is formed, the only interesting things that can be done are to send a +# `Bootstrap` (level 0) or `Accept` (level 3) message. +# +# Unless otherwise specified, messages must be delivered to the receiving application in the same +# order in which they were initiated by the sending application. The goal is to support "E-Order", +# which states that two calls made on the same reference must be delivered in the order which they +# were made: +# http://erights.org/elib/concurrency/partial-order.html +# +# Since the full protocol is complicated, we define multiple levels of support that an +# implementation may target. For many applications, level 1 support will be sufficient. +# Comments in this file indicate which level requires the corresponding feature to be +# implemented. +# +# * **Level 0:** The implementation does not support object references. Only the bootstrap interface +# can be called. At this level, the implementation does not support object-oriented protocols and +# is similar in complexity to JSON-RPC or Protobuf services. This level should be considered only +# a temporary stepping-stone toward level 1 as the lack of object references drastically changes +# how protocols are designed. Applications _should not_ attempt to design their protocols around +# the limitations of level 0 implementations. +# +# * **Level 1:** The implementation supports simple bilateral interaction with object references +# and promise pipelining, but interactions between three or more parties are supported only via +# proxying of objects. E.g. if Alice (in Vat A) wants to send Bob (in Vat B) a capability +# pointing to Carol (in Vat C), Alice must create a proxy of Carol within Vat A and send Bob a +# reference to that; Bob cannot form a direct connection to Carol. Level 1 implementations do +# not support checking if two capabilities received from different vats actually point to the +# same object ("join"), although they should be able to do this check on capabilities received +# from the same vat. +# +# * **Level 2:** The implementation supports saving persistent capabilities -- i.e. capabilities +# that remain valid even after disconnect, and can be restored on a future connection. When a +# capability is saved, the requester receives a `SturdyRef`, which is a token that can be used +# to restore the capability later. +# +# * **Level 3:** The implementation supports three-way interactions. That is, if Alice (in Vat A) +# sends Bob (in Vat B) a capability pointing to Carol (in Vat C), then Vat B will automatically +# form a direct connection to Vat C rather than have requests be proxied through Vat A. +# +# * **Level 4:** The entire protocol is implemented, including joins (checking if two capabilities +# are equivalent). +# +# Note that an implementation must also support specific networks (transports), as described in +# the "Network-specific Parameters" section below. An implementation might have different levels +# depending on the network used. +# +# New implementations of Cap'n Proto should start out targeting the simplistic two-party network +# type as defined in `rpc-twoparty.capnp`. With this network type, level 3 is irrelevant and +# levels 2 and 4 are much easier than usual to implement. When such an implementation is paired +# with a container proxy, the contained app effectively gets to make full use of the proxy's +# network at level 4. And since Cap'n Proto IPC is extremely fast, it may never make sense to +# bother implementing any other vat network protocol -- just use the correct container type and get +# it for free. + +using Cxx = import "/capnp/c++.capnp"; +$Cxx.namespace("capnp::rpc"); + +# ======================================================================================== +# The Four Tables +# +# Cap'n Proto RPC connections are stateful (although an application built on Cap'n Proto could +# export a stateless interface). As in CapTP, for each open connection, a vat maintains four state +# tables: questions, answers, imports, and exports. See the diagram at: +# http://www.erights.org/elib/distrib/captp/4tables.html +# +# The question table corresponds to the other end's answer table, and the imports table corresponds +# to the other end's exports table. +# +# The entries in each table are identified by ID numbers (defined below as 32-bit integers). These +# numbers are always specific to the connection; a newly-established connection starts with no +# valid IDs. Since low-numbered IDs will pack better, it is suggested that IDs be assigned like +# Unix file descriptors -- prefer the lowest-number ID that is currently available. +# +# IDs in the questions/answers tables are chosen by the questioner and generally represent method +# calls that are in progress. +# +# IDs in the imports/exports tables are chosen by the exporter and generally represent objects on +# which methods may be called. Exports may be "settled", meaning the exported object is an actual +# object living in the exporter's vat, or they may be "promises", meaning the exported object is +# the as-yet-unknown result of an ongoing operation and will eventually be resolved to some other +# object once that operation completes. Calls made to a promise will be forwarded to the eventual +# target once it is known. The eventual replacement object does *not* get the same ID as the +# promise, as it may turn out to be an object that is already exported (so already has an ID) or +# may even live in a completely different vat (and so won't get an ID on the same export table +# at all). +# +# IDs can be reused over time. To make this safe, we carefully define the lifetime of IDs. Since +# messages using the ID could be traveling in both directions simultaneously, we must define the +# end of life of each ID _in each direction_. The ID is only safe to reuse once it has been +# released by both sides. +# +# When a Cap'n Proto connection is lost, everything on the four tables is lost. All questions are +# canceled and throw exceptions. All imports become broken (all future calls to them throw +# exceptions). All exports and answers are implicitly released. The only things not lost are +# persistent capabilities (`SturdyRef`s). The application must plan for this and should respond by +# establishing a new connection and restoring from these persistent capabilities. + +using QuestionId = UInt32; +# **(level 0)** +# +# Identifies a question in the sender's question table (which corresponds to the receiver's answer +# table). The questioner (caller) chooses an ID when making a call. The ID remains valid in +# caller -> callee messages until a Finish message is sent, and remains valid in callee -> caller +# messages until a Return message is sent. + +using AnswerId = QuestionId; +# **(level 0)** +# +# Identifies an answer in the sender's answer table (which corresponds to the receiver's question +# table). +# +# AnswerId is physically equivalent to QuestionId, since the question and answer tables correspond, +# but we define a separate type for documentation purposes: we always use the type representing +# the sender's point of view. + +using ExportId = UInt32; +# **(level 1)** +# +# Identifies an exported capability or promise in the sender's export table (which corresponds +# to the receiver's import table). The exporter chooses an ID before sending a capability over the +# wire. If the capability is already in the table, the exporter should reuse the same ID. If the +# ID is a promise (as opposed to a settled capability), this must be indicated at the time the ID +# is introduced (e.g. by using `senderPromise` instead of `senderHosted` in `CapDescriptor`); in +# this case, the importer shall expect a later `Resolve` message that replaces the promise. +# +# ExportId/ImportIds are subject to reference counting. Whenever an `ExportId` is sent over the +# wire (from the exporter to the importer), the export's reference count is incremented (unless +# otherwise specified). The reference count is later decremented by a `Release` message. Since +# the `Release` message can specify an arbitrary number by which to reduce the reference count, the +# importer should usually batch reference decrements and only send a `Release` when it believes the +# reference count has hit zero. Of course, it is possible that a new reference to the export is +# in-flight at the time that the `Release` message is sent, so it is necessary for the exporter to +# keep track of the reference count on its end as well to avoid race conditions. +# +# When a connection is lost, all exports are implicitly released. It is not possible to restore +# a connection state after disconnect (although a transport layer could implement a concept of +# persistent connections if it is transparent to the RPC layer). + +using ImportId = ExportId; +# **(level 1)** +# +# Identifies an imported capability or promise in the sender's import table (which corresponds to +# the receiver's export table). +# +# ImportId is physically equivalent to ExportId, since the export and import tables correspond, +# but we define a separate type for documentation purposes: we always use the type representing +# the sender's point of view. +# +# An `ImportId` remains valid in importer -> exporter messages until the importer has sent +# `Release` messages that (it believes) have reduced the reference count to zero. + +# ======================================================================================== +# Messages + +struct Message { + # An RPC connection is a bi-directional stream of Messages. + + union { + unimplemented @0 :Message; + # The sender previously received this message from the peer but didn't understand it or doesn't + # yet implement the functionality that was requested. So, the sender is echoing the message + # back. In some cases, the receiver may be able to recover from this by pretending the sender + # had taken some appropriate "null" action. + # + # For example, say `resolve` is received by a level 0 implementation (because a previous call + # or return happened to contain a promise). The level 0 implementation will echo it back as + # `unimplemented`. The original sender can then simply release the cap to which the promise + # had resolved, thus avoiding a leak. + # + # For any message type that introduces a question, if the message comes back unimplemented, + # the original sender may simply treat it as if the question failed with an exception. + # + # In cases where there is no sensible way to react to an `unimplemented` message (without + # resource leaks or other serious problems), the connection may need to be aborted. This is + # a gray area; different implementations may take different approaches. + + abort @1 :Exception; + # Sent when a connection is being aborted due to an unrecoverable error. This could be e.g. + # because the sender received an invalid or nonsensical message (`isCallersFault` is true) or + # because the sender had an internal error (`isCallersFault` is false). The sender will shut + # down the outgoing half of the connection after `abort` and will completely close the + # connection shortly thereafter (it's up to the sender how much of a time buffer they want to + # offer for the client to receive the `abort` before the connection is reset). + + # Level 0 features ----------------------------------------------- + + bootstrap @8 :Bootstrap; # Request the peer's bootstrap interface. + call @2 :Call; # Begin a method call. + return @3 :Return; # Complete a method call. + finish @4 :Finish; # Release a returned answer / cancel a call. + + # Level 1 features ----------------------------------------------- + + resolve @5 :Resolve; # Resolve a previously-sent promise. + release @6 :Release; # Release a capability so that the remote object can be deallocated. + disembargo @13 :Disembargo; # Lift an embargo used to enforce E-order over promise resolution. + + # Level 2 features ----------------------------------------------- + + obsoleteSave @7 :AnyPointer; + # Obsolete request to save a capability, resulting in a SturdyRef. This has been replaced + # by the `Persistent` interface defined in `persistent.capnp`. This operation was never + # implemented. + + obsoleteDelete @9 :AnyPointer; + # Obsolete way to delete a SturdyRef. This operation was never implemented. + + # Level 3 features ----------------------------------------------- + + provide @10 :Provide; # Provide a capability to a third party. + accept @11 :Accept; # Accept a capability provided by a third party. + + # Level 4 features ----------------------------------------------- + + join @12 :Join; # Directly connect to the common root of two or more proxied caps. + } +} + +# Level 0 message types ---------------------------------------------- + +struct Bootstrap { + # **(level 0)** + # + # Get the "bootstrap" interface exported by the remote vat. + # + # For level 0, 1, and 2 implementations, the "bootstrap" interface is simply the main interface + # exported by a vat. If the vat acts as a server fielding connections from clients, then the + # bootstrap interface defines the basic functionality available to a client when it connects. + # The exact interface definition obviously depends on the application. + # + # We call this a "bootstrap" because in an ideal Cap'n Proto world, bootstrap interfaces would + # never be used. In such a world, any time you connect to a new vat, you do so because you + # received an introduction from some other vat (see `ThirdPartyCapId`). Thus, the first message + # you send is `Accept`, and further communications derive from there. `Bootstrap` is not used. + # + # In such an ideal world, DNS itself would support Cap'n Proto -- performing a DNS lookup would + # actually return a new Cap'n Proto capability, thus introducing you to the target system via + # level 3 RPC. Applications would receive the capability to talk to DNS in the first place as + # an initial endowment or part of a Powerbox interaction. Therefore, an app can form arbitrary + # connections without ever using `Bootstrap`. + # + # Of course, in the real world, DNS is not Cap'n-Proto-based, and we don't want Cap'n Proto to + # require a whole new internet infrastructure to be useful. Therefore, we offer bootstrap + # interfaces as a way to get up and running without a level 3 introduction. Thus, bootstrap + # interfaces are used to "bootstrap" from other, non-Cap'n-Proto-based means of service discovery, + # such as legacy DNS. + # + # Note that a vat need not provide a bootstrap interface, and in fact many vats (especially those + # acting as clients) do not. In this case, the vat should either reply to `Bootstrap` with a + # `Return` indicating an exception, or should return a dummy capability with no methods. + + questionId @0 :QuestionId; + # A new question ID identifying this request, which will eventually receive a Return message + # containing the restored capability. + + deprecatedObjectId @1 :AnyPointer; + # ** DEPRECATED ** + # + # A Vat may export multiple bootstrap interfaces. In this case, `deprecatedObjectId` specifies + # which one to return. If this pointer is null, then the default bootstrap interface is returned. + # + # As of verison 0.5, use of this field is deprecated. If a service wants to export multiple + # bootstrap interfaces, it should instead define a single bootstarp interface that has methods + # that return each of the other interfaces. + # + # **History** + # + # In the first version of Cap'n Proto RPC (0.4.x) the `Bootstrap` message was called `Restore`. + # At the time, it was thought that this would eventually serve as the way to restore SturdyRefs + # (level 2). Meanwhile, an application could offer its "main" interface on a well-known + # (non-secret) SturdyRef. + # + # Since level 2 RPC was not implemented at the time, the `Restore` message was in practice only + # used to obtain the main interface. Since most applications had only one main interface that + # they wanted to restore, they tended to designate this with a null `objectId`. + # + # Unfortunately, the earliest version of the EZ RPC interfaces set a precedent of exporting + # multiple main interfaces by allowing them to be exported under string names. In this case, + # `objectId` was a Text value specifying the name. + # + # All of this proved problematic for several reasons: + # + # - The arrangement assumed that a client wishing to restore a SturdyRef would know exactly what + # machine to connect to and would be able to immediately restore a SturdyRef on connection. + # However, in practice, the ability to restore SturdyRefs is itself a capability that may + # require going through an authentication process to obtain. Thus, it makes more sense to + # define a "restorer service" as a full Cap'n Proto interface. If this restorer interface is + # offered as the vat's bootstrap interface, then this is equivalent to the old arrangement. + # + # - Overloading "Restore" for the purpose of obtaining well-known capabilities encouraged the + # practice of exporting singleton services with string names. If singleton services are desired, + # it is better to have one main interface that has methods that can be used to obtain each + # service, in order to get all the usual benefits of schemas and type checking. + # + # - Overloading "Restore" also had a security problem: Often, "main" or "well-known" + # capabilities exported by a vat are in fact not public: they are intended to be accessed only + # by clients who are capable of forming a connection to the vat. This can lead to trouble if + # the client itself has other clients and wishes to foward some `Restore` requests from those + # external clients -- it has to be very careful not to allow through `Restore` requests + # addressing the default capability. + # + # For example, consider the case of a sandboxed Sandstorm application and its supervisor. The + # application exports a default capability to its supervisor that provides access to + # functionality that only the supervisor is supposed to access. Meanwhile, though, applications + # may publish other capabilities that may be persistent, in which case the application needs + # to field `Restore` requests that could come from anywhere. These requests of course have to + # pass through the supervisor, as all communications with the outside world must. But, the + # supervisor has to be careful not to honor an external request addressing the application's + # default capability, since this capability is privileged. Unfortunately, the default + # capability cannot be given an unguessable name, because then the supervisor itself would not + # be able to address it! + # + # As of Cap'n Proto 0.5, `Restore` has been renamed to `Bootstrap` and is no longer planned for + # use in restoring SturdyRefs. + # + # Note that 0.4 also defined a message type called `Delete` that, like `Restore`, addressed a + # SturdyRef, but indicated that the client would not restore the ref again in the future. This + # operation was never implemented, so it was removed entirely. If a "delete" operation is desired, + # it should exist as a method on the same interface that handles restoring SturdyRefs. However, + # the utility of such an operation is questionable. You wouldn't be able to rely on it for + # garbage collection since a client could always disappear permanently without remembering to + # delete all its SturdyRefs, thus leaving them dangling forever. Therefore, it is advisable to + # design systems such that SturdyRefs never represent "owned" pointers. + # + # For example, say a SturdyRef points to an image file hosted on some server. That image file + # should also live inside a collection (a gallery, perhaps) hosted on the same server, owned by + # a user who can delete the image at any time. If the user deletes the image, the SturdyRef + # stops working. On the other hand, if the SturdyRef is discarded, this has no effect on the + # existence of the image in its collection. +} + +struct Call { + # **(level 0)** + # + # Message type initiating a method call on a capability. + + questionId @0 :QuestionId; + # A number, chosen by the caller, that identifies this call in future messages. This number + # must be different from all other calls originating from the same end of the connection (but + # may overlap with question IDs originating from the opposite end). A fine strategy is to use + # sequential question IDs, but the recipient should not assume this. + # + # A question ID can be reused once both: + # - A matching Return has been received from the callee. + # - A matching Finish has been sent from the caller. + + target @1 :MessageTarget; + # The object that should receive this call. + + interfaceId @2 :UInt64; + # The type ID of the interface being called. Each capability may implement multiple interfaces. + + methodId @3 :UInt16; + # The ordinal number of the method to call within the requested interface. + + allowThirdPartyTailCall @8 :Bool = false; + # Indicates whether or not the receiver is allowed to send a `Return` containing + # `acceptFromThirdParty`. Level 3 implementations should set this true. Otherwise, the callee + # will have to proxy the return in the case of a tail call to a third-party vat. + + params @4 :Payload; + # The call parameters. `params.content` is a struct whose fields correspond to the parameters of + # the method. + + sendResultsTo :union { + # Where should the return message be sent? + + caller @5 :Void; + # Send the return message back to the caller (the usual). + + yourself @6 :Void; + # **(level 1)** + # + # Don't actually return the results to the sender. Instead, hold on to them and await + # instructions from the sender regarding what to do with them. In particular, the sender + # may subsequently send a `Return` for some other call (which the receiver had previously made + # to the sender) with `takeFromOtherQuestion` set. The results from this call are then used + # as the results of the other call. + # + # When `yourself` is used, the receiver must still send a `Return` for the call, but sets the + # field `resultsSentElsewhere` in that `Return` rather than including the results. + # + # This feature can be used to implement tail calls in which a call from Vat A to Vat B ends up + # returning the result of a call from Vat B back to Vat A. + # + # In particular, the most common use case for this feature is when Vat A makes a call to a + # promise in Vat B, and then that promise ends up resolving to a capability back in Vat A. + # Vat B must forward all the queued calls on that promise back to Vat A, but can set `yourself` + # in the calls so that the results need not pass back through Vat B. + # + # For example: + # - Alice, in Vat A, call foo() on Bob in Vat B. + # - Alice makes a pipelined call bar() on the promise returned by foo(). + # - Later on, Bob resolves the promise from foo() to point at Carol, who lives in Vat A (next + # to Alice). + # - Vat B dutifully forwards the bar() call to Carol. Let us call this forwarded call bar'(). + # Notice that bar() and bar'() are travelling in opposite directions on the same network + # link. + # - The `Call` for bar'() has `sendResultsTo` set to `yourself`, with the value being the + # question ID originally assigned to the bar() call. + # - Vat A receives bar'() and delivers it to Carol. + # - When bar'() returns, Vat A immediately takes the results and returns them from bar(). + # - Meanwhile, Vat A sends a `Return` for bar'() to Vat B, with `resultsSentElsewhere` set in + # place of results. + # - Vat A sends a `Finish` for that call to Vat B. + # - Vat B receives the `Return` for bar'() and sends a `Return` for bar(), with + # `receivedFromYourself` set in place of the results. + # - Vat B receives the `Finish` for bar() and sends a `Finish` to bar'(). + + thirdParty @7 :RecipientId; + # **(level 3)** + # + # The call's result should be returned to a different vat. The receiver (the callee) expects + # to receive an `Accept` message from the indicated vat, and should return the call's result + # to it, rather than to the sender of the `Call`. + # + # This operates much like `yourself`, above, except that Carol is in a separate Vat C. `Call` + # messages are sent from Vat A -> Vat B and Vat B -> Vat C. A `Return` message is sent from + # Vat B -> Vat A that contains `acceptFromThirdParty` in place of results. When Vat A sends + # an `Accept` to Vat C, it receives back a `Return` containing the call's actual result. Vat C + # also sends a `Return` to Vat B with `resultsSentElsewhere`. + } +} + +struct Return { + # **(level 0)** + # + # Message type sent from callee to caller indicating that the call has completed. + + answerId @0 :AnswerId; + # Equal to the QuestionId of the corresponding `Call` message. + + releaseParamCaps @1 :Bool = true; + # If true, all capabilities that were in the params should be considered released. The sender + # must not send separate `Release` messages for them. Level 0 implementations in particular + # should always set this true. This defaults true because if level 0 implementations forget to + # set it they'll never notice (just silently leak caps), but if level >=1 implementations forget + # to set it to false they'll quickly get errors. + + union { + results @2 :Payload; + # The result. + # + # For regular method calls, `results.content` points to the result struct. + # + # For a `Return` in response to an `Accept`, `results` contains a single capability (rather + # than a struct), and `results.content` is just a capability pointer with index 0. A `Finish` + # is still required in this case. + + exception @3 :Exception; + # Indicates that the call failed and explains why. + + canceled @4 :Void; + # Indicates that the call was canceled due to the caller sending a Finish message + # before the call had completed. + + resultsSentElsewhere @5 :Void; + # This is set when returning from a `Call` that had `sendResultsTo` set to something other + # than `caller`. + + takeFromOtherQuestion @6 :QuestionId; + # The sender has also sent (before this message) a `Call` with the given question ID and with + # `sendResultsTo.yourself` set, and the results of that other call should be used as the + # results here. + + acceptFromThirdParty @7 :ThirdPartyCapId; + # **(level 3)** + # + # The caller should contact a third-party vat to pick up the results. An `Accept` message + # sent to the vat will return the result. This pairs with `Call.sendResultsTo.thirdParty`. + # It should only be used if the corresponding `Call` had `allowThirdPartyTailCall` set. + } +} + +struct Finish { + # **(level 0)** + # + # Message type sent from the caller to the callee to indicate: + # 1) The questionId will no longer be used in any messages sent by the callee (no further + # pipelined requests). + # 2) If the call has not returned yet, the caller no longer cares about the result. If nothing + # else cares about the result either (e.g. there are no other outstanding calls pipelined on + # the result of this one) then the callee may wish to immediately cancel the operation and + # send back a Return message with "canceled" set. However, implementations are not required + # to support premature cancellation -- instead, the implementation may wait until the call + # actually completes and send a normal `Return` message. + # + # TODO(someday): Should we separate (1) and implicitly releasing result capabilities? It would be + # possible and useful to notify the server that it doesn't need to keep around the response to + # service pipeline requests even though the caller still wants to receive it / hasn't yet + # finished processing it. It could also be useful to notify the server that it need not marshal + # the results because the caller doesn't want them anyway, even if the caller is still sending + # pipelined calls, although this seems less useful (just saving some bytes on the wire). + + questionId @0 :QuestionId; + # ID of the call whose result is to be released. + + releaseResultCaps @1 :Bool = true; + # If true, all capabilities that were in the results should be considered released. The sender + # must not send separate `Release` messages for them. Level 0 implementations in particular + # should always set this true. This defaults true because if level 0 implementations forget to + # set it they'll never notice (just silently leak caps), but if level >=1 implementations forget + # set it false they'll quickly get errors. +} + +# Level 1 message types ---------------------------------------------- + +struct Resolve { + # **(level 1)** + # + # Message type sent to indicate that a previously-sent promise has now been resolved to some other + # object (possibly another promise) -- or broken, or canceled. + # + # Keep in mind that it's possible for a `Resolve` to be sent to a level 0 implementation that + # doesn't implement it. For example, a method call or return might contain a capability in the + # payload. Normally this is fine even if the receiver is level 0, because they will implicitly + # release all such capabilities on return / finish. But if the cap happens to be a promise, then + # a follow-up `Resolve` may be sent regardless of this release. The level 0 receiver will reply + # with an `unimplemented` message, and the sender (of the `Resolve`) can respond to this as if the + # receiver had immediately released any capability to which the promise resolved. + # + # When implementing promise resolution, it's important to understand how embargos work and the + # tricky case of the Tribble 4-way race condition. See the comments for the Disembargo message, + # below. + + promiseId @0 :ExportId; + # The ID of the promise to be resolved. + # + # Unlike all other instances of `ExportId` sent from the exporter, the `Resolve` message does + # _not_ increase the reference count of `promiseId`. In fact, it is expected that the receiver + # will release the export soon after receiving `Resolve`, and the sender will not send this + # `ExportId` again until it has been released and recycled. + # + # When an export ID sent over the wire (e.g. in a `CapDescriptor`) is indicated to be a promise, + # this indicates that the sender will follow up at some point with a `Resolve` message. If the + # same `promiseId` is sent again before `Resolve`, still only one `Resolve` is sent. If the + # same ID is sent again later _after_ a `Resolve`, it can only be because the export's + # reference count hit zero in the meantime and the ID was re-assigned to a new export, therefore + # this later promise does _not_ correspond to the earlier `Resolve`. + # + # If a promise ID's reference count reaches zero before a `Resolve` is sent, the `Resolve` + # message may or may not still be sent (the `Resolve` may have already been in-flight when + # `Release` was sent, but if the `Release` is received before `Resolve` then there is no longer + # any reason to send a `Resolve`). Thus a `Resolve` may be received for a promise of which + # the receiver has no knowledge, because it already released it earlier. In this case, the + # receiver should simply release the capability to which the promise resolved. + + union { + cap @1 :CapDescriptor; + # The object to which the promise resolved. + # + # The sender promises that from this point forth, until `promiseId` is released, it shall + # simply forward all messages to the capability designated by `cap`. This is true even if + # `cap` itself happens to desigate another promise, and that other promise later resolves -- + # messages sent to `promiseId` shall still go to that other promise, not to its resolution. + # This is important in the case that the receiver of the `Resolve` ends up sending a + # `Disembargo` message towards `promiseId` in order to control message ordering -- that + # `Disembargo` really needs to reflect back to exactly the object designated by `cap` even + # if that object is itself a promise. + + exception @2 :Exception; + # Indicates that the promise was broken. + } +} + +struct Release { + # **(level 1)** + # + # Message type sent to indicate that the sender is done with the given capability and the receiver + # can free resources allocated to it. + + id @0 :ImportId; + # What to release. + + referenceCount @1 :UInt32; + # The amount by which to decrement the reference count. The export is only actually released + # when the reference count reaches zero. +} + +struct Disembargo { + # **(level 1)** + # + # Message sent to indicate that an embargo on a recently-resolved promise may now be lifted. + # + # Embargos are used to enforce E-order in the presence of promise resolution. That is, if an + # application makes two calls foo() and bar() on the same capability reference, in that order, + # the calls should be delivered in the order in which they were made. But if foo() is called + # on a promise, and that promise happens to resolve before bar() is called, then the two calls + # may travel different paths over the network, and thus could arrive in the wrong order. In + # this case, the call to `bar()` must be embargoed, and a `Disembargo` message must be sent along + # the same path as `foo()` to ensure that the `Disembargo` arrives after `foo()`. Once the + # `Disembargo` arrives, `bar()` can then be delivered. + # + # There are two particular cases where embargos are important. Consider object Alice, in Vat A, + # who holds a promise P, pointing towards Vat B, that eventually resolves to Carol. The two + # cases are: + # - Carol lives in Vat A, i.e. next to Alice. In this case, Vat A needs to send a `Disembargo` + # message that echos through Vat B and back, to ensure that all pipelined calls on the promise + # have been delivered. + # - Carol lives in a different Vat C. When the promise resolves, a three-party handoff occurs + # (see `Provide` and `Accept`, which constitute level 3 of the protocol). In this case, we + # piggyback on the state that has already been set up to handle the handoff: the `Accept` + # message (from Vat A to Vat C) is embargoed, as are all pipelined messages sent to it, while + # a `Disembargo` message is sent from Vat A through Vat B to Vat C. See `Accept.embargo` for + # an example. + # + # Note that in the case where Carol actually lives in Vat B (i.e., the same vat that the promise + # already pointed at), no embargo is needed, because the pipelined calls are delivered over the + # same path as the later direct calls. + # + # Keep in mind that promise resolution happens both in the form of Resolve messages as well as + # Return messages (which resolve PromisedAnswers). Embargos apply in both cases. + # + # An alternative strategy for enforcing E-order over promise resolution could be for Vat A to + # implement the embargo internally. When Vat A is notified of promise resolution, it could + # send a dummy no-op call to promise P and wait for it to complete. Until that call completes, + # all calls to the capability are queued locally. This strategy works, but is pessimistic: + # in the three-party case, it requires an A -> B -> C -> B -> A round trip before calls can start + # being delivered directly to from Vat A to Vat C. The `Disembargo` message allows latency to be + # reduced. (In the two-party loopback case, the `Disembargo` message is just a more explicit way + # of accomplishing the same thing as a no-op call, but isn't any faster.) + # + # *The Tribble 4-way Race Condition* + # + # Any implementation of promise resolution and embargos must be aware of what we call the + # "Tribble 4-way race condition", after Dean Tribble, who explained the problem in a lively + # Friam meeting. + # + # Embargos are designed to work in the case where a two-hop path is being shortened to one hop. + # But sometimes there are more hops. Imagine that Alice has a reference to a remote promise P1 + # that eventually resolves to _another_ remote promise P2 (in a third vat), which _at the same + # time_ happens to resolve to Bob (in a fourth vat). In this case, we're shortening from a 3-hop + # path (with four parties) to a 1-hop path (Alice -> Bob). + # + # Extending the embargo/disembargo protocol to be able to shorted multiple hops at once seems + # difficult. Instead, we make a rule that prevents this case from coming up: + # + # One a promise P has been resolved to a remove object reference R, then all further messages + # received addressed to P will be forwarded strictly to R. Even if it turns out later that R is + # itself a promise, and has resolved to some other object Q, messages sent to P will still be + # forwarded to R, not directly to Q (R will of course further forward the messages to Q). + # + # This rule does not cause a significant performance burden because once P has resolved to R, it + # is expected that people sending messages to P will shortly start sending them to R instead and + # drop P. P is at end-of-life anyway, so it doesn't matter if it ignores chances to further + # optimize its path. + + target @0 :MessageTarget; + # What is to be disembargoed. + + using EmbargoId = UInt32; + # Used in `senderLoopback` and `receiverLoopback`, below. + + context :union { + senderLoopback @1 :EmbargoId; + # The sender is requesting a disembargo on a promise that is known to resolve back to a + # capability hosted by the sender. As soon as the receiver has echoed back all pipelined calls + # on this promise, it will deliver the Disembargo back to the sender with `receiverLoopback` + # set to the same value as `senderLoopback`. This value is chosen by the sender, and since + # it is also consumed be the sender, the sender can use whatever strategy it wants to make sure + # the value is unambiguous. + # + # The receiver must verify that the target capability actually resolves back to the sender's + # vat. Otherwise, the sender has committed a protocol error and should be disconnected. + + receiverLoopback @2 :EmbargoId; + # The receiver previously sent a `senderLoopback` Disembargo towards a promise resolving to + # this capability, and that Disembargo is now being echoed back. + + accept @3 :Void; + # **(level 3)** + # + # The sender is requesting a disembargo on a promise that is known to resolve to a third-party + # capability that the sender is currently in the process of accepting (using `Accept`). + # The receiver of this `Disembargo` has an outstanding `Provide` on said capability. The + # receiver should now send a `Disembargo` with `provide` set to the question ID of that + # `Provide` message. + # + # See `Accept.embargo` for an example. + + provide @4 :QuestionId; + # **(level 3)** + # + # The sender is requesting a disembargo on a capability currently being provided to a third + # party. The question ID identifies the `Provide` message previously sent by the sender to + # this capability. On receipt, the receiver (the capability host) shall release the embargo + # on the `Accept` message that it has received from the third party. See `Accept.embargo` for + # an example. + } +} + +# Level 2 message types ---------------------------------------------- + +# See persistent.capnp. + +# Level 3 message types ---------------------------------------------- + +struct Provide { + # **(level 3)** + # + # Message type sent to indicate that the sender wishes to make a particular capability implemented + # by the receiver available to a third party for direct access (without the need for the third + # party to proxy through the sender). + # + # (In CapTP, `Provide` and `Accept` are methods of the global `NonceLocator` object exported by + # every vat. In Cap'n Proto, we bake this into the core protocol.) + + questionId @0 :QuestionId; + # Question ID to be held open until the recipient has received the capability. A result will be + # returned once the third party has successfully received the capability. The sender must at some + # point send a `Finish` message as with any other call, and that message can be used to cancel the + # whole operation. + + target @1 :MessageTarget; + # What is to be provided to the third party. + + recipient @2 :RecipientId; + # Identity of the third party that is expected to pick up the capability. +} + +struct Accept { + # **(level 3)** + # + # Message type sent to pick up a capability hosted by the receiving vat and provided by a third + # party. The third party previously designated the capability using `Provide`. + # + # This message is also used to pick up a redirected return -- see `Return.redirect`. + + questionId @0 :QuestionId; + # A new question ID identifying this accept message, which will eventually receive a Return + # message containing the provided capability (or the call result in the case of a redirected + # return). + + provision @1 :ProvisionId; + # Identifies the provided object to be picked up. + + embargo @2 :Bool; + # If true, this accept shall be temporarily embargoed. The resulting `Return` will not be sent, + # and any pipelined calls will not be delivered, until the embargo is released. The receiver + # (the capability host) will expect the provider (the vat that sent the `Provide` message) to + # eventually send a `Disembargo` message with the field `context.provide` set to the question ID + # of the original `Provide` message. At that point, the embargo is released and the queued + # messages are delivered. + # + # For example: + # - Alice, in Vat A, holds a promise P, which currently points toward Vat B. + # - Alice calls foo() on P. The `Call` message is sent to Vat B. + # - The promise P in Vat B ends up resolving to Carol, in Vat C. + # - Vat B sends a `Provide` message to Vat C, identifying Vat A as the recipient. + # - Vat B sends a `Resolve` message to Vat A, indicating that the promise has resolved to a + # `ThirdPartyCapId` identifying Carol in Vat C. + # - Vat A sends an `Accept` message to Vat C to pick up the capability. Since Vat A knows that + # it has an outstanding call to the promise, it sets `embargo` to `true` in the `Accept` + # message. + # - Vat A sends a `Disembargo` message to Vat B on promise P, with `context.accept` set. + # - Alice makes a call bar() to promise P, which is now pointing towards Vat C. Alice doesn't + # know anything about the mechanics of promise resolution happening under the hood, but she + # expects that bar() will be delivered after foo() because that is the order in which she + # initiated the calls. + # - Vat A sends the bar() call to Vat C, as a pipelined call on the result of the `Accept` (which + # hasn't returned yet, due to the embargo). Since calls to the newly-accepted capability + # are embargoed, Vat C does not deliver the call yet. + # - At some point, Vat B forwards the foo() call from the beginning of this example on to Vat C. + # - Vat B forwards the `Disembargo` from Vat A on to vat C. It sets `context.provide` to the + # question ID of the `Provide` message it had sent previously. + # - Vat C receives foo() before `Disembargo`, thus allowing it to correctly deliver foo() + # before delivering bar(). + # - Vat C receives `Disembargo` from Vat B. It can now send a `Return` for the `Accept` from + # Vat A, as well as deliver bar(). +} + +# Level 4 message types ---------------------------------------------- + +struct Join { + # **(level 4)** + # + # Message type sent to implement E.join(), which, given a number of capabilities that are + # expected to be equivalent, finds the underlying object upon which they all agree and forms a + # direct connection to it, skipping any proxies that may have been constructed by other vats + # while transmitting the capability. See: + # http://erights.org/elib/equality/index.html + # + # Note that this should only serve to bypass fully-transparent proxies -- proxies that were + # created merely for convenience, without any intention of hiding the underlying object. + # + # For example, say Bob holds two capabilities hosted by Alice and Carol, but he expects that both + # are simply proxies for a capability hosted elsewhere. He then issues a join request, which + # operates as follows: + # - Bob issues Join requests on both Alice and Carol. Each request contains a different piece + # of the JoinKey. + # - Alice is proxying a capability hosted by Dana, so forwards the request to Dana's cap. + # - Dana receives the first request and sees that the JoinKeyPart is one of two. She notes that + # she doesn't have the other part yet, so she records the request and responds with a + # JoinResult. + # - Alice relays the JoinAswer back to Bob. + # - Carol is also proxying a capability from Dana, and so forwards her Join request to Dana as + # well. + # - Dana receives Carol's request and notes that she now has both parts of a JoinKey. She + # combines them in order to form information needed to form a secure connection to Bob. She + # also responds with another JoinResult. + # - Bob receives the responses from Alice and Carol. He uses the returned JoinResults to + # determine how to connect to Dana and attempts to form the connection. Since Bob and Dana now + # agree on a secret key that neither Alice nor Carol ever saw, this connection can be made + # securely even if Alice or Carol is conspiring against the other. (If Alice and Carol are + # conspiring _together_, they can obviously reproduce the key, but this doesn't matter because + # the whole point of the join is to verify that Alice and Carol agree on what capability they + # are proxying.) + # + # If the two capabilities aren't actually proxies of the same object, then the join requests + # will come back with conflicting `hostId`s and the join will fail before attempting to form any + # connection. + + questionId @0 :QuestionId; + # Question ID used to respond to this Join. (Note that this ID only identifies one part of the + # request for one hop; each part has a different ID and relayed copies of the request have + # (probably) different IDs still.) + # + # The receiver will reply with a `Return` whose `results` is a JoinResult. This `JoinResult` + # is relayed from the joined object's host, possibly with transformation applied as needed + # by the network. + # + # Like any return, the result must be released using a `Finish`. However, this release + # should not occur until the joiner has either successfully connected to the joined object. + # Vats relaying a `Join` message similarly must not release the result they receive until the + # return they relayed back towards the joiner has itself been released. This allows the + # joined object's host to detect when the Join operation is canceled before completing -- if + # it receives a `Finish` for one of the join results before the joiner successfully + # connects. It can then free any resources it had allocated as part of the join. + + target @1 :MessageTarget; + # The capability to join. + + keyPart @2 :JoinKeyPart; + # A part of the join key. These combine to form the complete join key, which is used to establish + # a direct connection. + + # TODO(before implementing): Change this so that multiple parts can be sent in a single Join + # message, so that if multiple join parts are going to cross the same connection they can be sent + # together, so that the receive can potentially optimize its handling of them. In the case where + # all parts are bundled together, should the recipient be expected to simply return a cap, so + # that the caller can immediately start pipelining to it? +} + +# ======================================================================================== +# Common structures used in messages + +struct MessageTarget { + # The target of a `Call` or other messages that target a capability. + + union { + importedCap @0 :ImportId; + # This message is to a capability or promise previously imported by the caller (exported by + # the receiver). + + promisedAnswer @1 :PromisedAnswer; + # This message is to a capability that is expected to be returned by another call that has not + # yet been completed. + # + # At level 0, this is supported only for addressing the result of a previous `Bootstrap`, so + # that initial startup doesn't require a round trip. + } +} + +struct Payload { + # Represents some data structure that might contain capabilities. + + content @0 :AnyPointer; + # Some Cap'n Proto data structure. Capability pointers embedded in this structure index into + # `capTable`. + + capTable @1 :List(CapDescriptor); + # Descriptors corresponding to the cap pointers in `content`. +} + +struct CapDescriptor { + # **(level 1)** + # + # When an application-defined type contains an interface pointer, that pointer contains an index + # into the message's capability table -- i.e. the `capTable` part of the `Payload`. Each + # capability in the table is represented as a `CapDescriptor`. The runtime API should not reveal + # the CapDescriptor directly to the application, but should instead wrap it in some kind of + # callable object with methods corresponding to the interface that the capability implements. + # + # Keep in mind that `ExportIds` in a `CapDescriptor` are subject to reference counting. See the + # description of `ExportId`. + + union { + none @0 :Void; + # There is no capability here. This `CapDescriptor` should not appear in the payload content. + # A `none` CapDescriptor can be generated when an application inserts a capability into a + # message and then later changes its mind and removes it -- rewriting all of the other + # capability pointers may be hard, so instead a tombstone is left, similar to the way a removed + # struct or list instance is zeroed out of the message but the space is not reclaimed. + # Hopefully this is unusual. + + senderHosted @1 :ExportId; + # A capability newly exported by the sender. This is the ID of the new capability in the + # sender's export table (receiver's import table). + + senderPromise @2 :ExportId; + # A promise that the sender will resolve later. The sender will send exactly one Resolve + # message at a future point in time to replace this promise. Note that even if the same + # `senderPromise` is received multiple times, only one `Resolve` is sent to cover all of + # them. If `senderPromise` is released before the `Resolve` is sent, the sender (of this + # `CapDescriptor`) may choose not to send the `Resolve` at all. + + receiverHosted @3 :ImportId; + # A capability (or promise) previously exported by the receiver (imported by the sender). + + receiverAnswer @4 :PromisedAnswer; + # A capability expected to be returned in the results of a currently-outstanding call posed + # by the sender. + + thirdPartyHosted @5 :ThirdPartyCapDescriptor; + # **(level 3)** + # + # A capability that lives in neither the sender's nor the receiver's vat. The sender needs + # to form a direct connection to a third party to pick up the capability. + # + # Level 1 and 2 implementations that receive a `thirdPartyHosted` may simply send calls to its + # `vine` instead. + } +} + +struct PromisedAnswer { + # **(mostly level 1)** + # + # Specifies how to derive a promise from an unanswered question, by specifying the path of fields + # to follow from the root of the eventual result struct to get to the desired capability. Used + # to address method calls to a not-yet-returned capability or to pass such a capability as an + # input to some other method call. + # + # Level 0 implementations must support `PromisedAnswer` only for the case where the answer is + # to a `Bootstrap` message. In this case, `path` is always empty since `Bootstrap` always returns + # a raw capability. + + questionId @0 :QuestionId; + # ID of the question (in the sender's question table / receiver's answer table) whose answer is + # expected to contain the capability. + + transform @1 :List(Op); + # Operations / transformations to apply to the result in order to get the capability actually + # being addressed. E.g. if the result is a struct and you want to call a method on a capability + # pointed to by a field of the struct, you need a `getPointerField` op. + + struct Op { + union { + noop @0 :Void; + # Does nothing. This member is mostly defined so that we can make `Op` a union even + # though (as of this writing) only one real operation is defined. + + getPointerField @1 :UInt16; + # Get a pointer field within a struct. The number is an index into the pointer section, NOT + # a field ordinal, so that the receiver does not need to understand the schema. + + # TODO(someday): We could add: + # - For lists, the ability to address every member of the list, or a slice of the list, the + # result of which would be another list. This is useful for implementing the equivalent of + # a SQL table join (not to be confused with the `Join` message type). + # - Maybe some ability to test a union. + # - Probably not a good idea: the ability to specify an arbitrary script to run on the + # result. We could define a little stack-based language where `Op` specifies one + # "instruction" or transformation to apply. Although this is not a good idea + # (over-engineered), any narrower additions to `Op` should be designed as if this + # were the eventual goal. + } + } +} + +struct ThirdPartyCapDescriptor { + # **(level 3)** + # + # Identifies a capability in a third-party vat that the sender wants the receiver to pick up. + + id @0 :ThirdPartyCapId; + # Identifies the third-party host and the specific capability to accept from it. + + vineId @1 :ExportId; + # A proxy for the third-party object exported by the sender. In CapTP terminology this is called + # a "vine", because it is an indirect reference to the third-party object that snakes through the + # sender vat. This serves two purposes: + # + # * Level 1 and 2 implementations that don't understand how to connect to a third party may + # simply send calls to the vine. Such calls will be forwarded to the third-party by the + # sender. + # + # * Level 3 implementations must release the vine once they have successfully picked up the + # object from the third party. This ensures that the capability is not released by the sender + # prematurely. + # + # The sender will close the `Provide` request that it has sent to the third party as soon as + # it receives either a `Call` or a `Release` message directed at the vine. +} + +struct Exception { + # **(level 0)** + # + # Describes an arbitrary error that prevented an operation (e.g. a call) from completing. + # + # Cap'n Proto exceptions always indicate that something went wrong. In other words, in a fantasy + # world where everything always works as expected, no exceptions would ever be thrown. Clients + # should only ever catch exceptions as a means to implement fault-tolerance, where "fault" can + # mean: + # - Bugs. + # - Invalid input. + # - Configuration errors. + # - Network problems. + # - Insufficient resources. + # - Version skew (unimplemented functionality). + # - Other logistical problems. + # + # Exceptions should NOT be used to flag application-specific conditions that a client is expected + # to handle in an application-specific way. Put another way, in the Cap'n Proto world, + # "checked exceptions" (where an interface explicitly defines the exceptions it throws and + # clients are forced by the type system to handle those exceptions) do NOT make sense. + + reason @0 :Text; + # Human-readable failure description. + + type @3 :Type; + # The type of the error. The purpose of this enum is not to describe the error itself, but + # rather to describe how the client might want to respond to the error. + + enum Type { + failed @0; + # A generic problem occurred, and it is believed that if the operation were repeated without + # any change in the state of the world, the problem would occur again. + # + # A client might respond to this error by logging it for investigation by the developer and/or + # displaying it to the user. + + overloaded @1; + # The request was rejected due to a temporary lack of resources. + # + # Examples include: + # - There's not enough CPU time to keep up with incoming requests, so some are rejected. + # - The server ran out of RAM or disk space during the request. + # - The operation timed out (took significantly longer than it should have). + # + # A client might respond to this error by scheduling to retry the operation much later. The + # client should NOT retry again immediately since this would likely exacerbate the problem. + + disconnected @2; + # The method failed because a connection to some necessary capability was lost. + # + # Examples include: + # - The client introduced the server to a third-party capability, the connection to that third + # party was subsequently lost, and then the client requested that the server use the dead + # capability for something. + # - The client previously requested that the server obtain a capability from some third party. + # The server returned a capability to an object wrapping the third-party capability. Later, + # the server's connection to the third party was lost. + # - The capability has been revoked. Revocation does not necessarily mean that the client is + # no longer authorized to use the capability; it is often used simply as a way to force the + # client to repeat the setup process, perhaps to efficiently move them to a new back-end or + # get them to recognize some other change that has occurred. + # + # A client should normally respond to this error by releasing all capabilities it is currently + # holding related to the one it called and then re-creating them by restoring SturdyRefs and/or + # repeating the method calls used to create them originally. In other words, disconnect and + # start over. This should in turn cause the server to obtain a new copy of the capability that + # it lost, thus making everything work. + # + # If the client receives another `disconnencted` error in the process of rebuilding the + # capability and retrying the call, it should treat this as an `overloaded` error: the network + # is currently unreliable, possibly due to load or other temporary issues. + + unimplemented @3; + # The server doesn't implement the requested method. If there is some other method that the + # client could call (perhaps an older and/or slower interface), it should try that instead. + # Otherwise, this should be treated like `failed`. + } + + obsoleteIsCallersFault @1 :Bool; + # OBSOLETE. Ignore. + + obsoleteDurability @2 :UInt16; + # OBSOLETE. See `type` instead. +} + +# ======================================================================================== +# Network-specific Parameters +# +# Some parts of the Cap'n Proto RPC protocol are not specified here because different vat networks +# may wish to use different approaches to solving them. For example, on the public internet, you +# may want to authenticate vats using public-key cryptography, but on a local intranet with trusted +# infrastructure, you may be happy to authenticate based on network address only, or some other +# lightweight mechanism. +# +# To accommodate this, we specify several "parameter" types. Each type is defined here as an +# alias for `AnyPointer`, but a specific network will want to define a specific set of types to use. +# All vats in a vat network must agree on these parameters in order to be able to communicate. +# Inter-network communication can be accomplished through "gateways" that perform translation +# between the primitives used on each network; these gateways may need to be deeply stateful, +# depending on the translations they perform. +# +# For interaction over the global internet between parties with no other prior arrangement, a +# particular set of bindings for these types is defined elsewhere. (TODO(someday): Specify where +# these common definitions live.) +# +# Another common network type is the two-party network, in which one of the parties typically +# interacts with the outside world entirely through the other party. In such a connection between +# Alice and Bob, all objects that exist on Bob's other networks appear to Alice as if they were +# hosted by Bob himself, and similarly all objects on Alice's network (if she even has one) appear +# to Bob as if they were hosted by Alice. This network type is interesting because from the point +# of view of a simple application that communicates with only one other party via the two-party +# protocol, there are no three-party interactions at all, and joins are unusually simple to +# implement, so implementing at level 4 is barely more complicated than implementing at level 1. +# Moreover, if you pair an app implementing the two-party network with a container that implements +# some other network, the app can then participate on the container's network just as if it +# implemented that network directly. The types used by the two-party network are defined in +# `rpc-twoparty.capnp`. +# +# The things that we need to parameterize are: +# - How to store capabilities long-term without holding a connection open (mostly level 2). +# - How to authenticate vats in three-party introductions (level 3). +# - How to implement `Join` (level 4). +# +# Persistent references +# --------------------- +# +# **(mostly level 2)** +# +# We want to allow some capabilities to be stored long-term, even if a connection is lost and later +# recreated. ExportId is a short-term identifier that is specific to a connection, so it doesn't +# help here. We need a way to specify long-term identifiers, as well as a strategy for +# reconnecting to a referenced capability later. +# +# Three-party interactions +# ------------------------ +# +# **(level 3)** +# +# In cases where more than two vats are interacting, we have situations where VatA holds a +# capability hosted by VatB and wants to send that capability to VatC. This can be accomplished +# by VatA proxying requests on the new capability, but doing so has two big problems: +# - It's inefficient, requiring an extra network hop. +# - If VatC receives another capability to the same object from VatD, it is difficult for VatC to +# detect that the two capabilities are really the same and to implement the E "join" operation, +# which is necessary for certain four-or-more-party interactions, such as the escrow pattern. +# See: http://www.erights.org/elib/equality/grant-matcher/index.html +# +# Instead, we want a way for VatC to form a direct, authenticated connection to VatB. +# +# Join +# ---- +# +# **(level 4)** +# +# The `Join` message type and corresponding operation arranges for a direct connection to be formed +# between the joiner and the host of the joined object, and this connection must be authenticated. +# Thus, the details are network-dependent. + +using SturdyRef = AnyPointer; +# **(level 2)** +# +# Identifies a persisted capability that can be restored in the future. How exactly a SturdyRef +# is restored to a live object is specified along with the SturdyRef definition (i.e. not by +# rpc.capnp). +# +# Generally a SturdyRef needs to specify three things: +# - How to reach the vat that can restore the ref (e.g. a hostname or IP address). +# - How to authenticate the vat after connecting (e.g. a public key fingerprint). +# - The identity of a specific object hosted by the vat. Generally, this is an opaque pointer whose +# format is defined by the specific vat -- the client has no need to inspect the object ID. +# It is important that the objec ID be unguessable if the object is not public (and objects +# should almost never be public). +# +# The above are only suggestions. Some networks might work differently. For example, a private +# network might employ a special restorer service whose sole purpose is to restore SturdyRefs. +# In this case, the entire contents of SturdyRef might be opaque, because they are intended only +# to be forwarded to the restorer service. + +using ProvisionId = AnyPointer; +# **(level 3)** +# +# The information that must be sent in an `Accept` message to identify the object being accepted. +# +# In a network where each vat has a public/private key pair, this could simply be the public key +# fingerprint of the provider vat along with the question ID used in the `Provide` message sent from +# that provider. + +using RecipientId = AnyPointer; +# **(level 3)** +# +# The information that must be sent in a `Provide` message to identify the recipient of the +# capability. +# +# In a network where each vat has a public/private key pair, this could simply be the public key +# fingerprint of the recipient. (CapTP also calls for a nonce to identify the object. In our +# case, the `Provide` message's `questionId` can serve as the nonce.) + +using ThirdPartyCapId = AnyPointer; +# **(level 3)** +# +# The information needed to connect to a third party and accept a capability from it. +# +# In a network where each vat has a public/private key pair, this could be a combination of the +# third party's public key fingerprint, hints on how to connect to the third party (e.g. an IP +# address), and the question ID used in the corresponding `Provide` message sent to that third party +# (used to identify which capability to pick up). + +using JoinKeyPart = AnyPointer; +# **(level 4)** +# +# A piece of a secret key. One piece is sent along each path that is expected to lead to the same +# place. Once the pieces are combined, a direct connection may be formed between the sender and +# the receiver, bypassing any men-in-the-middle along the paths. See the `Join` message type. +# +# The motivation for Joins is discussed under "Supporting Equality" in the "Unibus" protocol +# sketch: http://www.erights.org/elib/distrib/captp/unibus.html +# +# In a network where each vat has a public/private key pair and each vat forms no more than one +# connection to each other vat, Joins will rarely -- perhaps never -- be needed, as objects never +# need to be transparently proxied and references to the same object sent over the same connection +# have the same export ID. Thus, a successful join requires only checking that the two objects +# come from the same connection and have the same ID, and then completes immediately. +# +# However, in networks where two vats may form more than one connection between each other, or +# where proxying of objects occurs, joins are necessary. +# +# Typically, each JoinKeyPart would include a fixed-length data value such that all value parts +# XOR'd together forms a shared secret that can be used to form an encrypted connection between +# the joiner and the joined object's host. Each JoinKeyPart should also include an indication of +# how many parts to expect and a hash of the shared secret (used to match up parts). + +using JoinResult = AnyPointer; +# **(level 4)** +# +# Information returned as the result to a `Join` message, needed by the joiner in order to form a +# direct connection to a joined object. This might simply be the address of the joined object's +# host vat, since the `JoinKey` has already been communicated so the two vats already have a shared +# secret to use to authenticate each other. +# +# The `JoinResult` should also contain information that can be used to detect when the Join +# requests ended up reaching different objects, so that this situation can be detected easily. +# This could be a simple matter of including a sequence number -- if the joiner receives two +# `JoinResult`s with sequence number 0, then they must have come from different objects and the +# whole join is a failure. + +# ======================================================================================== +# Network interface sketch +# +# The interfaces below are meant to be pseudo-code to illustrate how the details of a particular +# vat network might be abstracted away. They are written like Cap'n Proto interfaces, but in +# practice you'd probably define these interfaces manually in the target programming language. A +# Cap'n Proto RPC implementation should be able to use these interfaces without knowing the +# definitions of the various network-specific parameters defined above. + +# interface VatNetwork { +# # Represents a vat network, with the ability to connect to particular vats and receive +# # connections from vats. +# # +# # Note that methods returning a `Connection` may return a pre-existing `Connection`, and the +# # caller is expected to find and share state with existing users of the connection. +# +# # Level 0 features ----------------------------------------------- +# +# connect(vatId :VatId) :Connection; +# # Connect to the given vat. The transport should return a promise that does not +# # resolve until authentication has completed, but allows messages to be pipelined in before +# # that; the transport either queues these messages until authenticated, or sends them encrypted +# # such that only the authentic vat would be able to decrypt them. The latter approach avoids a +# # round trip for authentication. +# +# accept() :Connection; +# # Wait for the next incoming connection and return it. Only connections formed by +# # connect() are returned by this method. +# +# # Level 4 features ----------------------------------------------- +# +# newJoiner(count :UInt32) :NewJoinerResponse; +# # Prepare a new Join operation, which will eventually lead to forming a new direct connection +# # to the host of the joined capability. `count` is the number of capabilities to join. +# +# struct NewJoinerResponse { +# joinKeyParts :List(JoinKeyPart); +# # Key parts to send in Join messages to each capability. +# +# joiner :Joiner; +# # Used to establish the final connection. +# } +# +# interface Joiner { +# addJoinResult(result :JoinResult) :Void; +# # Add a JoinResult received in response to one of the `Join` messages. All `JoinResult`s +# # returned from all paths must be added before trying to connect. +# +# connect() :ConnectionAndProvisionId; +# # Try to form a connection to the joined capability's host, verifying that it has received +# # all of the JoinKeyParts. Once the connection is formed, the caller should send an `Accept` +# # message on it with the specified `ProvisionId` in order to receive the final capability. +# } +# +# acceptConnectionFromJoiner(parts :List(JoinKeyPart), paths :List(VatPath)) +# :ConnectionAndProvisionId; +# # Called on a joined capability's host to receive the connection from the joiner, once all +# # key parts have arrived. The caller should expect to receive an `Accept` message over the +# # connection with the given ProvisionId. +# } +# +# interface Connection { +# # Level 0 features ----------------------------------------------- +# +# send(message :Message) :Void; +# # Send the message. Returns successfully when the message (and all preceding messages) has +# # been acknowledged by the recipient. +# +# receive() :Message; +# # Receive the next message, and acknowledges receipt to the sender. Messages are received in +# # the order in which they are sent. +# +# # Level 3 features ----------------------------------------------- +# +# introduceTo(recipient :Connection) :IntroductionInfo; +# # Call before starting a three-way introduction, assuming a `Provide` message is to be sent on +# # this connection and a `ThirdPartyCapId` is to be sent to `recipient`. +# +# struct IntroductionInfo { +# sendToRecipient :ThirdPartyCapId; +# sendToTarget :RecipientId; +# } +# +# connectToIntroduced(capId :ThirdPartyCapId) :ConnectionAndProvisionId; +# # Given a ThirdPartyCapId received over this connection, connect to the third party. The +# # caller should then send an `Accept` message over the new connection. +# +# acceptIntroducedConnection(recipientId :RecipientId) :Connection; +# # Given a RecipientId received in a `Provide` message on this `Connection`, wait for the +# # recipient to connect, and return the connection formed. Usually, the first message received +# # on the new connection will be an `Accept` message. +# } +# +# struct ConnectionAndProvisionId { +# # **(level 3)** +# +# connection :Connection; +# # Connection on which to issue `Accept` message. +# +# provision :ProvisionId; +# # `ProvisionId` to send in the `Accept` message. +# } diff --git a/phonelibs/capnp-cpp/include/capnp/rpc.capnp.h b/phonelibs/capnp-cpp/include/capnp/rpc.capnp.h new file mode 100644 index 00000000000000..0a440397fc3b51 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/rpc.capnp.h @@ -0,0 +1,4898 @@ +// Generated by Cap'n Proto compiler, DO NOT EDIT +// source: rpc.capnp + +#ifndef CAPNP_INCLUDED_b312981b2552a250_ +#define CAPNP_INCLUDED_b312981b2552a250_ + +#include + +#if CAPNP_VERSION != 6001 +#error "Version mismatch between generated code and library headers. You must use the same version of the Cap'n Proto compiler and library." +#endif + + +namespace capnp { +namespace schemas { + +CAPNP_DECLARE_SCHEMA(91b79f1f808db032); +CAPNP_DECLARE_SCHEMA(e94ccf8031176ec4); +CAPNP_DECLARE_SCHEMA(836a53ce789d4cd4); +CAPNP_DECLARE_SCHEMA(dae8b0f61aab5f99); +CAPNP_DECLARE_SCHEMA(9e19b28d3db3573a); +CAPNP_DECLARE_SCHEMA(d37d2eb2c2f80e63); +CAPNP_DECLARE_SCHEMA(bbc29655fa89086e); +CAPNP_DECLARE_SCHEMA(ad1a6c0d7dd07497); +CAPNP_DECLARE_SCHEMA(f964368b0fbd3711); +CAPNP_DECLARE_SCHEMA(d562b4df655bdd4d); +CAPNP_DECLARE_SCHEMA(9c6a046bfbc1ac5a); +CAPNP_DECLARE_SCHEMA(d4c9b56290554016); +CAPNP_DECLARE_SCHEMA(fbe1980490e001af); +CAPNP_DECLARE_SCHEMA(95bc14545813fbc1); +CAPNP_DECLARE_SCHEMA(9a0e61223d96743b); +CAPNP_DECLARE_SCHEMA(8523ddc40b86b8b0); +CAPNP_DECLARE_SCHEMA(d800b1d6cd6f1ca0); +CAPNP_DECLARE_SCHEMA(f316944415569081); +CAPNP_DECLARE_SCHEMA(d37007fde1f0027d); +CAPNP_DECLARE_SCHEMA(d625b7063acf691a); +CAPNP_DECLARE_SCHEMA(b28c96e23f4cbd58); +enum class Type_b28c96e23f4cbd58: uint16_t { + FAILED, + OVERLOADED, + DISCONNECTED, + UNIMPLEMENTED, +}; +CAPNP_DECLARE_ENUM(Type, b28c96e23f4cbd58); + +} // namespace schemas +} // namespace capnp + +namespace capnp { +namespace rpc { + +struct Message { + Message() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + UNIMPLEMENTED, + ABORT, + CALL, + RETURN, + FINISH, + RESOLVE, + RELEASE, + OBSOLETE_SAVE, + BOOTSTRAP, + OBSOLETE_DELETE, + PROVIDE, + ACCEPT, + JOIN, + DISEMBARGO, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(91b79f1f808db032, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Bootstrap { + Bootstrap() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(e94ccf8031176ec4, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Call { + Call() = delete; + + class Reader; + class Builder; + class Pipeline; + struct SendResultsTo; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(836a53ce789d4cd4, 3, 3) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Call::SendResultsTo { + SendResultsTo() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + CALLER, + YOURSELF, + THIRD_PARTY, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(dae8b0f61aab5f99, 3, 3) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Return { + Return() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + RESULTS, + EXCEPTION, + CANCELED, + RESULTS_SENT_ELSEWHERE, + TAKE_FROM_OTHER_QUESTION, + ACCEPT_FROM_THIRD_PARTY, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9e19b28d3db3573a, 2, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Finish { + Finish() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(d37d2eb2c2f80e63, 1, 0) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Resolve { + Resolve() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + CAP, + EXCEPTION, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(bbc29655fa89086e, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Release { + Release() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(ad1a6c0d7dd07497, 1, 0) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Disembargo { + Disembargo() = delete; + + class Reader; + class Builder; + class Pipeline; + struct Context; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(f964368b0fbd3711, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Disembargo::Context { + Context() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + SENDER_LOOPBACK, + RECEIVER_LOOPBACK, + ACCEPT, + PROVIDE, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(d562b4df655bdd4d, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Provide { + Provide() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9c6a046bfbc1ac5a, 1, 2) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Accept { + Accept() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(d4c9b56290554016, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Join { + Join() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(fbe1980490e001af, 1, 2) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct MessageTarget { + MessageTarget() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + IMPORTED_CAP, + PROMISED_ANSWER, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(95bc14545813fbc1, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Payload { + Payload() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9a0e61223d96743b, 0, 2) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct CapDescriptor { + CapDescriptor() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + NONE, + SENDER_HOSTED, + SENDER_PROMISE, + RECEIVER_HOSTED, + RECEIVER_ANSWER, + THIRD_PARTY_HOSTED, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(8523ddc40b86b8b0, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct PromisedAnswer { + PromisedAnswer() = delete; + + class Reader; + class Builder; + class Pipeline; + struct Op; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(d800b1d6cd6f1ca0, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct PromisedAnswer::Op { + Op() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + NOOP, + GET_POINTER_FIELD, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(f316944415569081, 1, 0) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct ThirdPartyCapDescriptor { + ThirdPartyCapDescriptor() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(d37007fde1f0027d, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Exception { + Exception() = delete; + + class Reader; + class Builder; + class Pipeline; + typedef ::capnp::schemas::Type_b28c96e23f4cbd58 Type; + + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(d625b7063acf691a, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +// ======================================================================================= + +class Message::Reader { +public: + typedef Message Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isUnimplemented() const; + inline bool hasUnimplemented() const; + inline ::capnp::rpc::Message::Reader getUnimplemented() const; + + inline bool isAbort() const; + inline bool hasAbort() const; + inline ::capnp::rpc::Exception::Reader getAbort() const; + + inline bool isCall() const; + inline bool hasCall() const; + inline ::capnp::rpc::Call::Reader getCall() const; + + inline bool isReturn() const; + inline bool hasReturn() const; + inline ::capnp::rpc::Return::Reader getReturn() const; + + inline bool isFinish() const; + inline bool hasFinish() const; + inline ::capnp::rpc::Finish::Reader getFinish() const; + + inline bool isResolve() const; + inline bool hasResolve() const; + inline ::capnp::rpc::Resolve::Reader getResolve() const; + + inline bool isRelease() const; + inline bool hasRelease() const; + inline ::capnp::rpc::Release::Reader getRelease() const; + + inline bool isObsoleteSave() const; + inline bool hasObsoleteSave() const; + inline ::capnp::AnyPointer::Reader getObsoleteSave() const; + + inline bool isBootstrap() const; + inline bool hasBootstrap() const; + inline ::capnp::rpc::Bootstrap::Reader getBootstrap() const; + + inline bool isObsoleteDelete() const; + inline bool hasObsoleteDelete() const; + inline ::capnp::AnyPointer::Reader getObsoleteDelete() const; + + inline bool isProvide() const; + inline bool hasProvide() const; + inline ::capnp::rpc::Provide::Reader getProvide() const; + + inline bool isAccept() const; + inline bool hasAccept() const; + inline ::capnp::rpc::Accept::Reader getAccept() const; + + inline bool isJoin() const; + inline bool hasJoin() const; + inline ::capnp::rpc::Join::Reader getJoin() const; + + inline bool isDisembargo() const; + inline bool hasDisembargo() const; + inline ::capnp::rpc::Disembargo::Reader getDisembargo() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Message::Builder { +public: + typedef Message Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isUnimplemented(); + inline bool hasUnimplemented(); + inline ::capnp::rpc::Message::Builder getUnimplemented(); + inline void setUnimplemented( ::capnp::rpc::Message::Reader value); + inline ::capnp::rpc::Message::Builder initUnimplemented(); + inline void adoptUnimplemented(::capnp::Orphan< ::capnp::rpc::Message>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Message> disownUnimplemented(); + + inline bool isAbort(); + inline bool hasAbort(); + inline ::capnp::rpc::Exception::Builder getAbort(); + inline void setAbort( ::capnp::rpc::Exception::Reader value); + inline ::capnp::rpc::Exception::Builder initAbort(); + inline void adoptAbort(::capnp::Orphan< ::capnp::rpc::Exception>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Exception> disownAbort(); + + inline bool isCall(); + inline bool hasCall(); + inline ::capnp::rpc::Call::Builder getCall(); + inline void setCall( ::capnp::rpc::Call::Reader value); + inline ::capnp::rpc::Call::Builder initCall(); + inline void adoptCall(::capnp::Orphan< ::capnp::rpc::Call>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Call> disownCall(); + + inline bool isReturn(); + inline bool hasReturn(); + inline ::capnp::rpc::Return::Builder getReturn(); + inline void setReturn( ::capnp::rpc::Return::Reader value); + inline ::capnp::rpc::Return::Builder initReturn(); + inline void adoptReturn(::capnp::Orphan< ::capnp::rpc::Return>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Return> disownReturn(); + + inline bool isFinish(); + inline bool hasFinish(); + inline ::capnp::rpc::Finish::Builder getFinish(); + inline void setFinish( ::capnp::rpc::Finish::Reader value); + inline ::capnp::rpc::Finish::Builder initFinish(); + inline void adoptFinish(::capnp::Orphan< ::capnp::rpc::Finish>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Finish> disownFinish(); + + inline bool isResolve(); + inline bool hasResolve(); + inline ::capnp::rpc::Resolve::Builder getResolve(); + inline void setResolve( ::capnp::rpc::Resolve::Reader value); + inline ::capnp::rpc::Resolve::Builder initResolve(); + inline void adoptResolve(::capnp::Orphan< ::capnp::rpc::Resolve>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Resolve> disownResolve(); + + inline bool isRelease(); + inline bool hasRelease(); + inline ::capnp::rpc::Release::Builder getRelease(); + inline void setRelease( ::capnp::rpc::Release::Reader value); + inline ::capnp::rpc::Release::Builder initRelease(); + inline void adoptRelease(::capnp::Orphan< ::capnp::rpc::Release>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Release> disownRelease(); + + inline bool isObsoleteSave(); + inline bool hasObsoleteSave(); + inline ::capnp::AnyPointer::Builder getObsoleteSave(); + inline ::capnp::AnyPointer::Builder initObsoleteSave(); + + inline bool isBootstrap(); + inline bool hasBootstrap(); + inline ::capnp::rpc::Bootstrap::Builder getBootstrap(); + inline void setBootstrap( ::capnp::rpc::Bootstrap::Reader value); + inline ::capnp::rpc::Bootstrap::Builder initBootstrap(); + inline void adoptBootstrap(::capnp::Orphan< ::capnp::rpc::Bootstrap>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Bootstrap> disownBootstrap(); + + inline bool isObsoleteDelete(); + inline bool hasObsoleteDelete(); + inline ::capnp::AnyPointer::Builder getObsoleteDelete(); + inline ::capnp::AnyPointer::Builder initObsoleteDelete(); + + inline bool isProvide(); + inline bool hasProvide(); + inline ::capnp::rpc::Provide::Builder getProvide(); + inline void setProvide( ::capnp::rpc::Provide::Reader value); + inline ::capnp::rpc::Provide::Builder initProvide(); + inline void adoptProvide(::capnp::Orphan< ::capnp::rpc::Provide>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Provide> disownProvide(); + + inline bool isAccept(); + inline bool hasAccept(); + inline ::capnp::rpc::Accept::Builder getAccept(); + inline void setAccept( ::capnp::rpc::Accept::Reader value); + inline ::capnp::rpc::Accept::Builder initAccept(); + inline void adoptAccept(::capnp::Orphan< ::capnp::rpc::Accept>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Accept> disownAccept(); + + inline bool isJoin(); + inline bool hasJoin(); + inline ::capnp::rpc::Join::Builder getJoin(); + inline void setJoin( ::capnp::rpc::Join::Reader value); + inline ::capnp::rpc::Join::Builder initJoin(); + inline void adoptJoin(::capnp::Orphan< ::capnp::rpc::Join>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Join> disownJoin(); + + inline bool isDisembargo(); + inline bool hasDisembargo(); + inline ::capnp::rpc::Disembargo::Builder getDisembargo(); + inline void setDisembargo( ::capnp::rpc::Disembargo::Reader value); + inline ::capnp::rpc::Disembargo::Builder initDisembargo(); + inline void adoptDisembargo(::capnp::Orphan< ::capnp::rpc::Disembargo>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Disembargo> disownDisembargo(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Message::Pipeline { +public: + typedef Message Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Bootstrap::Reader { +public: + typedef Bootstrap Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId() const; + + inline bool hasDeprecatedObjectId() const; + inline ::capnp::AnyPointer::Reader getDeprecatedObjectId() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Bootstrap::Builder { +public: + typedef Bootstrap Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId(); + inline void setQuestionId( ::uint32_t value); + + inline bool hasDeprecatedObjectId(); + inline ::capnp::AnyPointer::Builder getDeprecatedObjectId(); + inline ::capnp::AnyPointer::Builder initDeprecatedObjectId(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Bootstrap::Pipeline { +public: + typedef Bootstrap Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Call::Reader { +public: + typedef Call Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId() const; + + inline bool hasTarget() const; + inline ::capnp::rpc::MessageTarget::Reader getTarget() const; + + inline ::uint64_t getInterfaceId() const; + + inline ::uint16_t getMethodId() const; + + inline bool hasParams() const; + inline ::capnp::rpc::Payload::Reader getParams() const; + + inline typename SendResultsTo::Reader getSendResultsTo() const; + + inline bool getAllowThirdPartyTailCall() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Call::Builder { +public: + typedef Call Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId(); + inline void setQuestionId( ::uint32_t value); + + inline bool hasTarget(); + inline ::capnp::rpc::MessageTarget::Builder getTarget(); + inline void setTarget( ::capnp::rpc::MessageTarget::Reader value); + inline ::capnp::rpc::MessageTarget::Builder initTarget(); + inline void adoptTarget(::capnp::Orphan< ::capnp::rpc::MessageTarget>&& value); + inline ::capnp::Orphan< ::capnp::rpc::MessageTarget> disownTarget(); + + inline ::uint64_t getInterfaceId(); + inline void setInterfaceId( ::uint64_t value); + + inline ::uint16_t getMethodId(); + inline void setMethodId( ::uint16_t value); + + inline bool hasParams(); + inline ::capnp::rpc::Payload::Builder getParams(); + inline void setParams( ::capnp::rpc::Payload::Reader value); + inline ::capnp::rpc::Payload::Builder initParams(); + inline void adoptParams(::capnp::Orphan< ::capnp::rpc::Payload>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Payload> disownParams(); + + inline typename SendResultsTo::Builder getSendResultsTo(); + inline typename SendResultsTo::Builder initSendResultsTo(); + + inline bool getAllowThirdPartyTailCall(); + inline void setAllowThirdPartyTailCall(bool value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Call::Pipeline { +public: + typedef Call Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::rpc::MessageTarget::Pipeline getTarget(); + inline ::capnp::rpc::Payload::Pipeline getParams(); + inline typename SendResultsTo::Pipeline getSendResultsTo(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Call::SendResultsTo::Reader { +public: + typedef SendResultsTo Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isCaller() const; + inline ::capnp::Void getCaller() const; + + inline bool isYourself() const; + inline ::capnp::Void getYourself() const; + + inline bool isThirdParty() const; + inline bool hasThirdParty() const; + inline ::capnp::AnyPointer::Reader getThirdParty() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Call::SendResultsTo::Builder { +public: + typedef SendResultsTo Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isCaller(); + inline ::capnp::Void getCaller(); + inline void setCaller( ::capnp::Void value = ::capnp::VOID); + + inline bool isYourself(); + inline ::capnp::Void getYourself(); + inline void setYourself( ::capnp::Void value = ::capnp::VOID); + + inline bool isThirdParty(); + inline bool hasThirdParty(); + inline ::capnp::AnyPointer::Builder getThirdParty(); + inline ::capnp::AnyPointer::Builder initThirdParty(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Call::SendResultsTo::Pipeline { +public: + typedef SendResultsTo Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Return::Reader { +public: + typedef Return Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline ::uint32_t getAnswerId() const; + + inline bool getReleaseParamCaps() const; + + inline bool isResults() const; + inline bool hasResults() const; + inline ::capnp::rpc::Payload::Reader getResults() const; + + inline bool isException() const; + inline bool hasException() const; + inline ::capnp::rpc::Exception::Reader getException() const; + + inline bool isCanceled() const; + inline ::capnp::Void getCanceled() const; + + inline bool isResultsSentElsewhere() const; + inline ::capnp::Void getResultsSentElsewhere() const; + + inline bool isTakeFromOtherQuestion() const; + inline ::uint32_t getTakeFromOtherQuestion() const; + + inline bool isAcceptFromThirdParty() const; + inline bool hasAcceptFromThirdParty() const; + inline ::capnp::AnyPointer::Reader getAcceptFromThirdParty() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Return::Builder { +public: + typedef Return Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline ::uint32_t getAnswerId(); + inline void setAnswerId( ::uint32_t value); + + inline bool getReleaseParamCaps(); + inline void setReleaseParamCaps(bool value); + + inline bool isResults(); + inline bool hasResults(); + inline ::capnp::rpc::Payload::Builder getResults(); + inline void setResults( ::capnp::rpc::Payload::Reader value); + inline ::capnp::rpc::Payload::Builder initResults(); + inline void adoptResults(::capnp::Orphan< ::capnp::rpc::Payload>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Payload> disownResults(); + + inline bool isException(); + inline bool hasException(); + inline ::capnp::rpc::Exception::Builder getException(); + inline void setException( ::capnp::rpc::Exception::Reader value); + inline ::capnp::rpc::Exception::Builder initException(); + inline void adoptException(::capnp::Orphan< ::capnp::rpc::Exception>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Exception> disownException(); + + inline bool isCanceled(); + inline ::capnp::Void getCanceled(); + inline void setCanceled( ::capnp::Void value = ::capnp::VOID); + + inline bool isResultsSentElsewhere(); + inline ::capnp::Void getResultsSentElsewhere(); + inline void setResultsSentElsewhere( ::capnp::Void value = ::capnp::VOID); + + inline bool isTakeFromOtherQuestion(); + inline ::uint32_t getTakeFromOtherQuestion(); + inline void setTakeFromOtherQuestion( ::uint32_t value); + + inline bool isAcceptFromThirdParty(); + inline bool hasAcceptFromThirdParty(); + inline ::capnp::AnyPointer::Builder getAcceptFromThirdParty(); + inline ::capnp::AnyPointer::Builder initAcceptFromThirdParty(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Return::Pipeline { +public: + typedef Return Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Finish::Reader { +public: + typedef Finish Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId() const; + + inline bool getReleaseResultCaps() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Finish::Builder { +public: + typedef Finish Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId(); + inline void setQuestionId( ::uint32_t value); + + inline bool getReleaseResultCaps(); + inline void setReleaseResultCaps(bool value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Finish::Pipeline { +public: + typedef Finish Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Resolve::Reader { +public: + typedef Resolve Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline ::uint32_t getPromiseId() const; + + inline bool isCap() const; + inline bool hasCap() const; + inline ::capnp::rpc::CapDescriptor::Reader getCap() const; + + inline bool isException() const; + inline bool hasException() const; + inline ::capnp::rpc::Exception::Reader getException() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Resolve::Builder { +public: + typedef Resolve Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline ::uint32_t getPromiseId(); + inline void setPromiseId( ::uint32_t value); + + inline bool isCap(); + inline bool hasCap(); + inline ::capnp::rpc::CapDescriptor::Builder getCap(); + inline void setCap( ::capnp::rpc::CapDescriptor::Reader value); + inline ::capnp::rpc::CapDescriptor::Builder initCap(); + inline void adoptCap(::capnp::Orphan< ::capnp::rpc::CapDescriptor>&& value); + inline ::capnp::Orphan< ::capnp::rpc::CapDescriptor> disownCap(); + + inline bool isException(); + inline bool hasException(); + inline ::capnp::rpc::Exception::Builder getException(); + inline void setException( ::capnp::rpc::Exception::Reader value); + inline ::capnp::rpc::Exception::Builder initException(); + inline void adoptException(::capnp::Orphan< ::capnp::rpc::Exception>&& value); + inline ::capnp::Orphan< ::capnp::rpc::Exception> disownException(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Resolve::Pipeline { +public: + typedef Resolve Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Release::Reader { +public: + typedef Release Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getId() const; + + inline ::uint32_t getReferenceCount() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Release::Builder { +public: + typedef Release Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getId(); + inline void setId( ::uint32_t value); + + inline ::uint32_t getReferenceCount(); + inline void setReferenceCount( ::uint32_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Release::Pipeline { +public: + typedef Release Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Disembargo::Reader { +public: + typedef Disembargo Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasTarget() const; + inline ::capnp::rpc::MessageTarget::Reader getTarget() const; + + inline typename Context::Reader getContext() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Disembargo::Builder { +public: + typedef Disembargo Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasTarget(); + inline ::capnp::rpc::MessageTarget::Builder getTarget(); + inline void setTarget( ::capnp::rpc::MessageTarget::Reader value); + inline ::capnp::rpc::MessageTarget::Builder initTarget(); + inline void adoptTarget(::capnp::Orphan< ::capnp::rpc::MessageTarget>&& value); + inline ::capnp::Orphan< ::capnp::rpc::MessageTarget> disownTarget(); + + inline typename Context::Builder getContext(); + inline typename Context::Builder initContext(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Disembargo::Pipeline { +public: + typedef Disembargo Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::rpc::MessageTarget::Pipeline getTarget(); + inline typename Context::Pipeline getContext(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Disembargo::Context::Reader { +public: + typedef Context Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isSenderLoopback() const; + inline ::uint32_t getSenderLoopback() const; + + inline bool isReceiverLoopback() const; + inline ::uint32_t getReceiverLoopback() const; + + inline bool isAccept() const; + inline ::capnp::Void getAccept() const; + + inline bool isProvide() const; + inline ::uint32_t getProvide() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Disembargo::Context::Builder { +public: + typedef Context Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isSenderLoopback(); + inline ::uint32_t getSenderLoopback(); + inline void setSenderLoopback( ::uint32_t value); + + inline bool isReceiverLoopback(); + inline ::uint32_t getReceiverLoopback(); + inline void setReceiverLoopback( ::uint32_t value); + + inline bool isAccept(); + inline ::capnp::Void getAccept(); + inline void setAccept( ::capnp::Void value = ::capnp::VOID); + + inline bool isProvide(); + inline ::uint32_t getProvide(); + inline void setProvide( ::uint32_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Disembargo::Context::Pipeline { +public: + typedef Context Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Provide::Reader { +public: + typedef Provide Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId() const; + + inline bool hasTarget() const; + inline ::capnp::rpc::MessageTarget::Reader getTarget() const; + + inline bool hasRecipient() const; + inline ::capnp::AnyPointer::Reader getRecipient() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Provide::Builder { +public: + typedef Provide Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId(); + inline void setQuestionId( ::uint32_t value); + + inline bool hasTarget(); + inline ::capnp::rpc::MessageTarget::Builder getTarget(); + inline void setTarget( ::capnp::rpc::MessageTarget::Reader value); + inline ::capnp::rpc::MessageTarget::Builder initTarget(); + inline void adoptTarget(::capnp::Orphan< ::capnp::rpc::MessageTarget>&& value); + inline ::capnp::Orphan< ::capnp::rpc::MessageTarget> disownTarget(); + + inline bool hasRecipient(); + inline ::capnp::AnyPointer::Builder getRecipient(); + inline ::capnp::AnyPointer::Builder initRecipient(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Provide::Pipeline { +public: + typedef Provide Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::rpc::MessageTarget::Pipeline getTarget(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Accept::Reader { +public: + typedef Accept Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId() const; + + inline bool hasProvision() const; + inline ::capnp::AnyPointer::Reader getProvision() const; + + inline bool getEmbargo() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Accept::Builder { +public: + typedef Accept Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId(); + inline void setQuestionId( ::uint32_t value); + + inline bool hasProvision(); + inline ::capnp::AnyPointer::Builder getProvision(); + inline ::capnp::AnyPointer::Builder initProvision(); + + inline bool getEmbargo(); + inline void setEmbargo(bool value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Accept::Pipeline { +public: + typedef Accept Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Join::Reader { +public: + typedef Join Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId() const; + + inline bool hasTarget() const; + inline ::capnp::rpc::MessageTarget::Reader getTarget() const; + + inline bool hasKeyPart() const; + inline ::capnp::AnyPointer::Reader getKeyPart() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Join::Builder { +public: + typedef Join Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId(); + inline void setQuestionId( ::uint32_t value); + + inline bool hasTarget(); + inline ::capnp::rpc::MessageTarget::Builder getTarget(); + inline void setTarget( ::capnp::rpc::MessageTarget::Reader value); + inline ::capnp::rpc::MessageTarget::Builder initTarget(); + inline void adoptTarget(::capnp::Orphan< ::capnp::rpc::MessageTarget>&& value); + inline ::capnp::Orphan< ::capnp::rpc::MessageTarget> disownTarget(); + + inline bool hasKeyPart(); + inline ::capnp::AnyPointer::Builder getKeyPart(); + inline ::capnp::AnyPointer::Builder initKeyPart(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Join::Pipeline { +public: + typedef Join Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::rpc::MessageTarget::Pipeline getTarget(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class MessageTarget::Reader { +public: + typedef MessageTarget Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isImportedCap() const; + inline ::uint32_t getImportedCap() const; + + inline bool isPromisedAnswer() const; + inline bool hasPromisedAnswer() const; + inline ::capnp::rpc::PromisedAnswer::Reader getPromisedAnswer() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class MessageTarget::Builder { +public: + typedef MessageTarget Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isImportedCap(); + inline ::uint32_t getImportedCap(); + inline void setImportedCap( ::uint32_t value); + + inline bool isPromisedAnswer(); + inline bool hasPromisedAnswer(); + inline ::capnp::rpc::PromisedAnswer::Builder getPromisedAnswer(); + inline void setPromisedAnswer( ::capnp::rpc::PromisedAnswer::Reader value); + inline ::capnp::rpc::PromisedAnswer::Builder initPromisedAnswer(); + inline void adoptPromisedAnswer(::capnp::Orphan< ::capnp::rpc::PromisedAnswer>&& value); + inline ::capnp::Orphan< ::capnp::rpc::PromisedAnswer> disownPromisedAnswer(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class MessageTarget::Pipeline { +public: + typedef MessageTarget Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Payload::Reader { +public: + typedef Payload Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasContent() const; + inline ::capnp::AnyPointer::Reader getContent() const; + + inline bool hasCapTable() const; + inline ::capnp::List< ::capnp::rpc::CapDescriptor>::Reader getCapTable() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Payload::Builder { +public: + typedef Payload Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasContent(); + inline ::capnp::AnyPointer::Builder getContent(); + inline ::capnp::AnyPointer::Builder initContent(); + + inline bool hasCapTable(); + inline ::capnp::List< ::capnp::rpc::CapDescriptor>::Builder getCapTable(); + inline void setCapTable( ::capnp::List< ::capnp::rpc::CapDescriptor>::Reader value); + inline ::capnp::List< ::capnp::rpc::CapDescriptor>::Builder initCapTable(unsigned int size); + inline void adoptCapTable(::capnp::Orphan< ::capnp::List< ::capnp::rpc::CapDescriptor>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::rpc::CapDescriptor>> disownCapTable(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Payload::Pipeline { +public: + typedef Payload Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class CapDescriptor::Reader { +public: + typedef CapDescriptor Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isNone() const; + inline ::capnp::Void getNone() const; + + inline bool isSenderHosted() const; + inline ::uint32_t getSenderHosted() const; + + inline bool isSenderPromise() const; + inline ::uint32_t getSenderPromise() const; + + inline bool isReceiverHosted() const; + inline ::uint32_t getReceiverHosted() const; + + inline bool isReceiverAnswer() const; + inline bool hasReceiverAnswer() const; + inline ::capnp::rpc::PromisedAnswer::Reader getReceiverAnswer() const; + + inline bool isThirdPartyHosted() const; + inline bool hasThirdPartyHosted() const; + inline ::capnp::rpc::ThirdPartyCapDescriptor::Reader getThirdPartyHosted() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class CapDescriptor::Builder { +public: + typedef CapDescriptor Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isNone(); + inline ::capnp::Void getNone(); + inline void setNone( ::capnp::Void value = ::capnp::VOID); + + inline bool isSenderHosted(); + inline ::uint32_t getSenderHosted(); + inline void setSenderHosted( ::uint32_t value); + + inline bool isSenderPromise(); + inline ::uint32_t getSenderPromise(); + inline void setSenderPromise( ::uint32_t value); + + inline bool isReceiverHosted(); + inline ::uint32_t getReceiverHosted(); + inline void setReceiverHosted( ::uint32_t value); + + inline bool isReceiverAnswer(); + inline bool hasReceiverAnswer(); + inline ::capnp::rpc::PromisedAnswer::Builder getReceiverAnswer(); + inline void setReceiverAnswer( ::capnp::rpc::PromisedAnswer::Reader value); + inline ::capnp::rpc::PromisedAnswer::Builder initReceiverAnswer(); + inline void adoptReceiverAnswer(::capnp::Orphan< ::capnp::rpc::PromisedAnswer>&& value); + inline ::capnp::Orphan< ::capnp::rpc::PromisedAnswer> disownReceiverAnswer(); + + inline bool isThirdPartyHosted(); + inline bool hasThirdPartyHosted(); + inline ::capnp::rpc::ThirdPartyCapDescriptor::Builder getThirdPartyHosted(); + inline void setThirdPartyHosted( ::capnp::rpc::ThirdPartyCapDescriptor::Reader value); + inline ::capnp::rpc::ThirdPartyCapDescriptor::Builder initThirdPartyHosted(); + inline void adoptThirdPartyHosted(::capnp::Orphan< ::capnp::rpc::ThirdPartyCapDescriptor>&& value); + inline ::capnp::Orphan< ::capnp::rpc::ThirdPartyCapDescriptor> disownThirdPartyHosted(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class CapDescriptor::Pipeline { +public: + typedef CapDescriptor Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class PromisedAnswer::Reader { +public: + typedef PromisedAnswer Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId() const; + + inline bool hasTransform() const; + inline ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>::Reader getTransform() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class PromisedAnswer::Builder { +public: + typedef PromisedAnswer Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getQuestionId(); + inline void setQuestionId( ::uint32_t value); + + inline bool hasTransform(); + inline ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>::Builder getTransform(); + inline void setTransform( ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>::Reader value); + inline ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>::Builder initTransform(unsigned int size); + inline void adoptTransform(::capnp::Orphan< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>> disownTransform(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class PromisedAnswer::Pipeline { +public: + typedef PromisedAnswer Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class PromisedAnswer::Op::Reader { +public: + typedef Op Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isNoop() const; + inline ::capnp::Void getNoop() const; + + inline bool isGetPointerField() const; + inline ::uint16_t getGetPointerField() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class PromisedAnswer::Op::Builder { +public: + typedef Op Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isNoop(); + inline ::capnp::Void getNoop(); + inline void setNoop( ::capnp::Void value = ::capnp::VOID); + + inline bool isGetPointerField(); + inline ::uint16_t getGetPointerField(); + inline void setGetPointerField( ::uint16_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class PromisedAnswer::Op::Pipeline { +public: + typedef Op Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class ThirdPartyCapDescriptor::Reader { +public: + typedef ThirdPartyCapDescriptor Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasId() const; + inline ::capnp::AnyPointer::Reader getId() const; + + inline ::uint32_t getVineId() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class ThirdPartyCapDescriptor::Builder { +public: + typedef ThirdPartyCapDescriptor Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasId(); + inline ::capnp::AnyPointer::Builder getId(); + inline ::capnp::AnyPointer::Builder initId(); + + inline ::uint32_t getVineId(); + inline void setVineId( ::uint32_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class ThirdPartyCapDescriptor::Pipeline { +public: + typedef ThirdPartyCapDescriptor Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Exception::Reader { +public: + typedef Exception Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasReason() const; + inline ::capnp::Text::Reader getReason() const; + + inline bool getObsoleteIsCallersFault() const; + + inline ::uint16_t getObsoleteDurability() const; + + inline ::capnp::rpc::Exception::Type getType() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Exception::Builder { +public: + typedef Exception Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasReason(); + inline ::capnp::Text::Builder getReason(); + inline void setReason( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initReason(unsigned int size); + inline void adoptReason(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownReason(); + + inline bool getObsoleteIsCallersFault(); + inline void setObsoleteIsCallersFault(bool value); + + inline ::uint16_t getObsoleteDurability(); + inline void setObsoleteDurability( ::uint16_t value); + + inline ::capnp::rpc::Exception::Type getType(); + inline void setType( ::capnp::rpc::Exception::Type value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Exception::Pipeline { +public: + typedef Exception Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +// ======================================================================================= + +inline ::capnp::rpc::Message::Which Message::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline ::capnp::rpc::Message::Which Message::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline bool Message::Reader::isUnimplemented() const { + return which() == Message::UNIMPLEMENTED; +} +inline bool Message::Builder::isUnimplemented() { + return which() == Message::UNIMPLEMENTED; +} +inline bool Message::Reader::hasUnimplemented() const { + if (which() != Message::UNIMPLEMENTED) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasUnimplemented() { + if (which() != Message::UNIMPLEMENTED) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Message::Reader Message::Reader::getUnimplemented() const { + KJ_IREQUIRE((which() == Message::UNIMPLEMENTED), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Message>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Message::Builder Message::Builder::getUnimplemented() { + KJ_IREQUIRE((which() == Message::UNIMPLEMENTED), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Message>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setUnimplemented( ::capnp::rpc::Message::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::UNIMPLEMENTED); + ::capnp::_::PointerHelpers< ::capnp::rpc::Message>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Message::Builder Message::Builder::initUnimplemented() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::UNIMPLEMENTED); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Message>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptUnimplemented( + ::capnp::Orphan< ::capnp::rpc::Message>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::UNIMPLEMENTED); + ::capnp::_::PointerHelpers< ::capnp::rpc::Message>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Message> Message::Builder::disownUnimplemented() { + KJ_IREQUIRE((which() == Message::UNIMPLEMENTED), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Message>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isAbort() const { + return which() == Message::ABORT; +} +inline bool Message::Builder::isAbort() { + return which() == Message::ABORT; +} +inline bool Message::Reader::hasAbort() const { + if (which() != Message::ABORT) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasAbort() { + if (which() != Message::ABORT) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Exception::Reader Message::Reader::getAbort() const { + KJ_IREQUIRE((which() == Message::ABORT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Exception::Builder Message::Builder::getAbort() { + KJ_IREQUIRE((which() == Message::ABORT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setAbort( ::capnp::rpc::Exception::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::ABORT); + ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Exception::Builder Message::Builder::initAbort() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::ABORT); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptAbort( + ::capnp::Orphan< ::capnp::rpc::Exception>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::ABORT); + ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Exception> Message::Builder::disownAbort() { + KJ_IREQUIRE((which() == Message::ABORT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isCall() const { + return which() == Message::CALL; +} +inline bool Message::Builder::isCall() { + return which() == Message::CALL; +} +inline bool Message::Reader::hasCall() const { + if (which() != Message::CALL) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasCall() { + if (which() != Message::CALL) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Call::Reader Message::Reader::getCall() const { + KJ_IREQUIRE((which() == Message::CALL), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Call>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Call::Builder Message::Builder::getCall() { + KJ_IREQUIRE((which() == Message::CALL), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Call>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setCall( ::capnp::rpc::Call::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::CALL); + ::capnp::_::PointerHelpers< ::capnp::rpc::Call>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Call::Builder Message::Builder::initCall() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::CALL); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Call>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptCall( + ::capnp::Orphan< ::capnp::rpc::Call>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::CALL); + ::capnp::_::PointerHelpers< ::capnp::rpc::Call>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Call> Message::Builder::disownCall() { + KJ_IREQUIRE((which() == Message::CALL), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Call>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isReturn() const { + return which() == Message::RETURN; +} +inline bool Message::Builder::isReturn() { + return which() == Message::RETURN; +} +inline bool Message::Reader::hasReturn() const { + if (which() != Message::RETURN) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasReturn() { + if (which() != Message::RETURN) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Return::Reader Message::Reader::getReturn() const { + KJ_IREQUIRE((which() == Message::RETURN), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Return>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Return::Builder Message::Builder::getReturn() { + KJ_IREQUIRE((which() == Message::RETURN), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Return>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setReturn( ::capnp::rpc::Return::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::RETURN); + ::capnp::_::PointerHelpers< ::capnp::rpc::Return>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Return::Builder Message::Builder::initReturn() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::RETURN); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Return>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptReturn( + ::capnp::Orphan< ::capnp::rpc::Return>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::RETURN); + ::capnp::_::PointerHelpers< ::capnp::rpc::Return>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Return> Message::Builder::disownReturn() { + KJ_IREQUIRE((which() == Message::RETURN), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Return>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isFinish() const { + return which() == Message::FINISH; +} +inline bool Message::Builder::isFinish() { + return which() == Message::FINISH; +} +inline bool Message::Reader::hasFinish() const { + if (which() != Message::FINISH) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasFinish() { + if (which() != Message::FINISH) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Finish::Reader Message::Reader::getFinish() const { + KJ_IREQUIRE((which() == Message::FINISH), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Finish>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Finish::Builder Message::Builder::getFinish() { + KJ_IREQUIRE((which() == Message::FINISH), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Finish>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setFinish( ::capnp::rpc::Finish::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::FINISH); + ::capnp::_::PointerHelpers< ::capnp::rpc::Finish>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Finish::Builder Message::Builder::initFinish() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::FINISH); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Finish>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptFinish( + ::capnp::Orphan< ::capnp::rpc::Finish>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::FINISH); + ::capnp::_::PointerHelpers< ::capnp::rpc::Finish>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Finish> Message::Builder::disownFinish() { + KJ_IREQUIRE((which() == Message::FINISH), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Finish>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isResolve() const { + return which() == Message::RESOLVE; +} +inline bool Message::Builder::isResolve() { + return which() == Message::RESOLVE; +} +inline bool Message::Reader::hasResolve() const { + if (which() != Message::RESOLVE) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasResolve() { + if (which() != Message::RESOLVE) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Resolve::Reader Message::Reader::getResolve() const { + KJ_IREQUIRE((which() == Message::RESOLVE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Resolve>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Resolve::Builder Message::Builder::getResolve() { + KJ_IREQUIRE((which() == Message::RESOLVE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Resolve>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setResolve( ::capnp::rpc::Resolve::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::RESOLVE); + ::capnp::_::PointerHelpers< ::capnp::rpc::Resolve>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Resolve::Builder Message::Builder::initResolve() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::RESOLVE); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Resolve>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptResolve( + ::capnp::Orphan< ::capnp::rpc::Resolve>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::RESOLVE); + ::capnp::_::PointerHelpers< ::capnp::rpc::Resolve>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Resolve> Message::Builder::disownResolve() { + KJ_IREQUIRE((which() == Message::RESOLVE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Resolve>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isRelease() const { + return which() == Message::RELEASE; +} +inline bool Message::Builder::isRelease() { + return which() == Message::RELEASE; +} +inline bool Message::Reader::hasRelease() const { + if (which() != Message::RELEASE) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasRelease() { + if (which() != Message::RELEASE) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Release::Reader Message::Reader::getRelease() const { + KJ_IREQUIRE((which() == Message::RELEASE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Release>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Release::Builder Message::Builder::getRelease() { + KJ_IREQUIRE((which() == Message::RELEASE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Release>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setRelease( ::capnp::rpc::Release::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::RELEASE); + ::capnp::_::PointerHelpers< ::capnp::rpc::Release>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Release::Builder Message::Builder::initRelease() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::RELEASE); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Release>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptRelease( + ::capnp::Orphan< ::capnp::rpc::Release>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::RELEASE); + ::capnp::_::PointerHelpers< ::capnp::rpc::Release>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Release> Message::Builder::disownRelease() { + KJ_IREQUIRE((which() == Message::RELEASE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Release>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isObsoleteSave() const { + return which() == Message::OBSOLETE_SAVE; +} +inline bool Message::Builder::isObsoleteSave() { + return which() == Message::OBSOLETE_SAVE; +} +inline bool Message::Reader::hasObsoleteSave() const { + if (which() != Message::OBSOLETE_SAVE) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasObsoleteSave() { + if (which() != Message::OBSOLETE_SAVE) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Message::Reader::getObsoleteSave() const { + KJ_IREQUIRE((which() == Message::OBSOLETE_SAVE), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Message::Builder::getObsoleteSave() { + KJ_IREQUIRE((which() == Message::OBSOLETE_SAVE), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Message::Builder::initObsoleteSave() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::OBSOLETE_SAVE); + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline bool Message::Reader::isBootstrap() const { + return which() == Message::BOOTSTRAP; +} +inline bool Message::Builder::isBootstrap() { + return which() == Message::BOOTSTRAP; +} +inline bool Message::Reader::hasBootstrap() const { + if (which() != Message::BOOTSTRAP) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasBootstrap() { + if (which() != Message::BOOTSTRAP) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Bootstrap::Reader Message::Reader::getBootstrap() const { + KJ_IREQUIRE((which() == Message::BOOTSTRAP), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Bootstrap>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Bootstrap::Builder Message::Builder::getBootstrap() { + KJ_IREQUIRE((which() == Message::BOOTSTRAP), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Bootstrap>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setBootstrap( ::capnp::rpc::Bootstrap::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::BOOTSTRAP); + ::capnp::_::PointerHelpers< ::capnp::rpc::Bootstrap>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Bootstrap::Builder Message::Builder::initBootstrap() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::BOOTSTRAP); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Bootstrap>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptBootstrap( + ::capnp::Orphan< ::capnp::rpc::Bootstrap>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::BOOTSTRAP); + ::capnp::_::PointerHelpers< ::capnp::rpc::Bootstrap>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Bootstrap> Message::Builder::disownBootstrap() { + KJ_IREQUIRE((which() == Message::BOOTSTRAP), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Bootstrap>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isObsoleteDelete() const { + return which() == Message::OBSOLETE_DELETE; +} +inline bool Message::Builder::isObsoleteDelete() { + return which() == Message::OBSOLETE_DELETE; +} +inline bool Message::Reader::hasObsoleteDelete() const { + if (which() != Message::OBSOLETE_DELETE) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasObsoleteDelete() { + if (which() != Message::OBSOLETE_DELETE) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Message::Reader::getObsoleteDelete() const { + KJ_IREQUIRE((which() == Message::OBSOLETE_DELETE), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Message::Builder::getObsoleteDelete() { + KJ_IREQUIRE((which() == Message::OBSOLETE_DELETE), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Message::Builder::initObsoleteDelete() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::OBSOLETE_DELETE); + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline bool Message::Reader::isProvide() const { + return which() == Message::PROVIDE; +} +inline bool Message::Builder::isProvide() { + return which() == Message::PROVIDE; +} +inline bool Message::Reader::hasProvide() const { + if (which() != Message::PROVIDE) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasProvide() { + if (which() != Message::PROVIDE) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Provide::Reader Message::Reader::getProvide() const { + KJ_IREQUIRE((which() == Message::PROVIDE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Provide>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Provide::Builder Message::Builder::getProvide() { + KJ_IREQUIRE((which() == Message::PROVIDE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Provide>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setProvide( ::capnp::rpc::Provide::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::PROVIDE); + ::capnp::_::PointerHelpers< ::capnp::rpc::Provide>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Provide::Builder Message::Builder::initProvide() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::PROVIDE); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Provide>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptProvide( + ::capnp::Orphan< ::capnp::rpc::Provide>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::PROVIDE); + ::capnp::_::PointerHelpers< ::capnp::rpc::Provide>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Provide> Message::Builder::disownProvide() { + KJ_IREQUIRE((which() == Message::PROVIDE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Provide>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isAccept() const { + return which() == Message::ACCEPT; +} +inline bool Message::Builder::isAccept() { + return which() == Message::ACCEPT; +} +inline bool Message::Reader::hasAccept() const { + if (which() != Message::ACCEPT) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasAccept() { + if (which() != Message::ACCEPT) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Accept::Reader Message::Reader::getAccept() const { + KJ_IREQUIRE((which() == Message::ACCEPT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Accept>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Accept::Builder Message::Builder::getAccept() { + KJ_IREQUIRE((which() == Message::ACCEPT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Accept>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setAccept( ::capnp::rpc::Accept::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::ACCEPT); + ::capnp::_::PointerHelpers< ::capnp::rpc::Accept>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Accept::Builder Message::Builder::initAccept() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::ACCEPT); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Accept>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptAccept( + ::capnp::Orphan< ::capnp::rpc::Accept>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::ACCEPT); + ::capnp::_::PointerHelpers< ::capnp::rpc::Accept>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Accept> Message::Builder::disownAccept() { + KJ_IREQUIRE((which() == Message::ACCEPT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Accept>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isJoin() const { + return which() == Message::JOIN; +} +inline bool Message::Builder::isJoin() { + return which() == Message::JOIN; +} +inline bool Message::Reader::hasJoin() const { + if (which() != Message::JOIN) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasJoin() { + if (which() != Message::JOIN) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Join::Reader Message::Reader::getJoin() const { + KJ_IREQUIRE((which() == Message::JOIN), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Join>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Join::Builder Message::Builder::getJoin() { + KJ_IREQUIRE((which() == Message::JOIN), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Join>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setJoin( ::capnp::rpc::Join::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::JOIN); + ::capnp::_::PointerHelpers< ::capnp::rpc::Join>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Join::Builder Message::Builder::initJoin() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::JOIN); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Join>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptJoin( + ::capnp::Orphan< ::capnp::rpc::Join>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::JOIN); + ::capnp::_::PointerHelpers< ::capnp::rpc::Join>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Join> Message::Builder::disownJoin() { + KJ_IREQUIRE((which() == Message::JOIN), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Join>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Message::Reader::isDisembargo() const { + return which() == Message::DISEMBARGO; +} +inline bool Message::Builder::isDisembargo() { + return which() == Message::DISEMBARGO; +} +inline bool Message::Reader::hasDisembargo() const { + if (which() != Message::DISEMBARGO) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Message::Builder::hasDisembargo() { + if (which() != Message::DISEMBARGO) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Disembargo::Reader Message::Reader::getDisembargo() const { + KJ_IREQUIRE((which() == Message::DISEMBARGO), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Disembargo>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Disembargo::Builder Message::Builder::getDisembargo() { + KJ_IREQUIRE((which() == Message::DISEMBARGO), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Disembargo>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::setDisembargo( ::capnp::rpc::Disembargo::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::DISEMBARGO); + ::capnp::_::PointerHelpers< ::capnp::rpc::Disembargo>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Disembargo::Builder Message::Builder::initDisembargo() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::DISEMBARGO); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Disembargo>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Message::Builder::adoptDisembargo( + ::capnp::Orphan< ::capnp::rpc::Disembargo>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Message::DISEMBARGO); + ::capnp::_::PointerHelpers< ::capnp::rpc::Disembargo>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Disembargo> Message::Builder::disownDisembargo() { + KJ_IREQUIRE((which() == Message::DISEMBARGO), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Disembargo>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint32_t Bootstrap::Reader::getQuestionId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Bootstrap::Builder::getQuestionId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Bootstrap::Builder::setQuestionId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Bootstrap::Reader::hasDeprecatedObjectId() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Bootstrap::Builder::hasDeprecatedObjectId() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Bootstrap::Reader::getDeprecatedObjectId() const { + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Bootstrap::Builder::getDeprecatedObjectId() { + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Bootstrap::Builder::initDeprecatedObjectId() { + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline ::uint32_t Call::Reader::getQuestionId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Call::Builder::getQuestionId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Call::Builder::setQuestionId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Call::Reader::hasTarget() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Call::Builder::hasTarget() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::MessageTarget::Reader Call::Reader::getTarget() const { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::MessageTarget::Builder Call::Builder::getTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::rpc::MessageTarget::Pipeline Call::Pipeline::getTarget() { + return ::capnp::rpc::MessageTarget::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Call::Builder::setTarget( ::capnp::rpc::MessageTarget::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::MessageTarget::Builder Call::Builder::initTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Call::Builder::adoptTarget( + ::capnp::Orphan< ::capnp::rpc::MessageTarget>&& value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::MessageTarget> Call::Builder::disownTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint64_t Call::Reader::getInterfaceId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Call::Builder::getInterfaceId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Call::Builder::setInterfaceId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline ::uint16_t Call::Reader::getMethodId() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Call::Builder::getMethodId() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Call::Builder::setMethodId( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline bool Call::Reader::hasParams() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool Call::Builder::hasParams() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Payload::Reader Call::Reader::getParams() const { + return ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Payload::Builder Call::Builder::getParams() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::rpc::Payload::Pipeline Call::Pipeline::getParams() { + return ::capnp::rpc::Payload::Pipeline(_typeless.getPointerField(1)); +} +#endif // !CAPNP_LITE +inline void Call::Builder::setParams( ::capnp::rpc::Payload::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Payload::Builder Call::Builder::initParams() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void Call::Builder::adoptParams( + ::capnp::Orphan< ::capnp::rpc::Payload>&& value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Payload> Call::Builder::disownParams() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline typename Call::SendResultsTo::Reader Call::Reader::getSendResultsTo() const { + return typename Call::SendResultsTo::Reader(_reader); +} +inline typename Call::SendResultsTo::Builder Call::Builder::getSendResultsTo() { + return typename Call::SendResultsTo::Builder(_builder); +} +#if !CAPNP_LITE +inline typename Call::SendResultsTo::Pipeline Call::Pipeline::getSendResultsTo() { + return typename Call::SendResultsTo::Pipeline(_typeless.noop()); +} +#endif // !CAPNP_LITE +inline typename Call::SendResultsTo::Builder Call::Builder::initSendResultsTo() { + _builder.setDataField< ::uint16_t>(::capnp::bounded<3>() * ::capnp::ELEMENTS, 0); + _builder.getPointerField(::capnp::bounded<2>() * ::capnp::POINTERS).clear(); + return typename Call::SendResultsTo::Builder(_builder); +} +inline bool Call::Reader::getAllowThirdPartyTailCall() const { + return _reader.getDataField( + ::capnp::bounded<128>() * ::capnp::ELEMENTS); +} + +inline bool Call::Builder::getAllowThirdPartyTailCall() { + return _builder.getDataField( + ::capnp::bounded<128>() * ::capnp::ELEMENTS); +} +inline void Call::Builder::setAllowThirdPartyTailCall(bool value) { + _builder.setDataField( + ::capnp::bounded<128>() * ::capnp::ELEMENTS, value); +} + +inline ::capnp::rpc::Call::SendResultsTo::Which Call::SendResultsTo::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS); +} +inline ::capnp::rpc::Call::SendResultsTo::Which Call::SendResultsTo::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS); +} + +inline bool Call::SendResultsTo::Reader::isCaller() const { + return which() == Call::SendResultsTo::CALLER; +} +inline bool Call::SendResultsTo::Builder::isCaller() { + return which() == Call::SendResultsTo::CALLER; +} +inline ::capnp::Void Call::SendResultsTo::Reader::getCaller() const { + KJ_IREQUIRE((which() == Call::SendResultsTo::CALLER), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Call::SendResultsTo::Builder::getCaller() { + KJ_IREQUIRE((which() == Call::SendResultsTo::CALLER), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Call::SendResultsTo::Builder::setCaller( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Call::SendResultsTo::CALLER); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Call::SendResultsTo::Reader::isYourself() const { + return which() == Call::SendResultsTo::YOURSELF; +} +inline bool Call::SendResultsTo::Builder::isYourself() { + return which() == Call::SendResultsTo::YOURSELF; +} +inline ::capnp::Void Call::SendResultsTo::Reader::getYourself() const { + KJ_IREQUIRE((which() == Call::SendResultsTo::YOURSELF), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Call::SendResultsTo::Builder::getYourself() { + KJ_IREQUIRE((which() == Call::SendResultsTo::YOURSELF), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Call::SendResultsTo::Builder::setYourself( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Call::SendResultsTo::YOURSELF); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Call::SendResultsTo::Reader::isThirdParty() const { + return which() == Call::SendResultsTo::THIRD_PARTY; +} +inline bool Call::SendResultsTo::Builder::isThirdParty() { + return which() == Call::SendResultsTo::THIRD_PARTY; +} +inline bool Call::SendResultsTo::Reader::hasThirdParty() const { + if (which() != Call::SendResultsTo::THIRD_PARTY) return false; + return !_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline bool Call::SendResultsTo::Builder::hasThirdParty() { + if (which() != Call::SendResultsTo::THIRD_PARTY) return false; + return !_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Call::SendResultsTo::Reader::getThirdParty() const { + KJ_IREQUIRE((which() == Call::SendResultsTo::THIRD_PARTY), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Call::SendResultsTo::Builder::getThirdParty() { + KJ_IREQUIRE((which() == Call::SendResultsTo::THIRD_PARTY), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Call::SendResultsTo::Builder::initThirdParty() { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Call::SendResultsTo::THIRD_PARTY); + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline ::capnp::rpc::Return::Which Return::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS); +} +inline ::capnp::rpc::Return::Which Return::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Return::Reader::getAnswerId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Return::Builder::getAnswerId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Return::Builder::setAnswerId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Return::Reader::getReleaseParamCaps() const { + return _reader.getDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS, true); +} + +inline bool Return::Builder::getReleaseParamCaps() { + return _builder.getDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS, true); +} +inline void Return::Builder::setReleaseParamCaps(bool value) { + _builder.setDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS, value, true); +} + +inline bool Return::Reader::isResults() const { + return which() == Return::RESULTS; +} +inline bool Return::Builder::isResults() { + return which() == Return::RESULTS; +} +inline bool Return::Reader::hasResults() const { + if (which() != Return::RESULTS) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Return::Builder::hasResults() { + if (which() != Return::RESULTS) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Payload::Reader Return::Reader::getResults() const { + KJ_IREQUIRE((which() == Return::RESULTS), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Payload::Builder Return::Builder::getResults() { + KJ_IREQUIRE((which() == Return::RESULTS), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Return::Builder::setResults( ::capnp::rpc::Payload::Reader value) { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::RESULTS); + ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Payload::Builder Return::Builder::initResults() { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::RESULTS); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Return::Builder::adoptResults( + ::capnp::Orphan< ::capnp::rpc::Payload>&& value) { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::RESULTS); + ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Payload> Return::Builder::disownResults() { + KJ_IREQUIRE((which() == Return::RESULTS), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Payload>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Return::Reader::isException() const { + return which() == Return::EXCEPTION; +} +inline bool Return::Builder::isException() { + return which() == Return::EXCEPTION; +} +inline bool Return::Reader::hasException() const { + if (which() != Return::EXCEPTION) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Return::Builder::hasException() { + if (which() != Return::EXCEPTION) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Exception::Reader Return::Reader::getException() const { + KJ_IREQUIRE((which() == Return::EXCEPTION), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Exception::Builder Return::Builder::getException() { + KJ_IREQUIRE((which() == Return::EXCEPTION), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Return::Builder::setException( ::capnp::rpc::Exception::Reader value) { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::EXCEPTION); + ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Exception::Builder Return::Builder::initException() { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::EXCEPTION); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Return::Builder::adoptException( + ::capnp::Orphan< ::capnp::rpc::Exception>&& value) { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::EXCEPTION); + ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Exception> Return::Builder::disownException() { + KJ_IREQUIRE((which() == Return::EXCEPTION), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Return::Reader::isCanceled() const { + return which() == Return::CANCELED; +} +inline bool Return::Builder::isCanceled() { + return which() == Return::CANCELED; +} +inline ::capnp::Void Return::Reader::getCanceled() const { + KJ_IREQUIRE((which() == Return::CANCELED), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Return::Builder::getCanceled() { + KJ_IREQUIRE((which() == Return::CANCELED), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Return::Builder::setCanceled( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::CANCELED); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Return::Reader::isResultsSentElsewhere() const { + return which() == Return::RESULTS_SENT_ELSEWHERE; +} +inline bool Return::Builder::isResultsSentElsewhere() { + return which() == Return::RESULTS_SENT_ELSEWHERE; +} +inline ::capnp::Void Return::Reader::getResultsSentElsewhere() const { + KJ_IREQUIRE((which() == Return::RESULTS_SENT_ELSEWHERE), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Return::Builder::getResultsSentElsewhere() { + KJ_IREQUIRE((which() == Return::RESULTS_SENT_ELSEWHERE), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Return::Builder::setResultsSentElsewhere( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::RESULTS_SENT_ELSEWHERE); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Return::Reader::isTakeFromOtherQuestion() const { + return which() == Return::TAKE_FROM_OTHER_QUESTION; +} +inline bool Return::Builder::isTakeFromOtherQuestion() { + return which() == Return::TAKE_FROM_OTHER_QUESTION; +} +inline ::uint32_t Return::Reader::getTakeFromOtherQuestion() const { + KJ_IREQUIRE((which() == Return::TAKE_FROM_OTHER_QUESTION), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Return::Builder::getTakeFromOtherQuestion() { + KJ_IREQUIRE((which() == Return::TAKE_FROM_OTHER_QUESTION), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Return::Builder::setTakeFromOtherQuestion( ::uint32_t value) { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::TAKE_FROM_OTHER_QUESTION); + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline bool Return::Reader::isAcceptFromThirdParty() const { + return which() == Return::ACCEPT_FROM_THIRD_PARTY; +} +inline bool Return::Builder::isAcceptFromThirdParty() { + return which() == Return::ACCEPT_FROM_THIRD_PARTY; +} +inline bool Return::Reader::hasAcceptFromThirdParty() const { + if (which() != Return::ACCEPT_FROM_THIRD_PARTY) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Return::Builder::hasAcceptFromThirdParty() { + if (which() != Return::ACCEPT_FROM_THIRD_PARTY) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Return::Reader::getAcceptFromThirdParty() const { + KJ_IREQUIRE((which() == Return::ACCEPT_FROM_THIRD_PARTY), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Return::Builder::getAcceptFromThirdParty() { + KJ_IREQUIRE((which() == Return::ACCEPT_FROM_THIRD_PARTY), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Return::Builder::initAcceptFromThirdParty() { + _builder.setDataField( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, Return::ACCEPT_FROM_THIRD_PARTY); + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline ::uint32_t Finish::Reader::getQuestionId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Finish::Builder::getQuestionId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Finish::Builder::setQuestionId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Finish::Reader::getReleaseResultCaps() const { + return _reader.getDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS, true); +} + +inline bool Finish::Builder::getReleaseResultCaps() { + return _builder.getDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS, true); +} +inline void Finish::Builder::setReleaseResultCaps(bool value) { + _builder.setDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS, value, true); +} + +inline ::capnp::rpc::Resolve::Which Resolve::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline ::capnp::rpc::Resolve::Which Resolve::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Resolve::Reader::getPromiseId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Resolve::Builder::getPromiseId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Resolve::Builder::setPromiseId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Resolve::Reader::isCap() const { + return which() == Resolve::CAP; +} +inline bool Resolve::Builder::isCap() { + return which() == Resolve::CAP; +} +inline bool Resolve::Reader::hasCap() const { + if (which() != Resolve::CAP) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Resolve::Builder::hasCap() { + if (which() != Resolve::CAP) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::CapDescriptor::Reader Resolve::Reader::getCap() const { + KJ_IREQUIRE((which() == Resolve::CAP), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::CapDescriptor>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::CapDescriptor::Builder Resolve::Builder::getCap() { + KJ_IREQUIRE((which() == Resolve::CAP), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::CapDescriptor>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Resolve::Builder::setCap( ::capnp::rpc::CapDescriptor::Reader value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Resolve::CAP); + ::capnp::_::PointerHelpers< ::capnp::rpc::CapDescriptor>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::CapDescriptor::Builder Resolve::Builder::initCap() { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Resolve::CAP); + return ::capnp::_::PointerHelpers< ::capnp::rpc::CapDescriptor>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Resolve::Builder::adoptCap( + ::capnp::Orphan< ::capnp::rpc::CapDescriptor>&& value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Resolve::CAP); + ::capnp::_::PointerHelpers< ::capnp::rpc::CapDescriptor>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::CapDescriptor> Resolve::Builder::disownCap() { + KJ_IREQUIRE((which() == Resolve::CAP), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::CapDescriptor>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Resolve::Reader::isException() const { + return which() == Resolve::EXCEPTION; +} +inline bool Resolve::Builder::isException() { + return which() == Resolve::EXCEPTION; +} +inline bool Resolve::Reader::hasException() const { + if (which() != Resolve::EXCEPTION) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Resolve::Builder::hasException() { + if (which() != Resolve::EXCEPTION) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::Exception::Reader Resolve::Reader::getException() const { + KJ_IREQUIRE((which() == Resolve::EXCEPTION), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::Exception::Builder Resolve::Builder::getException() { + KJ_IREQUIRE((which() == Resolve::EXCEPTION), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Resolve::Builder::setException( ::capnp::rpc::Exception::Reader value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Resolve::EXCEPTION); + ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::Exception::Builder Resolve::Builder::initException() { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Resolve::EXCEPTION); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Resolve::Builder::adoptException( + ::capnp::Orphan< ::capnp::rpc::Exception>&& value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Resolve::EXCEPTION); + ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::Exception> Resolve::Builder::disownException() { + KJ_IREQUIRE((which() == Resolve::EXCEPTION), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::Exception>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint32_t Release::Reader::getId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Release::Builder::getId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Release::Builder::setId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint32_t Release::Reader::getReferenceCount() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Release::Builder::getReferenceCount() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Release::Builder::setReferenceCount( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Disembargo::Reader::hasTarget() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Disembargo::Builder::hasTarget() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::MessageTarget::Reader Disembargo::Reader::getTarget() const { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::MessageTarget::Builder Disembargo::Builder::getTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::rpc::MessageTarget::Pipeline Disembargo::Pipeline::getTarget() { + return ::capnp::rpc::MessageTarget::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Disembargo::Builder::setTarget( ::capnp::rpc::MessageTarget::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::MessageTarget::Builder Disembargo::Builder::initTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Disembargo::Builder::adoptTarget( + ::capnp::Orphan< ::capnp::rpc::MessageTarget>&& value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::MessageTarget> Disembargo::Builder::disownTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline typename Disembargo::Context::Reader Disembargo::Reader::getContext() const { + return typename Disembargo::Context::Reader(_reader); +} +inline typename Disembargo::Context::Builder Disembargo::Builder::getContext() { + return typename Disembargo::Context::Builder(_builder); +} +#if !CAPNP_LITE +inline typename Disembargo::Context::Pipeline Disembargo::Pipeline::getContext() { + return typename Disembargo::Context::Pipeline(_typeless.noop()); +} +#endif // !CAPNP_LITE +inline typename Disembargo::Context::Builder Disembargo::Builder::initContext() { + _builder.setDataField< ::uint32_t>(::capnp::bounded<0>() * ::capnp::ELEMENTS, 0); + _builder.setDataField< ::uint16_t>(::capnp::bounded<2>() * ::capnp::ELEMENTS, 0); + return typename Disembargo::Context::Builder(_builder); +} +inline ::capnp::rpc::Disembargo::Context::Which Disembargo::Context::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline ::capnp::rpc::Disembargo::Context::Which Disembargo::Context::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline bool Disembargo::Context::Reader::isSenderLoopback() const { + return which() == Disembargo::Context::SENDER_LOOPBACK; +} +inline bool Disembargo::Context::Builder::isSenderLoopback() { + return which() == Disembargo::Context::SENDER_LOOPBACK; +} +inline ::uint32_t Disembargo::Context::Reader::getSenderLoopback() const { + KJ_IREQUIRE((which() == Disembargo::Context::SENDER_LOOPBACK), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Disembargo::Context::Builder::getSenderLoopback() { + KJ_IREQUIRE((which() == Disembargo::Context::SENDER_LOOPBACK), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Disembargo::Context::Builder::setSenderLoopback( ::uint32_t value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Disembargo::Context::SENDER_LOOPBACK); + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Disembargo::Context::Reader::isReceiverLoopback() const { + return which() == Disembargo::Context::RECEIVER_LOOPBACK; +} +inline bool Disembargo::Context::Builder::isReceiverLoopback() { + return which() == Disembargo::Context::RECEIVER_LOOPBACK; +} +inline ::uint32_t Disembargo::Context::Reader::getReceiverLoopback() const { + KJ_IREQUIRE((which() == Disembargo::Context::RECEIVER_LOOPBACK), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Disembargo::Context::Builder::getReceiverLoopback() { + KJ_IREQUIRE((which() == Disembargo::Context::RECEIVER_LOOPBACK), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Disembargo::Context::Builder::setReceiverLoopback( ::uint32_t value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Disembargo::Context::RECEIVER_LOOPBACK); + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Disembargo::Context::Reader::isAccept() const { + return which() == Disembargo::Context::ACCEPT; +} +inline bool Disembargo::Context::Builder::isAccept() { + return which() == Disembargo::Context::ACCEPT; +} +inline ::capnp::Void Disembargo::Context::Reader::getAccept() const { + KJ_IREQUIRE((which() == Disembargo::Context::ACCEPT), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Disembargo::Context::Builder::getAccept() { + KJ_IREQUIRE((which() == Disembargo::Context::ACCEPT), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Disembargo::Context::Builder::setAccept( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Disembargo::Context::ACCEPT); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Disembargo::Context::Reader::isProvide() const { + return which() == Disembargo::Context::PROVIDE; +} +inline bool Disembargo::Context::Builder::isProvide() { + return which() == Disembargo::Context::PROVIDE; +} +inline ::uint32_t Disembargo::Context::Reader::getProvide() const { + KJ_IREQUIRE((which() == Disembargo::Context::PROVIDE), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Disembargo::Context::Builder::getProvide() { + KJ_IREQUIRE((which() == Disembargo::Context::PROVIDE), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Disembargo::Context::Builder::setProvide( ::uint32_t value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, Disembargo::Context::PROVIDE); + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint32_t Provide::Reader::getQuestionId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Provide::Builder::getQuestionId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Provide::Builder::setQuestionId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Provide::Reader::hasTarget() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Provide::Builder::hasTarget() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::MessageTarget::Reader Provide::Reader::getTarget() const { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::MessageTarget::Builder Provide::Builder::getTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::rpc::MessageTarget::Pipeline Provide::Pipeline::getTarget() { + return ::capnp::rpc::MessageTarget::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Provide::Builder::setTarget( ::capnp::rpc::MessageTarget::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::MessageTarget::Builder Provide::Builder::initTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Provide::Builder::adoptTarget( + ::capnp::Orphan< ::capnp::rpc::MessageTarget>&& value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::MessageTarget> Provide::Builder::disownTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Provide::Reader::hasRecipient() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool Provide::Builder::hasRecipient() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Provide::Reader::getRecipient() const { + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Provide::Builder::getRecipient() { + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Provide::Builder::initRecipient() { + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline ::uint32_t Accept::Reader::getQuestionId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Accept::Builder::getQuestionId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Accept::Builder::setQuestionId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Accept::Reader::hasProvision() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Accept::Builder::hasProvision() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Accept::Reader::getProvision() const { + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Accept::Builder::getProvision() { + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Accept::Builder::initProvision() { + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline bool Accept::Reader::getEmbargo() const { + return _reader.getDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS); +} + +inline bool Accept::Builder::getEmbargo() { + return _builder.getDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS); +} +inline void Accept::Builder::setEmbargo(bool value) { + _builder.setDataField( + ::capnp::bounded<32>() * ::capnp::ELEMENTS, value); +} + +inline ::uint32_t Join::Reader::getQuestionId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Join::Builder::getQuestionId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Join::Builder::setQuestionId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Join::Reader::hasTarget() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Join::Builder::hasTarget() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::MessageTarget::Reader Join::Reader::getTarget() const { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::MessageTarget::Builder Join::Builder::getTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::rpc::MessageTarget::Pipeline Join::Pipeline::getTarget() { + return ::capnp::rpc::MessageTarget::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Join::Builder::setTarget( ::capnp::rpc::MessageTarget::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::MessageTarget::Builder Join::Builder::initTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Join::Builder::adoptTarget( + ::capnp::Orphan< ::capnp::rpc::MessageTarget>&& value) { + ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::MessageTarget> Join::Builder::disownTarget() { + return ::capnp::_::PointerHelpers< ::capnp::rpc::MessageTarget>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Join::Reader::hasKeyPart() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool Join::Builder::hasKeyPart() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Join::Reader::getKeyPart() const { + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Join::Builder::getKeyPart() { + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Join::Builder::initKeyPart() { + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline ::capnp::rpc::MessageTarget::Which MessageTarget::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline ::capnp::rpc::MessageTarget::Which MessageTarget::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline bool MessageTarget::Reader::isImportedCap() const { + return which() == MessageTarget::IMPORTED_CAP; +} +inline bool MessageTarget::Builder::isImportedCap() { + return which() == MessageTarget::IMPORTED_CAP; +} +inline ::uint32_t MessageTarget::Reader::getImportedCap() const { + KJ_IREQUIRE((which() == MessageTarget::IMPORTED_CAP), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t MessageTarget::Builder::getImportedCap() { + KJ_IREQUIRE((which() == MessageTarget::IMPORTED_CAP), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void MessageTarget::Builder::setImportedCap( ::uint32_t value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, MessageTarget::IMPORTED_CAP); + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool MessageTarget::Reader::isPromisedAnswer() const { + return which() == MessageTarget::PROMISED_ANSWER; +} +inline bool MessageTarget::Builder::isPromisedAnswer() { + return which() == MessageTarget::PROMISED_ANSWER; +} +inline bool MessageTarget::Reader::hasPromisedAnswer() const { + if (which() != MessageTarget::PROMISED_ANSWER) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool MessageTarget::Builder::hasPromisedAnswer() { + if (which() != MessageTarget::PROMISED_ANSWER) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::PromisedAnswer::Reader MessageTarget::Reader::getPromisedAnswer() const { + KJ_IREQUIRE((which() == MessageTarget::PROMISED_ANSWER), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::PromisedAnswer::Builder MessageTarget::Builder::getPromisedAnswer() { + KJ_IREQUIRE((which() == MessageTarget::PROMISED_ANSWER), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void MessageTarget::Builder::setPromisedAnswer( ::capnp::rpc::PromisedAnswer::Reader value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, MessageTarget::PROMISED_ANSWER); + ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::PromisedAnswer::Builder MessageTarget::Builder::initPromisedAnswer() { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, MessageTarget::PROMISED_ANSWER); + return ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void MessageTarget::Builder::adoptPromisedAnswer( + ::capnp::Orphan< ::capnp::rpc::PromisedAnswer>&& value) { + _builder.setDataField( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, MessageTarget::PROMISED_ANSWER); + ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::PromisedAnswer> MessageTarget::Builder::disownPromisedAnswer() { + KJ_IREQUIRE((which() == MessageTarget::PROMISED_ANSWER), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Payload::Reader::hasContent() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Payload::Builder::hasContent() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Payload::Reader::getContent() const { + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Payload::Builder::getContent() { + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Payload::Builder::initContent() { + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline bool Payload::Reader::hasCapTable() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool Payload::Builder::hasCapTable() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::rpc::CapDescriptor>::Reader Payload::Reader::getCapTable() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::CapDescriptor>>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::rpc::CapDescriptor>::Builder Payload::Builder::getCapTable() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::CapDescriptor>>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void Payload::Builder::setCapTable( ::capnp::List< ::capnp::rpc::CapDescriptor>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::CapDescriptor>>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::rpc::CapDescriptor>::Builder Payload::Builder::initCapTable(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::CapDescriptor>>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), size); +} +inline void Payload::Builder::adoptCapTable( + ::capnp::Orphan< ::capnp::List< ::capnp::rpc::CapDescriptor>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::CapDescriptor>>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::rpc::CapDescriptor>> Payload::Builder::disownCapTable() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::CapDescriptor>>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline ::capnp::rpc::CapDescriptor::Which CapDescriptor::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline ::capnp::rpc::CapDescriptor::Which CapDescriptor::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline bool CapDescriptor::Reader::isNone() const { + return which() == CapDescriptor::NONE; +} +inline bool CapDescriptor::Builder::isNone() { + return which() == CapDescriptor::NONE; +} +inline ::capnp::Void CapDescriptor::Reader::getNone() const { + KJ_IREQUIRE((which() == CapDescriptor::NONE), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void CapDescriptor::Builder::getNone() { + KJ_IREQUIRE((which() == CapDescriptor::NONE), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void CapDescriptor::Builder::setNone( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::NONE); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool CapDescriptor::Reader::isSenderHosted() const { + return which() == CapDescriptor::SENDER_HOSTED; +} +inline bool CapDescriptor::Builder::isSenderHosted() { + return which() == CapDescriptor::SENDER_HOSTED; +} +inline ::uint32_t CapDescriptor::Reader::getSenderHosted() const { + KJ_IREQUIRE((which() == CapDescriptor::SENDER_HOSTED), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t CapDescriptor::Builder::getSenderHosted() { + KJ_IREQUIRE((which() == CapDescriptor::SENDER_HOSTED), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void CapDescriptor::Builder::setSenderHosted( ::uint32_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::SENDER_HOSTED); + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool CapDescriptor::Reader::isSenderPromise() const { + return which() == CapDescriptor::SENDER_PROMISE; +} +inline bool CapDescriptor::Builder::isSenderPromise() { + return which() == CapDescriptor::SENDER_PROMISE; +} +inline ::uint32_t CapDescriptor::Reader::getSenderPromise() const { + KJ_IREQUIRE((which() == CapDescriptor::SENDER_PROMISE), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t CapDescriptor::Builder::getSenderPromise() { + KJ_IREQUIRE((which() == CapDescriptor::SENDER_PROMISE), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void CapDescriptor::Builder::setSenderPromise( ::uint32_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::SENDER_PROMISE); + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool CapDescriptor::Reader::isReceiverHosted() const { + return which() == CapDescriptor::RECEIVER_HOSTED; +} +inline bool CapDescriptor::Builder::isReceiverHosted() { + return which() == CapDescriptor::RECEIVER_HOSTED; +} +inline ::uint32_t CapDescriptor::Reader::getReceiverHosted() const { + KJ_IREQUIRE((which() == CapDescriptor::RECEIVER_HOSTED), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t CapDescriptor::Builder::getReceiverHosted() { + KJ_IREQUIRE((which() == CapDescriptor::RECEIVER_HOSTED), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void CapDescriptor::Builder::setReceiverHosted( ::uint32_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::RECEIVER_HOSTED); + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool CapDescriptor::Reader::isReceiverAnswer() const { + return which() == CapDescriptor::RECEIVER_ANSWER; +} +inline bool CapDescriptor::Builder::isReceiverAnswer() { + return which() == CapDescriptor::RECEIVER_ANSWER; +} +inline bool CapDescriptor::Reader::hasReceiverAnswer() const { + if (which() != CapDescriptor::RECEIVER_ANSWER) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool CapDescriptor::Builder::hasReceiverAnswer() { + if (which() != CapDescriptor::RECEIVER_ANSWER) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::PromisedAnswer::Reader CapDescriptor::Reader::getReceiverAnswer() const { + KJ_IREQUIRE((which() == CapDescriptor::RECEIVER_ANSWER), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::PromisedAnswer::Builder CapDescriptor::Builder::getReceiverAnswer() { + KJ_IREQUIRE((which() == CapDescriptor::RECEIVER_ANSWER), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void CapDescriptor::Builder::setReceiverAnswer( ::capnp::rpc::PromisedAnswer::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::RECEIVER_ANSWER); + ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::PromisedAnswer::Builder CapDescriptor::Builder::initReceiverAnswer() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::RECEIVER_ANSWER); + return ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void CapDescriptor::Builder::adoptReceiverAnswer( + ::capnp::Orphan< ::capnp::rpc::PromisedAnswer>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::RECEIVER_ANSWER); + ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::PromisedAnswer> CapDescriptor::Builder::disownReceiverAnswer() { + KJ_IREQUIRE((which() == CapDescriptor::RECEIVER_ANSWER), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::PromisedAnswer>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool CapDescriptor::Reader::isThirdPartyHosted() const { + return which() == CapDescriptor::THIRD_PARTY_HOSTED; +} +inline bool CapDescriptor::Builder::isThirdPartyHosted() { + return which() == CapDescriptor::THIRD_PARTY_HOSTED; +} +inline bool CapDescriptor::Reader::hasThirdPartyHosted() const { + if (which() != CapDescriptor::THIRD_PARTY_HOSTED) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool CapDescriptor::Builder::hasThirdPartyHosted() { + if (which() != CapDescriptor::THIRD_PARTY_HOSTED) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::rpc::ThirdPartyCapDescriptor::Reader CapDescriptor::Reader::getThirdPartyHosted() const { + KJ_IREQUIRE((which() == CapDescriptor::THIRD_PARTY_HOSTED), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::ThirdPartyCapDescriptor>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::rpc::ThirdPartyCapDescriptor::Builder CapDescriptor::Builder::getThirdPartyHosted() { + KJ_IREQUIRE((which() == CapDescriptor::THIRD_PARTY_HOSTED), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::ThirdPartyCapDescriptor>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void CapDescriptor::Builder::setThirdPartyHosted( ::capnp::rpc::ThirdPartyCapDescriptor::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::THIRD_PARTY_HOSTED); + ::capnp::_::PointerHelpers< ::capnp::rpc::ThirdPartyCapDescriptor>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::rpc::ThirdPartyCapDescriptor::Builder CapDescriptor::Builder::initThirdPartyHosted() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::THIRD_PARTY_HOSTED); + return ::capnp::_::PointerHelpers< ::capnp::rpc::ThirdPartyCapDescriptor>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void CapDescriptor::Builder::adoptThirdPartyHosted( + ::capnp::Orphan< ::capnp::rpc::ThirdPartyCapDescriptor>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, CapDescriptor::THIRD_PARTY_HOSTED); + ::capnp::_::PointerHelpers< ::capnp::rpc::ThirdPartyCapDescriptor>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::rpc::ThirdPartyCapDescriptor> CapDescriptor::Builder::disownThirdPartyHosted() { + KJ_IREQUIRE((which() == CapDescriptor::THIRD_PARTY_HOSTED), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::rpc::ThirdPartyCapDescriptor>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint32_t PromisedAnswer::Reader::getQuestionId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t PromisedAnswer::Builder::getQuestionId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void PromisedAnswer::Builder::setQuestionId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool PromisedAnswer::Reader::hasTransform() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool PromisedAnswer::Builder::hasTransform() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>::Reader PromisedAnswer::Reader::getTransform() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>::Builder PromisedAnswer::Builder::getTransform() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void PromisedAnswer::Builder::setTransform( ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>::Builder PromisedAnswer::Builder::initTransform(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void PromisedAnswer::Builder::adoptTransform( + ::capnp::Orphan< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>> PromisedAnswer::Builder::disownTransform() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::rpc::PromisedAnswer::Op>>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::capnp::rpc::PromisedAnswer::Op::Which PromisedAnswer::Op::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline ::capnp::rpc::PromisedAnswer::Op::Which PromisedAnswer::Op::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline bool PromisedAnswer::Op::Reader::isNoop() const { + return which() == PromisedAnswer::Op::NOOP; +} +inline bool PromisedAnswer::Op::Builder::isNoop() { + return which() == PromisedAnswer::Op::NOOP; +} +inline ::capnp::Void PromisedAnswer::Op::Reader::getNoop() const { + KJ_IREQUIRE((which() == PromisedAnswer::Op::NOOP), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void PromisedAnswer::Op::Builder::getNoop() { + KJ_IREQUIRE((which() == PromisedAnswer::Op::NOOP), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void PromisedAnswer::Op::Builder::setNoop( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, PromisedAnswer::Op::NOOP); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool PromisedAnswer::Op::Reader::isGetPointerField() const { + return which() == PromisedAnswer::Op::GET_POINTER_FIELD; +} +inline bool PromisedAnswer::Op::Builder::isGetPointerField() { + return which() == PromisedAnswer::Op::GET_POINTER_FIELD; +} +inline ::uint16_t PromisedAnswer::Op::Reader::getGetPointerField() const { + KJ_IREQUIRE((which() == PromisedAnswer::Op::GET_POINTER_FIELD), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t PromisedAnswer::Op::Builder::getGetPointerField() { + KJ_IREQUIRE((which() == PromisedAnswer::Op::GET_POINTER_FIELD), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void PromisedAnswer::Op::Builder::setGetPointerField( ::uint16_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, PromisedAnswer::Op::GET_POINTER_FIELD); + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool ThirdPartyCapDescriptor::Reader::hasId() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool ThirdPartyCapDescriptor::Builder::hasId() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader ThirdPartyCapDescriptor::Reader::getId() const { + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder ThirdPartyCapDescriptor::Builder::getId() { + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder ThirdPartyCapDescriptor::Builder::initId() { + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline ::uint32_t ThirdPartyCapDescriptor::Reader::getVineId() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t ThirdPartyCapDescriptor::Builder::getVineId() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void ThirdPartyCapDescriptor::Builder::setVineId( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Exception::Reader::hasReason() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Exception::Builder::hasReason() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader Exception::Reader::getReason() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder Exception::Builder::getReason() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Exception::Builder::setReason( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder Exception::Builder::initReason(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Exception::Builder::adoptReason( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> Exception::Builder::disownReason() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Exception::Reader::getObsoleteIsCallersFault() const { + return _reader.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline bool Exception::Builder::getObsoleteIsCallersFault() { + return _builder.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Exception::Builder::setObsoleteIsCallersFault(bool value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint16_t Exception::Reader::getObsoleteDurability() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Exception::Builder::getObsoleteDurability() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Exception::Builder::setObsoleteDurability( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline ::capnp::rpc::Exception::Type Exception::Reader::getType() const { + return _reader.getDataField< ::capnp::rpc::Exception::Type>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::capnp::rpc::Exception::Type Exception::Builder::getType() { + return _builder.getDataField< ::capnp::rpc::Exception::Type>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Exception::Builder::setType( ::capnp::rpc::Exception::Type value) { + _builder.setDataField< ::capnp::rpc::Exception::Type>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +} // namespace +} // namespace + +#endif // CAPNP_INCLUDED_b312981b2552a250_ diff --git a/phonelibs/capnp-cpp/include/capnp/rpc.h b/phonelibs/capnp-cpp/include/capnp/rpc.h new file mode 100644 index 00000000000000..d84ed982e78314 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/rpc.h @@ -0,0 +1,537 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_RPC_H_ +#define CAPNP_RPC_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "capability.h" +#include "rpc-prelude.h" + +namespace capnp { + +template +class VatNetwork; +template +class SturdyRefRestorer; + +template +class BootstrapFactory: public _::BootstrapFactoryBase { + // Interface that constructs per-client bootstrap interfaces. Use this if you want each client + // who connects to see a different bootstrap interface based on their (authenticated) VatId. + // This allows an application to bootstrap off of the authentication performed at the VatNetwork + // level. (Typically VatId is some sort of public key.) + // + // This is only useful for multi-party networks. For TwoPartyVatNetwork, there's no reason to + // use a BootstrapFactory; just specify a single bootstrap capability in this case. + +public: + virtual Capability::Client createFor(typename VatId::Reader clientId) = 0; + // Create a bootstrap capability appropriate for exposing to the given client. VatNetwork will + // have authenticated the client VatId before this is called. + +private: + Capability::Client baseCreateFor(AnyStruct::Reader clientId) override; +}; + +template +class RpcSystem: public _::RpcSystemBase { + // Represents the RPC system, which is the portal to objects available on the network. + // + // The RPC implementation sits on top of an implementation of `VatNetwork`. The `VatNetwork` + // determines how to form connections between vats -- specifically, two-way, private, reliable, + // sequenced datagram connections. The RPC implementation determines how to use such connections + // to manage object references and make method calls. + // + // See `makeRpcServer()` and `makeRpcClient()` below for convenient syntax for setting up an + // `RpcSystem` given a `VatNetwork`. + // + // See `ez-rpc.h` for an even simpler interface for setting up RPC in a typical two-party + // client/server scenario. + +public: + template + RpcSystem( + VatNetwork& network, + kj::Maybe bootstrapInterface, + kj::Maybe::Client> gateway = nullptr); + + template + RpcSystem( + VatNetwork& network, + BootstrapFactory& bootstrapFactory, + kj::Maybe::Client> gateway = nullptr); + + template + RpcSystem( + VatNetwork& network, + SturdyRefRestorer& restorer); + + RpcSystem(RpcSystem&& other) = default; + + Capability::Client bootstrap(typename VatId::Reader vatId); + // Connect to the given vat and return its bootstrap interface. + + Capability::Client restore(typename VatId::Reader hostId, AnyPointer::Reader objectId) + KJ_DEPRECATED("Please transition to using a bootstrap interface instead."); + // ** DEPRECATED ** + // + // Restores the given SturdyRef from the network and return the capability representing it. + // + // `hostId` identifies the host from which to request the ref, in the format specified by the + // `VatNetwork` in use. `objectId` is the object ID in whatever format is expected by said host. + // + // This method will be removed in a future version of Cap'n Proto. Instead, please transition + // to using bootstrap(), which is equivalent to calling restore() with a null `objectId`. + // You may emulate the old concept of object IDs by exporting a bootstrap interface which has + // methods that can be used to obtain other capabilities by ID. + + void setFlowLimit(size_t words); + // Sets the incoming call flow limit. If more than `words` worth of call messages have not yet + // received responses, the RpcSystem will not read further messages from the stream. This can be + // used as a crude way to prevent a resource exhaustion attack (or bug) in which a peer makes an + // excessive number of simultaneous calls that consume the receiver's RAM. + // + // There are some caveats. When over the flow limit, all messages are blocked, including returns. + // If the outstanding calls are themselves waiting on calls going in the opposite direction, the + // flow limit may prevent those calls from completing, leading to deadlock. However, a + // sufficiently high limit should make this unlikely. + // + // Note that a call's parameter size counts against the flow limit until the call returns, even + // if the recipient calls releaseParams() to free the parameter memory early. This is because + // releaseParams() may simply indicate that the parameters have been forwarded to another + // machine, but are still in-memory there. For illustration, say that Alice made a call to Bob + // who forwarded the call to Carol. Bob has imposed a flow limit on Alice. Alice's calls are + // being forwarded to Carol, so Bob never keeps the parameters in-memory for more than a brief + // period. However, the flow limit counts all calls that haven't returned, even if Bob has + // already freed the memory they consumed. You might argue that the right solution here is + // instead for Carol to impose her own flow limit on Bob. This has a serious problem, though: + // Bob might be forwarding requests to Carol on behalf of many different parties, not just Alice. + // If Alice can pump enough data to hit the Bob -> Carol flow limit, then those other parties + // will be disrupted. Thus, we can only really impose the limit on the Alice -> Bob link, which + // only affects Alice. We need that one flow limit to limit Alice's impact on the whole system, + // so it has to count all in-flight calls. + // + // In Sandstorm, flow limits are imposed by the supervisor on calls coming out of a grain, in + // order to prevent a grain from inundating the system with in-flight calls. In practice, the + // main time this happens is when a grain is pushing a large file download and doesn't implement + // proper cooperative flow control. +}; + +template +RpcSystem makeRpcServer( + VatNetwork& network, + Capability::Client bootstrapInterface); +// Make an RPC server. Typical usage (e.g. in a main() function): +// +// MyEventLoop eventLoop; +// kj::WaitScope waitScope(eventLoop); +// MyNetwork network; +// MyMainInterface::Client bootstrap = makeMain(); +// auto server = makeRpcServer(network, bootstrap); +// kj::NEVER_DONE.wait(waitScope); // run forever +// +// See also ez-rpc.h, which has simpler instructions for the common case of a two-party +// client-server RPC connection. + +template , + typename ExternalRef = _::ExternalRefFromRealmGatewayClient> +RpcSystem makeRpcServer( + VatNetwork& network, + Capability::Client bootstrapInterface, RealmGatewayClient gateway); +// Make an RPC server for a VatNetwork that resides in a different realm from the application. +// The given RealmGateway is used to translate SturdyRefs between the app's ("internal") format +// and the network's ("external") format. + +template +RpcSystem makeRpcServer( + VatNetwork& network, + BootstrapFactory& bootstrapFactory); +// Make an RPC server that can serve different bootstrap interfaces to different clients via a +// BootstrapInterface. + +template , + typename ExternalRef = _::ExternalRefFromRealmGatewayClient> +RpcSystem makeRpcServer( + VatNetwork& network, + BootstrapFactory& bootstrapFactory, RealmGatewayClient gateway); +// Make an RPC server that can serve different bootstrap interfaces to different clients via a +// BootstrapInterface and communicates with a different realm than the application is in via a +// RealmGateway. + +template +RpcSystem makeRpcServer( + VatNetwork& network, + SturdyRefRestorer& restorer) + KJ_DEPRECATED("Please transition to using a bootstrap interface instead."); +// ** DEPRECATED ** +// +// Create an RPC server which exports multiple main interfaces by object ID. The `restorer` object +// can be used to look up objects by ID. +// +// Please transition to exporting only one interface, which is known as the "bootstrap" interface. +// For backwards-compatibility with old clients, continue to implement SturdyRefRestorer, but +// return the new bootstrap interface when the request object ID is null. When new clients connect +// and request the bootstrap interface, they will get that interface. Eventually, once all clients +// are updated to request only the bootstrap interface, stop implementing SturdyRefRestorer and +// switch to passing the bootstrap capability itself as the second parameter to `makeRpcServer()`. + +template +RpcSystem makeRpcClient( + VatNetwork& network); +// Make an RPC client. Typical usage (e.g. in a main() function): +// +// MyEventLoop eventLoop; +// kj::WaitScope waitScope(eventLoop); +// MyNetwork network; +// auto client = makeRpcClient(network); +// MyCapability::Client cap = client.restore(hostId, objId).castAs(); +// auto response = cap.fooRequest().send().wait(waitScope); +// handleMyResponse(response); +// +// See also ez-rpc.h, which has simpler instructions for the common case of a two-party +// client-server RPC connection. + +template , + typename ExternalRef = _::ExternalRefFromRealmGatewayClient> +RpcSystem makeRpcClient( + VatNetwork& network, + RealmGatewayClient gateway); +// Make an RPC client for a VatNetwork that resides in a different realm from the application. +// The given RealmGateway is used to translate SturdyRefs between the app's ("internal") format +// and the network's ("external") format. + +template +class SturdyRefRestorer: public _::SturdyRefRestorerBase { + // ** DEPRECATED ** + // + // In Cap'n Proto 0.4.x, applications could export multiple main interfaces identified by + // object IDs. The callback used to map object IDs to objects was `SturdyRefRestorer`, as we + // imagined this would eventually be used for restoring SturdyRefs as well. In practice, it was + // never used for real SturdyRefs, only for exporting singleton objects under well-known names. + // + // The new preferred strategy is to export only a _single_ such interface, called the + // "bootstrap interface". That interface can itself have methods for obtaining other objects, of + // course, but that is up to the app. `SturdyRefRestorer` exists for backwards-compatibility. + // + // Hint: Use SturdyRefRestorer to define a server that exports services under + // string names. + +public: + virtual Capability::Client restore(typename SturdyRefObjectId::Reader ref) + KJ_DEPRECATED( + "Please transition to using bootstrap interfaces instead of SturdyRefRestorer.") = 0; + // Restore the given object, returning a capability representing it. + +private: + Capability::Client baseRestore(AnyPointer::Reader ref) override final; +}; + +// ======================================================================================= +// VatNetwork + +class OutgoingRpcMessage { + // A message to be sent by a `VatNetwork`. + +public: + virtual AnyPointer::Builder getBody() = 0; + // Get the message body, which the caller may fill in any way it wants. (The standard RPC + // implementation initializes it as a Message as defined in rpc.capnp.) + + virtual void send() = 0; + // Send the message, or at least put it in a queue to be sent later. Note that the builder + // returned by `getBody()` remains valid at least until the `OutgoingRpcMessage` is destroyed. +}; + +class IncomingRpcMessage { + // A message received from a `VatNetwork`. + +public: + virtual AnyPointer::Reader getBody() = 0; + // Get the message body, to be interpreted by the caller. (The standard RPC implementation + // interprets it as a Message as defined in rpc.capnp.) +}; + +template +class VatNetwork: public _::VatNetworkBase { + // Cap'n Proto RPC operates between vats, where a "vat" is some sort of host of objects. + // Typically one Cap'n Proto process (in the Unix sense) is one vat. The RPC system is what + // allows calls between objects hosted in different vats. + // + // The RPC implementation sits on top of an implementation of `VatNetwork`. The `VatNetwork` + // determines how to form connections between vats -- specifically, two-way, private, reliable, + // sequenced datagram connections. The RPC implementation determines how to use such connections + // to manage object references and make method calls. + // + // The most common implementation of VatNetwork is TwoPartyVatNetwork (rpc-twoparty.h). Most + // simple client-server apps will want to use it. (You may even want to use the EZ RPC + // interfaces in `ez-rpc.h` and avoid all of this.) + // + // TODO(someday): Provide a standard implementation for the public internet. + +public: + class Connection; + + struct ConnectionAndProvisionId { + // Result of connecting to a vat introduced by another vat. + + kj::Own connection; + // Connection to the new vat. + + kj::Own firstMessage; + // An already-allocated `OutgoingRpcMessage` associated with `connection`. The RPC system will + // construct this as an `Accept` message and send it. + + Orphan provisionId; + // A `ProvisionId` already allocated inside `firstMessage`, which the RPC system will use to + // build the `Accept` message. + }; + + class Connection: public _::VatNetworkBase::Connection { + // A two-way RPC connection. + // + // This object may represent a connection that doesn't exist yet, but is expected to exist + // in the future. In this case, sent messages will automatically be queued and sent once the + // connection is ready, so that the caller doesn't need to know the difference. + + public: + // Level 0 features ---------------------------------------------- + + virtual typename VatId::Reader getPeerVatId() = 0; + // Returns the connected vat's authenticated VatId. It is the VatNetwork's responsibility to + // authenticate this, so that the caller can be assured that they are really talking to the + // identified vat and not an imposter. + + virtual kj::Own newOutgoingMessage(uint firstSegmentWordSize) override = 0; + // Allocate a new message to be sent on this connection. + // + // If `firstSegmentWordSize` is non-zero, it should be treated as a hint suggesting how large + // to make the first segment. This is entirely a hint and the connection may adjust it up or + // down. If it is zero, the connection should choose the size itself. + + virtual kj::Promise>> receiveIncomingMessage() override = 0; + // Wait for a message to be received and return it. If the read stream cleanly terminates, + // return null. If any other problem occurs, throw an exception. + + virtual kj::Promise shutdown() override KJ_WARN_UNUSED_RESULT = 0; + // Waits until all outgoing messages have been sent, then shuts down the outgoing stream. The + // returned promise resolves after shutdown is complete. + + private: + AnyStruct::Reader baseGetPeerVatId() override; + }; + + // Level 0 features ------------------------------------------------ + + virtual kj::Maybe> connect(typename VatId::Reader hostId) = 0; + // Connect to a VatId. Note that this method immediately returns a `Connection`, even + // if the network connection has not yet been established. Messages can be queued to this + // connection and will be delivered once it is open. The caller must attempt to read from the + // connection to verify that it actually succeeded; the read will fail if the connection + // couldn't be opened. Some network implementations may actually start sending messages before + // hearing back from the server at all, to avoid a round trip. + // + // Returns nullptr if `hostId` refers to the local host. + + virtual kj::Promise> accept() = 0; + // Wait for the next incoming connection and return it. + + // Level 4 features ------------------------------------------------ + // TODO(someday) + +private: + kj::Maybe> + baseConnect(AnyStruct::Reader hostId) override final; + kj::Promise> baseAccept() override final; +}; + +// ======================================================================================= +// *************************************************************************************** +// Inline implementation details start here +// *************************************************************************************** +// ======================================================================================= + +template +Capability::Client BootstrapFactory::baseCreateFor(AnyStruct::Reader clientId) { + return createFor(clientId.as()); +} + +template +kj::Maybe> + VatNetwork:: + baseConnect(AnyStruct::Reader ref) { + auto maybe = connect(ref.as()); + return maybe.map([](kj::Own& conn) -> kj::Own<_::VatNetworkBase::Connection> { + return kj::mv(conn); + }); +} + +template +kj::Promise> + VatNetwork::baseAccept() { + return accept().then( + [](kj::Own&& connection) -> kj::Own<_::VatNetworkBase::Connection> { + return kj::mv(connection); + }); +} + +template +AnyStruct::Reader VatNetwork< + SturdyRef, ProvisionId, RecipientId, ThirdPartyCapId, JoinResult>:: + Connection::baseGetPeerVatId() { + return getPeerVatId(); +} + +template +Capability::Client SturdyRefRestorer::baseRestore(AnyPointer::Reader ref) { +#pragma GCC diagnostic push +#pragma GCC diagnostic ignored "-Wdeprecated-declarations" + return restore(ref.getAs()); +#pragma GCC diagnostic pop +} + +template +template +RpcSystem::RpcSystem( + VatNetwork& network, + kj::Maybe bootstrap, + kj::Maybe::Client> gateway) + : _::RpcSystemBase(network, kj::mv(bootstrap), kj::mv(gateway)) {} + +template +template +RpcSystem::RpcSystem( + VatNetwork& network, + BootstrapFactory& bootstrapFactory, + kj::Maybe::Client> gateway) + : _::RpcSystemBase(network, bootstrapFactory, kj::mv(gateway)) {} + +template +template +RpcSystem::RpcSystem( + VatNetwork& network, + SturdyRefRestorer& restorer) + : _::RpcSystemBase(network, restorer) {} + +template +Capability::Client RpcSystem::bootstrap(typename VatId::Reader vatId) { + return baseBootstrap(_::PointerHelpers::getInternalReader(vatId)); +} + +template +Capability::Client RpcSystem::restore( + typename VatId::Reader hostId, AnyPointer::Reader objectId) { + return baseRestore(_::PointerHelpers::getInternalReader(hostId), objectId); +} + +template +inline void RpcSystem::setFlowLimit(size_t words) { + baseSetFlowLimit(words); +} + +template +RpcSystem makeRpcServer( + VatNetwork& network, + Capability::Client bootstrapInterface) { + return RpcSystem(network, kj::mv(bootstrapInterface)); +} + +template +RpcSystem makeRpcServer( + VatNetwork& network, + Capability::Client bootstrapInterface, RealmGatewayClient gateway) { + return RpcSystem(network, kj::mv(bootstrapInterface), + gateway.template castAs>()); +} + +template +RpcSystem makeRpcServer( + VatNetwork& network, + BootstrapFactory& bootstrapFactory) { + return RpcSystem(network, bootstrapFactory); +} + +template +RpcSystem makeRpcServer( + VatNetwork& network, + BootstrapFactory& bootstrapFactory, RealmGatewayClient gateway) { + return RpcSystem(network, bootstrapFactory, gateway.template castAs>()); +} + +template +RpcSystem makeRpcServer( + VatNetwork& network, + SturdyRefRestorer& restorer) { + return RpcSystem(network, restorer); +} + +template +RpcSystem makeRpcClient( + VatNetwork& network) { + return RpcSystem(network, nullptr); +} + +template +RpcSystem makeRpcClient( + VatNetwork& network, + RealmGatewayClient gateway) { + return RpcSystem(network, nullptr, gateway.template castAs>()); +} + +} // namespace capnp + +#endif // CAPNP_RPC_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/schema-lite.h b/phonelibs/capnp-cpp/include/capnp/schema-lite.h new file mode 100644 index 00000000000000..58a8c14c05b73e --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/schema-lite.h @@ -0,0 +1,48 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_SCHEMA_LITE_H_ +#define CAPNP_SCHEMA_LITE_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include +#include "message.h" + +namespace capnp { + +template +inline schema::Node::Reader schemaProto() { + // Get the schema::Node for this type's schema. This function works even in lite mode. + return readMessageUnchecked(CapnpPrivate::encodedSchema()); +} + +template ::typeId> +inline schema::Node::Reader schemaProto() { + // Get the schema::Node for this type's schema. This function works even in lite mode. + return readMessageUnchecked(schemas::EnumInfo::encodedSchema()); +} + +} // namespace capnp + +#endif // CAPNP_SCHEMA_LITE_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/schema-loader.h b/phonelibs/capnp-cpp/include/capnp/schema-loader.h new file mode 100644 index 00000000000000..0e34cba77fdbb8 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/schema-loader.h @@ -0,0 +1,173 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_SCHEMA_LOADER_H_ +#define CAPNP_SCHEMA_LOADER_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "schema.h" +#include +#include + +namespace capnp { + +class SchemaLoader { + // Class which can be used to construct Schema objects from schema::Nodes as defined in + // schema.capnp. + // + // It is a bad idea to use this class on untrusted input with exceptions disabled -- you may + // be exposing yourself to denial-of-service attacks, as attackers can easily construct schemas + // that are subtly inconsistent in a way that causes exceptions to be thrown either by + // SchemaLoader or by the dynamic API when the schemas are subsequently used. If you enable and + // properly catch exceptions, you should be OK -- assuming no bugs in the Cap'n Proto + // implementation, of course. + +public: + class LazyLoadCallback { + public: + virtual void load(const SchemaLoader& loader, uint64_t id) const = 0; + // Request that the schema node with the given ID be loaded into the given SchemaLoader. If + // the callback is able to find a schema for this ID, it should invoke `loadOnce()` on + // `loader` to load it. If no such node exists, it should simply do nothing and return. + // + // The callback is allowed to load schema nodes other than the one requested, e.g. because it + // expects they will be needed soon. + // + // If the `SchemaLoader` is used from multiple threads, the callback must be thread-safe. + // In particular, it's possible for multiple threads to invoke `load()` with the same ID. + // If the callback performs a large amount of work to look up IDs, it should be sure to + // de-dup these requests. + }; + + SchemaLoader(); + + SchemaLoader(const LazyLoadCallback& callback); + // Construct a SchemaLoader which will invoke the given callback when a schema node is requested + // that isn't already loaded. + + ~SchemaLoader() noexcept(false); + KJ_DISALLOW_COPY(SchemaLoader); + + Schema get(uint64_t id, schema::Brand::Reader brand = schema::Brand::Reader(), + Schema scope = Schema()) const; + // Gets the schema for the given ID, throwing an exception if it isn't present. + // + // The returned schema may be invalidated if load() is called with a new schema for the same ID. + // In general, you should not call load() while a schema from this loader is in-use. + // + // `brand` and `scope` are used to determine brand bindings where relevant. `brand` gives + // parameter bindings for the target type's brand parameters that were specified at the reference + // site. `scope` specifies the scope in which the type ID appeared -- if `brand` itself contains + // parameter references or indicates that some parameters will be inherited, these will be + // interpreted within / inherited from `scope`. + + kj::Maybe tryGet(uint64_t id, schema::Brand::Reader bindings = schema::Brand::Reader(), + Schema scope = Schema()) const; + // Like get() but doesn't throw. + + Schema getUnbound(uint64_t id) const; + // Gets a special version of the schema in which all brand parameters are "unbound". This means + // that if you look up a type via the Schema API, and it resolves to a brand parameter, the + // returned Type's getBrandParameter() method will return info about that parameter. Otherwise, + // normally, all brand parameters that aren't otherwise bound are assumed to simply be + // "AnyPointer". + + Type getType(schema::Type::Reader type, Schema scope = Schema()) const; + // Convenience method which interprets a schema::Type to produce a Type object. Implemented in + // terms of get(). + + Schema load(const schema::Node::Reader& reader); + // Loads the given schema node. Validates the node and throws an exception if invalid. This + // makes a copy of the schema, so the object passed in can be destroyed after this returns. + // + // If the node has any dependencies which are not already loaded, they will be initialized as + // stubs -- empty schemas of whichever kind is expected. + // + // If another schema for the given reader has already been seen, the loader will inspect both + // schemas to determine which one is newer, and use that that one. If the two versions are + // found to be incompatible, an exception is thrown. If the two versions differ but are + // compatible and the loader cannot determine which is newer (e.g., the only changes are renames), + // the existing schema will be preferred. Note that in any case, the loader will end up keeping + // around copies of both schemas, so you shouldn't repeatedly reload schemas into the same loader. + // + // The following properties of the schema node are validated: + // - Struct size and preferred list encoding are valid and consistent. + // - Struct members are fields or unions. + // - Union members are fields. + // - Field offsets are in-bounds. + // - Ordinals and codeOrders are sequential starting from zero. + // - Values are of the right union case to match their types. + // + // You should assume anything not listed above is NOT validated. In particular, things that are + // not validated now, but could be in the future, include but are not limited to: + // - Names. + // - Annotation values. (This is hard because the annotation declaration is not always + // available.) + // - Content of default/constant values of pointer type. (Validating these would require knowing + // their schema, but even if the schemas are available at validation time, they could be + // updated by a subsequent load(), invalidating existing values. Instead, these values are + // validated at the time they are used, as usual for Cap'n Proto objects.) + // + // Also note that unknown types are not considered invalid. Instead, the dynamic API returns + // a DynamicValue with type UNKNOWN for these. + + Schema loadOnce(const schema::Node::Reader& reader) const; + // Like `load()` but does nothing if a schema with the same ID is already loaded. In contrast, + // `load()` would attempt to compare the schemas and take the newer one. `loadOnce()` is safe + // to call even while concurrently using schemas from this loader. It should be considered an + // error to call `loadOnce()` with two non-identical schemas that share the same ID, although + // this error may or may not actually be detected by the implementation. + + template + void loadCompiledTypeAndDependencies(); + // Load the schema for the given compiled-in type and all of its dependencies. + // + // If you want to be able to cast a DynamicValue built from this SchemaLoader to the compiled-in + // type using as(), you must call this method before constructing the DynamicValue. Otherwise, + // as() will throw an exception complaining about type mismatch. + + kj::Array getAllLoaded() const; + // Get a complete list of all loaded schema nodes. It is particularly useful to call this after + // loadCompiledTypeAndDependencies() in order to get a flat list of all of T's transitive + // dependencies. + +private: + class Validator; + class CompatibilityChecker; + class Impl; + class InitializerImpl; + class BrandedInitializerImpl; + kj::MutexGuarded> impl; + + void loadNative(const _::RawSchema* nativeSchema); +}; + +template +inline void SchemaLoader::loadCompiledTypeAndDependencies() { + loadNative(&_::rawSchema()); +} + +} // namespace capnp + +#endif // CAPNP_SCHEMA_LOADER_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/schema-parser.h b/phonelibs/capnp-cpp/include/capnp/schema-parser.h new file mode 100644 index 00000000000000..3322bbfbfbc77a --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/schema-parser.h @@ -0,0 +1,207 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_SCHEMA_PARSER_H_ +#define CAPNP_SCHEMA_PARSER_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "schema-loader.h" +#include + +namespace capnp { + +class ParsedSchema; +class SchemaFile; + +class SchemaParser { + // Parses `.capnp` files to produce `Schema` objects. + // + // This class is thread-safe, hence all its methods are const. + +public: + SchemaParser(); + ~SchemaParser() noexcept(false); + + ParsedSchema parseDiskFile(kj::StringPtr displayName, kj::StringPtr diskPath, + kj::ArrayPtr importPath) const; + // Parse a file located on disk. Throws an exception if the file dosen't exist. + // + // Parameters: + // * `displayName`: The name that will appear in the file's schema node. (If the file has + // already been parsed, this will be ignored and the display name from the first time it was + // parsed will be kept.) + // * `diskPath`: The path to the file on disk. + // * `importPath`: Directories to search when resolving absolute imports within this file + // (imports that start with a `/`). Must remain valid until the SchemaParser is destroyed. + // (If the file has already been parsed, this will be ignored and the import path from the + // first time it was parsed will be kept.) + // + // This method is a shortcut, equivalent to: + // parser.parseFile(SchemaFile::newDiskFile(displayName, diskPath, importPath))`; + // + // This method throws an exception if any errors are encountered in the file or in anything the + // file depends on. Note that merely importing another file does not count as a dependency on + // anything in the imported file -- only the imported types which are actually used are + // "dependencies". + + ParsedSchema parseFile(kj::Own&& file) const; + // Advanced interface for parsing a file that may or may not be located in any global namespace. + // Most users will prefer `parseDiskFile()`. + // + // If the file has already been parsed (that is, a SchemaFile that compares equal to this one + // was parsed previously), the existing schema will be returned again. + // + // This method reports errors by calling SchemaFile::reportError() on the file where the error + // is located. If that call does not throw an exception, `parseFile()` may in fact return + // normally. In this case, the result is a best-effort attempt to compile the schema, but it + // may be invalid or corrupt, and using it for anything may cause exceptions to be thrown. + + template + inline void loadCompiledTypeAndDependencies() { + // See SchemaLoader::loadCompiledTypeAndDependencies(). + getLoader().loadCompiledTypeAndDependencies(); + } + +private: + struct Impl; + class ModuleImpl; + kj::Own impl; + mutable bool hadErrors = false; + + ModuleImpl& getModuleImpl(kj::Own&& file) const; + SchemaLoader& getLoader(); + + friend class ParsedSchema; +}; + +class ParsedSchema: public Schema { + // ParsedSchema is an extension of Schema which also has the ability to look up nested nodes + // by name. See `SchemaParser`. + +public: + inline ParsedSchema(): parser(nullptr) {} + + kj::Maybe findNested(kj::StringPtr name) const; + // Gets the nested node with the given name, or returns null if there is no such nested + // declaration. + + ParsedSchema getNested(kj::StringPtr name) const; + // Gets the nested node with the given name, or throws an exception if there is no such nested + // declaration. + +private: + inline ParsedSchema(Schema inner, const SchemaParser& parser): Schema(inner), parser(&parser) {} + + const SchemaParser* parser; + friend class SchemaParser; +}; + +// ======================================================================================= +// Advanced API + +class SchemaFile { + // Abstract interface representing a schema file. You can implement this yourself in order to + // gain more control over how the compiler resolves imports and reads files. For the + // common case of files on disk or other global filesystem-like namespaces, use + // `SchemaFile::newDiskFile()`. + +public: + class FileReader { + public: + virtual bool exists(kj::StringPtr path) const = 0; + virtual kj::Array read(kj::StringPtr path) const = 0; + }; + + class DiskFileReader final: public FileReader { + // Implementation of FileReader that uses the local disk. Files are read using mmap() if + // possible. + + public: + static const DiskFileReader instance; + + bool exists(kj::StringPtr path) const override; + kj::Array read(kj::StringPtr path) const override; + }; + + static kj::Own newDiskFile( + kj::StringPtr displayName, kj::StringPtr diskPath, + kj::ArrayPtr importPath, + const FileReader& fileReader = DiskFileReader::instance); + // Construct a SchemaFile representing a file on disk (or located in the filesystem-like + // namespace represented by `fileReader`). + // + // Parameters: + // * `displayName`: The name that will appear in the file's schema node. + // * `diskPath`: The path to the file on disk. + // * `importPath`: Directories to search when resolving absolute imports within this file + // (imports that start with a `/`). The array content must remain valid as long as the + // SchemaFile exists (which is at least as long as the SchemaParser that parses it exists). + // * `fileReader`: Allows you to use a filesystem other than the actual local disk. Although, + // if you find yourself using this, it may make more sense for you to implement SchemaFile + // yourself. + // + // The SchemaFile compares equal to any other SchemaFile that has exactly the same disk path, + // after canonicalization. + // + // The SchemaFile will throw an exception if any errors are reported. + + // ----------------------------------------------------------------- + // For more control, you can implement this interface. + + virtual kj::StringPtr getDisplayName() const = 0; + // Get the file's name, as it should appear in the schema. + + virtual kj::Array readContent() const = 0; + // Read the file's entire content and return it as a byte array. + + virtual kj::Maybe> import(kj::StringPtr path) const = 0; + // Resolve an import, relative to this file. + // + // `path` is exactly what appears between quotes after the `import` keyword in the source code. + // It is entirely up to the `SchemaFile` to decide how to map this to another file. Typically, + // a leading '/' means that the file is an "absolute" path and is searched for in some list of + // schema file repositories. On the other hand, a path that doesn't start with '/' is relative + // to the importing file. + + virtual bool operator==(const SchemaFile& other) const = 0; + virtual bool operator!=(const SchemaFile& other) const = 0; + virtual size_t hashCode() const = 0; + // Compare two SchemaFiles to see if they refer to the same underlying file. This is an + // optimization used to avoid the need to re-parse a file to check its ID. + + struct SourcePos { + uint byte; + uint line; + uint column; + }; + virtual void reportError(SourcePos start, SourcePos end, kj::StringPtr message) const = 0; + // Report that the file contains an error at the given interval. + +private: + class DiskSchemaFile; +}; + +} // namespace capnp + +#endif // CAPNP_SCHEMA_PARSER_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/schema.capnp b/phonelibs/capnp-cpp/include/capnp/schema.capnp new file mode 100644 index 00000000000000..4bef693f6cfd3e --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/schema.capnp @@ -0,0 +1,498 @@ +# Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +# Licensed under the MIT License: +# +# Permission is hereby granted, free of charge, to any person obtaining a copy +# of this software and associated documentation files (the "Software"), to deal +# in the Software without restriction, including without limitation the rights +# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +# copies of the Software, and to permit persons to whom the Software is +# furnished to do so, subject to the following conditions: +# +# The above copyright notice and this permission notice shall be included in +# all copies or substantial portions of the Software. +# +# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +# THE SOFTWARE. + +using Cxx = import "/capnp/c++.capnp"; + +@0xa93fc509624c72d9; +$Cxx.namespace("capnp::schema"); + +using Id = UInt64; +# The globally-unique ID of a file, type, or annotation. + +struct Node { + id @0 :Id; + + displayName @1 :Text; + # Name to present to humans to identify this Node. You should not attempt to parse this. Its + # format could change. It is not guaranteed to be unique. + # + # (On Zooko's triangle, this is the node's nickname.) + + displayNamePrefixLength @2 :UInt32; + # If you want a shorter version of `displayName` (just naming this node, without its surrounding + # scope), chop off this many characters from the beginning of `displayName`. + + scopeId @3 :Id; + # ID of the lexical parent node. Typically, the scope node will have a NestedNode pointing back + # at this node, but robust code should avoid relying on this (and, in fact, group nodes are not + # listed in the outer struct's nestedNodes, since they are listed in the fields). `scopeId` is + # zero if the node has no parent, which is normally only the case with files, but should be + # allowed for any kind of node (in order to make runtime type generation easier). + + parameters @32 :List(Parameter); + # If this node is parameterized (generic), the list of parameters. Empty for non-generic types. + + isGeneric @33 :Bool; + # True if this node is generic, meaning that it or one of its parent scopes has a non-empty + # `parameters`. + + struct Parameter { + # Information about one of the node's parameters. + + name @0 :Text; + } + + nestedNodes @4 :List(NestedNode); + # List of nodes nested within this node, along with the names under which they were declared. + + struct NestedNode { + name @0 :Text; + # Unqualified symbol name. Unlike Node.displayName, this *can* be used programmatically. + # + # (On Zooko's triangle, this is the node's petname according to its parent scope.) + + id @1 :Id; + # ID of the nested node. Typically, the target node's scopeId points back to this node, but + # robust code should avoid relying on this. + } + + annotations @5 :List(Annotation); + # Annotations applied to this node. + + union { + # Info specific to each kind of node. + + file @6 :Void; + + struct :group { + dataWordCount @7 :UInt16; + # Size of the data section, in words. + + pointerCount @8 :UInt16; + # Size of the pointer section, in pointers (which are one word each). + + preferredListEncoding @9 :ElementSize; + # The preferred element size to use when encoding a list of this struct. If this is anything + # other than `inlineComposite` then the struct is one word or less in size and is a candidate + # for list packing optimization. + + isGroup @10 :Bool; + # If true, then this "struct" node is actually not an independent node, but merely represents + # some named union or group within a particular parent struct. This node's scopeId refers + # to the parent struct, which may itself be a union/group in yet another struct. + # + # All group nodes share the same dataWordCount and pointerCount as the top-level + # struct, and their fields live in the same ordinal and offset spaces as all other fields in + # the struct. + # + # Note that a named union is considered a special kind of group -- in fact, a named union + # is exactly equivalent to a group that contains nothing but an unnamed union. + + discriminantCount @11 :UInt16; + # Number of fields in this struct which are members of an anonymous union, and thus may + # overlap. If this is non-zero, then a 16-bit discriminant is present indicating which + # of the overlapping fields is active. This can never be 1 -- if it is non-zero, it must be + # two or more. + # + # Note that the fields of an unnamed union are considered fields of the scope containing the + # union -- an unnamed union is not its own group. So, a top-level struct may contain a + # non-zero discriminant count. Named unions, on the other hand, are equivalent to groups + # containing unnamed unions. So, a named union has its own independent schema node, with + # `isGroup` = true. + + discriminantOffset @12 :UInt32; + # If `discriminantCount` is non-zero, this is the offset of the union discriminant, in + # multiples of 16 bits. + + fields @13 :List(Field); + # Fields defined within this scope (either the struct's top-level fields, or the fields of + # a particular group; see `isGroup`). + # + # The fields are sorted by ordinal number, but note that because groups share the same + # ordinal space, the field's index in this list is not necessarily exactly its ordinal. + # On the other hand, the field's position in this list does remain the same even as the + # protocol evolves, since it is not possible to insert or remove an earlier ordinal. + # Therefore, for most use cases, if you want to identify a field by number, it may make the + # most sense to use the field's index in this list rather than its ordinal. + } + + enum :group { + enumerants@14 :List(Enumerant); + # Enumerants ordered by numeric value (ordinal). + } + + interface :group { + methods @15 :List(Method); + # Methods ordered by ordinal. + + superclasses @31 :List(Superclass); + # Superclasses of this interface. + } + + const :group { + type @16 :Type; + value @17 :Value; + } + + annotation :group { + type @18 :Type; + + targetsFile @19 :Bool; + targetsConst @20 :Bool; + targetsEnum @21 :Bool; + targetsEnumerant @22 :Bool; + targetsStruct @23 :Bool; + targetsField @24 :Bool; + targetsUnion @25 :Bool; + targetsGroup @26 :Bool; + targetsInterface @27 :Bool; + targetsMethod @28 :Bool; + targetsParam @29 :Bool; + targetsAnnotation @30 :Bool; + } + } +} + +struct Field { + # Schema for a field of a struct. + + name @0 :Text; + + codeOrder @1 :UInt16; + # Indicates where this member appeared in the code, relative to other members. + # Code ordering may have semantic relevance -- programmers tend to place related fields + # together. So, using code ordering makes sense in human-readable formats where ordering is + # otherwise irrelevant, like JSON. The values of codeOrder are tightly-packed, so the maximum + # value is count(members) - 1. Fields that are members of a union are only ordered relative to + # the other members of that union, so the maximum value there is count(union.members). + + annotations @2 :List(Annotation); + + const noDiscriminant :UInt16 = 0xffff; + + discriminantValue @3 :UInt16 = Field.noDiscriminant; + # If the field is in a union, this is the value which the union's discriminant should take when + # the field is active. If the field is not in a union, this is 0xffff. + + union { + slot :group { + # A regular, non-group, non-fixed-list field. + + offset @4 :UInt32; + # Offset, in units of the field's size, from the beginning of the section in which the field + # resides. E.g. for a UInt32 field, multiply this by 4 to get the byte offset from the + # beginning of the data section. + + type @5 :Type; + defaultValue @6 :Value; + + hadExplicitDefault @10 :Bool; + # Whether the default value was specified explicitly. Non-explicit default values are always + # zero or empty values. Usually, whether the default value was explicit shouldn't matter. + # The main use case for this flag is for structs representing method parameters: + # explicitly-defaulted parameters may be allowed to be omitted when calling the method. + } + + group :group { + # A group. + + typeId @7 :Id; + # The ID of the group's node. + } + } + + ordinal :union { + implicit @8 :Void; + explicit @9 :UInt16; + # The original ordinal number given to the field. You probably should NOT use this; if you need + # a numeric identifier for a field, use its position within the field array for its scope. + # The ordinal is given here mainly just so that the original schema text can be reproduced given + # the compiled version -- i.e. so that `capnp compile -ocapnp` can do its job. + } +} + +struct Enumerant { + # Schema for member of an enum. + + name @0 :Text; + + codeOrder @1 :UInt16; + # Specifies order in which the enumerants were declared in the code. + # Like Struct.Field.codeOrder. + + annotations @2 :List(Annotation); +} + +struct Superclass { + id @0 :Id; + brand @1 :Brand; +} + +struct Method { + # Schema for method of an interface. + + name @0 :Text; + + codeOrder @1 :UInt16; + # Specifies order in which the methods were declared in the code. + # Like Struct.Field.codeOrder. + + implicitParameters @7 :List(Node.Parameter); + # The parameters listed in [] (typically, type / generic parameters), whose bindings are intended + # to be inferred rather than specified explicitly, although not all languages support this. + + paramStructType @2 :Id; + # ID of the parameter struct type. If a named parameter list was specified in the method + # declaration (rather than a single struct parameter type) then a corresponding struct type is + # auto-generated. Such an auto-generated type will not be listed in the interface's + # `nestedNodes` and its `scopeId` will be zero -- it is completely detached from the namespace. + # (Awkwardly, it does of course inherit generic parameters from the method's scope, which makes + # this a situation where you can't just climb the scope chain to find where a particular + # generic parameter was introduced. Making the `scopeId` zero was a mistake.) + + paramBrand @5 :Brand; + # Brand of param struct type. + + resultStructType @3 :Id; + # ID of the return struct type; similar to `paramStructType`. + + resultBrand @6 :Brand; + # Brand of result struct type. + + annotations @4 :List(Annotation); +} + +struct Type { + # Represents a type expression. + + union { + # The ordinals intentionally match those of Value. + + void @0 :Void; + bool @1 :Void; + int8 @2 :Void; + int16 @3 :Void; + int32 @4 :Void; + int64 @5 :Void; + uint8 @6 :Void; + uint16 @7 :Void; + uint32 @8 :Void; + uint64 @9 :Void; + float32 @10 :Void; + float64 @11 :Void; + text @12 :Void; + data @13 :Void; + + list :group { + elementType @14 :Type; + } + + enum :group { + typeId @15 :Id; + brand @21 :Brand; + } + struct :group { + typeId @16 :Id; + brand @22 :Brand; + } + interface :group { + typeId @17 :Id; + brand @23 :Brand; + } + + anyPointer :union { + unconstrained :union { + # A regular AnyPointer. + # + # The name "unconstrained" means as opposed to constraining it to match a type parameter. + # In retrospect this name is probably a poor choice given that it may still be constrained + # to be a struct, list, or capability. + + anyKind @18 :Void; # truly AnyPointer + struct @25 :Void; # AnyStruct + list @26 :Void; # AnyList + capability @27 :Void; # Capability + } + + parameter :group { + # This is actually a reference to a type parameter defined within this scope. + + scopeId @19 :Id; + # ID of the generic type whose parameter we're referencing. This should be a parent of the + # current scope. + + parameterIndex @20 :UInt16; + # Index of the parameter within the generic type's parameter list. + } + + implicitMethodParameter :group { + # This is actually a reference to an implicit (generic) parameter of a method. The only + # legal context for this type to appear is inside Method.paramBrand or Method.resultBrand. + + parameterIndex @24 :UInt16; + } + } + } +} + +struct Brand { + # Specifies bindings for parameters of generics. Since these bindings turn a generic into a + # non-generic, we call it the "brand". + + scopes @0 :List(Scope); + # For each of the target type and each of its parent scopes, a parameterization may be included + # in this list. If no parameterization is included for a particular relevant scope, then either + # that scope has no parameters or all parameters should be considered to be `AnyPointer`. + + struct Scope { + scopeId @0 :Id; + # ID of the scope to which these params apply. + + union { + bind @1 :List(Binding); + # List of parameter bindings. + + inherit @2 :Void; + # The place where this Brand appears is actually within this scope or a sub-scope, + # and the bindings for this scope should be inherited from the reference point. + } + } + + struct Binding { + union { + unbound @0 :Void; + type @1 :Type; + + # TODO(someday): Allow non-type parameters? Unsure if useful. + } + } +} + +struct Value { + # Represents a value, e.g. a field default value, constant value, or annotation value. + + union { + # The ordinals intentionally match those of Type. + + void @0 :Void; + bool @1 :Bool; + int8 @2 :Int8; + int16 @3 :Int16; + int32 @4 :Int32; + int64 @5 :Int64; + uint8 @6 :UInt8; + uint16 @7 :UInt16; + uint32 @8 :UInt32; + uint64 @9 :UInt64; + float32 @10 :Float32; + float64 @11 :Float64; + text @12 :Text; + data @13 :Data; + + list @14 :AnyPointer; + + enum @15 :UInt16; + struct @16 :AnyPointer; + + interface @17 :Void; + # The only interface value that can be represented statically is "null", whose methods always + # throw exceptions. + + anyPointer @18 :AnyPointer; + } +} + +struct Annotation { + # Describes an annotation applied to a declaration. Note AnnotationNode describes the + # annotation's declaration, while this describes a use of the annotation. + + id @0 :Id; + # ID of the annotation node. + + brand @2 :Brand; + # Brand of the annotation. + # + # Note that the annotation itself is not allowed to be parameterized, but its scope might be. + + value @1 :Value; +} + +enum ElementSize { + # Possible element sizes for encoded lists. These correspond exactly to the possible values of + # the 3-bit element size component of a list pointer. + + empty @0; # aka "void", but that's a keyword. + bit @1; + byte @2; + twoBytes @3; + fourBytes @4; + eightBytes @5; + pointer @6; + inlineComposite @7; +} + +struct CapnpVersion { + major @0 :UInt16; + minor @1 :UInt8; + micro @2 :UInt8; +} + +struct CodeGeneratorRequest { + capnpVersion @2 :CapnpVersion; + # Version of the `capnp` executable. Generally, code generators should ignore this, but the code + # generators that ship with `capnp` itself will print a warning if this mismatches since that + # probably indicates something is misconfigured. + # + # The first version of 'capnp' to set this was 0.6.0. So, if it's missing, the compiler version + # is older than that. + + nodes @0 :List(Node); + # All nodes parsed by the compiler, including for the files on the command line and their + # imports. + + requestedFiles @1 :List(RequestedFile); + # Files which were listed on the command line. + + struct RequestedFile { + id @0 :Id; + # ID of the file. + + filename @1 :Text; + # Name of the file as it appeared on the command-line (minus the src-prefix). You may use + # this to decide where to write the output. + + imports @2 :List(Import); + # List of all imported paths seen in this file. + + struct Import { + id @0 :Id; + # ID of the imported file. + + name @1 :Text; + # Name which *this* file used to refer to the foreign file. This may be a relative name. + # This information is provided because it might be useful for code generation, e.g. to + # generate #include directives in C++. We don't put this in Node.file because this + # information is only meaningful at compile time anyway. + # + # (On Zooko's triangle, this is the import's petname according to the importing file.) + } + } +} diff --git a/phonelibs/capnp-cpp/include/capnp/schema.capnp.h b/phonelibs/capnp-cpp/include/capnp/schema.capnp.h new file mode 100644 index 00000000000000..1f116c9f8fe7af --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/schema.capnp.h @@ -0,0 +1,7861 @@ +// Generated by Cap'n Proto compiler, DO NOT EDIT +// source: schema.capnp + +#ifndef CAPNP_INCLUDED_a93fc509624c72d9_ +#define CAPNP_INCLUDED_a93fc509624c72d9_ + +#include + +#if CAPNP_VERSION != 6001 +#error "Version mismatch between generated code and library headers. You must use the same version of the Cap'n Proto compiler and library." +#endif + + +namespace capnp { +namespace schemas { + +CAPNP_DECLARE_SCHEMA(e682ab4cf923a417); +CAPNP_DECLARE_SCHEMA(b9521bccf10fa3b1); +CAPNP_DECLARE_SCHEMA(debf55bbfa0fc242); +CAPNP_DECLARE_SCHEMA(9ea0b19b37fb4435); +CAPNP_DECLARE_SCHEMA(b54ab3364333f598); +CAPNP_DECLARE_SCHEMA(e82753cff0c2218f); +CAPNP_DECLARE_SCHEMA(b18aa5ac7a0d9420); +CAPNP_DECLARE_SCHEMA(ec1619d4400a0290); +CAPNP_DECLARE_SCHEMA(9aad50a41f4af45f); +CAPNP_DECLARE_SCHEMA(97b14cbe7cfec712); +CAPNP_DECLARE_SCHEMA(c42305476bb4746f); +CAPNP_DECLARE_SCHEMA(cafccddb68db1d11); +CAPNP_DECLARE_SCHEMA(bb90d5c287870be6); +CAPNP_DECLARE_SCHEMA(978a7cebdc549a4d); +CAPNP_DECLARE_SCHEMA(a9962a9ed0a4d7f8); +CAPNP_DECLARE_SCHEMA(9500cce23b334d80); +CAPNP_DECLARE_SCHEMA(d07378ede1f9cc60); +CAPNP_DECLARE_SCHEMA(87e739250a60ea97); +CAPNP_DECLARE_SCHEMA(9e0e78711a7f87a9); +CAPNP_DECLARE_SCHEMA(ac3a6f60ef4cc6d3); +CAPNP_DECLARE_SCHEMA(ed8bca69f7fb0cbf); +CAPNP_DECLARE_SCHEMA(c2573fe8a23e49f1); +CAPNP_DECLARE_SCHEMA(8e3b5f79fe593656); +CAPNP_DECLARE_SCHEMA(9dd1f724f4614a85); +CAPNP_DECLARE_SCHEMA(baefc9120c56e274); +CAPNP_DECLARE_SCHEMA(903455f06065422b); +CAPNP_DECLARE_SCHEMA(abd73485a9636bc9); +CAPNP_DECLARE_SCHEMA(c863cd16969ee7fc); +CAPNP_DECLARE_SCHEMA(ce23dcd2d7b00c9b); +CAPNP_DECLARE_SCHEMA(f1c8950dab257542); +CAPNP_DECLARE_SCHEMA(d1958f7dba521926); +enum class ElementSize_d1958f7dba521926: uint16_t { + EMPTY, + BIT, + BYTE, + TWO_BYTES, + FOUR_BYTES, + EIGHT_BYTES, + POINTER, + INLINE_COMPOSITE, +}; +CAPNP_DECLARE_ENUM(ElementSize, d1958f7dba521926); +CAPNP_DECLARE_SCHEMA(d85d305b7d839963); +CAPNP_DECLARE_SCHEMA(bfc546f6210ad7ce); +CAPNP_DECLARE_SCHEMA(cfea0eb02e810062); +CAPNP_DECLARE_SCHEMA(ae504193122357e5); + +} // namespace schemas +} // namespace capnp + +namespace capnp { +namespace schema { + +struct Node { + Node() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + FILE, + STRUCT, + ENUM, + INTERFACE, + CONST, + ANNOTATION, + }; + struct Parameter; + struct NestedNode; + struct Struct; + struct Enum; + struct Interface; + struct Const; + struct Annotation; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(e682ab4cf923a417, 5, 6) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Node::Parameter { + Parameter() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(b9521bccf10fa3b1, 0, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Node::NestedNode { + NestedNode() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(debf55bbfa0fc242, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Node::Struct { + Struct() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9ea0b19b37fb4435, 5, 6) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Node::Enum { + Enum() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(b54ab3364333f598, 5, 6) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Node::Interface { + Interface() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(e82753cff0c2218f, 5, 6) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Node::Const { + Const() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(b18aa5ac7a0d9420, 5, 6) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Node::Annotation { + Annotation() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(ec1619d4400a0290, 5, 6) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Field { + Field() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + SLOT, + GROUP, + }; + static constexpr ::uint16_t NO_DISCRIMINANT = 65535u; + struct Slot; + struct Group; + struct Ordinal; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9aad50a41f4af45f, 3, 4) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Field::Slot { + Slot() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(c42305476bb4746f, 3, 4) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Field::Group { + Group() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(cafccddb68db1d11, 3, 4) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Field::Ordinal { + Ordinal() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + IMPLICIT, + EXPLICIT, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(bb90d5c287870be6, 3, 4) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Enumerant { + Enumerant() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(978a7cebdc549a4d, 1, 2) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Superclass { + Superclass() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(a9962a9ed0a4d7f8, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Method { + Method() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9500cce23b334d80, 3, 5) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Type { + Type() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + VOID, + BOOL, + INT8, + INT16, + INT32, + INT64, + UINT8, + UINT16, + UINT32, + UINT64, + FLOAT32, + FLOAT64, + TEXT, + DATA, + LIST, + ENUM, + STRUCT, + INTERFACE, + ANY_POINTER, + }; + struct List; + struct Enum; + struct Struct; + struct Interface; + struct AnyPointer; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(d07378ede1f9cc60, 3, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Type::List { + List() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(87e739250a60ea97, 3, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Type::Enum { + Enum() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9e0e78711a7f87a9, 3, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Type::Struct { + Struct() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(ac3a6f60ef4cc6d3, 3, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Type::Interface { + Interface() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(ed8bca69f7fb0cbf, 3, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Type::AnyPointer { + AnyPointer() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + UNCONSTRAINED, + PARAMETER, + IMPLICIT_METHOD_PARAMETER, + }; + struct Unconstrained; + struct Parameter; + struct ImplicitMethodParameter; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(c2573fe8a23e49f1, 3, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Type::AnyPointer::Unconstrained { + Unconstrained() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + ANY_KIND, + STRUCT, + LIST, + CAPABILITY, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(8e3b5f79fe593656, 3, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Type::AnyPointer::Parameter { + Parameter() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(9dd1f724f4614a85, 3, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Type::AnyPointer::ImplicitMethodParameter { + ImplicitMethodParameter() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(baefc9120c56e274, 3, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Brand { + Brand() = delete; + + class Reader; + class Builder; + class Pipeline; + struct Scope; + struct Binding; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(903455f06065422b, 0, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Brand::Scope { + Scope() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + BIND, + INHERIT, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(abd73485a9636bc9, 2, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Brand::Binding { + Binding() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + UNBOUND, + TYPE, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(c863cd16969ee7fc, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Value { + Value() = delete; + + class Reader; + class Builder; + class Pipeline; + enum Which: uint16_t { + VOID, + BOOL, + INT8, + INT16, + INT32, + INT64, + UINT8, + UINT16, + UINT32, + UINT64, + FLOAT32, + FLOAT64, + TEXT, + DATA, + LIST, + ENUM, + STRUCT, + INTERFACE, + ANY_POINTER, + }; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(ce23dcd2d7b00c9b, 2, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct Annotation { + Annotation() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(f1c8950dab257542, 1, 2) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +typedef ::capnp::schemas::ElementSize_d1958f7dba521926 ElementSize; + +struct CapnpVersion { + CapnpVersion() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(d85d305b7d839963, 1, 0) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct CodeGeneratorRequest { + CodeGeneratorRequest() = delete; + + class Reader; + class Builder; + class Pipeline; + struct RequestedFile; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(bfc546f6210ad7ce, 0, 3) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct CodeGeneratorRequest::RequestedFile { + RequestedFile() = delete; + + class Reader; + class Builder; + class Pipeline; + struct Import; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(cfea0eb02e810062, 1, 2) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +struct CodeGeneratorRequest::RequestedFile::Import { + Import() = delete; + + class Reader; + class Builder; + class Pipeline; + + struct _capnpPrivate { + CAPNP_DECLARE_STRUCT_HEADER(ae504193122357e5, 1, 1) + #if !CAPNP_LITE + static constexpr ::capnp::_::RawBrandedSchema const* brand() { return &schema->defaultBrand; } + #endif // !CAPNP_LITE + }; +}; + +// ======================================================================================= + +class Node::Reader { +public: + typedef Node Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline ::uint64_t getId() const; + + inline bool hasDisplayName() const; + inline ::capnp::Text::Reader getDisplayName() const; + + inline ::uint32_t getDisplayNamePrefixLength() const; + + inline ::uint64_t getScopeId() const; + + inline bool hasNestedNodes() const; + inline ::capnp::List< ::capnp::schema::Node::NestedNode>::Reader getNestedNodes() const; + + inline bool hasAnnotations() const; + inline ::capnp::List< ::capnp::schema::Annotation>::Reader getAnnotations() const; + + inline bool isFile() const; + inline ::capnp::Void getFile() const; + + inline bool isStruct() const; + inline typename Struct::Reader getStruct() const; + + inline bool isEnum() const; + inline typename Enum::Reader getEnum() const; + + inline bool isInterface() const; + inline typename Interface::Reader getInterface() const; + + inline bool isConst() const; + inline typename Const::Reader getConst() const; + + inline bool isAnnotation() const; + inline typename Annotation::Reader getAnnotation() const; + + inline bool hasParameters() const; + inline ::capnp::List< ::capnp::schema::Node::Parameter>::Reader getParameters() const; + + inline bool getIsGeneric() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Node::Builder { +public: + typedef Node Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline ::uint64_t getId(); + inline void setId( ::uint64_t value); + + inline bool hasDisplayName(); + inline ::capnp::Text::Builder getDisplayName(); + inline void setDisplayName( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initDisplayName(unsigned int size); + inline void adoptDisplayName(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownDisplayName(); + + inline ::uint32_t getDisplayNamePrefixLength(); + inline void setDisplayNamePrefixLength( ::uint32_t value); + + inline ::uint64_t getScopeId(); + inline void setScopeId( ::uint64_t value); + + inline bool hasNestedNodes(); + inline ::capnp::List< ::capnp::schema::Node::NestedNode>::Builder getNestedNodes(); + inline void setNestedNodes( ::capnp::List< ::capnp::schema::Node::NestedNode>::Reader value); + inline ::capnp::List< ::capnp::schema::Node::NestedNode>::Builder initNestedNodes(unsigned int size); + inline void adoptNestedNodes(::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::NestedNode>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::NestedNode>> disownNestedNodes(); + + inline bool hasAnnotations(); + inline ::capnp::List< ::capnp::schema::Annotation>::Builder getAnnotations(); + inline void setAnnotations( ::capnp::List< ::capnp::schema::Annotation>::Reader value); + inline ::capnp::List< ::capnp::schema::Annotation>::Builder initAnnotations(unsigned int size); + inline void adoptAnnotations(::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>> disownAnnotations(); + + inline bool isFile(); + inline ::capnp::Void getFile(); + inline void setFile( ::capnp::Void value = ::capnp::VOID); + + inline bool isStruct(); + inline typename Struct::Builder getStruct(); + inline typename Struct::Builder initStruct(); + + inline bool isEnum(); + inline typename Enum::Builder getEnum(); + inline typename Enum::Builder initEnum(); + + inline bool isInterface(); + inline typename Interface::Builder getInterface(); + inline typename Interface::Builder initInterface(); + + inline bool isConst(); + inline typename Const::Builder getConst(); + inline typename Const::Builder initConst(); + + inline bool isAnnotation(); + inline typename Annotation::Builder getAnnotation(); + inline typename Annotation::Builder initAnnotation(); + + inline bool hasParameters(); + inline ::capnp::List< ::capnp::schema::Node::Parameter>::Builder getParameters(); + inline void setParameters( ::capnp::List< ::capnp::schema::Node::Parameter>::Reader value); + inline ::capnp::List< ::capnp::schema::Node::Parameter>::Builder initParameters(unsigned int size); + inline void adoptParameters(::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::Parameter>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::Parameter>> disownParameters(); + + inline bool getIsGeneric(); + inline void setIsGeneric(bool value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Node::Pipeline { +public: + typedef Node Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Node::Parameter::Reader { +public: + typedef Parameter Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasName() const; + inline ::capnp::Text::Reader getName() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Node::Parameter::Builder { +public: + typedef Parameter Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasName(); + inline ::capnp::Text::Builder getName(); + inline void setName( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initName(unsigned int size); + inline void adoptName(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownName(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Node::Parameter::Pipeline { +public: + typedef Parameter Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Node::NestedNode::Reader { +public: + typedef NestedNode Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasName() const; + inline ::capnp::Text::Reader getName() const; + + inline ::uint64_t getId() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Node::NestedNode::Builder { +public: + typedef NestedNode Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasName(); + inline ::capnp::Text::Builder getName(); + inline void setName( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initName(unsigned int size); + inline void adoptName(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownName(); + + inline ::uint64_t getId(); + inline void setId( ::uint64_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Node::NestedNode::Pipeline { +public: + typedef NestedNode Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Node::Struct::Reader { +public: + typedef Struct Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint16_t getDataWordCount() const; + + inline ::uint16_t getPointerCount() const; + + inline ::capnp::schema::ElementSize getPreferredListEncoding() const; + + inline bool getIsGroup() const; + + inline ::uint16_t getDiscriminantCount() const; + + inline ::uint32_t getDiscriminantOffset() const; + + inline bool hasFields() const; + inline ::capnp::List< ::capnp::schema::Field>::Reader getFields() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Node::Struct::Builder { +public: + typedef Struct Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint16_t getDataWordCount(); + inline void setDataWordCount( ::uint16_t value); + + inline ::uint16_t getPointerCount(); + inline void setPointerCount( ::uint16_t value); + + inline ::capnp::schema::ElementSize getPreferredListEncoding(); + inline void setPreferredListEncoding( ::capnp::schema::ElementSize value); + + inline bool getIsGroup(); + inline void setIsGroup(bool value); + + inline ::uint16_t getDiscriminantCount(); + inline void setDiscriminantCount( ::uint16_t value); + + inline ::uint32_t getDiscriminantOffset(); + inline void setDiscriminantOffset( ::uint32_t value); + + inline bool hasFields(); + inline ::capnp::List< ::capnp::schema::Field>::Builder getFields(); + inline void setFields( ::capnp::List< ::capnp::schema::Field>::Reader value); + inline ::capnp::List< ::capnp::schema::Field>::Builder initFields(unsigned int size); + inline void adoptFields(::capnp::Orphan< ::capnp::List< ::capnp::schema::Field>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Field>> disownFields(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Node::Struct::Pipeline { +public: + typedef Struct Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Node::Enum::Reader { +public: + typedef Enum Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasEnumerants() const; + inline ::capnp::List< ::capnp::schema::Enumerant>::Reader getEnumerants() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Node::Enum::Builder { +public: + typedef Enum Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasEnumerants(); + inline ::capnp::List< ::capnp::schema::Enumerant>::Builder getEnumerants(); + inline void setEnumerants( ::capnp::List< ::capnp::schema::Enumerant>::Reader value); + inline ::capnp::List< ::capnp::schema::Enumerant>::Builder initEnumerants(unsigned int size); + inline void adoptEnumerants(::capnp::Orphan< ::capnp::List< ::capnp::schema::Enumerant>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Enumerant>> disownEnumerants(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Node::Enum::Pipeline { +public: + typedef Enum Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Node::Interface::Reader { +public: + typedef Interface Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasMethods() const; + inline ::capnp::List< ::capnp::schema::Method>::Reader getMethods() const; + + inline bool hasSuperclasses() const; + inline ::capnp::List< ::capnp::schema::Superclass>::Reader getSuperclasses() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Node::Interface::Builder { +public: + typedef Interface Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasMethods(); + inline ::capnp::List< ::capnp::schema::Method>::Builder getMethods(); + inline void setMethods( ::capnp::List< ::capnp::schema::Method>::Reader value); + inline ::capnp::List< ::capnp::schema::Method>::Builder initMethods(unsigned int size); + inline void adoptMethods(::capnp::Orphan< ::capnp::List< ::capnp::schema::Method>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Method>> disownMethods(); + + inline bool hasSuperclasses(); + inline ::capnp::List< ::capnp::schema::Superclass>::Builder getSuperclasses(); + inline void setSuperclasses( ::capnp::List< ::capnp::schema::Superclass>::Reader value); + inline ::capnp::List< ::capnp::schema::Superclass>::Builder initSuperclasses(unsigned int size); + inline void adoptSuperclasses(::capnp::Orphan< ::capnp::List< ::capnp::schema::Superclass>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Superclass>> disownSuperclasses(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Node::Interface::Pipeline { +public: + typedef Interface Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Node::Const::Reader { +public: + typedef Const Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasType() const; + inline ::capnp::schema::Type::Reader getType() const; + + inline bool hasValue() const; + inline ::capnp::schema::Value::Reader getValue() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Node::Const::Builder { +public: + typedef Const Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasType(); + inline ::capnp::schema::Type::Builder getType(); + inline void setType( ::capnp::schema::Type::Reader value); + inline ::capnp::schema::Type::Builder initType(); + inline void adoptType(::capnp::Orphan< ::capnp::schema::Type>&& value); + inline ::capnp::Orphan< ::capnp::schema::Type> disownType(); + + inline bool hasValue(); + inline ::capnp::schema::Value::Builder getValue(); + inline void setValue( ::capnp::schema::Value::Reader value); + inline ::capnp::schema::Value::Builder initValue(); + inline void adoptValue(::capnp::Orphan< ::capnp::schema::Value>&& value); + inline ::capnp::Orphan< ::capnp::schema::Value> disownValue(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Node::Const::Pipeline { +public: + typedef Const Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Type::Pipeline getType(); + inline ::capnp::schema::Value::Pipeline getValue(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Node::Annotation::Reader { +public: + typedef Annotation Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasType() const; + inline ::capnp::schema::Type::Reader getType() const; + + inline bool getTargetsFile() const; + + inline bool getTargetsConst() const; + + inline bool getTargetsEnum() const; + + inline bool getTargetsEnumerant() const; + + inline bool getTargetsStruct() const; + + inline bool getTargetsField() const; + + inline bool getTargetsUnion() const; + + inline bool getTargetsGroup() const; + + inline bool getTargetsInterface() const; + + inline bool getTargetsMethod() const; + + inline bool getTargetsParam() const; + + inline bool getTargetsAnnotation() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Node::Annotation::Builder { +public: + typedef Annotation Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasType(); + inline ::capnp::schema::Type::Builder getType(); + inline void setType( ::capnp::schema::Type::Reader value); + inline ::capnp::schema::Type::Builder initType(); + inline void adoptType(::capnp::Orphan< ::capnp::schema::Type>&& value); + inline ::capnp::Orphan< ::capnp::schema::Type> disownType(); + + inline bool getTargetsFile(); + inline void setTargetsFile(bool value); + + inline bool getTargetsConst(); + inline void setTargetsConst(bool value); + + inline bool getTargetsEnum(); + inline void setTargetsEnum(bool value); + + inline bool getTargetsEnumerant(); + inline void setTargetsEnumerant(bool value); + + inline bool getTargetsStruct(); + inline void setTargetsStruct(bool value); + + inline bool getTargetsField(); + inline void setTargetsField(bool value); + + inline bool getTargetsUnion(); + inline void setTargetsUnion(bool value); + + inline bool getTargetsGroup(); + inline void setTargetsGroup(bool value); + + inline bool getTargetsInterface(); + inline void setTargetsInterface(bool value); + + inline bool getTargetsMethod(); + inline void setTargetsMethod(bool value); + + inline bool getTargetsParam(); + inline void setTargetsParam(bool value); + + inline bool getTargetsAnnotation(); + inline void setTargetsAnnotation(bool value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Node::Annotation::Pipeline { +public: + typedef Annotation Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Type::Pipeline getType(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Field::Reader { +public: + typedef Field Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool hasName() const; + inline ::capnp::Text::Reader getName() const; + + inline ::uint16_t getCodeOrder() const; + + inline bool hasAnnotations() const; + inline ::capnp::List< ::capnp::schema::Annotation>::Reader getAnnotations() const; + + inline ::uint16_t getDiscriminantValue() const; + + inline bool isSlot() const; + inline typename Slot::Reader getSlot() const; + + inline bool isGroup() const; + inline typename Group::Reader getGroup() const; + + inline typename Ordinal::Reader getOrdinal() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Field::Builder { +public: + typedef Field Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool hasName(); + inline ::capnp::Text::Builder getName(); + inline void setName( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initName(unsigned int size); + inline void adoptName(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownName(); + + inline ::uint16_t getCodeOrder(); + inline void setCodeOrder( ::uint16_t value); + + inline bool hasAnnotations(); + inline ::capnp::List< ::capnp::schema::Annotation>::Builder getAnnotations(); + inline void setAnnotations( ::capnp::List< ::capnp::schema::Annotation>::Reader value); + inline ::capnp::List< ::capnp::schema::Annotation>::Builder initAnnotations(unsigned int size); + inline void adoptAnnotations(::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>> disownAnnotations(); + + inline ::uint16_t getDiscriminantValue(); + inline void setDiscriminantValue( ::uint16_t value); + + inline bool isSlot(); + inline typename Slot::Builder getSlot(); + inline typename Slot::Builder initSlot(); + + inline bool isGroup(); + inline typename Group::Builder getGroup(); + inline typename Group::Builder initGroup(); + + inline typename Ordinal::Builder getOrdinal(); + inline typename Ordinal::Builder initOrdinal(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Field::Pipeline { +public: + typedef Field Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline typename Ordinal::Pipeline getOrdinal(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Field::Slot::Reader { +public: + typedef Slot Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint32_t getOffset() const; + + inline bool hasType() const; + inline ::capnp::schema::Type::Reader getType() const; + + inline bool hasDefaultValue() const; + inline ::capnp::schema::Value::Reader getDefaultValue() const; + + inline bool getHadExplicitDefault() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Field::Slot::Builder { +public: + typedef Slot Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint32_t getOffset(); + inline void setOffset( ::uint32_t value); + + inline bool hasType(); + inline ::capnp::schema::Type::Builder getType(); + inline void setType( ::capnp::schema::Type::Reader value); + inline ::capnp::schema::Type::Builder initType(); + inline void adoptType(::capnp::Orphan< ::capnp::schema::Type>&& value); + inline ::capnp::Orphan< ::capnp::schema::Type> disownType(); + + inline bool hasDefaultValue(); + inline ::capnp::schema::Value::Builder getDefaultValue(); + inline void setDefaultValue( ::capnp::schema::Value::Reader value); + inline ::capnp::schema::Value::Builder initDefaultValue(); + inline void adoptDefaultValue(::capnp::Orphan< ::capnp::schema::Value>&& value); + inline ::capnp::Orphan< ::capnp::schema::Value> disownDefaultValue(); + + inline bool getHadExplicitDefault(); + inline void setHadExplicitDefault(bool value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Field::Slot::Pipeline { +public: + typedef Slot Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Type::Pipeline getType(); + inline ::capnp::schema::Value::Pipeline getDefaultValue(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Field::Group::Reader { +public: + typedef Group Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint64_t getTypeId() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Field::Group::Builder { +public: + typedef Group Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint64_t getTypeId(); + inline void setTypeId( ::uint64_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Field::Group::Pipeline { +public: + typedef Group Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Field::Ordinal::Reader { +public: + typedef Ordinal Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isImplicit() const; + inline ::capnp::Void getImplicit() const; + + inline bool isExplicit() const; + inline ::uint16_t getExplicit() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Field::Ordinal::Builder { +public: + typedef Ordinal Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isImplicit(); + inline ::capnp::Void getImplicit(); + inline void setImplicit( ::capnp::Void value = ::capnp::VOID); + + inline bool isExplicit(); + inline ::uint16_t getExplicit(); + inline void setExplicit( ::uint16_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Field::Ordinal::Pipeline { +public: + typedef Ordinal Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Enumerant::Reader { +public: + typedef Enumerant Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasName() const; + inline ::capnp::Text::Reader getName() const; + + inline ::uint16_t getCodeOrder() const; + + inline bool hasAnnotations() const; + inline ::capnp::List< ::capnp::schema::Annotation>::Reader getAnnotations() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Enumerant::Builder { +public: + typedef Enumerant Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasName(); + inline ::capnp::Text::Builder getName(); + inline void setName( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initName(unsigned int size); + inline void adoptName(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownName(); + + inline ::uint16_t getCodeOrder(); + inline void setCodeOrder( ::uint16_t value); + + inline bool hasAnnotations(); + inline ::capnp::List< ::capnp::schema::Annotation>::Builder getAnnotations(); + inline void setAnnotations( ::capnp::List< ::capnp::schema::Annotation>::Reader value); + inline ::capnp::List< ::capnp::schema::Annotation>::Builder initAnnotations(unsigned int size); + inline void adoptAnnotations(::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>> disownAnnotations(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Enumerant::Pipeline { +public: + typedef Enumerant Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Superclass::Reader { +public: + typedef Superclass Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint64_t getId() const; + + inline bool hasBrand() const; + inline ::capnp::schema::Brand::Reader getBrand() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Superclass::Builder { +public: + typedef Superclass Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint64_t getId(); + inline void setId( ::uint64_t value); + + inline bool hasBrand(); + inline ::capnp::schema::Brand::Builder getBrand(); + inline void setBrand( ::capnp::schema::Brand::Reader value); + inline ::capnp::schema::Brand::Builder initBrand(); + inline void adoptBrand(::capnp::Orphan< ::capnp::schema::Brand>&& value); + inline ::capnp::Orphan< ::capnp::schema::Brand> disownBrand(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Superclass::Pipeline { +public: + typedef Superclass Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Brand::Pipeline getBrand(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Method::Reader { +public: + typedef Method Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasName() const; + inline ::capnp::Text::Reader getName() const; + + inline ::uint16_t getCodeOrder() const; + + inline ::uint64_t getParamStructType() const; + + inline ::uint64_t getResultStructType() const; + + inline bool hasAnnotations() const; + inline ::capnp::List< ::capnp::schema::Annotation>::Reader getAnnotations() const; + + inline bool hasParamBrand() const; + inline ::capnp::schema::Brand::Reader getParamBrand() const; + + inline bool hasResultBrand() const; + inline ::capnp::schema::Brand::Reader getResultBrand() const; + + inline bool hasImplicitParameters() const; + inline ::capnp::List< ::capnp::schema::Node::Parameter>::Reader getImplicitParameters() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Method::Builder { +public: + typedef Method Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasName(); + inline ::capnp::Text::Builder getName(); + inline void setName( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initName(unsigned int size); + inline void adoptName(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownName(); + + inline ::uint16_t getCodeOrder(); + inline void setCodeOrder( ::uint16_t value); + + inline ::uint64_t getParamStructType(); + inline void setParamStructType( ::uint64_t value); + + inline ::uint64_t getResultStructType(); + inline void setResultStructType( ::uint64_t value); + + inline bool hasAnnotations(); + inline ::capnp::List< ::capnp::schema::Annotation>::Builder getAnnotations(); + inline void setAnnotations( ::capnp::List< ::capnp::schema::Annotation>::Reader value); + inline ::capnp::List< ::capnp::schema::Annotation>::Builder initAnnotations(unsigned int size); + inline void adoptAnnotations(::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>> disownAnnotations(); + + inline bool hasParamBrand(); + inline ::capnp::schema::Brand::Builder getParamBrand(); + inline void setParamBrand( ::capnp::schema::Brand::Reader value); + inline ::capnp::schema::Brand::Builder initParamBrand(); + inline void adoptParamBrand(::capnp::Orphan< ::capnp::schema::Brand>&& value); + inline ::capnp::Orphan< ::capnp::schema::Brand> disownParamBrand(); + + inline bool hasResultBrand(); + inline ::capnp::schema::Brand::Builder getResultBrand(); + inline void setResultBrand( ::capnp::schema::Brand::Reader value); + inline ::capnp::schema::Brand::Builder initResultBrand(); + inline void adoptResultBrand(::capnp::Orphan< ::capnp::schema::Brand>&& value); + inline ::capnp::Orphan< ::capnp::schema::Brand> disownResultBrand(); + + inline bool hasImplicitParameters(); + inline ::capnp::List< ::capnp::schema::Node::Parameter>::Builder getImplicitParameters(); + inline void setImplicitParameters( ::capnp::List< ::capnp::schema::Node::Parameter>::Reader value); + inline ::capnp::List< ::capnp::schema::Node::Parameter>::Builder initImplicitParameters(unsigned int size); + inline void adoptImplicitParameters(::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::Parameter>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::Parameter>> disownImplicitParameters(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Method::Pipeline { +public: + typedef Method Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Brand::Pipeline getParamBrand(); + inline ::capnp::schema::Brand::Pipeline getResultBrand(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Type::Reader { +public: + typedef Type Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isVoid() const; + inline ::capnp::Void getVoid() const; + + inline bool isBool() const; + inline ::capnp::Void getBool() const; + + inline bool isInt8() const; + inline ::capnp::Void getInt8() const; + + inline bool isInt16() const; + inline ::capnp::Void getInt16() const; + + inline bool isInt32() const; + inline ::capnp::Void getInt32() const; + + inline bool isInt64() const; + inline ::capnp::Void getInt64() const; + + inline bool isUint8() const; + inline ::capnp::Void getUint8() const; + + inline bool isUint16() const; + inline ::capnp::Void getUint16() const; + + inline bool isUint32() const; + inline ::capnp::Void getUint32() const; + + inline bool isUint64() const; + inline ::capnp::Void getUint64() const; + + inline bool isFloat32() const; + inline ::capnp::Void getFloat32() const; + + inline bool isFloat64() const; + inline ::capnp::Void getFloat64() const; + + inline bool isText() const; + inline ::capnp::Void getText() const; + + inline bool isData() const; + inline ::capnp::Void getData() const; + + inline bool isList() const; + inline typename List::Reader getList() const; + + inline bool isEnum() const; + inline typename Enum::Reader getEnum() const; + + inline bool isStruct() const; + inline typename Struct::Reader getStruct() const; + + inline bool isInterface() const; + inline typename Interface::Reader getInterface() const; + + inline bool isAnyPointer() const; + inline typename AnyPointer::Reader getAnyPointer() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Type::Builder { +public: + typedef Type Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isVoid(); + inline ::capnp::Void getVoid(); + inline void setVoid( ::capnp::Void value = ::capnp::VOID); + + inline bool isBool(); + inline ::capnp::Void getBool(); + inline void setBool( ::capnp::Void value = ::capnp::VOID); + + inline bool isInt8(); + inline ::capnp::Void getInt8(); + inline void setInt8( ::capnp::Void value = ::capnp::VOID); + + inline bool isInt16(); + inline ::capnp::Void getInt16(); + inline void setInt16( ::capnp::Void value = ::capnp::VOID); + + inline bool isInt32(); + inline ::capnp::Void getInt32(); + inline void setInt32( ::capnp::Void value = ::capnp::VOID); + + inline bool isInt64(); + inline ::capnp::Void getInt64(); + inline void setInt64( ::capnp::Void value = ::capnp::VOID); + + inline bool isUint8(); + inline ::capnp::Void getUint8(); + inline void setUint8( ::capnp::Void value = ::capnp::VOID); + + inline bool isUint16(); + inline ::capnp::Void getUint16(); + inline void setUint16( ::capnp::Void value = ::capnp::VOID); + + inline bool isUint32(); + inline ::capnp::Void getUint32(); + inline void setUint32( ::capnp::Void value = ::capnp::VOID); + + inline bool isUint64(); + inline ::capnp::Void getUint64(); + inline void setUint64( ::capnp::Void value = ::capnp::VOID); + + inline bool isFloat32(); + inline ::capnp::Void getFloat32(); + inline void setFloat32( ::capnp::Void value = ::capnp::VOID); + + inline bool isFloat64(); + inline ::capnp::Void getFloat64(); + inline void setFloat64( ::capnp::Void value = ::capnp::VOID); + + inline bool isText(); + inline ::capnp::Void getText(); + inline void setText( ::capnp::Void value = ::capnp::VOID); + + inline bool isData(); + inline ::capnp::Void getData(); + inline void setData( ::capnp::Void value = ::capnp::VOID); + + inline bool isList(); + inline typename List::Builder getList(); + inline typename List::Builder initList(); + + inline bool isEnum(); + inline typename Enum::Builder getEnum(); + inline typename Enum::Builder initEnum(); + + inline bool isStruct(); + inline typename Struct::Builder getStruct(); + inline typename Struct::Builder initStruct(); + + inline bool isInterface(); + inline typename Interface::Builder getInterface(); + inline typename Interface::Builder initInterface(); + + inline bool isAnyPointer(); + inline typename AnyPointer::Builder getAnyPointer(); + inline typename AnyPointer::Builder initAnyPointer(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Type::Pipeline { +public: + typedef Type Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Type::List::Reader { +public: + typedef List Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasElementType() const; + inline ::capnp::schema::Type::Reader getElementType() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Type::List::Builder { +public: + typedef List Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasElementType(); + inline ::capnp::schema::Type::Builder getElementType(); + inline void setElementType( ::capnp::schema::Type::Reader value); + inline ::capnp::schema::Type::Builder initElementType(); + inline void adoptElementType(::capnp::Orphan< ::capnp::schema::Type>&& value); + inline ::capnp::Orphan< ::capnp::schema::Type> disownElementType(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Type::List::Pipeline { +public: + typedef List Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Type::Pipeline getElementType(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Type::Enum::Reader { +public: + typedef Enum Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint64_t getTypeId() const; + + inline bool hasBrand() const; + inline ::capnp::schema::Brand::Reader getBrand() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Type::Enum::Builder { +public: + typedef Enum Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint64_t getTypeId(); + inline void setTypeId( ::uint64_t value); + + inline bool hasBrand(); + inline ::capnp::schema::Brand::Builder getBrand(); + inline void setBrand( ::capnp::schema::Brand::Reader value); + inline ::capnp::schema::Brand::Builder initBrand(); + inline void adoptBrand(::capnp::Orphan< ::capnp::schema::Brand>&& value); + inline ::capnp::Orphan< ::capnp::schema::Brand> disownBrand(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Type::Enum::Pipeline { +public: + typedef Enum Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Brand::Pipeline getBrand(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Type::Struct::Reader { +public: + typedef Struct Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint64_t getTypeId() const; + + inline bool hasBrand() const; + inline ::capnp::schema::Brand::Reader getBrand() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Type::Struct::Builder { +public: + typedef Struct Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint64_t getTypeId(); + inline void setTypeId( ::uint64_t value); + + inline bool hasBrand(); + inline ::capnp::schema::Brand::Builder getBrand(); + inline void setBrand( ::capnp::schema::Brand::Reader value); + inline ::capnp::schema::Brand::Builder initBrand(); + inline void adoptBrand(::capnp::Orphan< ::capnp::schema::Brand>&& value); + inline ::capnp::Orphan< ::capnp::schema::Brand> disownBrand(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Type::Struct::Pipeline { +public: + typedef Struct Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Brand::Pipeline getBrand(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Type::Interface::Reader { +public: + typedef Interface Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint64_t getTypeId() const; + + inline bool hasBrand() const; + inline ::capnp::schema::Brand::Reader getBrand() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Type::Interface::Builder { +public: + typedef Interface Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint64_t getTypeId(); + inline void setTypeId( ::uint64_t value); + + inline bool hasBrand(); + inline ::capnp::schema::Brand::Builder getBrand(); + inline void setBrand( ::capnp::schema::Brand::Reader value); + inline ::capnp::schema::Brand::Builder initBrand(); + inline void adoptBrand(::capnp::Orphan< ::capnp::schema::Brand>&& value); + inline ::capnp::Orphan< ::capnp::schema::Brand> disownBrand(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Type::Interface::Pipeline { +public: + typedef Interface Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Brand::Pipeline getBrand(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Type::AnyPointer::Reader { +public: + typedef AnyPointer Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isUnconstrained() const; + inline typename Unconstrained::Reader getUnconstrained() const; + + inline bool isParameter() const; + inline typename Parameter::Reader getParameter() const; + + inline bool isImplicitMethodParameter() const; + inline typename ImplicitMethodParameter::Reader getImplicitMethodParameter() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Type::AnyPointer::Builder { +public: + typedef AnyPointer Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isUnconstrained(); + inline typename Unconstrained::Builder getUnconstrained(); + inline typename Unconstrained::Builder initUnconstrained(); + + inline bool isParameter(); + inline typename Parameter::Builder getParameter(); + inline typename Parameter::Builder initParameter(); + + inline bool isImplicitMethodParameter(); + inline typename ImplicitMethodParameter::Builder getImplicitMethodParameter(); + inline typename ImplicitMethodParameter::Builder initImplicitMethodParameter(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Type::AnyPointer::Pipeline { +public: + typedef AnyPointer Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Type::AnyPointer::Unconstrained::Reader { +public: + typedef Unconstrained Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isAnyKind() const; + inline ::capnp::Void getAnyKind() const; + + inline bool isStruct() const; + inline ::capnp::Void getStruct() const; + + inline bool isList() const; + inline ::capnp::Void getList() const; + + inline bool isCapability() const; + inline ::capnp::Void getCapability() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Type::AnyPointer::Unconstrained::Builder { +public: + typedef Unconstrained Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isAnyKind(); + inline ::capnp::Void getAnyKind(); + inline void setAnyKind( ::capnp::Void value = ::capnp::VOID); + + inline bool isStruct(); + inline ::capnp::Void getStruct(); + inline void setStruct( ::capnp::Void value = ::capnp::VOID); + + inline bool isList(); + inline ::capnp::Void getList(); + inline void setList( ::capnp::Void value = ::capnp::VOID); + + inline bool isCapability(); + inline ::capnp::Void getCapability(); + inline void setCapability( ::capnp::Void value = ::capnp::VOID); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Type::AnyPointer::Unconstrained::Pipeline { +public: + typedef Unconstrained Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Type::AnyPointer::Parameter::Reader { +public: + typedef Parameter Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint64_t getScopeId() const; + + inline ::uint16_t getParameterIndex() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Type::AnyPointer::Parameter::Builder { +public: + typedef Parameter Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint64_t getScopeId(); + inline void setScopeId( ::uint64_t value); + + inline ::uint16_t getParameterIndex(); + inline void setParameterIndex( ::uint16_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Type::AnyPointer::Parameter::Pipeline { +public: + typedef Parameter Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Type::AnyPointer::ImplicitMethodParameter::Reader { +public: + typedef ImplicitMethodParameter Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint16_t getParameterIndex() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Type::AnyPointer::ImplicitMethodParameter::Builder { +public: + typedef ImplicitMethodParameter Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint16_t getParameterIndex(); + inline void setParameterIndex( ::uint16_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Type::AnyPointer::ImplicitMethodParameter::Pipeline { +public: + typedef ImplicitMethodParameter Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Brand::Reader { +public: + typedef Brand Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasScopes() const; + inline ::capnp::List< ::capnp::schema::Brand::Scope>::Reader getScopes() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Brand::Builder { +public: + typedef Brand Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasScopes(); + inline ::capnp::List< ::capnp::schema::Brand::Scope>::Builder getScopes(); + inline void setScopes( ::capnp::List< ::capnp::schema::Brand::Scope>::Reader value); + inline ::capnp::List< ::capnp::schema::Brand::Scope>::Builder initScopes(unsigned int size); + inline void adoptScopes(::capnp::Orphan< ::capnp::List< ::capnp::schema::Brand::Scope>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Brand::Scope>> disownScopes(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Brand::Pipeline { +public: + typedef Brand Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Brand::Scope::Reader { +public: + typedef Scope Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline ::uint64_t getScopeId() const; + + inline bool isBind() const; + inline bool hasBind() const; + inline ::capnp::List< ::capnp::schema::Brand::Binding>::Reader getBind() const; + + inline bool isInherit() const; + inline ::capnp::Void getInherit() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Brand::Scope::Builder { +public: + typedef Scope Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline ::uint64_t getScopeId(); + inline void setScopeId( ::uint64_t value); + + inline bool isBind(); + inline bool hasBind(); + inline ::capnp::List< ::capnp::schema::Brand::Binding>::Builder getBind(); + inline void setBind( ::capnp::List< ::capnp::schema::Brand::Binding>::Reader value); + inline ::capnp::List< ::capnp::schema::Brand::Binding>::Builder initBind(unsigned int size); + inline void adoptBind(::capnp::Orphan< ::capnp::List< ::capnp::schema::Brand::Binding>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Brand::Binding>> disownBind(); + + inline bool isInherit(); + inline ::capnp::Void getInherit(); + inline void setInherit( ::capnp::Void value = ::capnp::VOID); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Brand::Scope::Pipeline { +public: + typedef Scope Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Brand::Binding::Reader { +public: + typedef Binding Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isUnbound() const; + inline ::capnp::Void getUnbound() const; + + inline bool isType() const; + inline bool hasType() const; + inline ::capnp::schema::Type::Reader getType() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Brand::Binding::Builder { +public: + typedef Binding Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isUnbound(); + inline ::capnp::Void getUnbound(); + inline void setUnbound( ::capnp::Void value = ::capnp::VOID); + + inline bool isType(); + inline bool hasType(); + inline ::capnp::schema::Type::Builder getType(); + inline void setType( ::capnp::schema::Type::Reader value); + inline ::capnp::schema::Type::Builder initType(); + inline void adoptType(::capnp::Orphan< ::capnp::schema::Type>&& value); + inline ::capnp::Orphan< ::capnp::schema::Type> disownType(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Brand::Binding::Pipeline { +public: + typedef Binding Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Value::Reader { +public: + typedef Value Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline Which which() const; + inline bool isVoid() const; + inline ::capnp::Void getVoid() const; + + inline bool isBool() const; + inline bool getBool() const; + + inline bool isInt8() const; + inline ::int8_t getInt8() const; + + inline bool isInt16() const; + inline ::int16_t getInt16() const; + + inline bool isInt32() const; + inline ::int32_t getInt32() const; + + inline bool isInt64() const; + inline ::int64_t getInt64() const; + + inline bool isUint8() const; + inline ::uint8_t getUint8() const; + + inline bool isUint16() const; + inline ::uint16_t getUint16() const; + + inline bool isUint32() const; + inline ::uint32_t getUint32() const; + + inline bool isUint64() const; + inline ::uint64_t getUint64() const; + + inline bool isFloat32() const; + inline float getFloat32() const; + + inline bool isFloat64() const; + inline double getFloat64() const; + + inline bool isText() const; + inline bool hasText() const; + inline ::capnp::Text::Reader getText() const; + + inline bool isData() const; + inline bool hasData() const; + inline ::capnp::Data::Reader getData() const; + + inline bool isList() const; + inline bool hasList() const; + inline ::capnp::AnyPointer::Reader getList() const; + + inline bool isEnum() const; + inline ::uint16_t getEnum() const; + + inline bool isStruct() const; + inline bool hasStruct() const; + inline ::capnp::AnyPointer::Reader getStruct() const; + + inline bool isInterface() const; + inline ::capnp::Void getInterface() const; + + inline bool isAnyPointer() const; + inline bool hasAnyPointer() const; + inline ::capnp::AnyPointer::Reader getAnyPointer() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Value::Builder { +public: + typedef Value Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline Which which(); + inline bool isVoid(); + inline ::capnp::Void getVoid(); + inline void setVoid( ::capnp::Void value = ::capnp::VOID); + + inline bool isBool(); + inline bool getBool(); + inline void setBool(bool value); + + inline bool isInt8(); + inline ::int8_t getInt8(); + inline void setInt8( ::int8_t value); + + inline bool isInt16(); + inline ::int16_t getInt16(); + inline void setInt16( ::int16_t value); + + inline bool isInt32(); + inline ::int32_t getInt32(); + inline void setInt32( ::int32_t value); + + inline bool isInt64(); + inline ::int64_t getInt64(); + inline void setInt64( ::int64_t value); + + inline bool isUint8(); + inline ::uint8_t getUint8(); + inline void setUint8( ::uint8_t value); + + inline bool isUint16(); + inline ::uint16_t getUint16(); + inline void setUint16( ::uint16_t value); + + inline bool isUint32(); + inline ::uint32_t getUint32(); + inline void setUint32( ::uint32_t value); + + inline bool isUint64(); + inline ::uint64_t getUint64(); + inline void setUint64( ::uint64_t value); + + inline bool isFloat32(); + inline float getFloat32(); + inline void setFloat32(float value); + + inline bool isFloat64(); + inline double getFloat64(); + inline void setFloat64(double value); + + inline bool isText(); + inline bool hasText(); + inline ::capnp::Text::Builder getText(); + inline void setText( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initText(unsigned int size); + inline void adoptText(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownText(); + + inline bool isData(); + inline bool hasData(); + inline ::capnp::Data::Builder getData(); + inline void setData( ::capnp::Data::Reader value); + inline ::capnp::Data::Builder initData(unsigned int size); + inline void adoptData(::capnp::Orphan< ::capnp::Data>&& value); + inline ::capnp::Orphan< ::capnp::Data> disownData(); + + inline bool isList(); + inline bool hasList(); + inline ::capnp::AnyPointer::Builder getList(); + inline ::capnp::AnyPointer::Builder initList(); + + inline bool isEnum(); + inline ::uint16_t getEnum(); + inline void setEnum( ::uint16_t value); + + inline bool isStruct(); + inline bool hasStruct(); + inline ::capnp::AnyPointer::Builder getStruct(); + inline ::capnp::AnyPointer::Builder initStruct(); + + inline bool isInterface(); + inline ::capnp::Void getInterface(); + inline void setInterface( ::capnp::Void value = ::capnp::VOID); + + inline bool isAnyPointer(); + inline bool hasAnyPointer(); + inline ::capnp::AnyPointer::Builder getAnyPointer(); + inline ::capnp::AnyPointer::Builder initAnyPointer(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Value::Pipeline { +public: + typedef Value Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class Annotation::Reader { +public: + typedef Annotation Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint64_t getId() const; + + inline bool hasValue() const; + inline ::capnp::schema::Value::Reader getValue() const; + + inline bool hasBrand() const; + inline ::capnp::schema::Brand::Reader getBrand() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class Annotation::Builder { +public: + typedef Annotation Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint64_t getId(); + inline void setId( ::uint64_t value); + + inline bool hasValue(); + inline ::capnp::schema::Value::Builder getValue(); + inline void setValue( ::capnp::schema::Value::Reader value); + inline ::capnp::schema::Value::Builder initValue(); + inline void adoptValue(::capnp::Orphan< ::capnp::schema::Value>&& value); + inline ::capnp::Orphan< ::capnp::schema::Value> disownValue(); + + inline bool hasBrand(); + inline ::capnp::schema::Brand::Builder getBrand(); + inline void setBrand( ::capnp::schema::Brand::Reader value); + inline ::capnp::schema::Brand::Builder initBrand(); + inline void adoptBrand(::capnp::Orphan< ::capnp::schema::Brand>&& value); + inline ::capnp::Orphan< ::capnp::schema::Brand> disownBrand(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class Annotation::Pipeline { +public: + typedef Annotation Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::Value::Pipeline getValue(); + inline ::capnp::schema::Brand::Pipeline getBrand(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class CapnpVersion::Reader { +public: + typedef CapnpVersion Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint16_t getMajor() const; + + inline ::uint8_t getMinor() const; + + inline ::uint8_t getMicro() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class CapnpVersion::Builder { +public: + typedef CapnpVersion Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint16_t getMajor(); + inline void setMajor( ::uint16_t value); + + inline ::uint8_t getMinor(); + inline void setMinor( ::uint8_t value); + + inline ::uint8_t getMicro(); + inline void setMicro( ::uint8_t value); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class CapnpVersion::Pipeline { +public: + typedef CapnpVersion Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class CodeGeneratorRequest::Reader { +public: + typedef CodeGeneratorRequest Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline bool hasNodes() const; + inline ::capnp::List< ::capnp::schema::Node>::Reader getNodes() const; + + inline bool hasRequestedFiles() const; + inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>::Reader getRequestedFiles() const; + + inline bool hasCapnpVersion() const; + inline ::capnp::schema::CapnpVersion::Reader getCapnpVersion() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class CodeGeneratorRequest::Builder { +public: + typedef CodeGeneratorRequest Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline bool hasNodes(); + inline ::capnp::List< ::capnp::schema::Node>::Builder getNodes(); + inline void setNodes( ::capnp::List< ::capnp::schema::Node>::Reader value); + inline ::capnp::List< ::capnp::schema::Node>::Builder initNodes(unsigned int size); + inline void adoptNodes(::capnp::Orphan< ::capnp::List< ::capnp::schema::Node>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node>> disownNodes(); + + inline bool hasRequestedFiles(); + inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>::Builder getRequestedFiles(); + inline void setRequestedFiles( ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>::Reader value); + inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>::Builder initRequestedFiles(unsigned int size); + inline void adoptRequestedFiles(::capnp::Orphan< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>> disownRequestedFiles(); + + inline bool hasCapnpVersion(); + inline ::capnp::schema::CapnpVersion::Builder getCapnpVersion(); + inline void setCapnpVersion( ::capnp::schema::CapnpVersion::Reader value); + inline ::capnp::schema::CapnpVersion::Builder initCapnpVersion(); + inline void adoptCapnpVersion(::capnp::Orphan< ::capnp::schema::CapnpVersion>&& value); + inline ::capnp::Orphan< ::capnp::schema::CapnpVersion> disownCapnpVersion(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class CodeGeneratorRequest::Pipeline { +public: + typedef CodeGeneratorRequest Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + + inline ::capnp::schema::CapnpVersion::Pipeline getCapnpVersion(); +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class CodeGeneratorRequest::RequestedFile::Reader { +public: + typedef RequestedFile Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint64_t getId() const; + + inline bool hasFilename() const; + inline ::capnp::Text::Reader getFilename() const; + + inline bool hasImports() const; + inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>::Reader getImports() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class CodeGeneratorRequest::RequestedFile::Builder { +public: + typedef RequestedFile Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint64_t getId(); + inline void setId( ::uint64_t value); + + inline bool hasFilename(); + inline ::capnp::Text::Builder getFilename(); + inline void setFilename( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initFilename(unsigned int size); + inline void adoptFilename(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownFilename(); + + inline bool hasImports(); + inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>::Builder getImports(); + inline void setImports( ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>::Reader value); + inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>::Builder initImports(unsigned int size); + inline void adoptImports(::capnp::Orphan< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>>&& value); + inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>> disownImports(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class CodeGeneratorRequest::RequestedFile::Pipeline { +public: + typedef RequestedFile Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +class CodeGeneratorRequest::RequestedFile::Import::Reader { +public: + typedef Import Reads; + + Reader() = default; + inline explicit Reader(::capnp::_::StructReader base): _reader(base) {} + + inline ::capnp::MessageSize totalSize() const { + return _reader.totalSize().asPublic(); + } + +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { + return ::capnp::_::structString(_reader, *_capnpPrivate::brand()); + } +#endif // !CAPNP_LITE + + inline ::uint64_t getId() const; + + inline bool hasName() const; + inline ::capnp::Text::Reader getName() const; + +private: + ::capnp::_::StructReader _reader; + template + friend struct ::capnp::ToDynamic_; + template + friend struct ::capnp::_::PointerHelpers; + template + friend struct ::capnp::List; + friend class ::capnp::MessageBuilder; + friend class ::capnp::Orphanage; +}; + +class CodeGeneratorRequest::RequestedFile::Import::Builder { +public: + typedef Import Builds; + + Builder() = delete; // Deleted to discourage incorrect usage. + // You can explicitly initialize to nullptr instead. + inline Builder(decltype(nullptr)) {} + inline explicit Builder(::capnp::_::StructBuilder base): _builder(base) {} + inline operator Reader() const { return Reader(_builder.asReader()); } + inline Reader asReader() const { return *this; } + + inline ::capnp::MessageSize totalSize() const { return asReader().totalSize(); } +#if !CAPNP_LITE + inline ::kj::StringTree toString() const { return asReader().toString(); } +#endif // !CAPNP_LITE + + inline ::uint64_t getId(); + inline void setId( ::uint64_t value); + + inline bool hasName(); + inline ::capnp::Text::Builder getName(); + inline void setName( ::capnp::Text::Reader value); + inline ::capnp::Text::Builder initName(unsigned int size); + inline void adoptName(::capnp::Orphan< ::capnp::Text>&& value); + inline ::capnp::Orphan< ::capnp::Text> disownName(); + +private: + ::capnp::_::StructBuilder _builder; + template + friend struct ::capnp::ToDynamic_; + friend class ::capnp::Orphanage; + template + friend struct ::capnp::_::PointerHelpers; +}; + +#if !CAPNP_LITE +class CodeGeneratorRequest::RequestedFile::Import::Pipeline { +public: + typedef Import Pipelines; + + inline Pipeline(decltype(nullptr)): _typeless(nullptr) {} + inline explicit Pipeline(::capnp::AnyPointer::Pipeline&& typeless) + : _typeless(kj::mv(typeless)) {} + +private: + ::capnp::AnyPointer::Pipeline _typeless; + friend class ::capnp::PipelineHook; + template + friend struct ::capnp::ToDynamic_; +}; +#endif // !CAPNP_LITE + +// ======================================================================================= + +inline ::capnp::schema::Node::Which Node::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<6>() * ::capnp::ELEMENTS); +} +inline ::capnp::schema::Node::Which Node::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<6>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Node::Reader::getId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Node::Builder::getId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Node::Builder::setId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Reader::hasDisplayName() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Builder::hasDisplayName() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader Node::Reader::getDisplayName() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder Node::Builder::getDisplayName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Node::Builder::setDisplayName( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder Node::Builder::initDisplayName(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Node::Builder::adoptDisplayName( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> Node::Builder::disownDisplayName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint32_t Node::Reader::getDisplayNamePrefixLength() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Node::Builder::getDisplayNamePrefixLength() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Node::Builder::setDisplayNamePrefixLength( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline ::uint64_t Node::Reader::getScopeId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Node::Builder::getScopeId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Node::Builder::setScopeId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Reader::hasNestedNodes() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Builder::hasNestedNodes() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Node::NestedNode>::Reader Node::Reader::getNestedNodes() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::NestedNode>>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Node::NestedNode>::Builder Node::Builder::getNestedNodes() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::NestedNode>>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void Node::Builder::setNestedNodes( ::capnp::List< ::capnp::schema::Node::NestedNode>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::NestedNode>>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Node::NestedNode>::Builder Node::Builder::initNestedNodes(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::NestedNode>>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), size); +} +inline void Node::Builder::adoptNestedNodes( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::NestedNode>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::NestedNode>>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::NestedNode>> Node::Builder::disownNestedNodes() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::NestedNode>>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline bool Node::Reader::hasAnnotations() const { + return !_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Builder::hasAnnotations() { + return !_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Reader Node::Reader::getAnnotations() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::get(_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Builder Node::Builder::getAnnotations() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::get(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline void Node::Builder::setAnnotations( ::capnp::List< ::capnp::schema::Annotation>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::set(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Builder Node::Builder::initAnnotations(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::init(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS), size); +} +inline void Node::Builder::adoptAnnotations( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::adopt(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>> Node::Builder::disownAnnotations() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::disown(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} + +inline bool Node::Reader::isFile() const { + return which() == Node::FILE; +} +inline bool Node::Builder::isFile() { + return which() == Node::FILE; +} +inline ::capnp::Void Node::Reader::getFile() const { + KJ_IREQUIRE((which() == Node::FILE), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Node::Builder::getFile() { + KJ_IREQUIRE((which() == Node::FILE), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Node::Builder::setFile( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<6>() * ::capnp::ELEMENTS, Node::FILE); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Reader::isStruct() const { + return which() == Node::STRUCT; +} +inline bool Node::Builder::isStruct() { + return which() == Node::STRUCT; +} +inline typename Node::Struct::Reader Node::Reader::getStruct() const { + KJ_IREQUIRE((which() == Node::STRUCT), + "Must check which() before get()ing a union member."); + return typename Node::Struct::Reader(_reader); +} +inline typename Node::Struct::Builder Node::Builder::getStruct() { + KJ_IREQUIRE((which() == Node::STRUCT), + "Must check which() before get()ing a union member."); + return typename Node::Struct::Builder(_builder); +} +inline typename Node::Struct::Builder Node::Builder::initStruct() { + _builder.setDataField( + ::capnp::bounded<6>() * ::capnp::ELEMENTS, Node::STRUCT); + _builder.setDataField< ::uint16_t>(::capnp::bounded<7>() * ::capnp::ELEMENTS, 0); + _builder.setDataField< ::uint16_t>(::capnp::bounded<12>() * ::capnp::ELEMENTS, 0); + _builder.setDataField< ::uint16_t>(::capnp::bounded<13>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<224>() * ::capnp::ELEMENTS, 0); + _builder.setDataField< ::uint16_t>(::capnp::bounded<15>() * ::capnp::ELEMENTS, 0); + _builder.setDataField< ::uint32_t>(::capnp::bounded<8>() * ::capnp::ELEMENTS, 0); + _builder.getPointerField(::capnp::bounded<3>() * ::capnp::POINTERS).clear(); + return typename Node::Struct::Builder(_builder); +} +inline bool Node::Reader::isEnum() const { + return which() == Node::ENUM; +} +inline bool Node::Builder::isEnum() { + return which() == Node::ENUM; +} +inline typename Node::Enum::Reader Node::Reader::getEnum() const { + KJ_IREQUIRE((which() == Node::ENUM), + "Must check which() before get()ing a union member."); + return typename Node::Enum::Reader(_reader); +} +inline typename Node::Enum::Builder Node::Builder::getEnum() { + KJ_IREQUIRE((which() == Node::ENUM), + "Must check which() before get()ing a union member."); + return typename Node::Enum::Builder(_builder); +} +inline typename Node::Enum::Builder Node::Builder::initEnum() { + _builder.setDataField( + ::capnp::bounded<6>() * ::capnp::ELEMENTS, Node::ENUM); + _builder.getPointerField(::capnp::bounded<3>() * ::capnp::POINTERS).clear(); + return typename Node::Enum::Builder(_builder); +} +inline bool Node::Reader::isInterface() const { + return which() == Node::INTERFACE; +} +inline bool Node::Builder::isInterface() { + return which() == Node::INTERFACE; +} +inline typename Node::Interface::Reader Node::Reader::getInterface() const { + KJ_IREQUIRE((which() == Node::INTERFACE), + "Must check which() before get()ing a union member."); + return typename Node::Interface::Reader(_reader); +} +inline typename Node::Interface::Builder Node::Builder::getInterface() { + KJ_IREQUIRE((which() == Node::INTERFACE), + "Must check which() before get()ing a union member."); + return typename Node::Interface::Builder(_builder); +} +inline typename Node::Interface::Builder Node::Builder::initInterface() { + _builder.setDataField( + ::capnp::bounded<6>() * ::capnp::ELEMENTS, Node::INTERFACE); + _builder.getPointerField(::capnp::bounded<3>() * ::capnp::POINTERS).clear(); + _builder.getPointerField(::capnp::bounded<4>() * ::capnp::POINTERS).clear(); + return typename Node::Interface::Builder(_builder); +} +inline bool Node::Reader::isConst() const { + return which() == Node::CONST; +} +inline bool Node::Builder::isConst() { + return which() == Node::CONST; +} +inline typename Node::Const::Reader Node::Reader::getConst() const { + KJ_IREQUIRE((which() == Node::CONST), + "Must check which() before get()ing a union member."); + return typename Node::Const::Reader(_reader); +} +inline typename Node::Const::Builder Node::Builder::getConst() { + KJ_IREQUIRE((which() == Node::CONST), + "Must check which() before get()ing a union member."); + return typename Node::Const::Builder(_builder); +} +inline typename Node::Const::Builder Node::Builder::initConst() { + _builder.setDataField( + ::capnp::bounded<6>() * ::capnp::ELEMENTS, Node::CONST); + _builder.getPointerField(::capnp::bounded<3>() * ::capnp::POINTERS).clear(); + _builder.getPointerField(::capnp::bounded<4>() * ::capnp::POINTERS).clear(); + return typename Node::Const::Builder(_builder); +} +inline bool Node::Reader::isAnnotation() const { + return which() == Node::ANNOTATION; +} +inline bool Node::Builder::isAnnotation() { + return which() == Node::ANNOTATION; +} +inline typename Node::Annotation::Reader Node::Reader::getAnnotation() const { + KJ_IREQUIRE((which() == Node::ANNOTATION), + "Must check which() before get()ing a union member."); + return typename Node::Annotation::Reader(_reader); +} +inline typename Node::Annotation::Builder Node::Builder::getAnnotation() { + KJ_IREQUIRE((which() == Node::ANNOTATION), + "Must check which() before get()ing a union member."); + return typename Node::Annotation::Builder(_builder); +} +inline typename Node::Annotation::Builder Node::Builder::initAnnotation() { + _builder.setDataField( + ::capnp::bounded<6>() * ::capnp::ELEMENTS, Node::ANNOTATION); + _builder.setDataField(::capnp::bounded<112>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<113>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<114>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<115>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<116>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<117>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<118>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<119>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<120>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<121>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<122>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<123>() * ::capnp::ELEMENTS, 0); + _builder.getPointerField(::capnp::bounded<3>() * ::capnp::POINTERS).clear(); + return typename Node::Annotation::Builder(_builder); +} +inline bool Node::Reader::hasParameters() const { + return !_reader.getPointerField( + ::capnp::bounded<5>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Builder::hasParameters() { + return !_builder.getPointerField( + ::capnp::bounded<5>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Node::Parameter>::Reader Node::Reader::getParameters() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::get(_reader.getPointerField( + ::capnp::bounded<5>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Node::Parameter>::Builder Node::Builder::getParameters() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::get(_builder.getPointerField( + ::capnp::bounded<5>() * ::capnp::POINTERS)); +} +inline void Node::Builder::setParameters( ::capnp::List< ::capnp::schema::Node::Parameter>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::set(_builder.getPointerField( + ::capnp::bounded<5>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Node::Parameter>::Builder Node::Builder::initParameters(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::init(_builder.getPointerField( + ::capnp::bounded<5>() * ::capnp::POINTERS), size); +} +inline void Node::Builder::adoptParameters( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::Parameter>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::adopt(_builder.getPointerField( + ::capnp::bounded<5>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::Parameter>> Node::Builder::disownParameters() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::disown(_builder.getPointerField( + ::capnp::bounded<5>() * ::capnp::POINTERS)); +} + +inline bool Node::Reader::getIsGeneric() const { + return _reader.getDataField( + ::capnp::bounded<288>() * ::capnp::ELEMENTS); +} + +inline bool Node::Builder::getIsGeneric() { + return _builder.getDataField( + ::capnp::bounded<288>() * ::capnp::ELEMENTS); +} +inline void Node::Builder::setIsGeneric(bool value) { + _builder.setDataField( + ::capnp::bounded<288>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Parameter::Reader::hasName() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Parameter::Builder::hasName() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader Node::Parameter::Reader::getName() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder Node::Parameter::Builder::getName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Node::Parameter::Builder::setName( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder Node::Parameter::Builder::initName(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Node::Parameter::Builder::adoptName( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> Node::Parameter::Builder::disownName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Node::NestedNode::Reader::hasName() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::NestedNode::Builder::hasName() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader Node::NestedNode::Reader::getName() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder Node::NestedNode::Builder::getName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Node::NestedNode::Builder::setName( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder Node::NestedNode::Builder::initName(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Node::NestedNode::Builder::adoptName( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> Node::NestedNode::Builder::disownName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint64_t Node::NestedNode::Reader::getId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Node::NestedNode::Builder::getId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Node::NestedNode::Builder::setId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint16_t Node::Struct::Reader::getDataWordCount() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<7>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Node::Struct::Builder::getDataWordCount() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<7>() * ::capnp::ELEMENTS); +} +inline void Node::Struct::Builder::setDataWordCount( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<7>() * ::capnp::ELEMENTS, value); +} + +inline ::uint16_t Node::Struct::Reader::getPointerCount() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<12>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Node::Struct::Builder::getPointerCount() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<12>() * ::capnp::ELEMENTS); +} +inline void Node::Struct::Builder::setPointerCount( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<12>() * ::capnp::ELEMENTS, value); +} + +inline ::capnp::schema::ElementSize Node::Struct::Reader::getPreferredListEncoding() const { + return _reader.getDataField< ::capnp::schema::ElementSize>( + ::capnp::bounded<13>() * ::capnp::ELEMENTS); +} + +inline ::capnp::schema::ElementSize Node::Struct::Builder::getPreferredListEncoding() { + return _builder.getDataField< ::capnp::schema::ElementSize>( + ::capnp::bounded<13>() * ::capnp::ELEMENTS); +} +inline void Node::Struct::Builder::setPreferredListEncoding( ::capnp::schema::ElementSize value) { + _builder.setDataField< ::capnp::schema::ElementSize>( + ::capnp::bounded<13>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Struct::Reader::getIsGroup() const { + return _reader.getDataField( + ::capnp::bounded<224>() * ::capnp::ELEMENTS); +} + +inline bool Node::Struct::Builder::getIsGroup() { + return _builder.getDataField( + ::capnp::bounded<224>() * ::capnp::ELEMENTS); +} +inline void Node::Struct::Builder::setIsGroup(bool value) { + _builder.setDataField( + ::capnp::bounded<224>() * ::capnp::ELEMENTS, value); +} + +inline ::uint16_t Node::Struct::Reader::getDiscriminantCount() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<15>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Node::Struct::Builder::getDiscriminantCount() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<15>() * ::capnp::ELEMENTS); +} +inline void Node::Struct::Builder::setDiscriminantCount( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<15>() * ::capnp::ELEMENTS, value); +} + +inline ::uint32_t Node::Struct::Reader::getDiscriminantOffset() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<8>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Node::Struct::Builder::getDiscriminantOffset() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<8>() * ::capnp::ELEMENTS); +} +inline void Node::Struct::Builder::setDiscriminantOffset( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<8>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Struct::Reader::hasFields() const { + return !_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Struct::Builder::hasFields() { + return !_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Field>::Reader Node::Struct::Reader::getFields() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Field>>::get(_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Field>::Builder Node::Struct::Builder::getFields() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Field>>::get(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline void Node::Struct::Builder::setFields( ::capnp::List< ::capnp::schema::Field>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Field>>::set(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Field>::Builder Node::Struct::Builder::initFields(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Field>>::init(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), size); +} +inline void Node::Struct::Builder::adoptFields( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Field>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Field>>::adopt(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Field>> Node::Struct::Builder::disownFields() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Field>>::disown(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} + +inline bool Node::Enum::Reader::hasEnumerants() const { + return !_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Enum::Builder::hasEnumerants() { + return !_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Enumerant>::Reader Node::Enum::Reader::getEnumerants() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Enumerant>>::get(_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Enumerant>::Builder Node::Enum::Builder::getEnumerants() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Enumerant>>::get(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline void Node::Enum::Builder::setEnumerants( ::capnp::List< ::capnp::schema::Enumerant>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Enumerant>>::set(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Enumerant>::Builder Node::Enum::Builder::initEnumerants(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Enumerant>>::init(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), size); +} +inline void Node::Enum::Builder::adoptEnumerants( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Enumerant>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Enumerant>>::adopt(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Enumerant>> Node::Enum::Builder::disownEnumerants() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Enumerant>>::disown(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} + +inline bool Node::Interface::Reader::hasMethods() const { + return !_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Interface::Builder::hasMethods() { + return !_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Method>::Reader Node::Interface::Reader::getMethods() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Method>>::get(_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Method>::Builder Node::Interface::Builder::getMethods() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Method>>::get(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline void Node::Interface::Builder::setMethods( ::capnp::List< ::capnp::schema::Method>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Method>>::set(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Method>::Builder Node::Interface::Builder::initMethods(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Method>>::init(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), size); +} +inline void Node::Interface::Builder::adoptMethods( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Method>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Method>>::adopt(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Method>> Node::Interface::Builder::disownMethods() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Method>>::disown(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} + +inline bool Node::Interface::Reader::hasSuperclasses() const { + return !_reader.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Interface::Builder::hasSuperclasses() { + return !_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Superclass>::Reader Node::Interface::Reader::getSuperclasses() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Superclass>>::get(_reader.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Superclass>::Builder Node::Interface::Builder::getSuperclasses() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Superclass>>::get(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} +inline void Node::Interface::Builder::setSuperclasses( ::capnp::List< ::capnp::schema::Superclass>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Superclass>>::set(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Superclass>::Builder Node::Interface::Builder::initSuperclasses(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Superclass>>::init(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS), size); +} +inline void Node::Interface::Builder::adoptSuperclasses( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Superclass>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Superclass>>::adopt(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Superclass>> Node::Interface::Builder::disownSuperclasses() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Superclass>>::disown(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} + +inline bool Node::Const::Reader::hasType() const { + return !_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Const::Builder::hasType() { + return !_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Type::Reader Node::Const::Reader::getType() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Type::Builder Node::Const::Builder::getType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Type::Pipeline Node::Const::Pipeline::getType() { + return ::capnp::schema::Type::Pipeline(_typeless.getPointerField(3)); +} +#endif // !CAPNP_LITE +inline void Node::Const::Builder::setType( ::capnp::schema::Type::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::set(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Type::Builder Node::Const::Builder::initType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::init(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline void Node::Const::Builder::adoptType( + ::capnp::Orphan< ::capnp::schema::Type>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::adopt(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Type> Node::Const::Builder::disownType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::disown(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} + +inline bool Node::Const::Reader::hasValue() const { + return !_reader.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Const::Builder::hasValue() { + return !_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Value::Reader Node::Const::Reader::getValue() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::get(_reader.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Value::Builder Node::Const::Builder::getValue() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::get(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Value::Pipeline Node::Const::Pipeline::getValue() { + return ::capnp::schema::Value::Pipeline(_typeless.getPointerField(4)); +} +#endif // !CAPNP_LITE +inline void Node::Const::Builder::setValue( ::capnp::schema::Value::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Value>::set(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Value::Builder Node::Const::Builder::initValue() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::init(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} +inline void Node::Const::Builder::adoptValue( + ::capnp::Orphan< ::capnp::schema::Value>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Value>::adopt(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Value> Node::Const::Builder::disownValue() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::disown(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} + +inline bool Node::Annotation::Reader::hasType() const { + return !_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline bool Node::Annotation::Builder::hasType() { + return !_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Type::Reader Node::Annotation::Reader::getType() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Type::Builder Node::Annotation::Builder::getType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Type::Pipeline Node::Annotation::Pipeline::getType() { + return ::capnp::schema::Type::Pipeline(_typeless.getPointerField(3)); +} +#endif // !CAPNP_LITE +inline void Node::Annotation::Builder::setType( ::capnp::schema::Type::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::set(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Type::Builder Node::Annotation::Builder::initType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::init(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline void Node::Annotation::Builder::adoptType( + ::capnp::Orphan< ::capnp::schema::Type>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::adopt(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Type> Node::Annotation::Builder::disownType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::disown(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} + +inline bool Node::Annotation::Reader::getTargetsFile() const { + return _reader.getDataField( + ::capnp::bounded<112>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsFile() { + return _builder.getDataField( + ::capnp::bounded<112>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsFile(bool value) { + _builder.setDataField( + ::capnp::bounded<112>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsConst() const { + return _reader.getDataField( + ::capnp::bounded<113>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsConst() { + return _builder.getDataField( + ::capnp::bounded<113>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsConst(bool value) { + _builder.setDataField( + ::capnp::bounded<113>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsEnum() const { + return _reader.getDataField( + ::capnp::bounded<114>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsEnum() { + return _builder.getDataField( + ::capnp::bounded<114>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsEnum(bool value) { + _builder.setDataField( + ::capnp::bounded<114>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsEnumerant() const { + return _reader.getDataField( + ::capnp::bounded<115>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsEnumerant() { + return _builder.getDataField( + ::capnp::bounded<115>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsEnumerant(bool value) { + _builder.setDataField( + ::capnp::bounded<115>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsStruct() const { + return _reader.getDataField( + ::capnp::bounded<116>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsStruct() { + return _builder.getDataField( + ::capnp::bounded<116>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsStruct(bool value) { + _builder.setDataField( + ::capnp::bounded<116>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsField() const { + return _reader.getDataField( + ::capnp::bounded<117>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsField() { + return _builder.getDataField( + ::capnp::bounded<117>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsField(bool value) { + _builder.setDataField( + ::capnp::bounded<117>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsUnion() const { + return _reader.getDataField( + ::capnp::bounded<118>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsUnion() { + return _builder.getDataField( + ::capnp::bounded<118>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsUnion(bool value) { + _builder.setDataField( + ::capnp::bounded<118>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsGroup() const { + return _reader.getDataField( + ::capnp::bounded<119>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsGroup() { + return _builder.getDataField( + ::capnp::bounded<119>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsGroup(bool value) { + _builder.setDataField( + ::capnp::bounded<119>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsInterface() const { + return _reader.getDataField( + ::capnp::bounded<120>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsInterface() { + return _builder.getDataField( + ::capnp::bounded<120>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsInterface(bool value) { + _builder.setDataField( + ::capnp::bounded<120>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsMethod() const { + return _reader.getDataField( + ::capnp::bounded<121>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsMethod() { + return _builder.getDataField( + ::capnp::bounded<121>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsMethod(bool value) { + _builder.setDataField( + ::capnp::bounded<121>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsParam() const { + return _reader.getDataField( + ::capnp::bounded<122>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsParam() { + return _builder.getDataField( + ::capnp::bounded<122>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsParam(bool value) { + _builder.setDataField( + ::capnp::bounded<122>() * ::capnp::ELEMENTS, value); +} + +inline bool Node::Annotation::Reader::getTargetsAnnotation() const { + return _reader.getDataField( + ::capnp::bounded<123>() * ::capnp::ELEMENTS); +} + +inline bool Node::Annotation::Builder::getTargetsAnnotation() { + return _builder.getDataField( + ::capnp::bounded<123>() * ::capnp::ELEMENTS); +} +inline void Node::Annotation::Builder::setTargetsAnnotation(bool value) { + _builder.setDataField( + ::capnp::bounded<123>() * ::capnp::ELEMENTS, value); +} + +inline ::capnp::schema::Field::Which Field::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS); +} +inline ::capnp::schema::Field::Which Field::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS); +} + +inline bool Field::Reader::hasName() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Field::Builder::hasName() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader Field::Reader::getName() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder Field::Builder::getName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Field::Builder::setName( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder Field::Builder::initName(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Field::Builder::adoptName( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> Field::Builder::disownName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint16_t Field::Reader::getCodeOrder() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Field::Builder::getCodeOrder() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Field::Builder::setCodeOrder( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Field::Reader::hasAnnotations() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool Field::Builder::hasAnnotations() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Reader Field::Reader::getAnnotations() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Builder Field::Builder::getAnnotations() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void Field::Builder::setAnnotations( ::capnp::List< ::capnp::schema::Annotation>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Builder Field::Builder::initAnnotations(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), size); +} +inline void Field::Builder::adoptAnnotations( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>> Field::Builder::disownAnnotations() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline ::uint16_t Field::Reader::getDiscriminantValue() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, 65535u); +} + +inline ::uint16_t Field::Builder::getDiscriminantValue() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, 65535u); +} +inline void Field::Builder::setDiscriminantValue( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value, 65535u); +} + +inline bool Field::Reader::isSlot() const { + return which() == Field::SLOT; +} +inline bool Field::Builder::isSlot() { + return which() == Field::SLOT; +} +inline typename Field::Slot::Reader Field::Reader::getSlot() const { + KJ_IREQUIRE((which() == Field::SLOT), + "Must check which() before get()ing a union member."); + return typename Field::Slot::Reader(_reader); +} +inline typename Field::Slot::Builder Field::Builder::getSlot() { + KJ_IREQUIRE((which() == Field::SLOT), + "Must check which() before get()ing a union member."); + return typename Field::Slot::Builder(_builder); +} +inline typename Field::Slot::Builder Field::Builder::initSlot() { + _builder.setDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS, Field::SLOT); + _builder.setDataField< ::uint32_t>(::capnp::bounded<1>() * ::capnp::ELEMENTS, 0); + _builder.setDataField(::capnp::bounded<128>() * ::capnp::ELEMENTS, 0); + _builder.getPointerField(::capnp::bounded<2>() * ::capnp::POINTERS).clear(); + _builder.getPointerField(::capnp::bounded<3>() * ::capnp::POINTERS).clear(); + return typename Field::Slot::Builder(_builder); +} +inline bool Field::Reader::isGroup() const { + return which() == Field::GROUP; +} +inline bool Field::Builder::isGroup() { + return which() == Field::GROUP; +} +inline typename Field::Group::Reader Field::Reader::getGroup() const { + KJ_IREQUIRE((which() == Field::GROUP), + "Must check which() before get()ing a union member."); + return typename Field::Group::Reader(_reader); +} +inline typename Field::Group::Builder Field::Builder::getGroup() { + KJ_IREQUIRE((which() == Field::GROUP), + "Must check which() before get()ing a union member."); + return typename Field::Group::Builder(_builder); +} +inline typename Field::Group::Builder Field::Builder::initGroup() { + _builder.setDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS, Field::GROUP); + _builder.setDataField< ::uint64_t>(::capnp::bounded<2>() * ::capnp::ELEMENTS, 0); + return typename Field::Group::Builder(_builder); +} +inline typename Field::Ordinal::Reader Field::Reader::getOrdinal() const { + return typename Field::Ordinal::Reader(_reader); +} +inline typename Field::Ordinal::Builder Field::Builder::getOrdinal() { + return typename Field::Ordinal::Builder(_builder); +} +#if !CAPNP_LITE +inline typename Field::Ordinal::Pipeline Field::Pipeline::getOrdinal() { + return typename Field::Ordinal::Pipeline(_typeless.noop()); +} +#endif // !CAPNP_LITE +inline typename Field::Ordinal::Builder Field::Builder::initOrdinal() { + _builder.setDataField< ::uint16_t>(::capnp::bounded<5>() * ::capnp::ELEMENTS, 0); + _builder.setDataField< ::uint16_t>(::capnp::bounded<6>() * ::capnp::ELEMENTS, 0); + return typename Field::Ordinal::Builder(_builder); +} +inline ::uint32_t Field::Slot::Reader::getOffset() const { + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Field::Slot::Builder::getOffset() { + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Field::Slot::Builder::setOffset( ::uint32_t value) { + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Field::Slot::Reader::hasType() const { + return !_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline bool Field::Slot::Builder::hasType() { + return !_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Type::Reader Field::Slot::Reader::getType() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Type::Builder Field::Slot::Builder::getType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Type::Pipeline Field::Slot::Pipeline::getType() { + return ::capnp::schema::Type::Pipeline(_typeless.getPointerField(2)); +} +#endif // !CAPNP_LITE +inline void Field::Slot::Builder::setType( ::capnp::schema::Type::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::set(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Type::Builder Field::Slot::Builder::initType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::init(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline void Field::Slot::Builder::adoptType( + ::capnp::Orphan< ::capnp::schema::Type>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::adopt(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Type> Field::Slot::Builder::disownType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::disown(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} + +inline bool Field::Slot::Reader::hasDefaultValue() const { + return !_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline bool Field::Slot::Builder::hasDefaultValue() { + return !_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Value::Reader Field::Slot::Reader::getDefaultValue() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::get(_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Value::Builder Field::Slot::Builder::getDefaultValue() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::get(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Value::Pipeline Field::Slot::Pipeline::getDefaultValue() { + return ::capnp::schema::Value::Pipeline(_typeless.getPointerField(3)); +} +#endif // !CAPNP_LITE +inline void Field::Slot::Builder::setDefaultValue( ::capnp::schema::Value::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Value>::set(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Value::Builder Field::Slot::Builder::initDefaultValue() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::init(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline void Field::Slot::Builder::adoptDefaultValue( + ::capnp::Orphan< ::capnp::schema::Value>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Value>::adopt(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Value> Field::Slot::Builder::disownDefaultValue() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::disown(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} + +inline bool Field::Slot::Reader::getHadExplicitDefault() const { + return _reader.getDataField( + ::capnp::bounded<128>() * ::capnp::ELEMENTS); +} + +inline bool Field::Slot::Builder::getHadExplicitDefault() { + return _builder.getDataField( + ::capnp::bounded<128>() * ::capnp::ELEMENTS); +} +inline void Field::Slot::Builder::setHadExplicitDefault(bool value) { + _builder.setDataField( + ::capnp::bounded<128>() * ::capnp::ELEMENTS, value); +} + +inline ::uint64_t Field::Group::Reader::getTypeId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Field::Group::Builder::getTypeId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Field::Group::Builder::setTypeId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline ::capnp::schema::Field::Ordinal::Which Field::Ordinal::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS); +} +inline ::capnp::schema::Field::Ordinal::Which Field::Ordinal::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS); +} + +inline bool Field::Ordinal::Reader::isImplicit() const { + return which() == Field::Ordinal::IMPLICIT; +} +inline bool Field::Ordinal::Builder::isImplicit() { + return which() == Field::Ordinal::IMPLICIT; +} +inline ::capnp::Void Field::Ordinal::Reader::getImplicit() const { + KJ_IREQUIRE((which() == Field::Ordinal::IMPLICIT), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Field::Ordinal::Builder::getImplicit() { + KJ_IREQUIRE((which() == Field::Ordinal::IMPLICIT), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Field::Ordinal::Builder::setImplicit( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS, Field::Ordinal::IMPLICIT); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Field::Ordinal::Reader::isExplicit() const { + return which() == Field::Ordinal::EXPLICIT; +} +inline bool Field::Ordinal::Builder::isExplicit() { + return which() == Field::Ordinal::EXPLICIT; +} +inline ::uint16_t Field::Ordinal::Reader::getExplicit() const { + KJ_IREQUIRE((which() == Field::Ordinal::EXPLICIT), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<6>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Field::Ordinal::Builder::getExplicit() { + KJ_IREQUIRE((which() == Field::Ordinal::EXPLICIT), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<6>() * ::capnp::ELEMENTS); +} +inline void Field::Ordinal::Builder::setExplicit( ::uint16_t value) { + _builder.setDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS, Field::Ordinal::EXPLICIT); + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<6>() * ::capnp::ELEMENTS, value); +} + +inline bool Enumerant::Reader::hasName() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Enumerant::Builder::hasName() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader Enumerant::Reader::getName() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder Enumerant::Builder::getName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Enumerant::Builder::setName( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder Enumerant::Builder::initName(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Enumerant::Builder::adoptName( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> Enumerant::Builder::disownName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint16_t Enumerant::Reader::getCodeOrder() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Enumerant::Builder::getCodeOrder() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Enumerant::Builder::setCodeOrder( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Enumerant::Reader::hasAnnotations() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool Enumerant::Builder::hasAnnotations() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Reader Enumerant::Reader::getAnnotations() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Builder Enumerant::Builder::getAnnotations() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void Enumerant::Builder::setAnnotations( ::capnp::List< ::capnp::schema::Annotation>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Builder Enumerant::Builder::initAnnotations(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), size); +} +inline void Enumerant::Builder::adoptAnnotations( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>> Enumerant::Builder::disownAnnotations() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline ::uint64_t Superclass::Reader::getId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Superclass::Builder::getId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Superclass::Builder::setId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Superclass::Reader::hasBrand() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Superclass::Builder::hasBrand() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Brand::Reader Superclass::Reader::getBrand() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Brand::Builder Superclass::Builder::getBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Brand::Pipeline Superclass::Pipeline::getBrand() { + return ::capnp::schema::Brand::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Superclass::Builder::setBrand( ::capnp::schema::Brand::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Brand::Builder Superclass::Builder::initBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Superclass::Builder::adoptBrand( + ::capnp::Orphan< ::capnp::schema::Brand>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Brand> Superclass::Builder::disownBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Method::Reader::hasName() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Method::Builder::hasName() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader Method::Reader::getName() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder Method::Builder::getName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Method::Builder::setName( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder Method::Builder::initName(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Method::Builder::adoptName( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> Method::Builder::disownName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint16_t Method::Reader::getCodeOrder() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Method::Builder::getCodeOrder() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Method::Builder::setCodeOrder( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint64_t Method::Reader::getParamStructType() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Method::Builder::getParamStructType() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Method::Builder::setParamStructType( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline ::uint64_t Method::Reader::getResultStructType() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Method::Builder::getResultStructType() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Method::Builder::setResultStructType( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline bool Method::Reader::hasAnnotations() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool Method::Builder::hasAnnotations() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Reader Method::Reader::getAnnotations() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Builder Method::Builder::getAnnotations() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void Method::Builder::setAnnotations( ::capnp::List< ::capnp::schema::Annotation>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Annotation>::Builder Method::Builder::initAnnotations(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), size); +} +inline void Method::Builder::adoptAnnotations( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Annotation>> Method::Builder::disownAnnotations() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Annotation>>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline bool Method::Reader::hasParamBrand() const { + return !_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline bool Method::Builder::hasParamBrand() { + return !_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Brand::Reader Method::Reader::getParamBrand() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Brand::Builder Method::Builder::getParamBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Brand::Pipeline Method::Pipeline::getParamBrand() { + return ::capnp::schema::Brand::Pipeline(_typeless.getPointerField(2)); +} +#endif // !CAPNP_LITE +inline void Method::Builder::setParamBrand( ::capnp::schema::Brand::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::set(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Brand::Builder Method::Builder::initParamBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::init(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline void Method::Builder::adoptParamBrand( + ::capnp::Orphan< ::capnp::schema::Brand>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::adopt(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Brand> Method::Builder::disownParamBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::disown(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} + +inline bool Method::Reader::hasResultBrand() const { + return !_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline bool Method::Builder::hasResultBrand() { + return !_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Brand::Reader Method::Reader::getResultBrand() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_reader.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Brand::Builder Method::Builder::getResultBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Brand::Pipeline Method::Pipeline::getResultBrand() { + return ::capnp::schema::Brand::Pipeline(_typeless.getPointerField(3)); +} +#endif // !CAPNP_LITE +inline void Method::Builder::setResultBrand( ::capnp::schema::Brand::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::set(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Brand::Builder Method::Builder::initResultBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::init(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} +inline void Method::Builder::adoptResultBrand( + ::capnp::Orphan< ::capnp::schema::Brand>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::adopt(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Brand> Method::Builder::disownResultBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::disown(_builder.getPointerField( + ::capnp::bounded<3>() * ::capnp::POINTERS)); +} + +inline bool Method::Reader::hasImplicitParameters() const { + return !_reader.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS).isNull(); +} +inline bool Method::Builder::hasImplicitParameters() { + return !_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Node::Parameter>::Reader Method::Reader::getImplicitParameters() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::get(_reader.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Node::Parameter>::Builder Method::Builder::getImplicitParameters() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::get(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} +inline void Method::Builder::setImplicitParameters( ::capnp::List< ::capnp::schema::Node::Parameter>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::set(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Node::Parameter>::Builder Method::Builder::initImplicitParameters(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::init(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS), size); +} +inline void Method::Builder::adoptImplicitParameters( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::Parameter>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::adopt(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node::Parameter>> Method::Builder::disownImplicitParameters() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node::Parameter>>::disown(_builder.getPointerField( + ::capnp::bounded<4>() * ::capnp::POINTERS)); +} + +inline ::capnp::schema::Type::Which Type::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline ::capnp::schema::Type::Which Type::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline bool Type::Reader::isVoid() const { + return which() == Type::VOID; +} +inline bool Type::Builder::isVoid() { + return which() == Type::VOID; +} +inline ::capnp::Void Type::Reader::getVoid() const { + KJ_IREQUIRE((which() == Type::VOID), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getVoid() { + KJ_IREQUIRE((which() == Type::VOID), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setVoid( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::VOID); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isBool() const { + return which() == Type::BOOL; +} +inline bool Type::Builder::isBool() { + return which() == Type::BOOL; +} +inline ::capnp::Void Type::Reader::getBool() const { + KJ_IREQUIRE((which() == Type::BOOL), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getBool() { + KJ_IREQUIRE((which() == Type::BOOL), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setBool( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::BOOL); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isInt8() const { + return which() == Type::INT8; +} +inline bool Type::Builder::isInt8() { + return which() == Type::INT8; +} +inline ::capnp::Void Type::Reader::getInt8() const { + KJ_IREQUIRE((which() == Type::INT8), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getInt8() { + KJ_IREQUIRE((which() == Type::INT8), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setInt8( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::INT8); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isInt16() const { + return which() == Type::INT16; +} +inline bool Type::Builder::isInt16() { + return which() == Type::INT16; +} +inline ::capnp::Void Type::Reader::getInt16() const { + KJ_IREQUIRE((which() == Type::INT16), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getInt16() { + KJ_IREQUIRE((which() == Type::INT16), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setInt16( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::INT16); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isInt32() const { + return which() == Type::INT32; +} +inline bool Type::Builder::isInt32() { + return which() == Type::INT32; +} +inline ::capnp::Void Type::Reader::getInt32() const { + KJ_IREQUIRE((which() == Type::INT32), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getInt32() { + KJ_IREQUIRE((which() == Type::INT32), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setInt32( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::INT32); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isInt64() const { + return which() == Type::INT64; +} +inline bool Type::Builder::isInt64() { + return which() == Type::INT64; +} +inline ::capnp::Void Type::Reader::getInt64() const { + KJ_IREQUIRE((which() == Type::INT64), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getInt64() { + KJ_IREQUIRE((which() == Type::INT64), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setInt64( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::INT64); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isUint8() const { + return which() == Type::UINT8; +} +inline bool Type::Builder::isUint8() { + return which() == Type::UINT8; +} +inline ::capnp::Void Type::Reader::getUint8() const { + KJ_IREQUIRE((which() == Type::UINT8), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getUint8() { + KJ_IREQUIRE((which() == Type::UINT8), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setUint8( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::UINT8); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isUint16() const { + return which() == Type::UINT16; +} +inline bool Type::Builder::isUint16() { + return which() == Type::UINT16; +} +inline ::capnp::Void Type::Reader::getUint16() const { + KJ_IREQUIRE((which() == Type::UINT16), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getUint16() { + KJ_IREQUIRE((which() == Type::UINT16), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setUint16( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::UINT16); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isUint32() const { + return which() == Type::UINT32; +} +inline bool Type::Builder::isUint32() { + return which() == Type::UINT32; +} +inline ::capnp::Void Type::Reader::getUint32() const { + KJ_IREQUIRE((which() == Type::UINT32), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getUint32() { + KJ_IREQUIRE((which() == Type::UINT32), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setUint32( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::UINT32); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isUint64() const { + return which() == Type::UINT64; +} +inline bool Type::Builder::isUint64() { + return which() == Type::UINT64; +} +inline ::capnp::Void Type::Reader::getUint64() const { + KJ_IREQUIRE((which() == Type::UINT64), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getUint64() { + KJ_IREQUIRE((which() == Type::UINT64), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setUint64( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::UINT64); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isFloat32() const { + return which() == Type::FLOAT32; +} +inline bool Type::Builder::isFloat32() { + return which() == Type::FLOAT32; +} +inline ::capnp::Void Type::Reader::getFloat32() const { + KJ_IREQUIRE((which() == Type::FLOAT32), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getFloat32() { + KJ_IREQUIRE((which() == Type::FLOAT32), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setFloat32( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::FLOAT32); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isFloat64() const { + return which() == Type::FLOAT64; +} +inline bool Type::Builder::isFloat64() { + return which() == Type::FLOAT64; +} +inline ::capnp::Void Type::Reader::getFloat64() const { + KJ_IREQUIRE((which() == Type::FLOAT64), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getFloat64() { + KJ_IREQUIRE((which() == Type::FLOAT64), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setFloat64( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::FLOAT64); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isText() const { + return which() == Type::TEXT; +} +inline bool Type::Builder::isText() { + return which() == Type::TEXT; +} +inline ::capnp::Void Type::Reader::getText() const { + KJ_IREQUIRE((which() == Type::TEXT), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getText() { + KJ_IREQUIRE((which() == Type::TEXT), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setText( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::TEXT); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isData() const { + return which() == Type::DATA; +} +inline bool Type::Builder::isData() { + return which() == Type::DATA; +} +inline ::capnp::Void Type::Reader::getData() const { + KJ_IREQUIRE((which() == Type::DATA), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::Builder::getData() { + KJ_IREQUIRE((which() == Type::DATA), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::Builder::setData( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::DATA); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Reader::isList() const { + return which() == Type::LIST; +} +inline bool Type::Builder::isList() { + return which() == Type::LIST; +} +inline typename Type::List::Reader Type::Reader::getList() const { + KJ_IREQUIRE((which() == Type::LIST), + "Must check which() before get()ing a union member."); + return typename Type::List::Reader(_reader); +} +inline typename Type::List::Builder Type::Builder::getList() { + KJ_IREQUIRE((which() == Type::LIST), + "Must check which() before get()ing a union member."); + return typename Type::List::Builder(_builder); +} +inline typename Type::List::Builder Type::Builder::initList() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::LIST); + _builder.getPointerField(::capnp::bounded<0>() * ::capnp::POINTERS).clear(); + return typename Type::List::Builder(_builder); +} +inline bool Type::Reader::isEnum() const { + return which() == Type::ENUM; +} +inline bool Type::Builder::isEnum() { + return which() == Type::ENUM; +} +inline typename Type::Enum::Reader Type::Reader::getEnum() const { + KJ_IREQUIRE((which() == Type::ENUM), + "Must check which() before get()ing a union member."); + return typename Type::Enum::Reader(_reader); +} +inline typename Type::Enum::Builder Type::Builder::getEnum() { + KJ_IREQUIRE((which() == Type::ENUM), + "Must check which() before get()ing a union member."); + return typename Type::Enum::Builder(_builder); +} +inline typename Type::Enum::Builder Type::Builder::initEnum() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::ENUM); + _builder.setDataField< ::uint64_t>(::capnp::bounded<1>() * ::capnp::ELEMENTS, 0); + _builder.getPointerField(::capnp::bounded<0>() * ::capnp::POINTERS).clear(); + return typename Type::Enum::Builder(_builder); +} +inline bool Type::Reader::isStruct() const { + return which() == Type::STRUCT; +} +inline bool Type::Builder::isStruct() { + return which() == Type::STRUCT; +} +inline typename Type::Struct::Reader Type::Reader::getStruct() const { + KJ_IREQUIRE((which() == Type::STRUCT), + "Must check which() before get()ing a union member."); + return typename Type::Struct::Reader(_reader); +} +inline typename Type::Struct::Builder Type::Builder::getStruct() { + KJ_IREQUIRE((which() == Type::STRUCT), + "Must check which() before get()ing a union member."); + return typename Type::Struct::Builder(_builder); +} +inline typename Type::Struct::Builder Type::Builder::initStruct() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::STRUCT); + _builder.setDataField< ::uint64_t>(::capnp::bounded<1>() * ::capnp::ELEMENTS, 0); + _builder.getPointerField(::capnp::bounded<0>() * ::capnp::POINTERS).clear(); + return typename Type::Struct::Builder(_builder); +} +inline bool Type::Reader::isInterface() const { + return which() == Type::INTERFACE; +} +inline bool Type::Builder::isInterface() { + return which() == Type::INTERFACE; +} +inline typename Type::Interface::Reader Type::Reader::getInterface() const { + KJ_IREQUIRE((which() == Type::INTERFACE), + "Must check which() before get()ing a union member."); + return typename Type::Interface::Reader(_reader); +} +inline typename Type::Interface::Builder Type::Builder::getInterface() { + KJ_IREQUIRE((which() == Type::INTERFACE), + "Must check which() before get()ing a union member."); + return typename Type::Interface::Builder(_builder); +} +inline typename Type::Interface::Builder Type::Builder::initInterface() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::INTERFACE); + _builder.setDataField< ::uint64_t>(::capnp::bounded<1>() * ::capnp::ELEMENTS, 0); + _builder.getPointerField(::capnp::bounded<0>() * ::capnp::POINTERS).clear(); + return typename Type::Interface::Builder(_builder); +} +inline bool Type::Reader::isAnyPointer() const { + return which() == Type::ANY_POINTER; +} +inline bool Type::Builder::isAnyPointer() { + return which() == Type::ANY_POINTER; +} +inline typename Type::AnyPointer::Reader Type::Reader::getAnyPointer() const { + KJ_IREQUIRE((which() == Type::ANY_POINTER), + "Must check which() before get()ing a union member."); + return typename Type::AnyPointer::Reader(_reader); +} +inline typename Type::AnyPointer::Builder Type::Builder::getAnyPointer() { + KJ_IREQUIRE((which() == Type::ANY_POINTER), + "Must check which() before get()ing a union member."); + return typename Type::AnyPointer::Builder(_builder); +} +inline typename Type::AnyPointer::Builder Type::Builder::initAnyPointer() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Type::ANY_POINTER); + _builder.setDataField< ::uint16_t>(::capnp::bounded<4>() * ::capnp::ELEMENTS, 0); + _builder.setDataField< ::uint16_t>(::capnp::bounded<5>() * ::capnp::ELEMENTS, 0); + _builder.setDataField< ::uint64_t>(::capnp::bounded<2>() * ::capnp::ELEMENTS, 0); + return typename Type::AnyPointer::Builder(_builder); +} +inline bool Type::List::Reader::hasElementType() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Type::List::Builder::hasElementType() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Type::Reader Type::List::Reader::getElementType() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Type::Builder Type::List::Builder::getElementType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Type::Pipeline Type::List::Pipeline::getElementType() { + return ::capnp::schema::Type::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Type::List::Builder::setElementType( ::capnp::schema::Type::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Type::Builder Type::List::Builder::initElementType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Type::List::Builder::adoptElementType( + ::capnp::Orphan< ::capnp::schema::Type>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Type> Type::List::Builder::disownElementType() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint64_t Type::Enum::Reader::getTypeId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Type::Enum::Builder::getTypeId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Type::Enum::Builder::setTypeId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Enum::Reader::hasBrand() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Type::Enum::Builder::hasBrand() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Brand::Reader Type::Enum::Reader::getBrand() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Brand::Builder Type::Enum::Builder::getBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Brand::Pipeline Type::Enum::Pipeline::getBrand() { + return ::capnp::schema::Brand::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Type::Enum::Builder::setBrand( ::capnp::schema::Brand::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Brand::Builder Type::Enum::Builder::initBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Type::Enum::Builder::adoptBrand( + ::capnp::Orphan< ::capnp::schema::Brand>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Brand> Type::Enum::Builder::disownBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint64_t Type::Struct::Reader::getTypeId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Type::Struct::Builder::getTypeId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Type::Struct::Builder::setTypeId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Struct::Reader::hasBrand() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Type::Struct::Builder::hasBrand() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Brand::Reader Type::Struct::Reader::getBrand() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Brand::Builder Type::Struct::Builder::getBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Brand::Pipeline Type::Struct::Pipeline::getBrand() { + return ::capnp::schema::Brand::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Type::Struct::Builder::setBrand( ::capnp::schema::Brand::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Brand::Builder Type::Struct::Builder::initBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Type::Struct::Builder::adoptBrand( + ::capnp::Orphan< ::capnp::schema::Brand>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Brand> Type::Struct::Builder::disownBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::uint64_t Type::Interface::Reader::getTypeId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Type::Interface::Builder::getTypeId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Type::Interface::Builder::setTypeId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::Interface::Reader::hasBrand() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Type::Interface::Builder::hasBrand() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Brand::Reader Type::Interface::Reader::getBrand() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Brand::Builder Type::Interface::Builder::getBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Brand::Pipeline Type::Interface::Pipeline::getBrand() { + return ::capnp::schema::Brand::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Type::Interface::Builder::setBrand( ::capnp::schema::Brand::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Brand::Builder Type::Interface::Builder::initBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Type::Interface::Builder::adoptBrand( + ::capnp::Orphan< ::capnp::schema::Brand>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Brand> Type::Interface::Builder::disownBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::capnp::schema::Type::AnyPointer::Which Type::AnyPointer::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS); +} +inline ::capnp::schema::Type::AnyPointer::Which Type::AnyPointer::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS); +} + +inline bool Type::AnyPointer::Reader::isUnconstrained() const { + return which() == Type::AnyPointer::UNCONSTRAINED; +} +inline bool Type::AnyPointer::Builder::isUnconstrained() { + return which() == Type::AnyPointer::UNCONSTRAINED; +} +inline typename Type::AnyPointer::Unconstrained::Reader Type::AnyPointer::Reader::getUnconstrained() const { + KJ_IREQUIRE((which() == Type::AnyPointer::UNCONSTRAINED), + "Must check which() before get()ing a union member."); + return typename Type::AnyPointer::Unconstrained::Reader(_reader); +} +inline typename Type::AnyPointer::Unconstrained::Builder Type::AnyPointer::Builder::getUnconstrained() { + KJ_IREQUIRE((which() == Type::AnyPointer::UNCONSTRAINED), + "Must check which() before get()ing a union member."); + return typename Type::AnyPointer::Unconstrained::Builder(_builder); +} +inline typename Type::AnyPointer::Unconstrained::Builder Type::AnyPointer::Builder::initUnconstrained() { + _builder.setDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS, Type::AnyPointer::UNCONSTRAINED); + _builder.setDataField< ::uint16_t>(::capnp::bounded<5>() * ::capnp::ELEMENTS, 0); + return typename Type::AnyPointer::Unconstrained::Builder(_builder); +} +inline bool Type::AnyPointer::Reader::isParameter() const { + return which() == Type::AnyPointer::PARAMETER; +} +inline bool Type::AnyPointer::Builder::isParameter() { + return which() == Type::AnyPointer::PARAMETER; +} +inline typename Type::AnyPointer::Parameter::Reader Type::AnyPointer::Reader::getParameter() const { + KJ_IREQUIRE((which() == Type::AnyPointer::PARAMETER), + "Must check which() before get()ing a union member."); + return typename Type::AnyPointer::Parameter::Reader(_reader); +} +inline typename Type::AnyPointer::Parameter::Builder Type::AnyPointer::Builder::getParameter() { + KJ_IREQUIRE((which() == Type::AnyPointer::PARAMETER), + "Must check which() before get()ing a union member."); + return typename Type::AnyPointer::Parameter::Builder(_builder); +} +inline typename Type::AnyPointer::Parameter::Builder Type::AnyPointer::Builder::initParameter() { + _builder.setDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS, Type::AnyPointer::PARAMETER); + _builder.setDataField< ::uint16_t>(::capnp::bounded<5>() * ::capnp::ELEMENTS, 0); + _builder.setDataField< ::uint64_t>(::capnp::bounded<2>() * ::capnp::ELEMENTS, 0); + return typename Type::AnyPointer::Parameter::Builder(_builder); +} +inline bool Type::AnyPointer::Reader::isImplicitMethodParameter() const { + return which() == Type::AnyPointer::IMPLICIT_METHOD_PARAMETER; +} +inline bool Type::AnyPointer::Builder::isImplicitMethodParameter() { + return which() == Type::AnyPointer::IMPLICIT_METHOD_PARAMETER; +} +inline typename Type::AnyPointer::ImplicitMethodParameter::Reader Type::AnyPointer::Reader::getImplicitMethodParameter() const { + KJ_IREQUIRE((which() == Type::AnyPointer::IMPLICIT_METHOD_PARAMETER), + "Must check which() before get()ing a union member."); + return typename Type::AnyPointer::ImplicitMethodParameter::Reader(_reader); +} +inline typename Type::AnyPointer::ImplicitMethodParameter::Builder Type::AnyPointer::Builder::getImplicitMethodParameter() { + KJ_IREQUIRE((which() == Type::AnyPointer::IMPLICIT_METHOD_PARAMETER), + "Must check which() before get()ing a union member."); + return typename Type::AnyPointer::ImplicitMethodParameter::Builder(_builder); +} +inline typename Type::AnyPointer::ImplicitMethodParameter::Builder Type::AnyPointer::Builder::initImplicitMethodParameter() { + _builder.setDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS, Type::AnyPointer::IMPLICIT_METHOD_PARAMETER); + _builder.setDataField< ::uint16_t>(::capnp::bounded<5>() * ::capnp::ELEMENTS, 0); + return typename Type::AnyPointer::ImplicitMethodParameter::Builder(_builder); +} +inline ::capnp::schema::Type::AnyPointer::Unconstrained::Which Type::AnyPointer::Unconstrained::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS); +} +inline ::capnp::schema::Type::AnyPointer::Unconstrained::Which Type::AnyPointer::Unconstrained::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS); +} + +inline bool Type::AnyPointer::Unconstrained::Reader::isAnyKind() const { + return which() == Type::AnyPointer::Unconstrained::ANY_KIND; +} +inline bool Type::AnyPointer::Unconstrained::Builder::isAnyKind() { + return which() == Type::AnyPointer::Unconstrained::ANY_KIND; +} +inline ::capnp::Void Type::AnyPointer::Unconstrained::Reader::getAnyKind() const { + KJ_IREQUIRE((which() == Type::AnyPointer::Unconstrained::ANY_KIND), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::AnyPointer::Unconstrained::Builder::getAnyKind() { + KJ_IREQUIRE((which() == Type::AnyPointer::Unconstrained::ANY_KIND), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::AnyPointer::Unconstrained::Builder::setAnyKind( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS, Type::AnyPointer::Unconstrained::ANY_KIND); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::AnyPointer::Unconstrained::Reader::isStruct() const { + return which() == Type::AnyPointer::Unconstrained::STRUCT; +} +inline bool Type::AnyPointer::Unconstrained::Builder::isStruct() { + return which() == Type::AnyPointer::Unconstrained::STRUCT; +} +inline ::capnp::Void Type::AnyPointer::Unconstrained::Reader::getStruct() const { + KJ_IREQUIRE((which() == Type::AnyPointer::Unconstrained::STRUCT), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::AnyPointer::Unconstrained::Builder::getStruct() { + KJ_IREQUIRE((which() == Type::AnyPointer::Unconstrained::STRUCT), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::AnyPointer::Unconstrained::Builder::setStruct( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS, Type::AnyPointer::Unconstrained::STRUCT); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::AnyPointer::Unconstrained::Reader::isList() const { + return which() == Type::AnyPointer::Unconstrained::LIST; +} +inline bool Type::AnyPointer::Unconstrained::Builder::isList() { + return which() == Type::AnyPointer::Unconstrained::LIST; +} +inline ::capnp::Void Type::AnyPointer::Unconstrained::Reader::getList() const { + KJ_IREQUIRE((which() == Type::AnyPointer::Unconstrained::LIST), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::AnyPointer::Unconstrained::Builder::getList() { + KJ_IREQUIRE((which() == Type::AnyPointer::Unconstrained::LIST), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::AnyPointer::Unconstrained::Builder::setList( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS, Type::AnyPointer::Unconstrained::LIST); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Type::AnyPointer::Unconstrained::Reader::isCapability() const { + return which() == Type::AnyPointer::Unconstrained::CAPABILITY; +} +inline bool Type::AnyPointer::Unconstrained::Builder::isCapability() { + return which() == Type::AnyPointer::Unconstrained::CAPABILITY; +} +inline ::capnp::Void Type::AnyPointer::Unconstrained::Reader::getCapability() const { + KJ_IREQUIRE((which() == Type::AnyPointer::Unconstrained::CAPABILITY), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Type::AnyPointer::Unconstrained::Builder::getCapability() { + KJ_IREQUIRE((which() == Type::AnyPointer::Unconstrained::CAPABILITY), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Type::AnyPointer::Unconstrained::Builder::setCapability( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<5>() * ::capnp::ELEMENTS, Type::AnyPointer::Unconstrained::CAPABILITY); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint64_t Type::AnyPointer::Parameter::Reader::getScopeId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Type::AnyPointer::Parameter::Builder::getScopeId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Type::AnyPointer::Parameter::Builder::setScopeId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline ::uint16_t Type::AnyPointer::Parameter::Reader::getParameterIndex() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<5>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Type::AnyPointer::Parameter::Builder::getParameterIndex() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<5>() * ::capnp::ELEMENTS); +} +inline void Type::AnyPointer::Parameter::Builder::setParameterIndex( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<5>() * ::capnp::ELEMENTS, value); +} + +inline ::uint16_t Type::AnyPointer::ImplicitMethodParameter::Reader::getParameterIndex() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<5>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Type::AnyPointer::ImplicitMethodParameter::Builder::getParameterIndex() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<5>() * ::capnp::ELEMENTS); +} +inline void Type::AnyPointer::ImplicitMethodParameter::Builder::setParameterIndex( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<5>() * ::capnp::ELEMENTS, value); +} + +inline bool Brand::Reader::hasScopes() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Brand::Builder::hasScopes() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Brand::Scope>::Reader Brand::Reader::getScopes() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Scope>>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Brand::Scope>::Builder Brand::Builder::getScopes() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Scope>>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Brand::Builder::setScopes( ::capnp::List< ::capnp::schema::Brand::Scope>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Scope>>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Brand::Scope>::Builder Brand::Builder::initScopes(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Scope>>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Brand::Builder::adoptScopes( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Brand::Scope>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Scope>>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Brand::Scope>> Brand::Builder::disownScopes() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Scope>>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::capnp::schema::Brand::Scope::Which Brand::Scope::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS); +} +inline ::capnp::schema::Brand::Scope::Which Brand::Scope::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Brand::Scope::Reader::getScopeId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Brand::Scope::Builder::getScopeId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Brand::Scope::Builder::setScopeId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Brand::Scope::Reader::isBind() const { + return which() == Brand::Scope::BIND; +} +inline bool Brand::Scope::Builder::isBind() { + return which() == Brand::Scope::BIND; +} +inline bool Brand::Scope::Reader::hasBind() const { + if (which() != Brand::Scope::BIND) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Brand::Scope::Builder::hasBind() { + if (which() != Brand::Scope::BIND) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Brand::Binding>::Reader Brand::Scope::Reader::getBind() const { + KJ_IREQUIRE((which() == Brand::Scope::BIND), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Binding>>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Brand::Binding>::Builder Brand::Scope::Builder::getBind() { + KJ_IREQUIRE((which() == Brand::Scope::BIND), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Binding>>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Brand::Scope::Builder::setBind( ::capnp::List< ::capnp::schema::Brand::Binding>::Reader value) { + _builder.setDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS, Brand::Scope::BIND); + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Binding>>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Brand::Binding>::Builder Brand::Scope::Builder::initBind(unsigned int size) { + _builder.setDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS, Brand::Scope::BIND); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Binding>>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Brand::Scope::Builder::adoptBind( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Brand::Binding>>&& value) { + _builder.setDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS, Brand::Scope::BIND); + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Binding>>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Brand::Binding>> Brand::Scope::Builder::disownBind() { + KJ_IREQUIRE((which() == Brand::Scope::BIND), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Brand::Binding>>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Brand::Scope::Reader::isInherit() const { + return which() == Brand::Scope::INHERIT; +} +inline bool Brand::Scope::Builder::isInherit() { + return which() == Brand::Scope::INHERIT; +} +inline ::capnp::Void Brand::Scope::Reader::getInherit() const { + KJ_IREQUIRE((which() == Brand::Scope::INHERIT), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Brand::Scope::Builder::getInherit() { + KJ_IREQUIRE((which() == Brand::Scope::INHERIT), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Brand::Scope::Builder::setInherit( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<4>() * ::capnp::ELEMENTS, Brand::Scope::INHERIT); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::capnp::schema::Brand::Binding::Which Brand::Binding::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline ::capnp::schema::Brand::Binding::Which Brand::Binding::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline bool Brand::Binding::Reader::isUnbound() const { + return which() == Brand::Binding::UNBOUND; +} +inline bool Brand::Binding::Builder::isUnbound() { + return which() == Brand::Binding::UNBOUND; +} +inline ::capnp::Void Brand::Binding::Reader::getUnbound() const { + KJ_IREQUIRE((which() == Brand::Binding::UNBOUND), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Brand::Binding::Builder::getUnbound() { + KJ_IREQUIRE((which() == Brand::Binding::UNBOUND), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Brand::Binding::Builder::setUnbound( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Brand::Binding::UNBOUND); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Brand::Binding::Reader::isType() const { + return which() == Brand::Binding::TYPE; +} +inline bool Brand::Binding::Builder::isType() { + return which() == Brand::Binding::TYPE; +} +inline bool Brand::Binding::Reader::hasType() const { + if (which() != Brand::Binding::TYPE) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Brand::Binding::Builder::hasType() { + if (which() != Brand::Binding::TYPE) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Type::Reader Brand::Binding::Reader::getType() const { + KJ_IREQUIRE((which() == Brand::Binding::TYPE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Type::Builder Brand::Binding::Builder::getType() { + KJ_IREQUIRE((which() == Brand::Binding::TYPE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Brand::Binding::Builder::setType( ::capnp::schema::Type::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Brand::Binding::TYPE); + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Type::Builder Brand::Binding::Builder::initType() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Brand::Binding::TYPE); + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Brand::Binding::Builder::adoptType( + ::capnp::Orphan< ::capnp::schema::Type>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Brand::Binding::TYPE); + ::capnp::_::PointerHelpers< ::capnp::schema::Type>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Type> Brand::Binding::Builder::disownType() { + KJ_IREQUIRE((which() == Brand::Binding::TYPE), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::schema::Type>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline ::capnp::schema::Value::Which Value::Reader::which() const { + return _reader.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline ::capnp::schema::Value::Which Value::Builder::which() { + return _builder.getDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline bool Value::Reader::isVoid() const { + return which() == Value::VOID; +} +inline bool Value::Builder::isVoid() { + return which() == Value::VOID; +} +inline ::capnp::Void Value::Reader::getVoid() const { + KJ_IREQUIRE((which() == Value::VOID), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Value::Builder::getVoid() { + KJ_IREQUIRE((which() == Value::VOID), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setVoid( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::VOID); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isBool() const { + return which() == Value::BOOL; +} +inline bool Value::Builder::isBool() { + return which() == Value::BOOL; +} +inline bool Value::Reader::getBool() const { + KJ_IREQUIRE((which() == Value::BOOL), + "Must check which() before get()ing a union member."); + return _reader.getDataField( + ::capnp::bounded<16>() * ::capnp::ELEMENTS); +} + +inline bool Value::Builder::getBool() { + KJ_IREQUIRE((which() == Value::BOOL), + "Must check which() before get()ing a union member."); + return _builder.getDataField( + ::capnp::bounded<16>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setBool(bool value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::BOOL); + _builder.setDataField( + ::capnp::bounded<16>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isInt8() const { + return which() == Value::INT8; +} +inline bool Value::Builder::isInt8() { + return which() == Value::INT8; +} +inline ::int8_t Value::Reader::getInt8() const { + KJ_IREQUIRE((which() == Value::INT8), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::int8_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::int8_t Value::Builder::getInt8() { + KJ_IREQUIRE((which() == Value::INT8), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::int8_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setInt8( ::int8_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::INT8); + _builder.setDataField< ::int8_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isInt16() const { + return which() == Value::INT16; +} +inline bool Value::Builder::isInt16() { + return which() == Value::INT16; +} +inline ::int16_t Value::Reader::getInt16() const { + KJ_IREQUIRE((which() == Value::INT16), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::int16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::int16_t Value::Builder::getInt16() { + KJ_IREQUIRE((which() == Value::INT16), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::int16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setInt16( ::int16_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::INT16); + _builder.setDataField< ::int16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isInt32() const { + return which() == Value::INT32; +} +inline bool Value::Builder::isInt32() { + return which() == Value::INT32; +} +inline ::int32_t Value::Reader::getInt32() const { + KJ_IREQUIRE((which() == Value::INT32), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::int32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::int32_t Value::Builder::getInt32() { + KJ_IREQUIRE((which() == Value::INT32), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::int32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setInt32( ::int32_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::INT32); + _builder.setDataField< ::int32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isInt64() const { + return which() == Value::INT64; +} +inline bool Value::Builder::isInt64() { + return which() == Value::INT64; +} +inline ::int64_t Value::Reader::getInt64() const { + KJ_IREQUIRE((which() == Value::INT64), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::int64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::int64_t Value::Builder::getInt64() { + KJ_IREQUIRE((which() == Value::INT64), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::int64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setInt64( ::int64_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::INT64); + _builder.setDataField< ::int64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isUint8() const { + return which() == Value::UINT8; +} +inline bool Value::Builder::isUint8() { + return which() == Value::UINT8; +} +inline ::uint8_t Value::Reader::getUint8() const { + KJ_IREQUIRE((which() == Value::UINT8), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint8_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint8_t Value::Builder::getUint8() { + KJ_IREQUIRE((which() == Value::UINT8), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint8_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setUint8( ::uint8_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::UINT8); + _builder.setDataField< ::uint8_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isUint16() const { + return which() == Value::UINT16; +} +inline bool Value::Builder::isUint16() { + return which() == Value::UINT16; +} +inline ::uint16_t Value::Reader::getUint16() const { + KJ_IREQUIRE((which() == Value::UINT16), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Value::Builder::getUint16() { + KJ_IREQUIRE((which() == Value::UINT16), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setUint16( ::uint16_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::UINT16); + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isUint32() const { + return which() == Value::UINT32; +} +inline bool Value::Builder::isUint32() { + return which() == Value::UINT32; +} +inline ::uint32_t Value::Reader::getUint32() const { + KJ_IREQUIRE((which() == Value::UINT32), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint32_t Value::Builder::getUint32() { + KJ_IREQUIRE((which() == Value::UINT32), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setUint32( ::uint32_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::UINT32); + _builder.setDataField< ::uint32_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isUint64() const { + return which() == Value::UINT64; +} +inline bool Value::Builder::isUint64() { + return which() == Value::UINT64; +} +inline ::uint64_t Value::Reader::getUint64() const { + KJ_IREQUIRE((which() == Value::UINT64), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Value::Builder::getUint64() { + KJ_IREQUIRE((which() == Value::UINT64), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setUint64( ::uint64_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::UINT64); + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isFloat32() const { + return which() == Value::FLOAT32; +} +inline bool Value::Builder::isFloat32() { + return which() == Value::FLOAT32; +} +inline float Value::Reader::getFloat32() const { + KJ_IREQUIRE((which() == Value::FLOAT32), + "Must check which() before get()ing a union member."); + return _reader.getDataField( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline float Value::Builder::getFloat32() { + KJ_IREQUIRE((which() == Value::FLOAT32), + "Must check which() before get()ing a union member."); + return _builder.getDataField( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setFloat32(float value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::FLOAT32); + _builder.setDataField( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isFloat64() const { + return which() == Value::FLOAT64; +} +inline bool Value::Builder::isFloat64() { + return which() == Value::FLOAT64; +} +inline double Value::Reader::getFloat64() const { + KJ_IREQUIRE((which() == Value::FLOAT64), + "Must check which() before get()ing a union member."); + return _reader.getDataField( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline double Value::Builder::getFloat64() { + KJ_IREQUIRE((which() == Value::FLOAT64), + "Must check which() before get()ing a union member."); + return _builder.getDataField( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setFloat64(double value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::FLOAT64); + _builder.setDataField( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isText() const { + return which() == Value::TEXT; +} +inline bool Value::Builder::isText() { + return which() == Value::TEXT; +} +inline bool Value::Reader::hasText() const { + if (which() != Value::TEXT) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Value::Builder::hasText() { + if (which() != Value::TEXT) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader Value::Reader::getText() const { + KJ_IREQUIRE((which() == Value::TEXT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder Value::Builder::getText() { + KJ_IREQUIRE((which() == Value::TEXT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Value::Builder::setText( ::capnp::Text::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::TEXT); + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder Value::Builder::initText(unsigned int size) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::TEXT); + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Value::Builder::adoptText( + ::capnp::Orphan< ::capnp::Text>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::TEXT); + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> Value::Builder::disownText() { + KJ_IREQUIRE((which() == Value::TEXT), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Value::Reader::isData() const { + return which() == Value::DATA; +} +inline bool Value::Builder::isData() { + return which() == Value::DATA; +} +inline bool Value::Reader::hasData() const { + if (which() != Value::DATA) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Value::Builder::hasData() { + if (which() != Value::DATA) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Data::Reader Value::Reader::getData() const { + KJ_IREQUIRE((which() == Value::DATA), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::Data>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Data::Builder Value::Builder::getData() { + KJ_IREQUIRE((which() == Value::DATA), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::Data>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Value::Builder::setData( ::capnp::Data::Reader value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::DATA); + ::capnp::_::PointerHelpers< ::capnp::Data>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Data::Builder Value::Builder::initData(unsigned int size) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::DATA); + return ::capnp::_::PointerHelpers< ::capnp::Data>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void Value::Builder::adoptData( + ::capnp::Orphan< ::capnp::Data>&& value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::DATA); + ::capnp::_::PointerHelpers< ::capnp::Data>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Data> Value::Builder::disownData() { + KJ_IREQUIRE((which() == Value::DATA), + "Must check which() before get()ing a union member."); + return ::capnp::_::PointerHelpers< ::capnp::Data>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Value::Reader::isList() const { + return which() == Value::LIST; +} +inline bool Value::Builder::isList() { + return which() == Value::LIST; +} +inline bool Value::Reader::hasList() const { + if (which() != Value::LIST) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Value::Builder::hasList() { + if (which() != Value::LIST) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Value::Reader::getList() const { + KJ_IREQUIRE((which() == Value::LIST), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Value::Builder::getList() { + KJ_IREQUIRE((which() == Value::LIST), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Value::Builder::initList() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::LIST); + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline bool Value::Reader::isEnum() const { + return which() == Value::ENUM; +} +inline bool Value::Builder::isEnum() { + return which() == Value::ENUM; +} +inline ::uint16_t Value::Reader::getEnum() const { + KJ_IREQUIRE((which() == Value::ENUM), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t Value::Builder::getEnum() { + KJ_IREQUIRE((which() == Value::ENUM), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setEnum( ::uint16_t value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::ENUM); + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<1>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isStruct() const { + return which() == Value::STRUCT; +} +inline bool Value::Builder::isStruct() { + return which() == Value::STRUCT; +} +inline bool Value::Reader::hasStruct() const { + if (which() != Value::STRUCT) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Value::Builder::hasStruct() { + if (which() != Value::STRUCT) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Value::Reader::getStruct() const { + KJ_IREQUIRE((which() == Value::STRUCT), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Value::Builder::getStruct() { + KJ_IREQUIRE((which() == Value::STRUCT), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Value::Builder::initStruct() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::STRUCT); + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline bool Value::Reader::isInterface() const { + return which() == Value::INTERFACE; +} +inline bool Value::Builder::isInterface() { + return which() == Value::INTERFACE; +} +inline ::capnp::Void Value::Reader::getInterface() const { + KJ_IREQUIRE((which() == Value::INTERFACE), + "Must check which() before get()ing a union member."); + return _reader.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::capnp::Void Value::Builder::getInterface() { + KJ_IREQUIRE((which() == Value::INTERFACE), + "Must check which() before get()ing a union member."); + return _builder.getDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Value::Builder::setInterface( ::capnp::Void value) { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::INTERFACE); + _builder.setDataField< ::capnp::Void>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Value::Reader::isAnyPointer() const { + return which() == Value::ANY_POINTER; +} +inline bool Value::Builder::isAnyPointer() { + return which() == Value::ANY_POINTER; +} +inline bool Value::Reader::hasAnyPointer() const { + if (which() != Value::ANY_POINTER) return false; + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Value::Builder::hasAnyPointer() { + if (which() != Value::ANY_POINTER) return false; + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::AnyPointer::Reader Value::Reader::getAnyPointer() const { + KJ_IREQUIRE((which() == Value::ANY_POINTER), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Reader(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Value::Builder::getAnyPointer() { + KJ_IREQUIRE((which() == Value::ANY_POINTER), + "Must check which() before get()ing a union member."); + return ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::AnyPointer::Builder Value::Builder::initAnyPointer() { + _builder.setDataField( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, Value::ANY_POINTER); + auto result = ::capnp::AnyPointer::Builder(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); + result.clear(); + return result; +} + +inline ::uint64_t Annotation::Reader::getId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t Annotation::Builder::getId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void Annotation::Builder::setId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool Annotation::Reader::hasValue() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool Annotation::Builder::hasValue() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Value::Reader Annotation::Reader::getValue() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Value::Builder Annotation::Builder::getValue() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Value::Pipeline Annotation::Pipeline::getValue() { + return ::capnp::schema::Value::Pipeline(_typeless.getPointerField(0)); +} +#endif // !CAPNP_LITE +inline void Annotation::Builder::setValue( ::capnp::schema::Value::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Value>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Value::Builder Annotation::Builder::initValue() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void Annotation::Builder::adoptValue( + ::capnp::Orphan< ::capnp::schema::Value>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Value>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Value> Annotation::Builder::disownValue() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Value>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool Annotation::Reader::hasBrand() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool Annotation::Builder::hasBrand() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::Brand::Reader Annotation::Reader::getBrand() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::Brand::Builder Annotation::Builder::getBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::Brand::Pipeline Annotation::Pipeline::getBrand() { + return ::capnp::schema::Brand::Pipeline(_typeless.getPointerField(1)); +} +#endif // !CAPNP_LITE +inline void Annotation::Builder::setBrand( ::capnp::schema::Brand::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::Brand::Builder Annotation::Builder::initBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void Annotation::Builder::adoptBrand( + ::capnp::Orphan< ::capnp::schema::Brand>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::Brand> Annotation::Builder::disownBrand() { + return ::capnp::_::PointerHelpers< ::capnp::schema::Brand>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline ::uint16_t CapnpVersion::Reader::getMajor() const { + return _reader.getDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint16_t CapnpVersion::Builder::getMajor() { + return _builder.getDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void CapnpVersion::Builder::setMajor( ::uint16_t value) { + _builder.setDataField< ::uint16_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline ::uint8_t CapnpVersion::Reader::getMinor() const { + return _reader.getDataField< ::uint8_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} + +inline ::uint8_t CapnpVersion::Builder::getMinor() { + return _builder.getDataField< ::uint8_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS); +} +inline void CapnpVersion::Builder::setMinor( ::uint8_t value) { + _builder.setDataField< ::uint8_t>( + ::capnp::bounded<2>() * ::capnp::ELEMENTS, value); +} + +inline ::uint8_t CapnpVersion::Reader::getMicro() const { + return _reader.getDataField< ::uint8_t>( + ::capnp::bounded<3>() * ::capnp::ELEMENTS); +} + +inline ::uint8_t CapnpVersion::Builder::getMicro() { + return _builder.getDataField< ::uint8_t>( + ::capnp::bounded<3>() * ::capnp::ELEMENTS); +} +inline void CapnpVersion::Builder::setMicro( ::uint8_t value) { + _builder.setDataField< ::uint8_t>( + ::capnp::bounded<3>() * ::capnp::ELEMENTS, value); +} + +inline bool CodeGeneratorRequest::Reader::hasNodes() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool CodeGeneratorRequest::Builder::hasNodes() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::Node>::Reader CodeGeneratorRequest::Reader::getNodes() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node>>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::Node>::Builder CodeGeneratorRequest::Builder::getNodes() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node>>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void CodeGeneratorRequest::Builder::setNodes( ::capnp::List< ::capnp::schema::Node>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node>>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::Node>::Builder CodeGeneratorRequest::Builder::initNodes(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node>>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void CodeGeneratorRequest::Builder::adoptNodes( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node>>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::Node>> CodeGeneratorRequest::Builder::disownNodes() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::Node>>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool CodeGeneratorRequest::Reader::hasRequestedFiles() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool CodeGeneratorRequest::Builder::hasRequestedFiles() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>::Reader CodeGeneratorRequest::Reader::getRequestedFiles() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>::Builder CodeGeneratorRequest::Builder::getRequestedFiles() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void CodeGeneratorRequest::Builder::setRequestedFiles( ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>::Builder CodeGeneratorRequest::Builder::initRequestedFiles(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), size); +} +inline void CodeGeneratorRequest::Builder::adoptRequestedFiles( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>> CodeGeneratorRequest::Builder::disownRequestedFiles() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile>>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline bool CodeGeneratorRequest::Reader::hasCapnpVersion() const { + return !_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline bool CodeGeneratorRequest::Builder::hasCapnpVersion() { + return !_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::schema::CapnpVersion::Reader CodeGeneratorRequest::Reader::getCapnpVersion() const { + return ::capnp::_::PointerHelpers< ::capnp::schema::CapnpVersion>::get(_reader.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline ::capnp::schema::CapnpVersion::Builder CodeGeneratorRequest::Builder::getCapnpVersion() { + return ::capnp::_::PointerHelpers< ::capnp::schema::CapnpVersion>::get(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +#if !CAPNP_LITE +inline ::capnp::schema::CapnpVersion::Pipeline CodeGeneratorRequest::Pipeline::getCapnpVersion() { + return ::capnp::schema::CapnpVersion::Pipeline(_typeless.getPointerField(2)); +} +#endif // !CAPNP_LITE +inline void CodeGeneratorRequest::Builder::setCapnpVersion( ::capnp::schema::CapnpVersion::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::schema::CapnpVersion>::set(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS), value); +} +inline ::capnp::schema::CapnpVersion::Builder CodeGeneratorRequest::Builder::initCapnpVersion() { + return ::capnp::_::PointerHelpers< ::capnp::schema::CapnpVersion>::init(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} +inline void CodeGeneratorRequest::Builder::adoptCapnpVersion( + ::capnp::Orphan< ::capnp::schema::CapnpVersion>&& value) { + ::capnp::_::PointerHelpers< ::capnp::schema::CapnpVersion>::adopt(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::schema::CapnpVersion> CodeGeneratorRequest::Builder::disownCapnpVersion() { + return ::capnp::_::PointerHelpers< ::capnp::schema::CapnpVersion>::disown(_builder.getPointerField( + ::capnp::bounded<2>() * ::capnp::POINTERS)); +} + +inline ::uint64_t CodeGeneratorRequest::RequestedFile::Reader::getId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t CodeGeneratorRequest::RequestedFile::Builder::getId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void CodeGeneratorRequest::RequestedFile::Builder::setId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool CodeGeneratorRequest::RequestedFile::Reader::hasFilename() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool CodeGeneratorRequest::RequestedFile::Builder::hasFilename() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader CodeGeneratorRequest::RequestedFile::Reader::getFilename() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder CodeGeneratorRequest::RequestedFile::Builder::getFilename() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void CodeGeneratorRequest::RequestedFile::Builder::setFilename( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder CodeGeneratorRequest::RequestedFile::Builder::initFilename(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void CodeGeneratorRequest::RequestedFile::Builder::adoptFilename( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> CodeGeneratorRequest::RequestedFile::Builder::disownFilename() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +inline bool CodeGeneratorRequest::RequestedFile::Reader::hasImports() const { + return !_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline bool CodeGeneratorRequest::RequestedFile::Builder::hasImports() { + return !_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>::Reader CodeGeneratorRequest::RequestedFile::Reader::getImports() const { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>>::get(_reader.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>::Builder CodeGeneratorRequest::RequestedFile::Builder::getImports() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>>::get(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} +inline void CodeGeneratorRequest::RequestedFile::Builder::setImports( ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>>::set(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), value); +} +inline ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>::Builder CodeGeneratorRequest::RequestedFile::Builder::initImports(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>>::init(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), size); +} +inline void CodeGeneratorRequest::RequestedFile::Builder::adoptImports( + ::capnp::Orphan< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>>&& value) { + ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>>::adopt(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>> CodeGeneratorRequest::RequestedFile::Builder::disownImports() { + return ::capnp::_::PointerHelpers< ::capnp::List< ::capnp::schema::CodeGeneratorRequest::RequestedFile::Import>>::disown(_builder.getPointerField( + ::capnp::bounded<1>() * ::capnp::POINTERS)); +} + +inline ::uint64_t CodeGeneratorRequest::RequestedFile::Import::Reader::getId() const { + return _reader.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} + +inline ::uint64_t CodeGeneratorRequest::RequestedFile::Import::Builder::getId() { + return _builder.getDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS); +} +inline void CodeGeneratorRequest::RequestedFile::Import::Builder::setId( ::uint64_t value) { + _builder.setDataField< ::uint64_t>( + ::capnp::bounded<0>() * ::capnp::ELEMENTS, value); +} + +inline bool CodeGeneratorRequest::RequestedFile::Import::Reader::hasName() const { + return !_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline bool CodeGeneratorRequest::RequestedFile::Import::Builder::hasName() { + return !_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS).isNull(); +} +inline ::capnp::Text::Reader CodeGeneratorRequest::RequestedFile::Import::Reader::getName() const { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_reader.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline ::capnp::Text::Builder CodeGeneratorRequest::RequestedFile::Import::Builder::getName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::get(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} +inline void CodeGeneratorRequest::RequestedFile::Import::Builder::setName( ::capnp::Text::Reader value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::set(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), value); +} +inline ::capnp::Text::Builder CodeGeneratorRequest::RequestedFile::Import::Builder::initName(unsigned int size) { + return ::capnp::_::PointerHelpers< ::capnp::Text>::init(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), size); +} +inline void CodeGeneratorRequest::RequestedFile::Import::Builder::adoptName( + ::capnp::Orphan< ::capnp::Text>&& value) { + ::capnp::_::PointerHelpers< ::capnp::Text>::adopt(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS), kj::mv(value)); +} +inline ::capnp::Orphan< ::capnp::Text> CodeGeneratorRequest::RequestedFile::Import::Builder::disownName() { + return ::capnp::_::PointerHelpers< ::capnp::Text>::disown(_builder.getPointerField( + ::capnp::bounded<0>() * ::capnp::POINTERS)); +} + +} // namespace +} // namespace + +#endif // CAPNP_INCLUDED_a93fc509624c72d9_ diff --git a/phonelibs/capnp-cpp/include/capnp/schema.h b/phonelibs/capnp-cpp/include/capnp/schema.h new file mode 100644 index 00000000000000..d59fa7523668d3 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/schema.h @@ -0,0 +1,934 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_SCHEMA_H_ +#define CAPNP_SCHEMA_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#if CAPNP_LITE +#error "Reflection APIs, including this header, are not available in lite mode." +#endif + +#include + +namespace capnp { + +class Schema; +class StructSchema; +class EnumSchema; +class InterfaceSchema; +class ConstSchema; +class ListSchema; +class Type; + +template ()> struct SchemaType_ { typedef Schema Type; }; +template struct SchemaType_ { typedef schema::Type::Which Type; }; +template struct SchemaType_ { typedef schema::Type::Which Type; }; +template struct SchemaType_ { typedef EnumSchema Type; }; +template struct SchemaType_ { typedef StructSchema Type; }; +template struct SchemaType_ { typedef InterfaceSchema Type; }; +template struct SchemaType_ { typedef ListSchema Type; }; + +template +using SchemaType = typename SchemaType_::Type; +// SchemaType is the type of T's schema, e.g. StructSchema if T is a struct. + +namespace _ { // private +extern const RawSchema NULL_SCHEMA; +extern const RawSchema NULL_STRUCT_SCHEMA; +extern const RawSchema NULL_ENUM_SCHEMA; +extern const RawSchema NULL_INTERFACE_SCHEMA; +extern const RawSchema NULL_CONST_SCHEMA; +// The schema types default to these null (empty) schemas in case of error, especially when +// exceptions are disabled. +} // namespace _ (private) + +class Schema { + // Convenience wrapper around capnp::schema::Node. + +public: + inline Schema(): raw(&_::NULL_SCHEMA.defaultBrand) {} + + template + static inline SchemaType from() { return SchemaType::template fromImpl(); } + // Get the Schema for a particular compiled-in type. + + schema::Node::Reader getProto() const; + // Get the underlying Cap'n Proto representation of the schema node. (Note that this accessor + // has performance comparable to accessors of struct-typed fields on Reader classes.) + + kj::ArrayPtr asUncheckedMessage() const; + // Get the encoded schema node content as a single message segment. It is safe to read as an + // unchecked message. + + Schema getDependency(uint64_t id) const KJ_DEPRECATED("Does not handle generics correctly."); + // DEPRECATED: This method cannot correctly account for generic type parameter bindings that + // may apply to the dependency. Instead of using this method, use a method of the Schema API + // that corresponds to the exact kind of dependency. For example, to get a field type, use + // StructSchema::Field::getType(). + // + // Gets the Schema for one of this Schema's dependencies. For example, if this Schema is for a + // struct, you could look up the schema for one of its fields' types. Throws an exception if this + // schema doesn't actually depend on the given id. + // + // Note that not all type IDs found in the schema node are considered "dependencies" -- only the + // ones that are needed to implement the dynamic API are. That includes: + // - Field types. + // - Group types. + // - scopeId for group nodes, but NOT otherwise. + // - Method parameter and return types. + // + // The following are NOT considered dependencies: + // - Nested nodes. + // - scopeId for a non-group node. + // - Annotations. + // + // To obtain schemas for those, you would need a SchemaLoader. + + bool isBranded() const; + // Returns true if this schema represents a non-default parameterization of this type. + + Schema getGeneric() const; + // Get the version of this schema with any brands removed. + + class BrandArgumentList; + BrandArgumentList getBrandArgumentsAtScope(uint64_t scopeId) const; + // Gets the values bound to the brand parameters at the given scope. + + StructSchema asStruct() const; + EnumSchema asEnum() const; + InterfaceSchema asInterface() const; + ConstSchema asConst() const; + // Cast the Schema to a specific type. Throws an exception if the type doesn't match. Use + // getProto() to determine type, e.g. getProto().isStruct(). + + inline bool operator==(const Schema& other) const { return raw == other.raw; } + inline bool operator!=(const Schema& other) const { return raw != other.raw; } + // Determine whether two Schemas are wrapping the exact same underlying data, by identity. If + // you want to check if two Schemas represent the same type (but possibly different versions of + // it), compare their IDs instead. + + template + void requireUsableAs() const; + // Throws an exception if a value with this Schema cannot safely be cast to a native value of + // the given type. This passes if either: + // - *this == from() + // - This schema was loaded with SchemaLoader, the type ID matches typeId(), and + // loadCompiledTypeAndDependencies() was called on the SchemaLoader. + + kj::StringPtr getShortDisplayName() const; + // Get the short version of the node's display name. + +private: + const _::RawBrandedSchema* raw; + + inline explicit Schema(const _::RawBrandedSchema* raw): raw(raw) { + KJ_IREQUIRE(raw->lazyInitializer == nullptr, + "Must call ensureInitialized() on RawSchema before constructing Schema."); + } + + template static inline Schema fromImpl() { + return Schema(&_::rawSchema()); + } + + void requireUsableAs(const _::RawSchema* expected) const; + + uint32_t getSchemaOffset(const schema::Value::Reader& value) const; + + Type getBrandBinding(uint64_t scopeId, uint index) const; + // Look up the binding for a brand parameter used by this Schema. Returns `AnyPointer` if the + // parameter is not bound. + // + // TODO(someday): Public interface for iterating over all bindings? + + Schema getDependency(uint64_t id, uint location) const; + // Look up schema for a particular dependency of this schema. `location` is the dependency + // location number as defined in _::RawBrandedSchema. + + Type interpretType(schema::Type::Reader proto, uint location) const; + // Interpret a schema::Type in the given location within the schema, compiling it into a + // Type object. + + friend class StructSchema; + friend class EnumSchema; + friend class InterfaceSchema; + friend class ConstSchema; + friend class ListSchema; + friend class SchemaLoader; + friend class Type; + friend kj::StringTree _::structString( + _::StructReader reader, const _::RawBrandedSchema& schema); + friend kj::String _::enumString(uint16_t value, const _::RawBrandedSchema& schema); +}; + +kj::StringPtr KJ_STRINGIFY(const Schema& schema); + +class Schema::BrandArgumentList { + // A list of generic parameter bindings for parameters of some particular type. Note that since + // parameters on an outer type apply to all inner types as well, a deeply-nested type can have + // multiple BrandArgumentLists that apply to it. + // + // A BrandArgumentList only represents the arguments that the client of the type specified. Since + // new parameters can be added over time, this list may not cover all defined parameters for the + // type. Missing parameters should be treated as AnyPointer. This class's implementation of + // operator[] already does this for you; out-of-bounds access will safely return AnyPointer. + +public: + inline BrandArgumentList(): scopeId(0), size_(0), bindings(nullptr) {} + + inline uint size() const { return size_; } + Type operator[](uint index) const; + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + +private: + uint64_t scopeId; + uint size_; + bool isUnbound; + const _::RawBrandedSchema::Binding* bindings; + + inline BrandArgumentList(uint64_t scopeId, bool isUnbound) + : scopeId(scopeId), size_(0), isUnbound(isUnbound), bindings(nullptr) {} + inline BrandArgumentList(uint64_t scopeId, uint size, + const _::RawBrandedSchema::Binding* bindings) + : scopeId(scopeId), size_(size), isUnbound(false), bindings(bindings) {} + + friend class Schema; +}; + +// ------------------------------------------------------------------- + +class StructSchema: public Schema { +public: + inline StructSchema(): Schema(&_::NULL_STRUCT_SCHEMA.defaultBrand) {} + + class Field; + class FieldList; + class FieldSubset; + + FieldList getFields() const; + // List top-level fields of this struct. This list will contain top-level groups (including + // named unions) but not the members of those groups. The list does, however, contain the + // members of the unnamed union, if there is one. + + FieldSubset getUnionFields() const; + // If the field contains an unnamed union, get a list of fields in the union, ordered by + // ordinal. Since discriminant values are assigned sequentially by ordinal, you may index this + // list by discriminant value. + + FieldSubset getNonUnionFields() const; + // Get the fields of this struct which are not in an unnamed union, ordered by ordinal. + + kj::Maybe findFieldByName(kj::StringPtr name) const; + // Find the field with the given name, or return null if there is no such field. If the struct + // contains an unnamed union, then this will find fields of that union in addition to fields + // of the outer struct, since they exist in the same namespace. It will not, however, find + // members of groups (including named unions) -- you must first look up the group itself, + // then dig into its type. + + Field getFieldByName(kj::StringPtr name) const; + // Like findFieldByName() but throws an exception on failure. + + kj::Maybe getFieldByDiscriminant(uint16_t discriminant) const; + // Finds the field whose `discriminantValue` is equal to the given value, or returns null if + // there is no such field. (If the schema does not represent a union or a struct containing + // an unnamed union, then this always returns null.) + +private: + StructSchema(Schema base): Schema(base) {} + template static inline StructSchema fromImpl() { + return StructSchema(Schema(&_::rawBrandedSchema())); + } + friend class Schema; + friend class Type; +}; + +class StructSchema::Field { +public: + Field() = default; + + inline schema::Field::Reader getProto() const { return proto; } + inline StructSchema getContainingStruct() const { return parent; } + + inline uint getIndex() const { return index; } + // Get the index of this field within the containing struct or union. + + Type getType() const; + // Get the type of this field. Note that this is preferred over getProto().getType() as this + // method will apply generics. + + uint32_t getDefaultValueSchemaOffset() const; + // For struct, list, and object fields, returns the offset, in words, within the first segment of + // the struct's schema, where this field's default value pointer is located. The schema is + // always stored as a single-segment unchecked message, which in turn means that the default + // value pointer itself can be treated as the root of an unchecked message -- if you know where + // to find it, which is what this method helps you with. + // + // For blobs, returns the offset of the beginning of the blob's content within the first segment + // of the struct's schema. + // + // This is primarily useful for code generators. The C++ code generator, for example, embeds + // the entire schema as a raw word array within the generated code. Of course, to implement + // field accessors, it needs access to those fields' default values. Embedding separate copies + // of those default values would be redundant since they are already included in the schema, but + // seeking through the schema at runtime to find the default values would be ugly. Instead, + // the code generator can use getDefaultValueSchemaOffset() to find the offset of the default + // value within the schema, and can simply apply that offset at runtime. + // + // If the above does not make sense, you probably don't need this method. + + inline bool operator==(const Field& other) const; + inline bool operator!=(const Field& other) const { return !(*this == other); } + +private: + StructSchema parent; + uint index; + schema::Field::Reader proto; + + inline Field(StructSchema parent, uint index, schema::Field::Reader proto) + : parent(parent), index(index), proto(proto) {} + + friend class StructSchema; +}; + +kj::StringPtr KJ_STRINGIFY(const StructSchema::Field& field); + +class StructSchema::FieldList { +public: + FieldList() = default; // empty list + + inline uint size() const { return list.size(); } + inline Field operator[](uint index) const { return Field(parent, index, list[index]); } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + +private: + StructSchema parent; + List::Reader list; + + inline FieldList(StructSchema parent, List::Reader list) + : parent(parent), list(list) {} + + friend class StructSchema; +}; + +class StructSchema::FieldSubset { +public: + FieldSubset() = default; // empty list + + inline uint size() const { return size_; } + inline Field operator[](uint index) const { + return Field(parent, indices[index], list[indices[index]]); + } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + +private: + StructSchema parent; + List::Reader list; + const uint16_t* indices; + uint size_; + + inline FieldSubset(StructSchema parent, List::Reader list, + const uint16_t* indices, uint size) + : parent(parent), list(list), indices(indices), size_(size) {} + + friend class StructSchema; +}; + +// ------------------------------------------------------------------- + +class EnumSchema: public Schema { +public: + inline EnumSchema(): Schema(&_::NULL_ENUM_SCHEMA.defaultBrand) {} + + class Enumerant; + class EnumerantList; + + EnumerantList getEnumerants() const; + + kj::Maybe findEnumerantByName(kj::StringPtr name) const; + + Enumerant getEnumerantByName(kj::StringPtr name) const; + // Like findEnumerantByName() but throws an exception on failure. + +private: + EnumSchema(Schema base): Schema(base) {} + template static inline EnumSchema fromImpl() { + return EnumSchema(Schema(&_::rawBrandedSchema())); + } + friend class Schema; + friend class Type; +}; + +class EnumSchema::Enumerant { +public: + Enumerant() = default; + + inline schema::Enumerant::Reader getProto() const { return proto; } + inline EnumSchema getContainingEnum() const { return parent; } + + inline uint16_t getOrdinal() const { return ordinal; } + inline uint getIndex() const { return ordinal; } + + inline bool operator==(const Enumerant& other) const; + inline bool operator!=(const Enumerant& other) const { return !(*this == other); } + +private: + EnumSchema parent; + uint16_t ordinal; + schema::Enumerant::Reader proto; + + inline Enumerant(EnumSchema parent, uint16_t ordinal, schema::Enumerant::Reader proto) + : parent(parent), ordinal(ordinal), proto(proto) {} + + friend class EnumSchema; +}; + +class EnumSchema::EnumerantList { +public: + EnumerantList() = default; // empty list + + inline uint size() const { return list.size(); } + inline Enumerant operator[](uint index) const { return Enumerant(parent, index, list[index]); } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + +private: + EnumSchema parent; + List::Reader list; + + inline EnumerantList(EnumSchema parent, List::Reader list) + : parent(parent), list(list) {} + + friend class EnumSchema; +}; + +// ------------------------------------------------------------------- + +class InterfaceSchema: public Schema { +public: + inline InterfaceSchema(): Schema(&_::NULL_INTERFACE_SCHEMA.defaultBrand) {} + + class Method; + class MethodList; + + MethodList getMethods() const; + + kj::Maybe findMethodByName(kj::StringPtr name) const; + + Method getMethodByName(kj::StringPtr name) const; + // Like findMethodByName() but throws an exception on failure. + + class SuperclassList; + + SuperclassList getSuperclasses() const; + // Get the immediate superclasses of this type, after applying generics. + + bool extends(InterfaceSchema other) const; + // Returns true if `other` is a superclass of this interface (including if `other == *this`). + + kj::Maybe findSuperclass(uint64_t typeId) const; + // Find the superclass of this interface with the given type ID. Returns null if the interface + // extends no such type. + +private: + InterfaceSchema(Schema base): Schema(base) {} + template static inline InterfaceSchema fromImpl() { + return InterfaceSchema(Schema(&_::rawBrandedSchema())); + } + friend class Schema; + friend class Type; + + kj::Maybe findMethodByName(kj::StringPtr name, uint& counter) const; + bool extends(InterfaceSchema other, uint& counter) const; + kj::Maybe findSuperclass(uint64_t typeId, uint& counter) const; + // We protect against malicious schemas with large or cyclic hierarchies by cutting off the + // search when the counter reaches a threshold. +}; + +class InterfaceSchema::Method { +public: + Method() = default; + + inline schema::Method::Reader getProto() const { return proto; } + inline InterfaceSchema getContainingInterface() const { return parent; } + + inline uint16_t getOrdinal() const { return ordinal; } + inline uint getIndex() const { return ordinal; } + + StructSchema getParamType() const; + StructSchema getResultType() const; + // Get the parameter and result types, including substituting generic parameters. + + inline bool operator==(const Method& other) const; + inline bool operator!=(const Method& other) const { return !(*this == other); } + +private: + InterfaceSchema parent; + uint16_t ordinal; + schema::Method::Reader proto; + + inline Method(InterfaceSchema parent, uint16_t ordinal, + schema::Method::Reader proto) + : parent(parent), ordinal(ordinal), proto(proto) {} + + friend class InterfaceSchema; +}; + +class InterfaceSchema::MethodList { +public: + MethodList() = default; // empty list + + inline uint size() const { return list.size(); } + inline Method operator[](uint index) const { return Method(parent, index, list[index]); } + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + +private: + InterfaceSchema parent; + List::Reader list; + + inline MethodList(InterfaceSchema parent, List::Reader list) + : parent(parent), list(list) {} + + friend class InterfaceSchema; +}; + +class InterfaceSchema::SuperclassList { +public: + SuperclassList() = default; // empty list + + inline uint size() const { return list.size(); } + InterfaceSchema operator[](uint index) const; + + typedef _::IndexingIterator Iterator; + inline Iterator begin() const { return Iterator(this, 0); } + inline Iterator end() const { return Iterator(this, size()); } + +private: + InterfaceSchema parent; + List::Reader list; + + inline SuperclassList(InterfaceSchema parent, List::Reader list) + : parent(parent), list(list) {} + + friend class InterfaceSchema; +}; + +// ------------------------------------------------------------------- + +class ConstSchema: public Schema { + // Represents a constant declaration. + // + // `ConstSchema` can be implicitly cast to DynamicValue to read its value. + +public: + inline ConstSchema(): Schema(&_::NULL_CONST_SCHEMA.defaultBrand) {} + + template + ReaderFor as() const; + // Read the constant's value. This is a convenience method equivalent to casting the ConstSchema + // to a DynamicValue and then calling its `as()` method. For dependency reasons, this method + // is defined in , which you must #include explicitly. + + uint32_t getValueSchemaOffset() const; + // Much like StructSchema::Field::getDefaultValueSchemaOffset(), if the constant has pointer + // type, this gets the offset from the beginning of the constant's schema node to a pointer + // representing the constant value. + + Type getType() const; + +private: + ConstSchema(Schema base): Schema(base) {} + friend class Schema; +}; + +// ------------------------------------------------------------------- + +class Type { +public: + struct BrandParameter { + uint64_t scopeId; + uint index; + }; + struct ImplicitParameter { + uint index; + }; + + inline Type(); + inline Type(schema::Type::Which primitive); + inline Type(StructSchema schema); + inline Type(EnumSchema schema); + inline Type(InterfaceSchema schema); + inline Type(ListSchema schema); + inline Type(schema::Type::AnyPointer::Unconstrained::Which anyPointerKind); + inline Type(BrandParameter param); + inline Type(ImplicitParameter param); + + template + inline static Type from(); + + inline schema::Type::Which which() const; + + StructSchema asStruct() const; + EnumSchema asEnum() const; + InterfaceSchema asInterface() const; + ListSchema asList() const; + // Each of these methods may only be called if which() returns the corresponding type. + + kj::Maybe getBrandParameter() const; + // Only callable if which() returns ANY_POINTER. Returns null if the type is just a regular + // AnyPointer and not a parameter. + + kj::Maybe getImplicitParameter() const; + // Only callable if which() returns ANY_POINTER. Returns null if the type is just a regular + // AnyPointer and not a parameter. "Implicit parameters" refer to type parameters on methods. + + inline schema::Type::AnyPointer::Unconstrained::Which whichAnyPointerKind() const; + // Only callable if which() returns ANY_POINTER. + + inline bool isVoid() const; + inline bool isBool() const; + inline bool isInt8() const; + inline bool isInt16() const; + inline bool isInt32() const; + inline bool isInt64() const; + inline bool isUInt8() const; + inline bool isUInt16() const; + inline bool isUInt32() const; + inline bool isUInt64() const; + inline bool isFloat32() const; + inline bool isFloat64() const; + inline bool isText() const; + inline bool isData() const; + inline bool isList() const; + inline bool isEnum() const; + inline bool isStruct() const; + inline bool isInterface() const; + inline bool isAnyPointer() const; + + bool operator==(const Type& other) const; + inline bool operator!=(const Type& other) const { return !(*this == other); } + + size_t hashCode() const; + + inline Type wrapInList(uint depth = 1) const; + // Return the Type formed by wrapping this type in List() `depth` times. + + inline Type(schema::Type::Which derived, const _::RawBrandedSchema* schema); + // For internal use. + +private: + schema::Type::Which baseType; // type not including applications of List() + uint8_t listDepth; // 0 for T, 1 for List(T), 2 for List(List(T)), ... + + bool isImplicitParam; + // If true, this refers to an implicit method parameter. baseType must be ANY_POINTER, scopeId + // must be zero, and paramIndex indicates the parameter index. + + union { + uint16_t paramIndex; + // If baseType is ANY_POINTER but this Type actually refers to a type parameter, this is the + // index of the parameter among the parameters at its scope, and `scopeId` below is the type ID + // of the scope where the parameter was defined. + + schema::Type::AnyPointer::Unconstrained::Which anyPointerKind; + // If scopeId is zero and isImplicitParam is false. + }; + + union { + const _::RawBrandedSchema* schema; // if type is struct, enum, interface... + uint64_t scopeId; // if type is AnyPointer but it's actually a type parameter... + }; + + Type(schema::Type::Which baseType, uint8_t listDepth, const _::RawBrandedSchema* schema) + : baseType(baseType), listDepth(listDepth), schema(schema) { + KJ_IREQUIRE(baseType != schema::Type::ANY_POINTER); + } + + void requireUsableAs(Type expected) const; + + friend class ListSchema; // only for requireUsableAs() +}; + +// ------------------------------------------------------------------- + +class ListSchema { + // ListSchema is a little different because list types are not described by schema nodes. So, + // ListSchema doesn't subclass Schema. + +public: + ListSchema() = default; + + static ListSchema of(schema::Type::Which primitiveType); + static ListSchema of(StructSchema elementType); + static ListSchema of(EnumSchema elementType); + static ListSchema of(InterfaceSchema elementType); + static ListSchema of(ListSchema elementType); + static ListSchema of(Type elementType); + // Construct the schema for a list of the given type. + + static ListSchema of(schema::Type::Reader elementType, Schema context) + KJ_DEPRECATED("Does not handle generics correctly."); + // DEPRECATED: This method cannot correctly account for generic type parameter bindings that + // may apply to the input type. Instead of using this method, use a method of the Schema API + // that corresponds to the exact kind of dependency. For example, to get a field type, use + // StructSchema::Field::getType(). + // + // Construct from an element type schema. Requires a context which can handle getDependency() + // requests for any type ID found in the schema. + + Type getElementType() const; + + inline schema::Type::Which whichElementType() const; + // Get the element type's "which()". ListSchema does not actually store a schema::Type::Reader + // describing the element type, but if it did, this would be equivalent to calling + // .getBody().which() on that type. + + StructSchema getStructElementType() const; + EnumSchema getEnumElementType() const; + InterfaceSchema getInterfaceElementType() const; + ListSchema getListElementType() const; + // Get the schema for complex element types. Each of these throws an exception if the element + // type is not of the requested kind. + + inline bool operator==(const ListSchema& other) const { return elementType == other.elementType; } + inline bool operator!=(const ListSchema& other) const { return elementType != other.elementType; } + + template + void requireUsableAs() const; + +private: + Type elementType; + + inline explicit ListSchema(Type elementType): elementType(elementType) {} + + template + struct FromImpl; + template static inline ListSchema fromImpl() { + return FromImpl::get(); + } + + void requireUsableAs(ListSchema expected) const; + + friend class Schema; +}; + +// ======================================================================================= +// inline implementation + +template <> inline schema::Type::Which Schema::from() { return schema::Type::VOID; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::BOOL; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::INT8; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::INT16; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::INT32; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::INT64; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::UINT8; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::UINT16; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::UINT32; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::UINT64; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::FLOAT32; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::FLOAT64; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::TEXT; } +template <> inline schema::Type::Which Schema::from() { return schema::Type::DATA; } + +inline Schema Schema::getDependency(uint64_t id) const { + return getDependency(id, 0); +} + +inline bool Schema::isBranded() const { + return raw != &raw->generic->defaultBrand; +} + +inline Schema Schema::getGeneric() const { + return Schema(&raw->generic->defaultBrand); +} + +template +inline void Schema::requireUsableAs() const { + requireUsableAs(&_::rawSchema()); +} + +inline bool StructSchema::Field::operator==(const Field& other) const { + return parent == other.parent && index == other.index; +} +inline bool EnumSchema::Enumerant::operator==(const Enumerant& other) const { + return parent == other.parent && ordinal == other.ordinal; +} +inline bool InterfaceSchema::Method::operator==(const Method& other) const { + return parent == other.parent && ordinal == other.ordinal; +} + +inline ListSchema ListSchema::of(StructSchema elementType) { + return ListSchema(Type(elementType)); +} +inline ListSchema ListSchema::of(EnumSchema elementType) { + return ListSchema(Type(elementType)); +} +inline ListSchema ListSchema::of(InterfaceSchema elementType) { + return ListSchema(Type(elementType)); +} +inline ListSchema ListSchema::of(ListSchema elementType) { + return ListSchema(Type(elementType)); +} +inline ListSchema ListSchema::of(Type elementType) { + return ListSchema(elementType); +} + +inline Type ListSchema::getElementType() const { + return elementType; +} + +inline schema::Type::Which ListSchema::whichElementType() const { + return elementType.which(); +} + +inline StructSchema ListSchema::getStructElementType() const { + return elementType.asStruct(); +} + +inline EnumSchema ListSchema::getEnumElementType() const { + return elementType.asEnum(); +} + +inline InterfaceSchema ListSchema::getInterfaceElementType() const { + return elementType.asInterface(); +} + +inline ListSchema ListSchema::getListElementType() const { + return elementType.asList(); +} + +template +inline void ListSchema::requireUsableAs() const { + static_assert(kind() == Kind::LIST, + "ListSchema::requireUsableAs() requires T is a list type."); + requireUsableAs(Schema::from()); +} + +inline void ListSchema::requireUsableAs(ListSchema expected) const { + elementType.requireUsableAs(expected.elementType); +} + +template +struct ListSchema::FromImpl> { + static inline ListSchema get() { return of(Schema::from()); } +}; + +inline Type::Type(): baseType(schema::Type::VOID), listDepth(0), schema(nullptr) {} +inline Type::Type(schema::Type::Which primitive) + : baseType(primitive), listDepth(0), isImplicitParam(false) { + KJ_IREQUIRE(primitive != schema::Type::STRUCT && + primitive != schema::Type::ENUM && + primitive != schema::Type::INTERFACE && + primitive != schema::Type::LIST); + if (primitive == schema::Type::ANY_POINTER) { + scopeId = 0; + anyPointerKind = schema::Type::AnyPointer::Unconstrained::ANY_KIND; + } else { + schema = nullptr; + } +} +inline Type::Type(schema::Type::Which derived, const _::RawBrandedSchema* schema) + : baseType(derived), listDepth(0), isImplicitParam(false), schema(schema) { + KJ_IREQUIRE(derived == schema::Type::STRUCT || + derived == schema::Type::ENUM || + derived == schema::Type::INTERFACE); +} + +inline Type::Type(StructSchema schema) + : baseType(schema::Type::STRUCT), listDepth(0), schema(schema.raw) {} +inline Type::Type(EnumSchema schema) + : baseType(schema::Type::ENUM), listDepth(0), schema(schema.raw) {} +inline Type::Type(InterfaceSchema schema) + : baseType(schema::Type::INTERFACE), listDepth(0), schema(schema.raw) {} +inline Type::Type(ListSchema schema) + : Type(schema.getElementType()) { ++listDepth; } +inline Type::Type(schema::Type::AnyPointer::Unconstrained::Which anyPointerKind) + : baseType(schema::Type::ANY_POINTER), listDepth(0), isImplicitParam(false), + anyPointerKind(anyPointerKind), scopeId(0) {} +inline Type::Type(BrandParameter param) + : baseType(schema::Type::ANY_POINTER), listDepth(0), isImplicitParam(false), + paramIndex(param.index), scopeId(param.scopeId) {} +inline Type::Type(ImplicitParameter param) + : baseType(schema::Type::ANY_POINTER), listDepth(0), isImplicitParam(true), + paramIndex(param.index), scopeId(0) {} + +inline schema::Type::Which Type::which() const { + return listDepth > 0 ? schema::Type::LIST : baseType; +} + +inline schema::Type::AnyPointer::Unconstrained::Which Type::whichAnyPointerKind() const { + KJ_IREQUIRE(baseType == schema::Type::ANY_POINTER); + return !isImplicitParam && scopeId == 0 ? anyPointerKind + : schema::Type::AnyPointer::Unconstrained::ANY_KIND; +} + +template +inline Type Type::from() { return Type(Schema::from()); } + +inline bool Type::isVoid () const { return baseType == schema::Type::VOID && listDepth == 0; } +inline bool Type::isBool () const { return baseType == schema::Type::BOOL && listDepth == 0; } +inline bool Type::isInt8 () const { return baseType == schema::Type::INT8 && listDepth == 0; } +inline bool Type::isInt16 () const { return baseType == schema::Type::INT16 && listDepth == 0; } +inline bool Type::isInt32 () const { return baseType == schema::Type::INT32 && listDepth == 0; } +inline bool Type::isInt64 () const { return baseType == schema::Type::INT64 && listDepth == 0; } +inline bool Type::isUInt8 () const { return baseType == schema::Type::UINT8 && listDepth == 0; } +inline bool Type::isUInt16 () const { return baseType == schema::Type::UINT16 && listDepth == 0; } +inline bool Type::isUInt32 () const { return baseType == schema::Type::UINT32 && listDepth == 0; } +inline bool Type::isUInt64 () const { return baseType == schema::Type::UINT64 && listDepth == 0; } +inline bool Type::isFloat32() const { return baseType == schema::Type::FLOAT32 && listDepth == 0; } +inline bool Type::isFloat64() const { return baseType == schema::Type::FLOAT64 && listDepth == 0; } +inline bool Type::isText () const { return baseType == schema::Type::TEXT && listDepth == 0; } +inline bool Type::isData () const { return baseType == schema::Type::DATA && listDepth == 0; } +inline bool Type::isList () const { return listDepth > 0; } +inline bool Type::isEnum () const { return baseType == schema::Type::ENUM && listDepth == 0; } +inline bool Type::isStruct () const { return baseType == schema::Type::STRUCT && listDepth == 0; } +inline bool Type::isInterface() const { + return baseType == schema::Type::INTERFACE && listDepth == 0; +} +inline bool Type::isAnyPointer() const { + return baseType == schema::Type::ANY_POINTER && listDepth == 0; +} + +inline Type Type::wrapInList(uint depth) const { + Type result = *this; + result.listDepth += depth; + return result; +} + +} // namespace capnp + +#endif // CAPNP_SCHEMA_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/serialize-async.h b/phonelibs/capnp-cpp/include/capnp/serialize-async.h new file mode 100644 index 00000000000000..a16bfd8975a6c7 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/serialize-async.h @@ -0,0 +1,64 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_SERIALIZE_ASYNC_H_ +#define CAPNP_SERIALIZE_ASYNC_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include +#include "message.h" + +namespace capnp { + +kj::Promise> readMessage( + kj::AsyncInputStream& input, ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr); +// Read a message asynchronously. +// +// `input` must remain valid until the returned promise resolves (or is canceled). +// +// `scratchSpace`, if provided, must remain valid until the returned MessageReader is destroyed. + +kj::Promise>> tryReadMessage( + kj::AsyncInputStream& input, ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr); +// Like `readMessage` but returns null on EOF. + +kj::Promise writeMessage(kj::AsyncOutputStream& output, + kj::ArrayPtr> segments) + KJ_WARN_UNUSED_RESULT; +kj::Promise writeMessage(kj::AsyncOutputStream& output, MessageBuilder& builder) + KJ_WARN_UNUSED_RESULT; +// Write asynchronously. The parameters must remain valid until the returned promise resolves. + +// ======================================================================================= +// inline implementation details + +inline kj::Promise writeMessage(kj::AsyncOutputStream& output, MessageBuilder& builder) { + return writeMessage(output, builder.getSegmentsForOutput()); +} + +} // namespace capnp + +#endif // CAPNP_SERIALIZE_ASYNC_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/serialize-packed.h b/phonelibs/capnp-cpp/include/capnp/serialize-packed.h new file mode 100644 index 00000000000000..a71260ce1dd4c1 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/serialize-packed.h @@ -0,0 +1,130 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_SERIALIZE_PACKED_H_ +#define CAPNP_SERIALIZE_PACKED_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "serialize.h" + +namespace capnp { + +namespace _ { // private + +class PackedInputStream: public kj::InputStream { + // An input stream that unpacks packed data with a picky constraint: The caller must read data + // in the exact same size and sequence as the data was written to PackedOutputStream. + +public: + explicit PackedInputStream(kj::BufferedInputStream& inner); + KJ_DISALLOW_COPY(PackedInputStream); + ~PackedInputStream() noexcept(false); + + // implements InputStream ------------------------------------------ + size_t tryRead(void* buffer, size_t minBytes, size_t maxBytes) override; + void skip(size_t bytes) override; + +private: + kj::BufferedInputStream& inner; +}; + +class PackedOutputStream: public kj::OutputStream { +public: + explicit PackedOutputStream(kj::BufferedOutputStream& inner); + KJ_DISALLOW_COPY(PackedOutputStream); + ~PackedOutputStream() noexcept(false); + + // implements OutputStream ----------------------------------------- + void write(const void* buffer, size_t bytes) override; + +private: + kj::BufferedOutputStream& inner; +}; + +} // namespace _ (private) + +class PackedMessageReader: private _::PackedInputStream, public InputStreamMessageReader { +public: + PackedMessageReader(kj::BufferedInputStream& inputStream, ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr); + KJ_DISALLOW_COPY(PackedMessageReader); + ~PackedMessageReader() noexcept(false); +}; + +class PackedFdMessageReader: private kj::FdInputStream, private kj::BufferedInputStreamWrapper, + public PackedMessageReader { +public: + PackedFdMessageReader(int fd, ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr); + // Read message from a file descriptor, without taking ownership of the descriptor. + // Note that if you want to reuse the descriptor after the reader is destroyed, you'll need to + // seek it, since otherwise the position is unspecified. + + PackedFdMessageReader(kj::AutoCloseFd fd, ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr); + // Read a message from a file descriptor, taking ownership of the descriptor. + + KJ_DISALLOW_COPY(PackedFdMessageReader); + + ~PackedFdMessageReader() noexcept(false); +}; + +void writePackedMessage(kj::BufferedOutputStream& output, MessageBuilder& builder); +void writePackedMessage(kj::BufferedOutputStream& output, + kj::ArrayPtr> segments); +// Write a packed message to a buffered output stream. + +void writePackedMessage(kj::OutputStream& output, MessageBuilder& builder); +void writePackedMessage(kj::OutputStream& output, + kj::ArrayPtr> segments); +// Write a packed message to an unbuffered output stream. If you intend to write multiple messages +// in succession, consider wrapping your output in a buffered stream in order to reduce system +// call overhead. + +void writePackedMessageToFd(int fd, MessageBuilder& builder); +void writePackedMessageToFd(int fd, kj::ArrayPtr> segments); +// Write a single packed message to the file descriptor. + +size_t computeUnpackedSizeInWords(kj::ArrayPtr packedBytes); +// Computes the number of words to which the given packed bytes will unpack. Not intended for use +// in performance-sensitive situations. + +// ======================================================================================= +// inline stuff + +inline void writePackedMessage(kj::BufferedOutputStream& output, MessageBuilder& builder) { + writePackedMessage(output, builder.getSegmentsForOutput()); +} + +inline void writePackedMessage(kj::OutputStream& output, MessageBuilder& builder) { + writePackedMessage(output, builder.getSegmentsForOutput()); +} + +inline void writePackedMessageToFd(int fd, MessageBuilder& builder) { + writePackedMessageToFd(fd, builder.getSegmentsForOutput()); +} + +} // namespace capnp + +#endif // CAPNP_SERIALIZE_PACKED_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/serialize-text.h b/phonelibs/capnp-cpp/include/capnp/serialize-text.h new file mode 100644 index 00000000000000..d86fc2c00ec8a5 --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/serialize-text.h @@ -0,0 +1,96 @@ +// Copyright (c) 2015 Philip Quinn. +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef CAPNP_SERIALIZE_TEXT_H_ +#define CAPNP_SERIALIZE_TEXT_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include +#include "dynamic.h" +#include "orphan.h" +#include "schema.h" + +namespace capnp { + +class TextCodec { + // Reads and writes Cap'n Proto objects in a plain text format (as used in the schema + // language for constants, and read/written by the 'decode' and 'encode' commands of + // the capnp tool). + // + // This format is useful for debugging or human input, but it is not a robust alternative + // to the binary format. Changes to a schema's types or names that are permitted in a + // schema's binary evolution will likely break messages stored in this format. + // + // Note that definitions or references (to constants, other fields, or files) are not + // permitted in this format. To evaluate declarations with the full expressiveness of the + // schema language, see `capnp::SchemaParser`. + // + // Requires linking with the capnpc library. + +public: + TextCodec(); + ~TextCodec() noexcept(true); + + void setPrettyPrint(bool enabled); + // If enabled, pads the output of `encode()` with spaces and newlines to make it more + // human-readable. + + template + kj::String encode(T&& value) const; + kj::String encode(DynamicValue::Reader value) const; + // Encode any Cap'n Proto value. + + template + Orphan decode(kj::StringPtr input, Orphanage orphanage) const; + // Decode a text message into a Cap'n Proto object of type T, allocated in the given + // orphanage. Any errors parsing the input or assigning the fields of T are thrown as + // exceptions. + + void decode(kj::StringPtr input, DynamicStruct::Builder output) const; + // Decode a text message for a struct into the given builder. Any errors parsing the + // input or assigning the fields of the output are thrown as exceptions. + + // TODO(someday): expose some control over the error handling? +private: + Orphan decode(kj::StringPtr input, Type type, Orphanage orphanage) const; + + bool prettyPrint; +}; + +// ======================================================================================= +// inline stuff + +template +inline kj::String TextCodec::encode(T&& value) const { + return encode(DynamicValue::Reader(ReaderFor>(kj::fwd(value)))); +} + +template +inline Orphan TextCodec::decode(kj::StringPtr input, Orphanage orphanage) const { + return decode(input, Type::from(), orphanage).template releaseAs(); +} + +} // namespace capnp + +#endif // CAPNP_SERIALIZE_TEXT_H_ diff --git a/phonelibs/capnp-cpp/include/capnp/serialize.h b/phonelibs/capnp-cpp/include/capnp/serialize.h new file mode 100644 index 00000000000000..797db517662abd --- /dev/null +++ b/phonelibs/capnp-cpp/include/capnp/serialize.h @@ -0,0 +1,237 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file implements a simple serialization format for Cap'n Proto messages. The format +// is as follows: +// +// * 32-bit little-endian segment count (4 bytes). +// * 32-bit little-endian size of each segment (4*(segment count) bytes). +// * Padding so that subsequent data is 64-bit-aligned (0 or 4 bytes). (I.e., if there are an even +// number of segments, there are 4 bytes of zeros here, otherwise there is no padding.) +// * Data from each segment, in order (8*sum(segment sizes) bytes) +// +// This format has some important properties: +// - It is self-delimiting, so multiple messages may be written to a stream without any external +// delimiter. +// - The total size and position of each segment can be determined by reading only the first part +// of the message, allowing lazy and random-access reading of the segment data. +// - A message is always at least 8 bytes. +// - A single-segment message can be read entirely in two system calls with no buffering. +// - A multi-segment message can be read entirely in three system calls with no buffering. +// - The format is appropriate for mmap()ing since all data is aligned. + +#ifndef CAPNP_SERIALIZE_H_ +#define CAPNP_SERIALIZE_H_ + +#if defined(__GNUC__) && !defined(CAPNP_HEADER_WARNINGS) +#pragma GCC system_header +#endif + +#include "message.h" +#include + +namespace capnp { + +class FlatArrayMessageReader: public MessageReader { + // Parses a message from a flat array. Note that it makes sense to use this together with mmap() + // for extremely fast parsing. + +public: + FlatArrayMessageReader(kj::ArrayPtr array, ReaderOptions options = ReaderOptions()); + // The array must remain valid until the MessageReader is destroyed. + + kj::ArrayPtr getSegment(uint id) override; + + const word* getEnd() const { return end; } + // Get a pointer just past the end of the message as determined by reading the message header. + // This could actually be before the end of the input array. This pointer is useful e.g. if + // you know that the input array has extra stuff appended after the message and you want to + // get at it. + +private: + // Optimize for single-segment case. + kj::ArrayPtr segment0; + kj::Array> moreSegments; + const word* end; +}; + +kj::ArrayPtr initMessageBuilderFromFlatArrayCopy( + kj::ArrayPtr array, MessageBuilder& target, + ReaderOptions options = ReaderOptions()); +// Convenience function which reads a message using `FlatArrayMessageReader` then copies the +// content into the target `MessageBuilder`, verifying that the message structure is valid +// (although not necessarily that it matches the desired schema). +// +// Returns an ArrayPtr containing any words left over in the array after consuming the whole +// message. This is useful when reading multiple messages that have been concatenated. See also +// FlatArrayMessageReader::getEnd(). +// +// (Note that it's also possible to initialize a `MessageBuilder` directly without a copy using one +// of `MessageBuilder`'s constructors. However, this approach skips the validation step and is not +// safe to use on untrusted input. Therefore, we do not provide a convenience method for it.) + +kj::Array messageToFlatArray(MessageBuilder& builder); +// Constructs a flat array containing the entire content of the given message. +// +// To output the message as bytes, use `.asBytes()` on the returned word array. Keep in mind that +// `asBytes()` returns an ArrayPtr, so you have to save the Array as well to prevent it from being +// deleted. For example: +// +// kj::Array words = messageToFlatArray(myMessage); +// kj::ArrayPtr bytes = words.asBytes(); +// write(fd, bytes.begin(), bytes.size()); + +kj::Array messageToFlatArray(kj::ArrayPtr> segments); +// Version of messageToFlatArray that takes a raw segment array. + +size_t computeSerializedSizeInWords(MessageBuilder& builder); +// Returns the size, in words, that will be needed to serialize the message, including the header. + +size_t computeSerializedSizeInWords(kj::ArrayPtr> segments); +// Version of computeSerializedSizeInWords that takes a raw segment array. + +size_t expectedSizeInWordsFromPrefix(kj::ArrayPtr messagePrefix); +// Given a prefix of a serialized message, try to determine the expected total size of the message, +// in words. The returned size is based on the information known so far; it may be an underestimate +// if the prefix doesn't contain the full segment table. +// +// If the returned value is greater than `messagePrefix.size()`, then the message is not yet +// complete and the app cannot parse it yet. If the returned value is less than or equal to +// `messagePrefix.size()`, then the returned value is the exact total size of the message; any +// remaining bytes are part of the next message. +// +// This function is useful when reading messages from a stream in an asynchronous way, but when +// using the full KJ async infrastructure would be too difficult. Each time bytes are received, +// use this function to determine if an entire message is ready to be parsed. + +// ======================================================================================= + +class InputStreamMessageReader: public MessageReader { + // A MessageReader that reads from an abstract kj::InputStream. See also StreamFdMessageReader + // for a subclass specific to file descriptors. + +public: + InputStreamMessageReader(kj::InputStream& inputStream, + ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr); + ~InputStreamMessageReader() noexcept(false); + + // implements MessageReader ---------------------------------------- + kj::ArrayPtr getSegment(uint id) override; + +private: + kj::InputStream& inputStream; + byte* readPos; + + // Optimize for single-segment case. + kj::ArrayPtr segment0; + kj::Array> moreSegments; + + kj::Array ownedSpace; + // Only if scratchSpace wasn't big enough. + + kj::UnwindDetector unwindDetector; +}; + +void readMessageCopy(kj::InputStream& input, MessageBuilder& target, + ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr); +// Convenience function which reads a message using `InputStreamMessageReader` then copies the +// content into the target `MessageBuilder`, verifying that the message structure is valid +// (although not necessarily that it matches the desired schema). +// +// (Note that it's also possible to initialize a `MessageBuilder` directly without a copy using one +// of `MessageBuilder`'s constructors. However, this approach skips the validation step and is not +// safe to use on untrusted input. Therefore, we do not provide a convenience method for it.) + +void writeMessage(kj::OutputStream& output, MessageBuilder& builder); +// Write the message to the given output stream. + +void writeMessage(kj::OutputStream& output, kj::ArrayPtr> segments); +// Write the segment array to the given output stream. + +// ======================================================================================= +// Specializations for reading from / writing to file descriptors. + +class StreamFdMessageReader: private kj::FdInputStream, public InputStreamMessageReader { + // A MessageReader that reads from a steam-based file descriptor. + +public: + StreamFdMessageReader(int fd, ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr) + : FdInputStream(fd), InputStreamMessageReader(*this, options, scratchSpace) {} + // Read message from a file descriptor, without taking ownership of the descriptor. + + StreamFdMessageReader(kj::AutoCloseFd fd, ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr) + : FdInputStream(kj::mv(fd)), InputStreamMessageReader(*this, options, scratchSpace) {} + // Read a message from a file descriptor, taking ownership of the descriptor. + + ~StreamFdMessageReader() noexcept(false); +}; + +void readMessageCopyFromFd(int fd, MessageBuilder& target, + ReaderOptions options = ReaderOptions(), + kj::ArrayPtr scratchSpace = nullptr); +// Convenience function which reads a message using `StreamFdMessageReader` then copies the +// content into the target `MessageBuilder`, verifying that the message structure is valid +// (although not necessarily that it matches the desired schema). +// +// (Note that it's also possible to initialize a `MessageBuilder` directly without a copy using one +// of `MessageBuilder`'s constructors. However, this approach skips the validation step and is not +// safe to use on untrusted input. Therefore, we do not provide a convenience method for it.) + +void writeMessageToFd(int fd, MessageBuilder& builder); +// Write the message to the given file descriptor. +// +// This function throws an exception on any I/O error. If your code is not exception-safe, be sure +// you catch this exception at the call site. If throwing an exception is not acceptable, you +// can implement your own OutputStream with arbitrary error handling and then use writeMessage(). + +void writeMessageToFd(int fd, kj::ArrayPtr> segments); +// Write the segment array to the given file descriptor. +// +// This function throws an exception on any I/O error. If your code is not exception-safe, be sure +// you catch this exception at the call site. If throwing an exception is not acceptable, you +// can implement your own OutputStream with arbitrary error handling and then use writeMessage(). + +// ======================================================================================= +// inline stuff + +inline kj::Array messageToFlatArray(MessageBuilder& builder) { + return messageToFlatArray(builder.getSegmentsForOutput()); +} + +inline size_t computeSerializedSizeInWords(MessageBuilder& builder) { + return computeSerializedSizeInWords(builder.getSegmentsForOutput()); +} + +inline void writeMessage(kj::OutputStream& output, MessageBuilder& builder) { + writeMessage(output, builder.getSegmentsForOutput()); +} + +inline void writeMessageToFd(int fd, MessageBuilder& builder) { + writeMessageToFd(fd, builder.getSegmentsForOutput()); +} + +} // namespace capnp + +#endif // SERIALIZE_H_ diff --git a/phonelibs/capnp-cpp/include/kj/arena.h b/phonelibs/capnp-cpp/include/kj/arena.h new file mode 100644 index 00000000000000..32c1f61c51626f --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/arena.h @@ -0,0 +1,213 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_ARENA_H_ +#define KJ_ARENA_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "memory.h" +#include "array.h" +#include "string.h" + +namespace kj { + +class Arena { + // A class which allows several objects to be allocated in contiguous chunks of memory, then + // frees them all at once. + // + // Allocating from the same Arena in multiple threads concurrently is NOT safe, because making + // it safe would require atomic operations that would slow down allocation even when + // single-threaded. If you need to use arena allocation in a multithreaded context, consider + // allocating thread-local arenas. + +public: + explicit Arena(size_t chunkSizeHint = 1024); + // Create an Arena. `chunkSizeHint` hints at where to start when allocating chunks, but is only + // a hint -- the Arena will, for example, allocate progressively larger chunks as time goes on, + // in order to reduce overall allocation overhead. + + explicit Arena(ArrayPtr scratch); + // Allocates from the given scratch space first, only resorting to the heap when it runs out. + + KJ_DISALLOW_COPY(Arena); + ~Arena() noexcept(false); + + template + T& allocate(Params&&... params); + template + ArrayPtr allocateArray(size_t size); + // Allocate an object or array of type T. If T has a non-trivial destructor, that destructor + // will be run during the Arena's destructor. Such destructors are run in opposite order of + // allocation. Note that these methods must maintain a list of destructors to call, which has + // overhead, but this overhead only applies if T has a non-trivial destructor. + + template + Own allocateOwn(Params&&... params); + template + Array allocateOwnArray(size_t size); + template + ArrayBuilder allocateOwnArrayBuilder(size_t capacity); + // Allocate an object or array of type T. Destructors are executed when the returned Own + // or Array goes out-of-scope, which must happen before the Arena is destroyed. This variant + // is useful when you need to control when the destructor is called. This variant also avoids + // the need for the Arena itself to keep track of destructors to call later, which may make it + // slightly more efficient. + + template + inline T& copy(T&& value) { return allocate>(kj::fwd(value)); } + // Allocate a copy of the given value in the arena. This is just a shortcut for calling the + // type's copy (or move) constructor. + + StringPtr copyString(StringPtr content); + // Make a copy of the given string inside the arena, and return a pointer to the copy. + +private: + struct ChunkHeader { + ChunkHeader* next; + byte* pos; // first unallocated byte in this chunk + byte* end; // end of this chunk + }; + struct ObjectHeader { + void (*destructor)(void*); + ObjectHeader* next; + }; + + size_t nextChunkSize; + ChunkHeader* chunkList = nullptr; + ObjectHeader* objectList = nullptr; + + ChunkHeader* currentChunk = nullptr; + + void cleanup(); + // Run all destructors, leaving the above pointers null. If a destructor throws, the State is + // left in a consistent state, such that if cleanup() is called again, it will pick up where + // it left off. + + void* allocateBytes(size_t amount, uint alignment, bool hasDisposer); + // Allocate the given number of bytes. `hasDisposer` must be true if `setDisposer()` may be + // called on this pointer later. + + void* allocateBytesInternal(size_t amount, uint alignment); + // Try to allocate the given number of bytes without taking a lock. Fails if and only if there + // is no space left in the current chunk. + + void setDestructor(void* ptr, void (*destructor)(void*)); + // Schedule the given destructor to be executed when the Arena is destroyed. `ptr` must be a + // pointer previously returned by an `allocateBytes()` call for which `hasDisposer` was true. + + template + static void destroyArray(void* pointer) { + size_t elementCount = *reinterpret_cast(pointer); + constexpr size_t prefixSize = kj::max(alignof(T), sizeof(size_t)); + DestructorOnlyArrayDisposer::instance.disposeImpl( + reinterpret_cast(pointer) + prefixSize, + sizeof(T), elementCount, elementCount, &destroyObject); + } + + template + static void destroyObject(void* pointer) { + dtor(*reinterpret_cast(pointer)); + } +}; + +// ======================================================================================= +// Inline implementation details + +template +T& Arena::allocate(Params&&... params) { + T& result = *reinterpret_cast(allocateBytes( + sizeof(T), alignof(T), !__has_trivial_destructor(T))); + if (!__has_trivial_constructor(T) || sizeof...(Params) > 0) { + ctor(result, kj::fwd(params)...); + } + if (!__has_trivial_destructor(T)) { + setDestructor(&result, &destroyObject); + } + return result; +} + +template +ArrayPtr Arena::allocateArray(size_t size) { + if (__has_trivial_destructor(T)) { + ArrayPtr result = + arrayPtr(reinterpret_cast(allocateBytes( + sizeof(T) * size, alignof(T), false)), size); + if (!__has_trivial_constructor(T)) { + for (size_t i = 0; i < size; i++) { + ctor(result[i]); + } + } + return result; + } else { + // Allocate with a 64-bit prefix in which we store the array size. + constexpr size_t prefixSize = kj::max(alignof(T), sizeof(size_t)); + void* base = allocateBytes(sizeof(T) * size + prefixSize, alignof(T), true); + size_t& tag = *reinterpret_cast(base); + ArrayPtr result = + arrayPtr(reinterpret_cast(reinterpret_cast(base) + prefixSize), size); + setDestructor(base, &destroyArray); + + if (__has_trivial_constructor(T)) { + tag = size; + } else { + // In case of constructor exceptions, we need the tag to end up storing the number of objects + // that were successfully constructed, so that they'll be properly destroyed. + tag = 0; + for (size_t i = 0; i < size; i++) { + ctor(result[i]); + tag = i + 1; + } + } + return result; + } +} + +template +Own Arena::allocateOwn(Params&&... params) { + T& result = *reinterpret_cast(allocateBytes(sizeof(T), alignof(T), false)); + if (!__has_trivial_constructor(T) || sizeof...(Params) > 0) { + ctor(result, kj::fwd(params)...); + } + return Own(&result, DestructorOnlyDisposer::instance); +} + +template +Array Arena::allocateOwnArray(size_t size) { + ArrayBuilder result = allocateOwnArrayBuilder(size); + for (size_t i = 0; i < size; i++) { + result.add(); + } + return result.finish(); +} + +template +ArrayBuilder Arena::allocateOwnArrayBuilder(size_t capacity) { + return ArrayBuilder( + reinterpret_cast(allocateBytes(sizeof(T) * capacity, alignof(T), false)), + capacity, DestructorOnlyArrayDisposer::instance); +} + +} // namespace kj + +#endif // KJ_ARENA_H_ diff --git a/phonelibs/capnp-cpp/include/kj/array.h b/phonelibs/capnp-cpp/include/kj/array.h new file mode 100644 index 00000000000000..51b5dcf31949ab --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/array.h @@ -0,0 +1,813 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_ARRAY_H_ +#define KJ_ARRAY_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "common.h" +#include +#include + +namespace kj { + +// ======================================================================================= +// ArrayDisposer -- Implementation details. + +class ArrayDisposer { + // Much like Disposer from memory.h. + +protected: + // Do not declare a destructor, as doing so will force a global initializer for + // HeapArrayDisposer::instance. + + virtual void disposeImpl(void* firstElement, size_t elementSize, size_t elementCount, + size_t capacity, void (*destroyElement)(void*)) const = 0; + // Disposes of the array. `destroyElement` invokes the destructor of each element, or is nullptr + // if the elements have trivial destructors. `capacity` is the amount of space that was + // allocated while `elementCount` is the number of elements that were actually constructed; + // these are always the same number for Array but may be different when using ArrayBuilder. + +public: + + template + void dispose(T* firstElement, size_t elementCount, size_t capacity) const; + // Helper wrapper around disposeImpl(). + // + // Callers must not call dispose() on the same array twice, even if the first call throws + // an exception. + +private: + template + struct Dispose_; +}; + +class ExceptionSafeArrayUtil { + // Utility class that assists in constructing or destroying elements of an array, where the + // constructor or destructor could throw exceptions. In case of an exception, + // ExceptionSafeArrayUtil's destructor will call destructors on all elements that have been + // constructed but not destroyed. Remember that destructors that throw exceptions are required + // to use UnwindDetector to detect unwind and avoid exceptions in this case. Therefore, no more + // than one exception will be thrown (and the program will not terminate). + +public: + inline ExceptionSafeArrayUtil(void* ptr, size_t elementSize, size_t constructedElementCount, + void (*destroyElement)(void*)) + : pos(reinterpret_cast(ptr) + elementSize * constructedElementCount), + elementSize(elementSize), constructedElementCount(constructedElementCount), + destroyElement(destroyElement) {} + KJ_DISALLOW_COPY(ExceptionSafeArrayUtil); + + inline ~ExceptionSafeArrayUtil() noexcept(false) { + if (constructedElementCount > 0) destroyAll(); + } + + void construct(size_t count, void (*constructElement)(void*)); + // Construct the given number of elements. + + void destroyAll(); + // Destroy all elements. Call this immediately before ExceptionSafeArrayUtil goes out-of-scope + // to ensure that one element throwing an exception does not prevent the others from being + // destroyed. + + void release() { constructedElementCount = 0; } + // Prevent ExceptionSafeArrayUtil's destructor from destroying the constructed elements. + // Call this after you've successfully finished constructing. + +private: + byte* pos; + size_t elementSize; + size_t constructedElementCount; + void (*destroyElement)(void*); +}; + +class DestructorOnlyArrayDisposer: public ArrayDisposer { +public: + static const DestructorOnlyArrayDisposer instance; + + void disposeImpl(void* firstElement, size_t elementSize, size_t elementCount, + size_t capacity, void (*destroyElement)(void*)) const override; +}; + +class NullArrayDisposer: public ArrayDisposer { + // An ArrayDisposer that does nothing. Can be used to construct a fake Arrays that doesn't + // actually own its content. + +public: + static const NullArrayDisposer instance; + + void disposeImpl(void* firstElement, size_t elementSize, size_t elementCount, + size_t capacity, void (*destroyElement)(void*)) const override; +}; + +// ======================================================================================= +// Array + +template +class Array { + // An owned array which will automatically be disposed of (using an ArrayDisposer) in the + // destructor. Can be moved, but not copied. Much like Own, but for arrays rather than + // single objects. + +public: + inline Array(): ptr(nullptr), size_(0), disposer(nullptr) {} + inline Array(decltype(nullptr)): ptr(nullptr), size_(0), disposer(nullptr) {} + inline Array(Array&& other) noexcept + : ptr(other.ptr), size_(other.size_), disposer(other.disposer) { + other.ptr = nullptr; + other.size_ = 0; + } + inline Array(Array>&& other) noexcept + : ptr(other.ptr), size_(other.size_), disposer(other.disposer) { + other.ptr = nullptr; + other.size_ = 0; + } + inline Array(T* firstElement, size_t size, const ArrayDisposer& disposer) + : ptr(firstElement), size_(size), disposer(&disposer) {} + + KJ_DISALLOW_COPY(Array); + inline ~Array() noexcept { dispose(); } + + inline operator ArrayPtr() { + return ArrayPtr(ptr, size_); + } + inline operator ArrayPtr() const { + return ArrayPtr(ptr, size_); + } + inline ArrayPtr asPtr() { + return ArrayPtr(ptr, size_); + } + inline ArrayPtr asPtr() const { + return ArrayPtr(ptr, size_); + } + + inline size_t size() const { return size_; } + inline T& operator[](size_t index) const { + KJ_IREQUIRE(index < size_, "Out-of-bounds Array access."); + return ptr[index]; + } + + inline const T* begin() const { return ptr; } + inline const T* end() const { return ptr + size_; } + inline const T& front() const { return *ptr; } + inline const T& back() const { return *(ptr + size_ - 1); } + inline T* begin() { return ptr; } + inline T* end() { return ptr + size_; } + inline T& front() { return *ptr; } + inline T& back() { return *(ptr + size_ - 1); } + + inline ArrayPtr slice(size_t start, size_t end) { + KJ_IREQUIRE(start <= end && end <= size_, "Out-of-bounds Array::slice()."); + return ArrayPtr(ptr + start, end - start); + } + inline ArrayPtr slice(size_t start, size_t end) const { + KJ_IREQUIRE(start <= end && end <= size_, "Out-of-bounds Array::slice()."); + return ArrayPtr(ptr + start, end - start); + } + + inline ArrayPtr asBytes() const { return asPtr().asBytes(); } + inline ArrayPtr> asBytes() { return asPtr().asBytes(); } + inline ArrayPtr asChars() const { return asPtr().asChars(); } + inline ArrayPtr> asChars() { return asPtr().asChars(); } + + inline Array> releaseAsBytes() { + // Like asBytes() but transfers ownership. + static_assert(sizeof(T) == sizeof(byte), + "releaseAsBytes() only possible on arrays with byte-size elements (e.g. chars)."); + Array> result( + reinterpret_cast*>(ptr), size_, *disposer); + ptr = nullptr; + size_ = 0; + return result; + } + inline Array> releaseAsChars() { + // Like asChars() but transfers ownership. + static_assert(sizeof(T) == sizeof(PropagateConst), + "releaseAsChars() only possible on arrays with char-size elements (e.g. bytes)."); + Array> result( + reinterpret_cast*>(ptr), size_, *disposer); + ptr = nullptr; + size_ = 0; + return result; + } + + inline bool operator==(decltype(nullptr)) const { return size_ == 0; } + inline bool operator!=(decltype(nullptr)) const { return size_ != 0; } + + inline Array& operator=(decltype(nullptr)) { + dispose(); + return *this; + } + + inline Array& operator=(Array&& other) { + dispose(); + ptr = other.ptr; + size_ = other.size_; + disposer = other.disposer; + other.ptr = nullptr; + other.size_ = 0; + return *this; + } + +private: + T* ptr; + size_t size_; + const ArrayDisposer* disposer; + + inline void dispose() { + // Make sure that if an exception is thrown, we are left with a null ptr, so we won't possibly + // dispose again. + T* ptrCopy = ptr; + size_t sizeCopy = size_; + if (ptrCopy != nullptr) { + ptr = nullptr; + size_ = 0; + disposer->dispose(ptrCopy, sizeCopy, sizeCopy); + } + } + + template + friend class Array; +}; + +static_assert(!canMemcpy>(), "canMemcpy<>() is broken"); + +namespace _ { // private + +class HeapArrayDisposer final: public ArrayDisposer { +public: + template + static T* allocate(size_t count); + template + static T* allocateUninitialized(size_t count); + + static const HeapArrayDisposer instance; + +private: + static void* allocateImpl(size_t elementSize, size_t elementCount, size_t capacity, + void (*constructElement)(void*), void (*destroyElement)(void*)); + // Allocates and constructs the array. Both function pointers are null if the constructor is + // trivial, otherwise destroyElement is null if the constructor doesn't throw. + + virtual void disposeImpl(void* firstElement, size_t elementSize, size_t elementCount, + size_t capacity, void (*destroyElement)(void*)) const override; + + template + struct Allocate_; +}; + +} // namespace _ (private) + +template +inline Array heapArray(size_t size) { + // Much like `heap()` from memory.h, allocates a new array on the heap. + + return Array(_::HeapArrayDisposer::allocate(size), size, + _::HeapArrayDisposer::instance); +} + +template Array heapArray(const T* content, size_t size); +template Array heapArray(ArrayPtr content); +template Array heapArray(ArrayPtr content); +template Array heapArray(Iterator begin, Iterator end); +template Array heapArray(std::initializer_list init); +// Allocate a heap array containing a copy of the given content. + +template +Array heapArrayFromIterable(Container&& a) { return heapArray(a.begin(), a.end()); } +template +Array heapArrayFromIterable(Array&& a) { return mv(a); } + +// ======================================================================================= +// ArrayBuilder + +template +class ArrayBuilder { + // Class which lets you build an Array specifying the exact constructor arguments for each + // element, rather than starting by default-constructing them. + +public: + ArrayBuilder(): ptr(nullptr), pos(nullptr), endPtr(nullptr) {} + ArrayBuilder(decltype(nullptr)): ptr(nullptr), pos(nullptr), endPtr(nullptr) {} + explicit ArrayBuilder(RemoveConst* firstElement, size_t capacity, + const ArrayDisposer& disposer) + : ptr(firstElement), pos(firstElement), endPtr(firstElement + capacity), + disposer(&disposer) {} + ArrayBuilder(ArrayBuilder&& other) + : ptr(other.ptr), pos(other.pos), endPtr(other.endPtr), disposer(other.disposer) { + other.ptr = nullptr; + other.pos = nullptr; + other.endPtr = nullptr; + } + KJ_DISALLOW_COPY(ArrayBuilder); + inline ~ArrayBuilder() noexcept(false) { dispose(); } + + inline operator ArrayPtr() { + return arrayPtr(ptr, pos); + } + inline operator ArrayPtr() const { + return arrayPtr(ptr, pos); + } + inline ArrayPtr asPtr() { + return arrayPtr(ptr, pos); + } + inline ArrayPtr asPtr() const { + return arrayPtr(ptr, pos); + } + + inline size_t size() const { return pos - ptr; } + inline size_t capacity() const { return endPtr - ptr; } + inline T& operator[](size_t index) const { + KJ_IREQUIRE(index < implicitCast(pos - ptr), "Out-of-bounds Array access."); + return ptr[index]; + } + + inline const T* begin() const { return ptr; } + inline const T* end() const { return pos; } + inline const T& front() const { return *ptr; } + inline const T& back() const { return *(pos - 1); } + inline T* begin() { return ptr; } + inline T* end() { return pos; } + inline T& front() { return *ptr; } + inline T& back() { return *(pos - 1); } + + ArrayBuilder& operator=(ArrayBuilder&& other) { + dispose(); + ptr = other.ptr; + pos = other.pos; + endPtr = other.endPtr; + disposer = other.disposer; + other.ptr = nullptr; + other.pos = nullptr; + other.endPtr = nullptr; + return *this; + } + ArrayBuilder& operator=(decltype(nullptr)) { + dispose(); + return *this; + } + + template + T& add(Params&&... params) { + KJ_IREQUIRE(pos < endPtr, "Added too many elements to ArrayBuilder."); + ctor(*pos, kj::fwd(params)...); + return *pos++; + } + + template + void addAll(Container&& container) { + addAll()>( + container.begin(), container.end()); + } + + template + void addAll(Iterator start, Iterator end); + + void removeLast() { + KJ_IREQUIRE(pos > ptr, "No elements present to remove."); + kj::dtor(*--pos); + } + + void truncate(size_t size) { + KJ_IREQUIRE(size <= this->size(), "can't use truncate() to expand"); + + T* target = ptr + size; + if (__has_trivial_destructor(T)) { + pos = target; + } else { + while (pos > target) { + kj::dtor(*--pos); + } + } + } + + void resize(size_t size) { + KJ_IREQUIRE(size <= capacity(), "can't resize past capacity"); + + T* target = ptr + size; + if (target > pos) { + // expand + if (__has_trivial_constructor(T)) { + pos = target; + } else { + while (pos < target) { + kj::ctor(*pos++); + } + } + } else { + // truncate + if (__has_trivial_destructor(T)) { + pos = target; + } else { + while (pos > target) { + kj::dtor(*--pos); + } + } + } + } + + Array finish() { + // We could safely remove this check if we assume that the disposer implementation doesn't + // need to know the original capacity, as is thes case with HeapArrayDisposer since it uses + // operator new() or if we created a custom disposer for ArrayBuilder which stores the capacity + // in a prefix. But that would make it hard to write cleverer heap allocators, and anyway this + // check might catch bugs. Probably people should use Vector if they want to build arrays + // without knowing the final size in advance. + KJ_IREQUIRE(pos == endPtr, "ArrayBuilder::finish() called prematurely."); + Array result(reinterpret_cast(ptr), pos - ptr, *disposer); + ptr = nullptr; + pos = nullptr; + endPtr = nullptr; + return result; + } + + inline bool isFull() const { + return pos == endPtr; + } + +private: + T* ptr; + RemoveConst* pos; + T* endPtr; + const ArrayDisposer* disposer; + + inline void dispose() { + // Make sure that if an exception is thrown, we are left with a null ptr, so we won't possibly + // dispose again. + T* ptrCopy = ptr; + T* posCopy = pos; + T* endCopy = endPtr; + if (ptrCopy != nullptr) { + ptr = nullptr; + pos = nullptr; + endPtr = nullptr; + disposer->dispose(ptrCopy, posCopy - ptrCopy, endCopy - ptrCopy); + } + } +}; + +template +inline ArrayBuilder heapArrayBuilder(size_t size) { + // Like `heapArray()` but does not default-construct the elements. You must construct them + // manually by calling `add()`. + + return ArrayBuilder(_::HeapArrayDisposer::allocateUninitialized>(size), + size, _::HeapArrayDisposer::instance); +} + +// ======================================================================================= +// Inline Arrays + +template +class FixedArray { + // A fixed-width array whose storage is allocated inline rather than on the heap. + +public: + inline size_t size() const { return fixedSize; } + inline T* begin() { return content; } + inline T* end() { return content + fixedSize; } + inline const T* begin() const { return content; } + inline const T* end() const { return content + fixedSize; } + + inline operator ArrayPtr() { + return arrayPtr(content, fixedSize); + } + inline operator ArrayPtr() const { + return arrayPtr(content, fixedSize); + } + + inline T& operator[](size_t index) { return content[index]; } + inline const T& operator[](size_t index) const { return content[index]; } + +private: + T content[fixedSize]; +}; + +template +class CappedArray { + // Like `FixedArray` but can be dynamically resized as long as the size does not exceed the limit + // specified by the template parameter. + // + // TODO(someday): Don't construct elements past currentSize? + +public: + inline KJ_CONSTEXPR() CappedArray(): currentSize(fixedSize) {} + inline explicit constexpr CappedArray(size_t s): currentSize(s) {} + + inline size_t size() const { return currentSize; } + inline void setSize(size_t s) { KJ_IREQUIRE(s <= fixedSize); currentSize = s; } + inline T* begin() { return content; } + inline T* end() { return content + currentSize; } + inline const T* begin() const { return content; } + inline const T* end() const { return content + currentSize; } + + inline operator ArrayPtr() { + return arrayPtr(content, currentSize); + } + inline operator ArrayPtr() const { + return arrayPtr(content, currentSize); + } + + inline T& operator[](size_t index) { return content[index]; } + inline const T& operator[](size_t index) const { return content[index]; } + +private: + size_t currentSize; + T content[fixedSize]; +}; + +// ======================================================================================= +// KJ_MAP + +#define KJ_MAP(elementName, array) \ + ::kj::_::Mapper(array) * \ + [&](typename ::kj::_::Mapper::Element elementName) +// Applies some function to every element of an array, returning an Array of the results, with +// nice syntax. Example: +// +// StringPtr foo = "abcd"; +// Array bar = KJ_MAP(c, foo) -> char { return c + 1; }; +// KJ_ASSERT(str(bar) == "bcde"); + +namespace _ { // private + +template +struct Mapper { + T array; + Mapper(T&& array): array(kj::fwd(array)) {} + template + auto operator*(Func&& func) -> Array { + auto builder = heapArrayBuilder(array.size()); + for (auto iter = array.begin(); iter != array.end(); ++iter) { + builder.add(func(*iter)); + } + return builder.finish(); + } + typedef decltype(*kj::instance().begin()) Element; +}; + +template +struct Mapper { + T* array; + Mapper(T* array): array(array) {} + template + auto operator*(Func&& func) -> Array { + auto builder = heapArrayBuilder(s); + for (size_t i = 0; i < s; i++) { + builder.add(func(array[i])); + } + return builder.finish(); + } + typedef decltype(*array)& Element; +}; + +} // namespace _ (private) + +// ======================================================================================= +// Inline implementation details + +template +struct ArrayDisposer::Dispose_ { + static void dispose(T* firstElement, size_t elementCount, size_t capacity, + const ArrayDisposer& disposer) { + disposer.disposeImpl(const_cast*>(firstElement), + sizeof(T), elementCount, capacity, nullptr); + } +}; +template +struct ArrayDisposer::Dispose_ { + static void destruct(void* ptr) { + kj::dtor(*reinterpret_cast(ptr)); + } + + static void dispose(T* firstElement, size_t elementCount, size_t capacity, + const ArrayDisposer& disposer) { + disposer.disposeImpl(firstElement, sizeof(T), elementCount, capacity, &destruct); + } +}; + +template +void ArrayDisposer::dispose(T* firstElement, size_t elementCount, size_t capacity) const { + Dispose_::dispose(firstElement, elementCount, capacity, *this); +} + +namespace _ { // private + +template +struct HeapArrayDisposer::Allocate_ { + static T* allocate(size_t elementCount, size_t capacity) { + return reinterpret_cast(allocateImpl( + sizeof(T), elementCount, capacity, nullptr, nullptr)); + } +}; +template +struct HeapArrayDisposer::Allocate_ { + static void construct(void* ptr) { + kj::ctor(*reinterpret_cast(ptr)); + } + static T* allocate(size_t elementCount, size_t capacity) { + return reinterpret_cast(allocateImpl( + sizeof(T), elementCount, capacity, &construct, nullptr)); + } +}; +template +struct HeapArrayDisposer::Allocate_ { + static void construct(void* ptr) { + kj::ctor(*reinterpret_cast(ptr)); + } + static void destruct(void* ptr) { + kj::dtor(*reinterpret_cast(ptr)); + } + static T* allocate(size_t elementCount, size_t capacity) { + return reinterpret_cast(allocateImpl( + sizeof(T), elementCount, capacity, &construct, &destruct)); + } +}; + +template +T* HeapArrayDisposer::allocate(size_t count) { + return Allocate_::allocate(count, count); +} + +template +T* HeapArrayDisposer::allocateUninitialized(size_t count) { + return Allocate_::allocate(0, count); +} + +template ()> +struct CopyConstructArray_; + +template +struct CopyConstructArray_ { + static inline T* apply(T* __restrict__ pos, T* start, T* end) { + memcpy(pos, start, reinterpret_cast(end) - reinterpret_cast(start)); + return pos + (end - start); + } +}; + +template +struct CopyConstructArray_ { + static inline T* apply(T* __restrict__ pos, const T* start, const T* end) { + memcpy(pos, start, reinterpret_cast(end) - reinterpret_cast(start)); + return pos + (end - start); + } +}; + +template +struct CopyConstructArray_ { + static inline T* apply(T* __restrict__ pos, Iterator start, Iterator end) { + // Since both the copy constructor and assignment operator are trivial, we know that assignment + // is equivalent to copy-constructing. So we can make this case somewhat easier for the + // compiler to optimize. + while (start != end) { + *pos++ = *start++; + } + return pos; + } +}; + +template +struct CopyConstructArray_ { + struct ExceptionGuard { + T* start; + T* pos; + inline explicit ExceptionGuard(T* pos): start(pos), pos(pos) {} + ~ExceptionGuard() noexcept(false) { + while (pos > start) { + dtor(*--pos); + } + } + }; + + static T* apply(T* __restrict__ pos, Iterator start, Iterator end) { + // Verify that T can be *implicitly* constructed from the source values. + if (false) implicitCast(*start); + + if (noexcept(T(*start))) { + while (start != end) { + ctor(*pos++, *start++); + } + return pos; + } else { + // Crap. This is complicated. + ExceptionGuard guard(pos); + while (start != end) { + ctor(*guard.pos, *start++); + ++guard.pos; + } + guard.start = guard.pos; + return guard.pos; + } + } +}; + +template +struct CopyConstructArray_ { + // Actually move-construct. + + struct ExceptionGuard { + T* start; + T* pos; + inline explicit ExceptionGuard(T* pos): start(pos), pos(pos) {} + ~ExceptionGuard() noexcept(false) { + while (pos > start) { + dtor(*--pos); + } + } + }; + + static T* apply(T* __restrict__ pos, Iterator start, Iterator end) { + // Verify that T can be *implicitly* constructed from the source values. + if (false) implicitCast(kj::mv(*start)); + + if (noexcept(T(kj::mv(*start)))) { + while (start != end) { + ctor(*pos++, kj::mv(*start++)); + } + return pos; + } else { + // Crap. This is complicated. + ExceptionGuard guard(pos); + while (start != end) { + ctor(*guard.pos, kj::mv(*start++)); + ++guard.pos; + } + guard.start = guard.pos; + return guard.pos; + } + } +}; + +} // namespace _ (private) + +template +template +void ArrayBuilder::addAll(Iterator start, Iterator end) { + pos = _::CopyConstructArray_, Decay, move>::apply(pos, start, end); +} + +template +Array heapArray(const T* content, size_t size) { + ArrayBuilder builder = heapArrayBuilder(size); + builder.addAll(content, content + size); + return builder.finish(); +} + +template +Array heapArray(T* content, size_t size) { + ArrayBuilder builder = heapArrayBuilder(size); + builder.addAll(content, content + size); + return builder.finish(); +} + +template +Array heapArray(ArrayPtr content) { + ArrayBuilder builder = heapArrayBuilder(content.size()); + builder.addAll(content); + return builder.finish(); +} + +template +Array heapArray(ArrayPtr content) { + ArrayBuilder builder = heapArrayBuilder(content.size()); + builder.addAll(content); + return builder.finish(); +} + +template Array +heapArray(Iterator begin, Iterator end) { + ArrayBuilder builder = heapArrayBuilder(end - begin); + builder.addAll(begin, end); + return builder.finish(); +} + +template +inline Array heapArray(std::initializer_list init) { + return heapArray(init.begin(), init.end()); +} + +} // namespace kj + +#endif // KJ_ARRAY_H_ diff --git a/phonelibs/capnp-cpp/include/kj/async-inl.h b/phonelibs/capnp-cpp/include/kj/async-inl.h new file mode 100644 index 00000000000000..f11e4fcd5b9f74 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/async-inl.h @@ -0,0 +1,1112 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file contains extended inline implementation details that are required along with async.h. +// We move this all into a separate file to make async.h more readable. +// +// Non-inline declarations here are defined in async.c++. + +#ifndef KJ_ASYNC_H_ +#error "Do not include this directly; include kj/async.h." +#include "async.h" // help IDE parse this file +#endif + +#ifndef KJ_ASYNC_INL_H_ +#define KJ_ASYNC_INL_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +namespace kj { +namespace _ { // private + +template +class ExceptionOr; + +class ExceptionOrValue { +public: + ExceptionOrValue(bool, Exception&& exception): exception(kj::mv(exception)) {} + KJ_DISALLOW_COPY(ExceptionOrValue); + + void addException(Exception&& exception) { + if (this->exception == nullptr) { + this->exception = kj::mv(exception); + } + } + + template + ExceptionOr& as() { return *static_cast*>(this); } + template + const ExceptionOr& as() const { return *static_cast*>(this); } + + Maybe exception; + +protected: + // Allow subclasses to have move constructor / assignment. + ExceptionOrValue() = default; + ExceptionOrValue(ExceptionOrValue&& other) = default; + ExceptionOrValue& operator=(ExceptionOrValue&& other) = default; +}; + +template +class ExceptionOr: public ExceptionOrValue { +public: + ExceptionOr() = default; + ExceptionOr(T&& value): value(kj::mv(value)) {} + ExceptionOr(bool, Exception&& exception): ExceptionOrValue(false, kj::mv(exception)) {} + ExceptionOr(ExceptionOr&&) = default; + ExceptionOr& operator=(ExceptionOr&&) = default; + + Maybe value; +}; + +class Event { + // An event waiting to be executed. Not for direct use by applications -- promises use this + // internally. + +public: + Event(); + ~Event() noexcept(false); + KJ_DISALLOW_COPY(Event); + + void armDepthFirst(); + // Enqueue this event so that `fire()` will be called from the event loop soon. + // + // Events scheduled in this way are executed in depth-first order: if an event callback arms + // more events, those events are placed at the front of the queue (in the order in which they + // were armed), so that they run immediately after the first event's callback returns. + // + // Depth-first event scheduling is appropriate for events that represent simple continuations + // of a previous event that should be globbed together for performance. Depth-first scheduling + // can lead to starvation, so any long-running task must occasionally yield with + // `armBreadthFirst()`. (Promise::then() uses depth-first whereas evalLater() uses + // breadth-first.) + // + // To use breadth-first scheduling instead, use `armBreadthFirst()`. + + void armBreadthFirst(); + // Like `armDepthFirst()` except that the event is placed at the end of the queue. + + kj::String trace(); + // Dump debug info about this event. + + virtual _::PromiseNode* getInnerForTrace(); + // If this event wraps a PromiseNode, get that node. Used for debug tracing. + // Default implementation returns nullptr. + +protected: + virtual Maybe> fire() = 0; + // Fire the event. Possibly returns a pointer to itself, which will be discarded by the + // caller. This is the only way that an event can delete itself as a result of firing, as + // doing so from within fire() will throw an exception. + +private: + friend class kj::EventLoop; + EventLoop& loop; + Event* next; + Event** prev; + bool firing = false; +}; + +class PromiseNode { + // A Promise contains a chain of PromiseNodes tracking the pending transformations. + // + // To reduce generated code bloat, PromiseNode is not a template. Instead, it makes very hacky + // use of pointers to ExceptionOrValue which actually point to ExceptionOr, but are only + // so down-cast in the few places that really need to be templated. Luckily this is all + // internal implementation details. + +public: + virtual void onReady(Event& event) noexcept = 0; + // Arms the given event when ready. + + virtual void setSelfPointer(Own* selfPtr) noexcept; + // Tells the node that `selfPtr` is the pointer that owns this node, and will continue to own + // this node until it is destroyed or setSelfPointer() is called again. ChainPromiseNode uses + // this to shorten redundant chains. The default implementation does nothing; only + // ChainPromiseNode should implement this. + + virtual void get(ExceptionOrValue& output) noexcept = 0; + // Get the result. `output` points to an ExceptionOr into which the result will be written. + // Can only be called once, and only after the node is ready. Must be called directly from the + // event loop, with no application code on the stack. + + virtual PromiseNode* getInnerForTrace(); + // If this node wraps some other PromiseNode, get the wrapped node. Used for debug tracing. + // Default implementation returns nullptr. + +protected: + class OnReadyEvent { + // Helper class for implementing onReady(). + + public: + void init(Event& newEvent); + // Returns true if arm() was already called. + + void arm(); + // Arms the event if init() has already been called and makes future calls to init() return + // true. + + private: + Event* event = nullptr; + }; +}; + +// ------------------------------------------------------------------- + +class ImmediatePromiseNodeBase: public PromiseNode { +public: + ImmediatePromiseNodeBase(); + ~ImmediatePromiseNodeBase() noexcept(false); + + void onReady(Event& event) noexcept override; +}; + +template +class ImmediatePromiseNode final: public ImmediatePromiseNodeBase { + // A promise that has already been resolved to an immediate value or exception. + +public: + ImmediatePromiseNode(ExceptionOr&& result): result(kj::mv(result)) {} + + void get(ExceptionOrValue& output) noexcept override { + output.as() = kj::mv(result); + } + +private: + ExceptionOr result; +}; + +class ImmediateBrokenPromiseNode final: public ImmediatePromiseNodeBase { +public: + ImmediateBrokenPromiseNode(Exception&& exception); + + void get(ExceptionOrValue& output) noexcept override; + +private: + Exception exception; +}; + +// ------------------------------------------------------------------- + +class AttachmentPromiseNodeBase: public PromiseNode { +public: + AttachmentPromiseNodeBase(Own&& dependency); + + void onReady(Event& event) noexcept override; + void get(ExceptionOrValue& output) noexcept override; + PromiseNode* getInnerForTrace() override; + +private: + Own dependency; + + void dropDependency(); + + template + friend class AttachmentPromiseNode; +}; + +template +class AttachmentPromiseNode final: public AttachmentPromiseNodeBase { + // A PromiseNode that holds on to some object (usually, an Own, but could be any movable + // object) until the promise resolves. + +public: + AttachmentPromiseNode(Own&& dependency, Attachment&& attachment) + : AttachmentPromiseNodeBase(kj::mv(dependency)), + attachment(kj::mv(attachment)) {} + + ~AttachmentPromiseNode() noexcept(false) { + // We need to make sure the dependency is deleted before we delete the attachment because the + // dependency may be using the attachment. + dropDependency(); + } + +private: + Attachment attachment; +}; + +// ------------------------------------------------------------------- + +class PtmfHelper { + // This class is a private helper for GetFunctorStartAddress. The class represents the internal + // representation of a pointer-to-member-function. + + template + friend struct GetFunctorStartAddress; + +#if __GNUG__ + + void* ptr; + ptrdiff_t adj; + // Layout of a pointer-to-member-function used by GCC and compatible compilers. + + void* apply(void* obj) { +#if defined(__arm__) || defined(__mips__) || defined(__aarch64__) + if (adj & 1) { + ptrdiff_t voff = (ptrdiff_t)ptr; +#else + ptrdiff_t voff = (ptrdiff_t)ptr; + if (voff & 1) { + voff &= ~1; +#endif + return *(void**)(*(char**)obj + voff); + } else { + return ptr; + } + } + +#define BODY \ + PtmfHelper result; \ + static_assert(sizeof(p) == sizeof(result), "unknown ptmf layout"); \ + memcpy(&result, &p, sizeof(result)); \ + return result + +#else // __GNUG__ + + void* apply(void* obj) { return nullptr; } + // TODO(port): PTMF instruction address extraction + +#define BODY return PtmfHelper{} + +#endif // __GNUG__, else + + template + static PtmfHelper from(F p) { BODY; } + // Create a PtmfHelper from some arbitrary pointer-to-member-function which is not + // overloaded nor a template. In this case the compiler is able to deduce the full function + // signature directly given the name since there is only one function with that name. + + template + static PtmfHelper from(R (C::*p)(NoInfer

...)) { BODY; } + template + static PtmfHelper from(R (C::*p)(NoInfer

...) const) { BODY; } + // Create a PtmfHelper from some poniter-to-member-function which is a template. In this case + // the function must match exactly the containing type C, return type R, and parameter types P... + // GetFunctorStartAddress normally specifies exactly the correct C and R, but can only make a + // guess at P. Luckily, if the function parameters are template parameters then it's not + // necessary to be precise about P. +#undef BODY +}; + +template +struct GetFunctorStartAddress { + // Given a functor (any object defining operator()), return the start address of the function, + // suitable for passing to addr2line to obtain a source file/line for debugging purposes. + // + // This turns out to be incredibly hard to implement in the presence of overloaded or templated + // functors. Therefore, we impose these specific restrictions, specific to our use case: + // - Overloading is not allowed, but templating is. (Generally we only intend to support lambdas + // anyway.) + // - The template parameters to GetFunctorStartAddress specify a hint as to the expected + // parameter types. If the functor is templated, its parameters must match exactly these types. + // (If it's not templated, ParamTypes are ignored.) + + template + static void* apply(Func&& func) { + typedef decltype(func(instance()...)) ReturnType; + return PtmfHelper::from, ParamTypes...>( + &Decay::operator()).apply(&func); + } +}; + +template <> +struct GetFunctorStartAddress: public GetFunctorStartAddress<> {}; +// Hack for TransformPromiseNode use case: an input type of `Void` indicates that the function +// actually has no parameters. + +class TransformPromiseNodeBase: public PromiseNode { +public: + TransformPromiseNodeBase(Own&& dependency, void* continuationTracePtr); + + void onReady(Event& event) noexcept override; + void get(ExceptionOrValue& output) noexcept override; + PromiseNode* getInnerForTrace() override; + +private: + Own dependency; + void* continuationTracePtr; + + void dropDependency(); + void getDepResult(ExceptionOrValue& output); + + virtual void getImpl(ExceptionOrValue& output) = 0; + + template + friend class TransformPromiseNode; +}; + +template +class TransformPromiseNode final: public TransformPromiseNodeBase { + // A PromiseNode that transforms the result of another PromiseNode through an application-provided + // function (implements `then()`). + +public: + TransformPromiseNode(Own&& dependency, Func&& func, ErrorFunc&& errorHandler) + : TransformPromiseNodeBase(kj::mv(dependency), + GetFunctorStartAddress::apply(func)), + func(kj::fwd(func)), errorHandler(kj::fwd(errorHandler)) {} + + ~TransformPromiseNode() noexcept(false) { + // We need to make sure the dependency is deleted before we delete the continuations because it + // is a common pattern for the continuations to hold ownership of objects that might be in-use + // by the dependency. + dropDependency(); + } + +private: + Func func; + ErrorFunc errorHandler; + + void getImpl(ExceptionOrValue& output) override { + ExceptionOr depResult; + getDepResult(depResult); + KJ_IF_MAYBE(depException, depResult.exception) { + output.as() = handle( + MaybeVoidCaller>>::apply( + errorHandler, kj::mv(*depException))); + } else KJ_IF_MAYBE(depValue, depResult.value) { + output.as() = handle(MaybeVoidCaller::apply(func, kj::mv(*depValue))); + } + } + + ExceptionOr handle(T&& value) { + return kj::mv(value); + } + ExceptionOr handle(PropagateException::Bottom&& value) { + return ExceptionOr(false, value.asException()); + } +}; + +// ------------------------------------------------------------------- + +class ForkHubBase; + +class ForkBranchBase: public PromiseNode { +public: + ForkBranchBase(Own&& hub); + ~ForkBranchBase() noexcept(false); + + void hubReady() noexcept; + // Called by the hub to indicate that it is ready. + + // implements PromiseNode ------------------------------------------ + void onReady(Event& event) noexcept override; + PromiseNode* getInnerForTrace() override; + +protected: + inline ExceptionOrValue& getHubResultRef(); + + void releaseHub(ExceptionOrValue& output); + // Release the hub. If an exception is thrown, add it to `output`. + +private: + OnReadyEvent onReadyEvent; + + Own hub; + ForkBranchBase* next = nullptr; + ForkBranchBase** prevPtr = nullptr; + + friend class ForkHubBase; +}; + +template T copyOrAddRef(T& t) { return t; } +template Own copyOrAddRef(Own& t) { return t->addRef(); } + +template +class ForkBranch final: public ForkBranchBase { + // A PromiseNode that implements one branch of a fork -- i.e. one of the branches that receives + // a const reference. + +public: + ForkBranch(Own&& hub): ForkBranchBase(kj::mv(hub)) {} + + void get(ExceptionOrValue& output) noexcept override { + ExceptionOr& hubResult = getHubResultRef().template as(); + KJ_IF_MAYBE(value, hubResult.value) { + output.as().value = copyOrAddRef(*value); + } else { + output.as().value = nullptr; + } + output.exception = hubResult.exception; + releaseHub(output); + } +}; + +template +class SplitBranch final: public ForkBranchBase { + // A PromiseNode that implements one branch of a fork -- i.e. one of the branches that receives + // a const reference. + +public: + SplitBranch(Own&& hub): ForkBranchBase(kj::mv(hub)) {} + + typedef kj::Decay(kj::instance()))> Element; + + void get(ExceptionOrValue& output) noexcept override { + ExceptionOr& hubResult = getHubResultRef().template as(); + KJ_IF_MAYBE(value, hubResult.value) { + output.as().value = kj::mv(kj::get(*value)); + } else { + output.as().value = nullptr; + } + output.exception = hubResult.exception; + releaseHub(output); + } +}; + +// ------------------------------------------------------------------- + +class ForkHubBase: public Refcounted, protected Event { +public: + ForkHubBase(Own&& inner, ExceptionOrValue& resultRef); + + inline ExceptionOrValue& getResultRef() { return resultRef; } + +private: + Own inner; + ExceptionOrValue& resultRef; + + ForkBranchBase* headBranch = nullptr; + ForkBranchBase** tailBranch = &headBranch; + // Tail becomes null once the inner promise is ready and all branches have been notified. + + Maybe> fire() override; + _::PromiseNode* getInnerForTrace() override; + + friend class ForkBranchBase; +}; + +template +class ForkHub final: public ForkHubBase { + // A PromiseNode that implements the hub of a fork. The first call to Promise::fork() replaces + // the promise's outer node with a ForkHub, and subsequent calls add branches to that hub (if + // possible). + +public: + ForkHub(Own&& inner): ForkHubBase(kj::mv(inner), result) {} + + Promise<_::UnfixVoid> addBranch() { + return Promise<_::UnfixVoid>(false, kj::heap>(addRef(*this))); + } + + _::SplitTuplePromise split() { + return splitImpl(MakeIndexes()>()); + } + +private: + ExceptionOr result; + + template + _::SplitTuplePromise splitImpl(Indexes) { + return kj::tuple(addSplit()...); + } + + template + Promise::Element>> addSplit() { + return Promise::Element>>( + false, maybeChain(kj::heap>(addRef(*this)), + implicitCast::Element*>(nullptr))); + } +}; + +inline ExceptionOrValue& ForkBranchBase::getHubResultRef() { + return hub->getResultRef(); +} + +// ------------------------------------------------------------------- + +class ChainPromiseNode final: public PromiseNode, public Event { + // Promise node which reduces Promise> to Promise. + // + // `Event` is only a public base class because otherwise we can't cast Own to + // Own. Ugh, templates and private... + +public: + explicit ChainPromiseNode(Own inner); + ~ChainPromiseNode() noexcept(false); + + void onReady(Event& event) noexcept override; + void setSelfPointer(Own* selfPtr) noexcept override; + void get(ExceptionOrValue& output) noexcept override; + PromiseNode* getInnerForTrace() override; + +private: + enum State { + STEP1, + STEP2 + }; + + State state; + + Own inner; + // In STEP1, a PromiseNode for a Promise. + // In STEP2, a PromiseNode for a T. + + Event* onReadyEvent = nullptr; + Own* selfPtr = nullptr; + + Maybe> fire() override; +}; + +template +Own maybeChain(Own&& node, Promise*) { + return heap(kj::mv(node)); +} + +template +Own&& maybeChain(Own&& node, T*) { + return kj::mv(node); +} + +// ------------------------------------------------------------------- + +class ExclusiveJoinPromiseNode final: public PromiseNode { +public: + ExclusiveJoinPromiseNode(Own left, Own right); + ~ExclusiveJoinPromiseNode() noexcept(false); + + void onReady(Event& event) noexcept override; + void get(ExceptionOrValue& output) noexcept override; + PromiseNode* getInnerForTrace() override; + +private: + class Branch: public Event { + public: + Branch(ExclusiveJoinPromiseNode& joinNode, Own dependency); + ~Branch() noexcept(false); + + bool get(ExceptionOrValue& output); + // Returns true if this is the side that finished. + + Maybe> fire() override; + _::PromiseNode* getInnerForTrace() override; + + private: + ExclusiveJoinPromiseNode& joinNode; + Own dependency; + }; + + Branch left; + Branch right; + OnReadyEvent onReadyEvent; +}; + +// ------------------------------------------------------------------- + +class ArrayJoinPromiseNodeBase: public PromiseNode { +public: + ArrayJoinPromiseNodeBase(Array> promises, + ExceptionOrValue* resultParts, size_t partSize); + ~ArrayJoinPromiseNodeBase() noexcept(false); + + void onReady(Event& event) noexcept override final; + void get(ExceptionOrValue& output) noexcept override final; + PromiseNode* getInnerForTrace() override final; + +protected: + virtual void getNoError(ExceptionOrValue& output) noexcept = 0; + // Called to compile the result only in the case where there were no errors. + +private: + uint countLeft; + OnReadyEvent onReadyEvent; + + class Branch final: public Event { + public: + Branch(ArrayJoinPromiseNodeBase& joinNode, Own dependency, + ExceptionOrValue& output); + ~Branch() noexcept(false); + + Maybe> fire() override; + _::PromiseNode* getInnerForTrace() override; + + Maybe getPart(); + // Calls dependency->get(output). If there was an exception, return it. + + private: + ArrayJoinPromiseNodeBase& joinNode; + Own dependency; + ExceptionOrValue& output; + }; + + Array branches; +}; + +template +class ArrayJoinPromiseNode final: public ArrayJoinPromiseNodeBase { +public: + ArrayJoinPromiseNode(Array> promises, + Array> resultParts) + : ArrayJoinPromiseNodeBase(kj::mv(promises), resultParts.begin(), sizeof(ExceptionOr)), + resultParts(kj::mv(resultParts)) {} + +protected: + void getNoError(ExceptionOrValue& output) noexcept override { + auto builder = heapArrayBuilder(resultParts.size()); + for (auto& part: resultParts) { + KJ_IASSERT(part.value != nullptr, + "Bug in KJ promise framework: Promise result had neither value no exception."); + builder.add(kj::mv(*_::readMaybe(part.value))); + } + output.as>() = builder.finish(); + } + +private: + Array> resultParts; +}; + +template <> +class ArrayJoinPromiseNode final: public ArrayJoinPromiseNodeBase { +public: + ArrayJoinPromiseNode(Array> promises, + Array> resultParts); + ~ArrayJoinPromiseNode(); + +protected: + void getNoError(ExceptionOrValue& output) noexcept override; + +private: + Array> resultParts; +}; + +// ------------------------------------------------------------------- + +class EagerPromiseNodeBase: public PromiseNode, protected Event { + // A PromiseNode that eagerly evaluates its dependency even if its dependent does not eagerly + // evaluate it. + +public: + EagerPromiseNodeBase(Own&& dependency, ExceptionOrValue& resultRef); + + void onReady(Event& event) noexcept override; + PromiseNode* getInnerForTrace() override; + +private: + Own dependency; + OnReadyEvent onReadyEvent; + + ExceptionOrValue& resultRef; + + Maybe> fire() override; +}; + +template +class EagerPromiseNode final: public EagerPromiseNodeBase { +public: + EagerPromiseNode(Own&& dependency) + : EagerPromiseNodeBase(kj::mv(dependency), result) {} + + void get(ExceptionOrValue& output) noexcept override { + output.as() = kj::mv(result); + } + +private: + ExceptionOr result; +}; + +template +Own spark(Own&& node) { + // Forces evaluation of the given node to begin as soon as possible, even if no one is waiting + // on it. + return heap>(kj::mv(node)); +} + +// ------------------------------------------------------------------- + +class AdapterPromiseNodeBase: public PromiseNode { +public: + void onReady(Event& event) noexcept override; + +protected: + inline void setReady() { + onReadyEvent.arm(); + } + +private: + OnReadyEvent onReadyEvent; +}; + +template +class AdapterPromiseNode final: public AdapterPromiseNodeBase, + private PromiseFulfiller> { + // A PromiseNode that wraps a PromiseAdapter. + +public: + template + AdapterPromiseNode(Params&&... params) + : adapter(static_cast>&>(*this), kj::fwd(params)...) {} + + void get(ExceptionOrValue& output) noexcept override { + KJ_IREQUIRE(!isWaiting()); + output.as() = kj::mv(result); + } + +private: + ExceptionOr result; + bool waiting = true; + Adapter adapter; + + void fulfill(T&& value) override { + if (waiting) { + waiting = false; + result = ExceptionOr(kj::mv(value)); + setReady(); + } + } + + void reject(Exception&& exception) override { + if (waiting) { + waiting = false; + result = ExceptionOr(false, kj::mv(exception)); + setReady(); + } + } + + bool isWaiting() override { + return waiting; + } +}; + +} // namespace _ (private) + +// ======================================================================================= + +template +Promise::Promise(_::FixVoid value) + : PromiseBase(heap<_::ImmediatePromiseNode<_::FixVoid>>(kj::mv(value))) {} + +template +Promise::Promise(kj::Exception&& exception) + : PromiseBase(heap<_::ImmediateBrokenPromiseNode>(kj::mv(exception))) {} + +template +template +PromiseForResult Promise::then(Func&& func, ErrorFunc&& errorHandler) { + typedef _::FixVoid<_::ReturnType> ResultT; + + Own<_::PromiseNode> intermediate = + heap<_::TransformPromiseNode, Func, ErrorFunc>>( + kj::mv(node), kj::fwd(func), kj::fwd(errorHandler)); + return PromiseForResult(false, + _::maybeChain(kj::mv(intermediate), implicitCast(nullptr))); +} + +namespace _ { // private + +template +struct IdentityFunc { + inline T operator()(T&& value) const { + return kj::mv(value); + } +}; +template +struct IdentityFunc> { + inline Promise operator()(T&& value) const { + return kj::mv(value); + } +}; +template <> +struct IdentityFunc { + inline void operator()() const {} +}; +template <> +struct IdentityFunc> { + Promise operator()() const; + // This can't be inline because it will make the translation unit depend on kj-async. Awkwardly, + // Cap'n Proto relies on being able to include this header without creating such a link-time + // dependency. +}; + +} // namespace _ (private) + +template +template +Promise Promise::catch_(ErrorFunc&& errorHandler) { + // then()'s ErrorFunc can only return a Promise if Func also returns a Promise. In this case, + // Func is being filled in automatically. We want to make sure ErrorFunc can return a Promise, + // but we don't want the extra overhead of promise chaining if ErrorFunc doesn't actually + // return a promise. So we make our Func return match ErrorFunc. + return then(_::IdentityFunc()))>(), + kj::fwd(errorHandler)); +} + +template +T Promise::wait(WaitScope& waitScope) { + _::ExceptionOr<_::FixVoid> result; + + waitImpl(kj::mv(node), result, waitScope); + + KJ_IF_MAYBE(value, result.value) { + KJ_IF_MAYBE(exception, result.exception) { + throwRecoverableException(kj::mv(*exception)); + } + return _::returnMaybeVoid(kj::mv(*value)); + } else KJ_IF_MAYBE(exception, result.exception) { + throwFatalException(kj::mv(*exception)); + } else { + // Result contained neither a value nor an exception? + KJ_UNREACHABLE; + } +} + +template <> +inline void Promise::wait(WaitScope& waitScope) { + // Override case to use throwRecoverableException(). + + _::ExceptionOr<_::Void> result; + + waitImpl(kj::mv(node), result, waitScope); + + if (result.value != nullptr) { + KJ_IF_MAYBE(exception, result.exception) { + throwRecoverableException(kj::mv(*exception)); + } + } else KJ_IF_MAYBE(exception, result.exception) { + throwRecoverableException(kj::mv(*exception)); + } else { + // Result contained neither a value nor an exception? + KJ_UNREACHABLE; + } +} + +template +ForkedPromise Promise::fork() { + return ForkedPromise(false, refcounted<_::ForkHub<_::FixVoid>>(kj::mv(node))); +} + +template +Promise ForkedPromise::addBranch() { + return hub->addBranch(); +} + +template +_::SplitTuplePromise Promise::split() { + return refcounted<_::ForkHub<_::FixVoid>>(kj::mv(node))->split(); +} + +template +Promise Promise::exclusiveJoin(Promise&& other) { + return Promise(false, heap<_::ExclusiveJoinPromiseNode>(kj::mv(node), kj::mv(other.node))); +} + +template +template +Promise Promise::attach(Attachments&&... attachments) { + return Promise(false, kj::heap<_::AttachmentPromiseNode>>( + kj::mv(node), kj::tuple(kj::fwd(attachments)...))); +} + +template +template +Promise Promise::eagerlyEvaluate(ErrorFunc&& errorHandler) { + // See catch_() for commentary. + return Promise(false, _::spark<_::FixVoid>(then( + _::IdentityFunc()))>(), + kj::fwd(errorHandler)).node)); +} + +template +Promise Promise::eagerlyEvaluate(decltype(nullptr)) { + return Promise(false, _::spark<_::FixVoid>(kj::mv(node))); +} + +template +kj::String Promise::trace() { + return PromiseBase::trace(); +} + +template +inline PromiseForResult evalLater(Func&& func) { + return _::yield().then(kj::fwd(func), _::PropagateException()); +} + +template +inline PromiseForResult evalNow(Func&& func) { + PromiseForResult result = nullptr; + KJ_IF_MAYBE(e, kj::runCatchingExceptions([&]() { + result = func(); + })) { + result = kj::mv(*e); + } + return result; +} + +template +template +void Promise::detach(ErrorFunc&& errorHandler) { + return _::detach(then([](T&&) {}, kj::fwd(errorHandler))); +} + +template <> +template +void Promise::detach(ErrorFunc&& errorHandler) { + return _::detach(then([]() {}, kj::fwd(errorHandler))); +} + +template +Promise> joinPromises(Array>&& promises) { + return Promise>(false, kj::heap<_::ArrayJoinPromiseNode>( + KJ_MAP(p, promises) { return kj::mv(p.node); }, + heapArray<_::ExceptionOr>(promises.size()))); +} + +// ======================================================================================= + +namespace _ { // private + +template +class WeakFulfiller final: public PromiseFulfiller, private kj::Disposer { + // A wrapper around PromiseFulfiller which can be detached. + // + // There are a couple non-trivialities here: + // - If the WeakFulfiller is discarded, we want the promise it fulfills to be implicitly + // rejected. + // - We cannot destroy the WeakFulfiller until the application has discarded it *and* it has been + // detached from the underlying fulfiller, because otherwise the later detach() call will go + // to a dangling pointer. Essentially, WeakFulfiller is reference counted, although the + // refcount never goes over 2 and we manually implement the refcounting because we need to do + // other special things when each side detaches anyway. To this end, WeakFulfiller is its own + // Disposer -- dispose() is called when the application discards its owned pointer to the + // fulfiller and detach() is called when the promise is destroyed. + +public: + KJ_DISALLOW_COPY(WeakFulfiller); + + static kj::Own make() { + WeakFulfiller* ptr = new WeakFulfiller; + return Own(ptr, *ptr); + } + + void fulfill(FixVoid&& value) override { + if (inner != nullptr) { + inner->fulfill(kj::mv(value)); + } + } + + void reject(Exception&& exception) override { + if (inner != nullptr) { + inner->reject(kj::mv(exception)); + } + } + + bool isWaiting() override { + return inner != nullptr && inner->isWaiting(); + } + + void attach(PromiseFulfiller& newInner) { + inner = &newInner; + } + + void detach(PromiseFulfiller& from) { + if (inner == nullptr) { + // Already disposed. + delete this; + } else { + KJ_IREQUIRE(inner == &from); + inner = nullptr; + } + } + +private: + mutable PromiseFulfiller* inner; + + WeakFulfiller(): inner(nullptr) {} + + void disposeImpl(void* pointer) const override { + // TODO(perf): Factor some of this out so it isn't regenerated for every fulfiller type? + + if (inner == nullptr) { + // Already detached. + delete this; + } else { + if (inner->isWaiting()) { + inner->reject(kj::Exception(kj::Exception::Type::FAILED, __FILE__, __LINE__, + kj::heapString("PromiseFulfiller was destroyed without fulfilling the promise."))); + } + inner = nullptr; + } + } +}; + +template +class PromiseAndFulfillerAdapter { +public: + PromiseAndFulfillerAdapter(PromiseFulfiller& fulfiller, + WeakFulfiller& wrapper) + : fulfiller(fulfiller), wrapper(wrapper) { + wrapper.attach(fulfiller); + } + + ~PromiseAndFulfillerAdapter() noexcept(false) { + wrapper.detach(fulfiller); + } + +private: + PromiseFulfiller& fulfiller; + WeakFulfiller& wrapper; +}; + +} // namespace _ (private) + +template +template +bool PromiseFulfiller::rejectIfThrows(Func&& func) { + KJ_IF_MAYBE(exception, kj::runCatchingExceptions(kj::mv(func))) { + reject(kj::mv(*exception)); + return false; + } else { + return true; + } +} + +template +bool PromiseFulfiller::rejectIfThrows(Func&& func) { + KJ_IF_MAYBE(exception, kj::runCatchingExceptions(kj::mv(func))) { + reject(kj::mv(*exception)); + return false; + } else { + return true; + } +} + +template +Promise newAdaptedPromise(Params&&... adapterConstructorParams) { + return Promise(false, heap<_::AdapterPromiseNode<_::FixVoid, Adapter>>( + kj::fwd(adapterConstructorParams)...)); +} + +template +PromiseFulfillerPair newPromiseAndFulfiller() { + auto wrapper = _::WeakFulfiller::make(); + + Own<_::PromiseNode> intermediate( + heap<_::AdapterPromiseNode<_::FixVoid, _::PromiseAndFulfillerAdapter>>(*wrapper)); + Promise<_::JoinPromises> promise(false, + _::maybeChain(kj::mv(intermediate), implicitCast(nullptr))); + + return PromiseFulfillerPair { kj::mv(promise), kj::mv(wrapper) }; +} + +} // namespace kj + +#endif // KJ_ASYNC_INL_H_ diff --git a/phonelibs/capnp-cpp/include/kj/async-io.h b/phonelibs/capnp-cpp/include/kj/async-io.h new file mode 100644 index 00000000000000..2804ed7289603d --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/async-io.h @@ -0,0 +1,561 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_ASYNC_IO_H_ +#define KJ_ASYNC_IO_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "async.h" +#include "function.h" +#include "thread.h" +#include "time.h" + +struct sockaddr; + +namespace kj { + +#if _WIN32 +class Win32EventPort; +#else +class UnixEventPort; +#endif + +class NetworkAddress; +class AsyncOutputStream; + +// ======================================================================================= +// Streaming I/O + +class AsyncInputStream { + // Asynchronous equivalent of InputStream (from io.h). + +public: + virtual Promise read(void* buffer, size_t minBytes, size_t maxBytes); + virtual Promise tryRead(void* buffer, size_t minBytes, size_t maxBytes) = 0; + + Promise read(void* buffer, size_t bytes); + + virtual Maybe tryGetLength(); + // Get the remaining number of bytes that will be produced by this stream, if known. + // + // This is used e.g. to fill in the Content-Length header of an HTTP message. If unknown, the + // HTTP implementation may need to fall back to Transfer-Encoding: chunked. + // + // The default implementation always returns null. + + virtual Promise pumpTo( + AsyncOutputStream& output, uint64_t amount = kj::maxValue); + // Read `amount` bytes from this stream (or to EOF) and write them to `output`, returning the + // total bytes actually pumped (which is only less than `amount` if EOF was reached). + // + // Override this if your stream type knows how to pump itself to certain kinds of output + // streams more efficiently than via the naive approach. You can use + // kj::dynamicDowncastIfAvailable() to test for stream types you recognize, and if none match, + // delegate to the default implementation. + // + // The default implementation first tries calling output.tryPumpFrom(), but if that fails, it + // performs a naive pump by allocating a buffer and reading to it / writing from it in a loop. + + Promise> readAllBytes(); + Promise readAllText(); + // Read until EOF and return as one big byte array or string. +}; + +class AsyncOutputStream { + // Asynchronous equivalent of OutputStream (from io.h). + +public: + virtual Promise write(const void* buffer, size_t size) KJ_WARN_UNUSED_RESULT = 0; + virtual Promise write(ArrayPtr> pieces) + KJ_WARN_UNUSED_RESULT = 0; + + virtual Maybe> tryPumpFrom( + AsyncInputStream& input, uint64_t amount = kj::maxValue); + // Implements double-dispatch for AsyncInputStream::pumpTo(). + // + // This method should only be called from within an implementation of pumpTo(). + // + // This method examines the type of `input` to find optimized ways to pump data from it to this + // output stream. If it finds one, it performs the pump. Otherwise, it returns null. + // + // The default implementation always returns null. +}; + +class AsyncIoStream: public AsyncInputStream, public AsyncOutputStream { + // A combination input and output stream. + +public: + virtual void shutdownWrite() = 0; + // Cleanly shut down just the write end of the stream, while keeping the read end open. + + virtual void abortRead() {} + // Similar to shutdownWrite, but this will shut down the read end of the stream, and should only + // be called when an error has occurred. + + virtual void getsockopt(int level, int option, void* value, uint* length); + virtual void setsockopt(int level, int option, const void* value, uint length); + // Corresponds to getsockopt() and setsockopt() syscalls. Will throw an "unimplemented" exception + // if the stream is not a socket or the option is not appropriate for the socket type. The + // default implementations always throw "unimplemented". + + virtual void getsockname(struct sockaddr* addr, uint* length); + virtual void getpeername(struct sockaddr* addr, uint* length); + // Corresponds to getsockname() and getpeername() syscalls. Will throw an "unimplemented" + // exception if the stream is not a socket. The default implementations always throw + // "unimplemented". + // + // Note that we don't provide methods that return NetworkAddress because it usually wouldn't + // be useful. You can't connect() to or listen() on these addresses, obviously, because they are + // ephemeral addresses for a single connection. +}; + +struct OneWayPipe { + // A data pipe with an input end and an output end. (Typically backed by pipe() system call.) + + Own in; + Own out; +}; + +struct TwoWayPipe { + // A data pipe that supports sending in both directions. Each end's output sends data to the + // other end's input. (Typically backed by socketpair() system call.) + + Own ends[2]; +}; + +class ConnectionReceiver { + // Represents a server socket listening on a port. + +public: + virtual Promise> accept() = 0; + // Accept the next incoming connection. + + virtual uint getPort() = 0; + // Gets the port number, if applicable (i.e. if listening on IP). This is useful if you didn't + // specify a port when constructing the NetworkAddress -- one will have been assigned + // automatically. + + virtual void getsockopt(int level, int option, void* value, uint* length); + virtual void setsockopt(int level, int option, const void* value, uint length); + // Same as the methods of AsyncIoStream. +}; + +// ======================================================================================= +// Datagram I/O + +class AncillaryMessage { + // Represents an ancillary message (aka control message) received using the recvmsg() system + // call (or equivalent). Most apps will not use this. + +public: + inline AncillaryMessage(int level, int type, ArrayPtr data); + AncillaryMessage() = default; + + inline int getLevel() const; + // Originating protocol / socket level. + + inline int getType() const; + // Protocol-specific message type. + + template + inline Maybe as(); + // Interpret the ancillary message as the given struct type. Most ancillary messages are some + // sort of struct, so this is a convenient way to access it. Returns nullptr if the message + // is smaller than the struct -- this can happen if the message was truncated due to + // insufficient ancillary buffer space. + + template + inline ArrayPtr asArray(); + // Interpret the ancillary message as an array of items. If the message size does not evenly + // divide into elements of type T, the remainder is discarded -- this can happen if the message + // was truncated due to insufficient ancillary buffer space. + +private: + int level; + int type; + ArrayPtr data; + // Message data. In most cases you should use `as()` or `asArray()`. +}; + +class DatagramReceiver { + // Class encapsulating the recvmsg() system call. You must specify the DatagramReceiver's + // capacity in advance; if a received packet is larger than the capacity, it will be truncated. + +public: + virtual Promise receive() = 0; + // Receive a new message, overwriting this object's content. + // + // receive() may reuse the same buffers for content and ancillary data with each call. + + template + struct MaybeTruncated { + T value; + + bool isTruncated; + // True if the Receiver's capacity was insufficient to receive the value and therefore the + // value is truncated. + }; + + virtual MaybeTruncated> getContent() = 0; + // Get the content of the datagram. + + virtual MaybeTruncated> getAncillary() = 0; + // Ancilarry messages received with the datagram. See the recvmsg() system call and the cmsghdr + // struct. Most apps don't need this. + // + // If the returned value is truncated, then the last message in the array may itself be + // truncated, meaning its as() method will return nullptr or its asArray() method will + // return fewer elements than expected. Truncation can also mean that additional messages were + // available but discarded. + + virtual NetworkAddress& getSource() = 0; + // Get the datagram sender's address. + + struct Capacity { + size_t content = 8192; + // How much space to allocate for the datagram content. If a datagram is received that is + // larger than this, it will be truncated, with no way to recover the tail. + + size_t ancillary = 0; + // How much space to allocate for ancillary messages. As with content, if the ancillary data + // is larger than this, it will be truncated. + }; +}; + +class DatagramPort { +public: + virtual Promise send(const void* buffer, size_t size, NetworkAddress& destination) = 0; + virtual Promise send(ArrayPtr> pieces, + NetworkAddress& destination) = 0; + + virtual Own makeReceiver( + DatagramReceiver::Capacity capacity = DatagramReceiver::Capacity()) = 0; + // Create a new `Receiver` that can be used to receive datagrams. `capacity` specifies how much + // space to allocate for the received message. The `DatagramPort` must outlive the `Receiver`. + + virtual uint getPort() = 0; + // Gets the port number, if applicable (i.e. if listening on IP). This is useful if you didn't + // specify a port when constructing the NetworkAddress -- one will have been assigned + // automatically. + + virtual void getsockopt(int level, int option, void* value, uint* length); + virtual void setsockopt(int level, int option, const void* value, uint length); + // Same as the methods of AsyncIoStream. +}; + +// ======================================================================================= +// Networks + +class NetworkAddress { + // Represents a remote address to which the application can connect. + +public: + virtual Promise> connect() = 0; + // Make a new connection to this address. + // + // The address must not be a wildcard ("*"). If it is an IP address, it must have a port number. + + virtual Own listen() = 0; + // Listen for incoming connections on this address. + // + // The address must be local. + + virtual Own bindDatagramPort(); + // Open this address as a datagram (e.g. UDP) port. + // + // The address must be local. + + virtual Own clone() = 0; + // Returns an equivalent copy of this NetworkAddress. + + virtual String toString() = 0; + // Produce a human-readable string which hopefully can be passed to Network::parseAddress() + // to reproduce this address, although whether or not that works of course depends on the Network + // implementation. This should be called only to display the address to human users, who will + // hopefully know what they are able to do with it. +}; + +class Network { + // Factory for NetworkAddress instances, representing the network services offered by the + // operating system. + // + // This interface typically represents broad authority, and well-designed code should limit its + // use to high-level startup code and user interaction. Low-level APIs should accept + // NetworkAddress instances directly and work from there, if at all possible. + +public: + virtual Promise> parseAddress(StringPtr addr, uint portHint = 0) = 0; + // Construct a network address from a user-provided string. The format of the address + // strings is not specified at the API level, and application code should make no assumptions + // about them. These strings should always be provided by humans, and said humans will know + // what format to use in their particular context. + // + // `portHint`, if provided, specifies the "standard" IP port number for the application-level + // service in play. If the address turns out to be an IP address (v4 or v6), and it lacks a + // port number, this port will be used. If `addr` lacks a port number *and* `portHint` is + // omitted, then the returned address will only support listen() and bindDatagramPort() + // (not connect()), and an unused port will be chosen each time one of those methods is called. + + virtual Own getSockaddr(const void* sockaddr, uint len) = 0; + // Construct a network address from a legacy struct sockaddr. +}; + +// ======================================================================================= +// I/O Provider + +class AsyncIoProvider { + // Class which constructs asynchronous wrappers around the operating system's I/O facilities. + // + // Generally, the implementation of this interface must integrate closely with a particular + // `EventLoop` implementation. Typically, the EventLoop implementation itself will provide + // an AsyncIoProvider. + +public: + virtual OneWayPipe newOneWayPipe() = 0; + // Creates an input/output stream pair representing the ends of a one-way pipe (e.g. created with + // the pipe(2) system call). + + virtual TwoWayPipe newTwoWayPipe() = 0; + // Creates two AsyncIoStreams representing the two ends of a two-way pipe (e.g. created with + // socketpair(2) system call). Data written to one end can be read from the other. + + virtual Network& getNetwork() = 0; + // Creates a new `Network` instance representing the networks exposed by the operating system. + // + // DO NOT CALL THIS except at the highest levels of your code, ideally in the main() function. If + // you call this from low-level code, then you are preventing higher-level code from injecting an + // alternative implementation. Instead, if your code needs to use network functionality, it + // should ask for a `Network` as a constructor or method parameter, so that higher-level code can + // chose what implementation to use. The system network is essentially a singleton. See: + // http://www.object-oriented-security.org/lets-argue/singletons + // + // Code that uses the system network should not make any assumptions about what kinds of + // addresses it will parse, as this could differ across platforms. String addresses should come + // strictly from the user, who will know how to write them correctly for their system. + // + // With that said, KJ currently supports the following string address formats: + // - IPv4: "1.2.3.4", "1.2.3.4:80" + // - IPv6: "1234:5678::abcd", "[1234:5678::abcd]:80" + // - Local IP wildcard (covers both v4 and v6): "*", "*:80" + // - Symbolic names: "example.com", "example.com:80", "example.com:http", "1.2.3.4:http" + // - Unix domain: "unix:/path/to/socket" + + struct PipeThread { + // A combination of a thread and a two-way pipe that communicates with that thread. + // + // The fields are intentionally ordered so that the pipe will be destroyed (and therefore + // disconnected) before the thread is destroyed (and therefore joined). Thus if the thread + // arranges to exit when it detects disconnect, destruction should be clean. + + Own thread; + Own pipe; + }; + + virtual PipeThread newPipeThread( + Function startFunc) = 0; + // Create a new thread and set up a two-way pipe (socketpair) which can be used to communicate + // with it. One end of the pipe is passed to the thread's start function and the other end of + // the pipe is returned. The new thread also gets its own `AsyncIoProvider` instance and will + // already have an active `EventLoop` when `startFunc` is called. + // + // TODO(someday): I'm not entirely comfortable with this interface. It seems to be doing too + // much at once but I'm not sure how to cleanly break it down. + + virtual Timer& getTimer() = 0; + // Returns a `Timer` based on real time. Time does not pass while event handlers are running -- + // it only updates when the event loop polls for system events. This means that calling `now()` + // on this timer does not require a system call. + // + // This timer is not affected by changes to the system date. It is unspecified whether the timer + // continues to count while the system is suspended. +}; + +class LowLevelAsyncIoProvider { + // Similar to `AsyncIoProvider`, but represents a lower-level interface that may differ on + // different operating systems. You should prefer to use `AsyncIoProvider` over this interface + // whenever possible, as `AsyncIoProvider` is portable and friendlier to dependency-injection. + // + // On Unix, this interface can be used to import native file descriptors into the async framework. + // Different implementations of this interface might work on top of different event handling + // primitives, such as poll vs. epoll vs. kqueue vs. some higher-level event library. + // + // On Windows, this interface can be used to import native HANDLEs into the async framework. + // Different implementations of this interface might work on top of different event handling + // primitives, such as I/O completion ports vs. completion routines. + // + // TODO(port): Actually implement Windows support. + +public: + // --------------------------------------------------------------------------- + // Unix-specific stuff + + enum Flags { + // Flags controlling how to wrap a file descriptor. + + TAKE_OWNERSHIP = 1 << 0, + // The returned object should own the file descriptor, automatically closing it when destroyed. + // The close-on-exec flag will be set on the descriptor if it is not already. + // + // If this flag is not used, then the file descriptor is not automatically closed and the + // close-on-exec flag is not modified. + +#if !_WIN32 + ALREADY_CLOEXEC = 1 << 1, + // Indicates that the close-on-exec flag is known already to be set, so need not be set again. + // Only relevant when combined with TAKE_OWNERSHIP. + // + // On Linux, all system calls which yield new file descriptors have flags or variants which + // set the close-on-exec flag immediately. Unfortunately, other OS's do not. + + ALREADY_NONBLOCK = 1 << 2 + // Indicates that the file descriptor is known already to be in non-blocking mode, so the flag + // need not be set again. Otherwise, all wrap*Fd() methods will enable non-blocking mode + // automatically. + // + // On Linux, all system calls which yield new file descriptors have flags or variants which + // enable non-blocking mode immediately. Unfortunately, other OS's do not. +#endif + }; + +#if _WIN32 + typedef uintptr_t Fd; + // On Windows, the `fd` parameter to each of these methods must be a SOCKET, and must have the + // flag WSA_FLAG_OVERLAPPED (which socket() uses by default, but WSASocket() wants you to specify + // explicitly). +#else + typedef int Fd; + // On Unix, any arbitrary file descriptor is supported. +#endif + + virtual Own wrapInputFd(Fd fd, uint flags = 0) = 0; + // Create an AsyncInputStream wrapping a file descriptor. + // + // `flags` is a bitwise-OR of the values of the `Flags` enum. + + virtual Own wrapOutputFd(Fd fd, uint flags = 0) = 0; + // Create an AsyncOutputStream wrapping a file descriptor. + // + // `flags` is a bitwise-OR of the values of the `Flags` enum. + + virtual Own wrapSocketFd(Fd fd, uint flags = 0) = 0; + // Create an AsyncIoStream wrapping a socket file descriptor. + // + // `flags` is a bitwise-OR of the values of the `Flags` enum. + + virtual Promise> wrapConnectingSocketFd( + Fd fd, const struct sockaddr* addr, uint addrlen, uint flags = 0) = 0; + // Create an AsyncIoStream wrapping a socket and initiate a connection to the given address. + // The returned promise does not resolve until connection has completed. + // + // `flags` is a bitwise-OR of the values of the `Flags` enum. + + virtual Own wrapListenSocketFd(Fd fd, uint flags = 0) = 0; + // Create an AsyncIoStream wrapping a listen socket file descriptor. This socket should already + // have had `bind()` and `listen()` called on it, so it's ready for `accept()`. + // + // `flags` is a bitwise-OR of the values of the `Flags` enum. + + virtual Own wrapDatagramSocketFd(Fd fd, uint flags = 0); + + virtual Timer& getTimer() = 0; + // Returns a `Timer` based on real time. Time does not pass while event handlers are running -- + // it only updates when the event loop polls for system events. This means that calling `now()` + // on this timer does not require a system call. + // + // This timer is not affected by changes to the system date. It is unspecified whether the timer + // continues to count while the system is suspended. +}; + +Own newAsyncIoProvider(LowLevelAsyncIoProvider& lowLevel); +// Make a new AsyncIoProvider wrapping a `LowLevelAsyncIoProvider`. + +struct AsyncIoContext { + Own lowLevelProvider; + Own provider; + WaitScope& waitScope; + +#if _WIN32 + Win32EventPort& win32EventPort; +#else + UnixEventPort& unixEventPort; + // TEMPORARY: Direct access to underlying UnixEventPort, mainly for waiting on signals. This + // field will go away at some point when we have a chance to improve these interfaces. +#endif +}; + +AsyncIoContext setupAsyncIo(); +// Convenience method which sets up the current thread with everything it needs to do async I/O. +// The returned objects contain an `EventLoop` which is wrapping an appropriate `EventPort` for +// doing I/O on the host system, so everything is ready for the thread to start making async calls +// and waiting on promises. +// +// You would typically call this in your main() loop or in the start function of a thread. +// Example: +// +// int main() { +// auto ioContext = kj::setupAsyncIo(); +// +// // Now we can call an async function. +// Promise textPromise = getHttp(*ioContext.provider, "http://example.com"); +// +// // And we can wait for the promise to complete. Note that you can only use `wait()` +// // from the top level, not from inside a promise callback. +// String text = textPromise.wait(ioContext.waitScope); +// print(text); +// return 0; +// } +// +// WARNING: An AsyncIoContext can only be used in the thread and process that created it. In +// particular, note that after a fork(), an AsyncIoContext created in the parent process will +// not work correctly in the child, even if the parent ceases to use its copy. In particular +// note that this means that server processes which daemonize themselves at startup must wait +// until after daemonization to create an AsyncIoContext. + +// ======================================================================================= +// inline implementation details + +inline AncillaryMessage::AncillaryMessage( + int level, int type, ArrayPtr data) + : level(level), type(type), data(data) {} + +inline int AncillaryMessage::getLevel() const { return level; } +inline int AncillaryMessage::getType() const { return type; } + +template +inline Maybe AncillaryMessage::as() { + if (data.size() >= sizeof(T)) { + return *reinterpret_cast(data.begin()); + } else { + return nullptr; + } +} + +template +inline ArrayPtr AncillaryMessage::asArray() { + return arrayPtr(reinterpret_cast(data.begin()), data.size() / sizeof(T)); +} + +} // namespace kj + +#endif // KJ_ASYNC_IO_H_ diff --git a/phonelibs/capnp-cpp/include/kj/async-prelude.h b/phonelibs/capnp-cpp/include/kj/async-prelude.h new file mode 100644 index 00000000000000..0a5843f88a4d77 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/async-prelude.h @@ -0,0 +1,218 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file contains a bunch of internal declarations that must appear before async.h can start. +// We don't define these directly in async.h because it makes the file hard to read. + +#ifndef KJ_ASYNC_PRELUDE_H_ +#define KJ_ASYNC_PRELUDE_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "exception.h" +#include "tuple.h" + +namespace kj { + +class EventLoop; +template +class Promise; +class WaitScope; + +template +Promise> joinPromises(Array>&& promises); +Promise joinPromises(Array>&& promises); + +namespace _ { // private + +template struct JoinPromises_ { typedef T Type; }; +template struct JoinPromises_> { typedef T Type; }; + +template +using JoinPromises = typename JoinPromises_::Type; +// If T is Promise, resolves to U, otherwise resolves to T. +// +// TODO(cleanup): Rename to avoid confusion with joinPromises() call which is completely +// unrelated. + +class PropagateException { + // A functor which accepts a kj::Exception as a parameter and returns a broken promise of + // arbitrary type which simply propagates the exception. +public: + class Bottom { + public: + Bottom(Exception&& exception): exception(kj::mv(exception)) {} + + Exception asException() { return kj::mv(exception); } + + private: + Exception exception; + }; + + Bottom operator()(Exception&& e) { + return Bottom(kj::mv(e)); + } + Bottom operator()(const Exception& e) { + return Bottom(kj::cp(e)); + } +}; + +template +struct ReturnType_ { typedef decltype(instance()(instance())) Type; }; +template +struct ReturnType_ { typedef decltype(instance()()) Type; }; + +template +using ReturnType = typename ReturnType_::Type; +// The return type of functor Func given a parameter of type T, with the special exception that if +// T is void, this is the return type of Func called with no arguments. + +template struct SplitTuplePromise_ { typedef Promise Type; }; +template +struct SplitTuplePromise_> { + typedef kj::Tuple>...> Type; +}; + +template +using SplitTuplePromise = typename SplitTuplePromise_::Type; +// T -> Promise +// Tuple -> Tuple> + +struct Void {}; +// Application code should NOT refer to this! See `kj::READY_NOW` instead. + +template struct FixVoid_ { typedef T Type; }; +template <> struct FixVoid_ { typedef Void Type; }; +template using FixVoid = typename FixVoid_::Type; +// FixVoid is just T unless T is void in which case it is _::Void (an empty struct). + +template struct UnfixVoid_ { typedef T Type; }; +template <> struct UnfixVoid_ { typedef void Type; }; +template using UnfixVoid = typename UnfixVoid_::Type; +// UnfixVoid is the opposite of FixVoid. + +template +struct MaybeVoidCaller { + // Calls the function converting a Void input to an empty parameter list and a void return + // value to a Void output. + + template + static inline Out apply(Func& func, In&& in) { + return func(kj::mv(in)); + } +}; +template +struct MaybeVoidCaller { + template + static inline Out apply(Func& func, In& in) { + return func(in); + } +}; +template +struct MaybeVoidCaller { + template + static inline Out apply(Func& func, Void&& in) { + return func(); + } +}; +template +struct MaybeVoidCaller { + template + static inline Void apply(Func& func, In&& in) { + func(kj::mv(in)); + return Void(); + } +}; +template +struct MaybeVoidCaller { + template + static inline Void apply(Func& func, In& in) { + func(in); + return Void(); + } +}; +template <> +struct MaybeVoidCaller { + template + static inline Void apply(Func& func, Void&& in) { + func(); + return Void(); + } +}; + +template +inline T&& returnMaybeVoid(T&& t) { + return kj::fwd(t); +} +inline void returnMaybeVoid(Void&& v) {} + +class ExceptionOrValue; +class PromiseNode; +class ChainPromiseNode; +template +class ForkHub; + +class TaskSetImpl; + +class Event; + +class PromiseBase { +public: + kj::String trace(); + // Dump debug info about this promise. + +private: + Own node; + + PromiseBase() = default; + PromiseBase(Own&& node): node(kj::mv(node)) {} + + friend class kj::EventLoop; + friend class ChainPromiseNode; + template + friend class kj::Promise; + friend class TaskSetImpl; + template + friend Promise> kj::joinPromises(Array>&& promises); + friend Promise kj::joinPromises(Array>&& promises); +}; + +void detach(kj::Promise&& promise); +void waitImpl(Own<_::PromiseNode>&& node, _::ExceptionOrValue& result, WaitScope& waitScope); +Promise yield(); +Own neverDone(); + +class NeverDone { +public: + template + operator Promise() const { + return Promise(false, neverDone()); + } + + KJ_NORETURN(void wait(WaitScope& waitScope) const); +}; + +} // namespace _ (private) +} // namespace kj + +#endif // KJ_ASYNC_PRELUDE_H_ diff --git a/phonelibs/capnp-cpp/include/kj/async-unix.h b/phonelibs/capnp-cpp/include/kj/async-unix.h new file mode 100644 index 00000000000000..06f128a50eeddb --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/async-unix.h @@ -0,0 +1,274 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_ASYNC_UNIX_H_ +#define KJ_ASYNC_UNIX_H_ + +#if _WIN32 +#error "This file is Unix-specific. On Windows, include async-win32.h instead." +#endif + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "async.h" +#include "time.h" +#include "vector.h" +#include "io.h" +#include + +#if __linux__ && !__BIONIC__ && !defined(KJ_USE_EPOLL) +// Default to epoll on Linux, except on Bionic (Android) which doesn't have signalfd.h. +#define KJ_USE_EPOLL 1 +#endif + +namespace kj { + +class UnixEventPort: public EventPort { + // An EventPort implementation which can wait for events on file descriptors as well as signals. + // This API only makes sense on Unix. + // + // The implementation uses `poll()` or possibly a platform-specific API (e.g. epoll, kqueue). + // To also wait on signals without race conditions, the implementation may block signals until + // just before `poll()` while using a signal handler which `siglongjmp()`s back to just before + // the signal was unblocked, or it may use a nicer platform-specific API like signalfd. + // + // The implementation reserves a signal for internal use. By default, it uses SIGUSR1. If you + // need to use SIGUSR1 for something else, you must offer a different signal by calling + // setReservedSignal() at startup. + // + // WARNING: A UnixEventPort can only be used in the thread and process that created it. In + // particular, note that after a fork(), a UnixEventPort created in the parent process will + // not work correctly in the child, even if the parent ceases to use its copy. In particular + // note that this means that server processes which daemonize themselves at startup must wait + // until after daemonization to create a UnixEventPort. + +public: + UnixEventPort(); + ~UnixEventPort() noexcept(false); + + class FdObserver; + // Class that watches an fd for readability or writability. See definition below. + + Promise onSignal(int signum); + // When the given signal is delivered to this thread, return the corresponding siginfo_t. + // The signal must have been captured using `captureSignal()`. + // + // If `onSignal()` has not been called, the signal will remain blocked in this thread. + // Therefore, a signal which arrives before `onSignal()` was called will not be "missed" -- the + // next call to 'onSignal()' will receive it. Also, you can control which thread receives a + // process-wide signal by only calling `onSignal()` on that thread's event loop. + // + // The result of waiting on the same signal twice at once is undefined. + + static void captureSignal(int signum); + // Arranges for the given signal to be captured and handled via UnixEventPort, so that you may + // then pass it to `onSignal()`. This method is static because it registers a signal handler + // which applies process-wide. If any other threads exist in the process when `captureSignal()` + // is called, you *must* set the signal mask in those threads to block this signal, otherwise + // terrible things will happen if the signal happens to be delivered to those threads. If at + // all possible, call `captureSignal()` *before* creating threads, so that threads you create in + // the future will inherit the proper signal mask. + // + // To un-capture a signal, simply install a different signal handler and then un-block it from + // the signal mask. + + static void setReservedSignal(int signum); + // Sets the signal number which `UnixEventPort` reserves for internal use. If your application + // needs to use SIGUSR1, call this at startup (before any calls to `captureSignal()` and before + // constructing an `UnixEventPort`) to offer a different signal. + + Timer& getTimer() { return timerImpl; } + + // implements EventPort ------------------------------------------------------ + bool wait() override; + bool poll() override; + void wake() const override; + +private: + struct TimerSet; // Defined in source file to avoid STL include. + class TimerPromiseAdapter; + class SignalPromiseAdapter; + + TimerImpl timerImpl; + + SignalPromiseAdapter* signalHead = nullptr; + SignalPromiseAdapter** signalTail = &signalHead; + + TimePoint readClock(); + void gotSignal(const siginfo_t& siginfo); + + friend class TimerPromiseAdapter; + +#if KJ_USE_EPOLL + AutoCloseFd epollFd; + AutoCloseFd signalFd; + AutoCloseFd eventFd; // Used for cross-thread wakeups. + + sigset_t signalFdSigset; + // Signal mask as currently set on the signalFd. Tracked so we can detect whether or not it + // needs updating. + + bool doEpollWait(int timeout); + +#else + class PollContext; + + FdObserver* observersHead = nullptr; + FdObserver** observersTail = &observersHead; + + unsigned long long threadId; // actually pthread_t +#endif +}; + +class UnixEventPort::FdObserver { + // Object which watches a file descriptor to determine when it is readable or writable. + // + // For listen sockets, "readable" means that there is a connection to accept(). For everything + // else, it means that read() (or recv()) will return data. + // + // The presence of out-of-band data should NOT fire this event. However, the event may + // occasionally fire spuriously (when there is actually no data to read), and one thing that can + // cause such spurious events is the arrival of OOB data on certain platforms whose event + // interfaces fail to distinguish between regular and OOB data (e.g. Mac OSX). + // + // WARNING: The exact behavior of this class differs across systems, since event interfaces + // vary wildly. Be sure to read the documentation carefully and avoid depending on unspecified + // behavior. If at all possible, use the higher-level AsyncInputStream interface instead. + +public: + enum Flags { + OBSERVE_READ = 1, + OBSERVE_WRITE = 2, + OBSERVE_URGENT = 4, + OBSERVE_READ_WRITE = OBSERVE_READ | OBSERVE_WRITE + }; + + FdObserver(UnixEventPort& eventPort, int fd, uint flags); + // Begin watching the given file descriptor for readability. Only one ReadObserver may exist + // for a given file descriptor at a time. + + ~FdObserver() noexcept(false); + + KJ_DISALLOW_COPY(FdObserver); + + Promise whenBecomesReadable(); + // Resolves the next time the file descriptor transitions from having no data to read to having + // some data to read. + // + // KJ uses "edge-triggered" event notification whenever possible. As a result, it is an error + // to call this method when there is already data in the read buffer which has been there since + // prior to the last turn of the event loop or prior to creation FdWatcher. In this case, it is + // unspecified whether the promise will ever resolve -- it depends on the underlying event + // mechanism being used. + // + // In order to avoid this problem, make sure that you only call `whenBecomesReadable()` + // only at times when you know the buffer is empty. You know this for sure when one of the + // following happens: + // * read() or recv() fails with EAGAIN or EWOULDBLOCK. (You MUST have non-blocking mode + // enabled on the fd!) + // * The file descriptor is a regular byte-oriented object (like a socket or pipe), + // read() or recv() returns fewer than the number of bytes requested, and `atEndHint()` + // returns false. This can only happen if the buffer is empty but EOF is not reached. (Note, + // though, that for record-oriented file descriptors like Linux's inotify interface, this + // rule does not hold, because it could simply be that the next record did not fit into the + // space available.) + // + // It is an error to call `whenBecomesReadable()` again when the promise returned previously + // has not yet resolved. If you do this, the previous promise may throw an exception. + + inline Maybe atEndHint() { return atEnd; } + // Returns true if the event system has indicated that EOF has been received. There may still + // be data in the read buffer, but once that is gone, there's nothing left. + // + // Returns false if the event system has indicated that EOF had NOT been received as of the + // last turn of the event loop. + // + // Returns nullptr if the event system does not know whether EOF has been reached. In this + // case, the only way to know for sure is to call read() or recv() and check if it returns + // zero. + // + // This hint may be useful as an optimization to avoid an unnecessary system call. + + Promise whenBecomesWritable(); + // Resolves the next time the file descriptor transitions from having no space available in the + // write buffer to having some space available. + // + // KJ uses "edge-triggered" event notification whenever possible. As a result, it is an error + // to call this method when there is already space in the write buffer which has been there + // since prior to the last turn of the event loop or prior to creation FdWatcher. In this case, + // it is unspecified whether the promise will ever resolve -- it depends on the underlying + // event mechanism being used. + // + // In order to avoid this problem, make sure that you only call `whenBecomesWritable()` + // only at times when you know the buffer is full. You know this for sure when one of the + // following happens: + // * write() or send() fails with EAGAIN or EWOULDBLOCK. (You MUST have non-blocking mode + // enabled on the fd!) + // * write() or send() succeeds but accepts fewer than the number of bytes provided. This can + // only happen if the buffer is full. + // + // It is an error to call `whenBecomesWritable()` again when the promise returned previously + // has not yet resolved. If you do this, the previous promise may throw an exception. + + Promise whenUrgentDataAvailable(); + // Resolves the next time the file descriptor's read buffer contains "urgent" data. + // + // The conditions for availability of urgent data are specific to the file descriptor's + // underlying implementation. + // + // It is an error to call `whenUrgentDataAvailable()` again when the promise returned previously + // has not yet resolved. If you do this, the previous promise may throw an exception. + // + // WARNING: This has some known weird behavior on macOS. See + // https://github.com/sandstorm-io/capnproto/issues/374. + +private: + UnixEventPort& eventPort; + int fd; + uint flags; + + kj::Maybe>> readFulfiller; + kj::Maybe>> writeFulfiller; + kj::Maybe>> urgentFulfiller; + // Replaced each time `whenBecomesReadable()` or `whenBecomesWritable()` is called. Reverted to + // null every time an event is fired. + + Maybe atEnd; + + void fire(short events); + +#if !KJ_USE_EPOLL + FdObserver* next; + FdObserver** prev; + // Linked list of observers which currently have a non-null readFulfiller or writeFulfiller. + // If `prev` is null then the observer is not currently in the list. + + short getEventMask(); +#endif + + friend class UnixEventPort; +}; + +} // namespace kj + +#endif // KJ_ASYNC_UNIX_H_ diff --git a/phonelibs/capnp-cpp/include/kj/async-win32.h b/phonelibs/capnp-cpp/include/kj/async-win32.h new file mode 100644 index 00000000000000..b70c42e016c5ba --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/async-win32.h @@ -0,0 +1,234 @@ +// Copyright (c) 2016 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_ASYNC_WIN32_H_ +#define KJ_ASYNC_WIN32_H_ + +#if !_WIN32 +#error "This file is Windows-specific. On Unix, include async-unix.h instead." +#endif + +#include "async.h" +#include "time.h" +#include "io.h" +#include +#include + +// Include windows.h as lean as possible. (If you need more of the Windows API for your app, +// #include windows.h yourself before including this header.) +#define WIN32_LEAN_AND_MEAN 1 +#define NOSERVICE 1 +#define NOMCX 1 +#define NOIME 1 +#include +#include "windows-sanity.h" + +namespace kj { + +class Win32EventPort: public EventPort { + // Abstract base interface for EventPorts that can listen on Win32 event types. Due to the + // absurd complexity of the Win32 API, it's not possible to standardize on a single + // implementation of EventPort. In particular, there is no way for a single thread to use I/O + // completion ports (the most efficient way of handling I/O) while at the same time waiting for + // signalable handles or UI messages. + // + // Note that UI messages are not supported at all by this interface because the message queue + // is implemented by user32.dll and we want libkj to depend only on kernel32.dll. A separate + // compat library could provide a Win32EventPort implementation that works with the UI message + // queue. + +public: + // --------------------------------------------------------------------------- + // overlapped I/O + + struct IoResult { + DWORD errorCode; + DWORD bytesTransferred; + }; + + class IoOperation { + public: + virtual LPOVERLAPPED getOverlapped() = 0; + // Gets the OVERLAPPED structure to pass to the Win32 I/O call. Do NOT modify it; just pass it + // on. + + virtual Promise onComplete() = 0; + // After making the Win32 call, if the return value indicates that the operation was + // successfully queued (i.e. the completion event will definitely occur), call this to wait + // for completion. + // + // You MUST call this if the operation was successfully queued, and you MUST NOT call this + // otherwise. If the Win32 call failed (without queuing any operation or event) then you should + // simply drop the IoOperation object. + // + // Dropping the returned Promise cancels the operation via Win32's CancelIoEx(). The destructor + // will wait for the cancellation to complete, such that after dropping the proimse it is safe + // to free the buffer that the operation was reading from / writing to. + // + // You may safely drop the `IoOperation` while still waiting for this promise. You may not, + // however, drop the `IoObserver`. + }; + + class IoObserver { + public: + virtual Own newOperation(uint64_t offset) = 0; + // Begin an I/O operation. For file operations, `offset` is the offset within the file at + // which the operation will start. For stream operations, `offset` is ignored. + }; + + virtual Own observeIo(HANDLE handle) = 0; + // Given a handle which supports overlapped I/O, arrange to receive I/O completion events via + // this EventPort. + // + // Different Win32EventPort implementations may handle this in different ways, such as by using + // completion routines (APCs) or by using I/O completion ports. The caller should not assume + // any particular technique. + // + // WARNING: It is only safe to call observeIo() on a particular handle once during its lifetime. + // You cannot observe the same handle from multiple Win32EventPorts, even if not at the same + // time. This is because the Win32 API provides no way to disassociate a handle from an I/O + // completion port once it is associated. + + // --------------------------------------------------------------------------- + // signalable handles + // + // Warning: Due to limitations in the Win32 API, implementations of EventPort may be forced to + // spawn additional threads to wait for signaled objects. This is necessary if the EventPort + // implementation is based on I/O completion ports, or if you need to wait on more than 64 + // handles at once. + + class SignalObserver { + public: + virtual Promise onSignaled() = 0; + // Returns a promise that completes the next time the handle enters the signaled state. + // + // Depending on the type of handle, the handle may automatically be reset to a non-signaled + // state before the promise resolves. The underlying implementaiton uses WaitForSingleObject() + // or an equivalent wait call, so check the documentation for that to understand the semantics. + // + // If the handle is a mutex and it is abandoned without being unlocked, the promise breaks with + // an exception. + + virtual Promise onSignaledOrAbandoned() = 0; + // Like onSingaled(), but instead of throwing when a mutex is abandoned, resolves to `true`. + // Resolves to `false` for non-abandoned signals. + }; + + virtual Own observeSignalState(HANDLE handle) = 0; + // Given a handle that supports waiting for it to become "signaled" via WaitForSingleObject(), + // return an object that can wait for this state using the EventPort. + + // --------------------------------------------------------------------------- + // APCs + + virtual void allowApc() = 0; + // If this is ever called, the Win32EventPort will switch modes so that APCs can be scheduled + // on the thread, e.g. through the Win32 QueueUserAPC() call. In the future, this may be enabled + // by default. However, as of this writing, Wine does not support the necessary + // GetQueuedCompletionStatusEx() call, thus allowApc() breaks Wine support. (Tested on Wine + // 1.8.7.) + // + // If the event port implementation can't support APCs for some reason, this throws. + + // --------------------------------------------------------------------------- + // time + + virtual Timer& getTimer() = 0; +}; + +class Win32WaitObjectThreadPool { + // Helper class that implements Win32EventPort::observeSignalState() by spawning additional + // threads as needed to perform the actual waiting. + // + // This class is intended to be used to assist in building Win32EventPort implementations. + +public: + Win32WaitObjectThreadPool(uint mainThreadCount = 0); + // `mainThreadCount` indicates the number of objects the main thread is able to listen on + // directly. Typically this would be zero (e.g. if the main thread watches an I/O completion + // port) or MAXIMUM_WAIT_OBJECTS (e.g. if the main thread is a UI thread but can use + // MsgWaitForMultipleObjectsEx() to wait on some handles at the same time as messages). + + Own observeSignalState(HANDLE handle); + // Implemetns Win32EventPort::observeSignalState(). + + uint prepareMainThreadWait(HANDLE* handles[]); + // Call immediately before invoking WaitForMultipleObjects() or similar in the main thread. + // Fills in `handles` with the handle pointers to wait on, and returns the number of handles + // in this array. (The array should be allocated to be at least the size passed to the + // constructor). + // + // There's no need to call this if `mainThreadCount` as passed to the constructor was zero. + + bool finishedMainThreadWait(DWORD returnCode); + // Call immediately after invoking WaitForMultipleObjects() or similar in the main thread, + // passing the value returend by that call. Returns true if the event indicated by `returnCode` + // has been handled (i.e. it was WAIT_OBJECT_n or WAIT_ABANDONED_n where n is in-range for the + // last call to prepareMainThreadWait()). +}; + +class Win32IocpEventPort final: public Win32EventPort { + // An EventPort implementation which uses Windows I/O completion ports to listen for events. + // + // With this implementation, observeSignalState() requires spawning a separate thread. + +public: + Win32IocpEventPort(); + ~Win32IocpEventPort() noexcept(false); + + // implements EventPort ------------------------------------------------------ + bool wait() override; + bool poll() override; + void wake() const override; + + // implements Win32IocpEventPort --------------------------------------------- + Own observeIo(HANDLE handle) override; + Own observeSignalState(HANDLE handle) override; + Timer& getTimer() override { return timerImpl; } + void allowApc() override { isAllowApc = true; } + +private: + class IoPromiseAdapter; + class IoOperationImpl; + class IoObserverImpl; + + AutoCloseHandle iocp; + AutoCloseHandle thread; + Win32WaitObjectThreadPool waitThreads; + TimerImpl timerImpl; + mutable std::atomic sentWake {false}; + bool isAllowApc = false; + + static TimePoint readClock(); + + void waitIocp(DWORD timeoutMs); + // Wait on the I/O completion port for up to timeoutMs and pump events. Does not advance the + // timer; caller must do that. + + bool receivedWake(); + + static AutoCloseHandle newIocpHandle(); + static AutoCloseHandle openCurrentThread(); +}; + +} // namespace kj + +#endif // KJ_ASYNC_WIN32_H_ diff --git a/phonelibs/capnp-cpp/include/kj/async.h b/phonelibs/capnp-cpp/include/kj/async.h new file mode 100644 index 00000000000000..5a9d9bdae717dc --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/async.h @@ -0,0 +1,682 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_ASYNC_H_ +#define KJ_ASYNC_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "async-prelude.h" +#include "exception.h" +#include "refcount.h" + +namespace kj { + +class EventLoop; +class WaitScope; + +template +class Promise; +template +class ForkedPromise; +template +class PromiseFulfiller; +template +struct PromiseFulfillerPair; + +template +using PromiseForResult = Promise<_::JoinPromises<_::ReturnType>>; +// Evaluates to the type of Promise for the result of calling functor type Func with parameter type +// T. If T is void, then the promise is for the result of calling Func with no arguments. If +// Func itself returns a promise, the promises are joined, so you never get Promise>. + +// ======================================================================================= +// Promises + +template +class Promise: protected _::PromiseBase { + // The basic primitive of asynchronous computation in KJ. Similar to "futures", but designed + // specifically for event loop concurrency. Similar to E promises and JavaScript Promises/A. + // + // A Promise represents a promise to produce a value of type T some time in the future. Once + // that value has been produced, the promise is "fulfilled". Alternatively, a promise can be + // "broken", with an Exception describing what went wrong. You may implicitly convert a value of + // type T to an already-fulfilled Promise. You may implicitly convert the constant + // `kj::READY_NOW` to an already-fulfilled Promise. You may also implicitly convert a + // `kj::Exception` to an already-broken promise of any type. + // + // Promises are linear types -- they are moveable but not copyable. If a Promise is destroyed + // or goes out of scope (without being moved elsewhere), any ongoing asynchronous operations + // meant to fulfill the promise will be canceled if possible. All methods of `Promise` (unless + // otherwise noted) actually consume the promise in the sense of move semantics. (Arguably they + // should be rvalue-qualified, but at the time this interface was created compilers didn't widely + // support that yet and anyway it would be pretty ugly typing kj::mv(promise).whatever().) If + // you want to use one Promise in two different places, you must fork it with `fork()`. + // + // To use the result of a Promise, you must call `then()` and supply a callback function to + // call with the result. `then()` returns another promise, for the result of the callback. + // Any time that this would result in Promise>, the promises are collapsed into a + // simple Promise that first waits for the outer promise, then the inner. Example: + // + // // Open a remote file, read the content, and then count the + // // number of lines of text. + // // Note that none of the calls here block. `file`, `content` + // // and `lineCount` are all initialized immediately before any + // // asynchronous operations occur. The lambda callbacks are + // // called later. + // Promise> file = openFtp("ftp://host/foo/bar"); + // Promise content = file.then( + // [](Own file) -> Promise { + // return file.readAll(); + // }); + // Promise lineCount = content.then( + // [](String text) -> int { + // uint count = 0; + // for (char c: text) count += (c == '\n'); + // return count; + // }); + // + // For `then()` to work, the current thread must have an active `EventLoop`. Each callback + // is scheduled to execute in that loop. Since `then()` schedules callbacks only on the current + // thread's event loop, you do not need to worry about two callbacks running at the same time. + // You will need to set up at least one `EventLoop` at the top level of your program before you + // can use promises. + // + // To adapt a non-Promise-based asynchronous API to promises, use `newAdaptedPromise()`. + // + // Systems using promises should consider supporting the concept of "pipelining". Pipelining + // means allowing a caller to start issuing method calls against a promised object before the + // promise has actually been fulfilled. This is particularly useful if the promise is for a + // remote object living across a network, as this can avoid round trips when chaining a series + // of calls. It is suggested that any class T which supports pipelining implement a subclass of + // Promise which adds "eventual send" methods -- methods which, when called, say "please + // invoke the corresponding method on the promised value once it is available". These methods + // should in turn return promises for the eventual results of said invocations. Cap'n Proto, + // for example, implements the type `RemotePromise` which supports pipelining RPC requests -- see + // `capnp/capability.h`. + // + // KJ Promises are based on E promises: + // http://wiki.erights.org/wiki/Walnut/Distributed_Computing#Promises + // + // KJ Promises are also inspired in part by the evolving standards for JavaScript/ECMAScript + // promises, which are themselves influenced by E promises: + // http://promisesaplus.com/ + // https://github.com/domenic/promises-unwrapping + +public: + Promise(_::FixVoid value); + // Construct an already-fulfilled Promise from a value of type T. For non-void promises, the + // parameter type is simply T. So, e.g., in a function that returns `Promise`, you can + // say `return 123;` to return a promise that is already fulfilled to 123. + // + // For void promises, use `kj::READY_NOW` as the value, e.g. `return kj::READY_NOW`. + + Promise(kj::Exception&& e); + // Construct an already-broken Promise. + + inline Promise(decltype(nullptr)) {} + + template + PromiseForResult then(Func&& func, ErrorFunc&& errorHandler = _::PropagateException()) + KJ_WARN_UNUSED_RESULT; + // Register a continuation function to be executed when the promise completes. The continuation + // (`func`) takes the promised value (an rvalue of type `T`) as its parameter. The continuation + // may return a new value; `then()` itself returns a promise for the continuation's eventual + // result. If the continuation itself returns a `Promise`, then `then()` shall also return + // a `Promise` which first waits for the original promise, then executes the continuation, + // then waits for the inner promise (i.e. it automatically "unwraps" the promise). + // + // In all cases, `then()` returns immediately. The continuation is executed later. The + // continuation is always executed on the same EventLoop (and, therefore, the same thread) which + // called `then()`, therefore no synchronization is necessary on state shared by the continuation + // and the surrounding scope. If no EventLoop is running on the current thread, `then()` throws + // an exception. + // + // You may also specify an error handler continuation as the second parameter. `errorHandler` + // must be a functor taking a parameter of type `kj::Exception&&`. It must return the same + // type as `func` returns (except when `func` returns `Promise`, in which case `errorHandler` + // may return either `Promise` or just `U`). The default error handler simply propagates the + // exception to the returned promise. + // + // Either `func` or `errorHandler` may, of course, throw an exception, in which case the promise + // is broken. When compiled with -fno-exceptions, the framework will still detect when a + // recoverable exception was thrown inside of a continuation and will consider the promise + // broken even though a (presumably garbage) result was returned. + // + // If the returned promise is destroyed before the callback runs, the callback will be canceled + // (it will never run). + // + // Note that `then()` -- like all other Promise methods -- consumes the promise on which it is + // called, in the sense of move semantics. After returning, the original promise is no longer + // valid, but `then()` returns a new promise. + // + // *Advanced implementation tips:* Most users will never need to worry about the below, but + // it is good to be aware of. + // + // As an optimization, if the callback function `func` does _not_ return another promise, then + // execution of `func` itself may be delayed until its result is known to be needed. The + // expectation here is that `func` is just doing some transformation on the results, not + // scheduling any other actions, therefore the system doesn't need to be proactive about + // evaluating it. This way, a chain of trivial then() transformations can be executed all at + // once without repeatedly re-scheduling through the event loop. Use the `eagerlyEvaluate()` + // method to suppress this behavior. + // + // On the other hand, if `func` _does_ return another promise, then the system evaluates `func` + // as soon as possible, because the promise it returns might be for a newly-scheduled + // long-running asynchronous task. + // + // As another optimization, when a callback function registered with `then()` is actually + // scheduled, it is scheduled to occur immediately, preempting other work in the event queue. + // This allows a long chain of `then`s to execute all at once, improving cache locality by + // clustering operations on the same data. However, this implies that starvation can occur + // if a chain of `then()`s takes a very long time to execute without ever stopping to wait for + // actual I/O. To solve this, use `kj::evalLater()` to yield control; this way, all other events + // in the queue will get a chance to run before your callback is executed. + + Promise ignoreResult() KJ_WARN_UNUSED_RESULT { return then([](T&&) {}); } + // Convenience method to convert the promise to a void promise by ignoring the return value. + // + // You must still wait on the returned promise if you want the task to execute. + + template + Promise catch_(ErrorFunc&& errorHandler) KJ_WARN_UNUSED_RESULT; + // Equivalent to `.then(identityFunc, errorHandler)`, where `identifyFunc` is a function that + // just returns its input. + + T wait(WaitScope& waitScope); + // Run the event loop until the promise is fulfilled, then return its result. If the promise + // is rejected, throw an exception. + // + // wait() is primarily useful at the top level of a program -- typically, within the function + // that allocated the EventLoop. For example, a program that performs one or two RPCs and then + // exits would likely use wait() in its main() function to wait on each RPC. On the other hand, + // server-side code generally cannot use wait(), because it has to be able to accept multiple + // requests at once. + // + // If the promise is rejected, `wait()` throws an exception. If the program was compiled without + // exceptions (-fno-exceptions), this will usually abort. In this case you really should first + // use `then()` to set an appropriate handler for the exception case, so that the promise you + // actually wait on never throws. + // + // `waitScope` is an object proving that the caller is in a scope where wait() is allowed. By + // convention, any function which might call wait(), or which might call another function which + // might call wait(), must take `WaitScope&` as one of its parameters. This is needed for two + // reasons: + // * `wait()` is not allowed during an event callback, because event callbacks are themselves + // called during some other `wait()`, and such recursive `wait()`s would only be able to + // complete in LIFO order, which might mean that the outer `wait()` ends up waiting longer + // than it is supposed to. To prevent this, a `WaitScope` cannot be constructed or used during + // an event callback. + // * Since `wait()` runs the event loop, unrelated event callbacks may execute before `wait()` + // returns. This means that anyone calling `wait()` must be reentrant -- state may change + // around them in arbitrary ways. Therefore, callers really need to know if a function they + // are calling might wait(), and the `WaitScope&` parameter makes this clear. + // + // TODO(someday): Implement fibers, and let them call wait() even when they are handling an + // event. + + ForkedPromise fork() KJ_WARN_UNUSED_RESULT; + // Forks the promise, so that multiple different clients can independently wait on the result. + // `T` must be copy-constructable for this to work. Or, in the special case where `T` is + // `Own`, `U` must have a method `Own addRef()` which returns a new reference to the same + // (or an equivalent) object (probably implemented via reference counting). + + _::SplitTuplePromise split(); + // Split a promise for a tuple into a tuple of promises. + // + // E.g. if you have `Promise>`, `split()` returns + // `kj::Tuple, Promise>`. + + Promise exclusiveJoin(Promise&& other) KJ_WARN_UNUSED_RESULT; + // Return a new promise that resolves when either the original promise resolves or `other` + // resolves (whichever comes first). The promise that didn't resolve first is canceled. + + // TODO(someday): inclusiveJoin(), or perhaps just join(), which waits for both completions + // and produces a tuple? + + template + Promise attach(Attachments&&... attachments) KJ_WARN_UNUSED_RESULT; + // "Attaches" one or more movable objects (often, Owns) to the promise, such that they will + // be destroyed when the promise resolves. This is useful when a promise's callback contains + // pointers into some object and you want to make sure the object still exists when the callback + // runs -- after calling then(), use attach() to add necessary objects to the result. + + template + Promise eagerlyEvaluate(ErrorFunc&& errorHandler) KJ_WARN_UNUSED_RESULT; + Promise eagerlyEvaluate(decltype(nullptr)) KJ_WARN_UNUSED_RESULT; + // Force eager evaluation of this promise. Use this if you are going to hold on to the promise + // for awhile without consuming the result, but you want to make sure that the system actually + // processes it. + // + // `errorHandler` is a function that takes `kj::Exception&&`, like the second parameter to + // `then()`, except that it must return void. We make you specify this because otherwise it's + // easy to forget to handle errors in a promise that you never use. You may specify nullptr for + // the error handler if you are sure that ignoring errors is fine, or if you know that you'll + // eventually wait on the promise somewhere. + + template + void detach(ErrorFunc&& errorHandler); + // Allows the promise to continue running in the background until it completes or the + // `EventLoop` is destroyed. Be careful when using this: since you can no longer cancel this + // promise, you need to make sure that the promise owns all the objects it touches or make sure + // those objects outlive the EventLoop. + // + // `errorHandler` is a function that takes `kj::Exception&&`, like the second parameter to + // `then()`, except that it must return void. + // + // This function exists mainly to implement the Cap'n Proto requirement that RPC calls cannot be + // canceled unless the callee explicitly permits it. + + kj::String trace(); + // Returns a dump of debug info about this promise. Not for production use. Requires RTTI. + // This method does NOT consume the promise as other methods do. + +private: + Promise(bool, Own<_::PromiseNode>&& node): PromiseBase(kj::mv(node)) {} + // Second parameter prevent ambiguity with immediate-value constructor. + + template + friend class Promise; + friend class EventLoop; + template + friend Promise newAdaptedPromise(Params&&... adapterConstructorParams); + template + friend PromiseFulfillerPair newPromiseAndFulfiller(); + template + friend class _::ForkHub; + friend class _::TaskSetImpl; + friend Promise _::yield(); + friend class _::NeverDone; + template + friend Promise> joinPromises(Array>&& promises); + friend Promise joinPromises(Array>&& promises); +}; + +template +class ForkedPromise { + // The result of `Promise::fork()` and `EventLoop::fork()`. Allows branches to be created. + // Like `Promise`, this is a pass-by-move type. + +public: + inline ForkedPromise(decltype(nullptr)) {} + + Promise addBranch(); + // Add a new branch to the fork. The branch is equivalent to the original promise. + +private: + Own<_::ForkHub<_::FixVoid>> hub; + + inline ForkedPromise(bool, Own<_::ForkHub<_::FixVoid>>&& hub): hub(kj::mv(hub)) {} + + friend class Promise; + friend class EventLoop; +}; + +constexpr _::Void READY_NOW = _::Void(); +// Use this when you need a Promise that is already fulfilled -- this value can be implicitly +// cast to `Promise`. + +constexpr _::NeverDone NEVER_DONE = _::NeverDone(); +// The opposite of `READY_NOW`, return this when the promise should never resolve. This can be +// implicitly converted to any promise type. You may also call `NEVER_DONE.wait()` to wait +// forever (useful for servers). + +template +PromiseForResult evalLater(Func&& func) KJ_WARN_UNUSED_RESULT; +// Schedule for the given zero-parameter function to be executed in the event loop at some +// point in the near future. Returns a Promise for its result -- or, if `func()` itself returns +// a promise, `evalLater()` returns a Promise for the result of resolving that promise. +// +// Example usage: +// Promise x = evalLater([]() { return 123; }); +// +// The above is exactly equivalent to: +// Promise x = Promise(READY_NOW).then([]() { return 123; }); +// +// If the returned promise is destroyed before the callback runs, the callback will be canceled +// (never called). +// +// If you schedule several evaluations with `evalLater` during the same callback, they are +// guaranteed to be executed in order. + +template +PromiseForResult evalNow(Func&& func) KJ_WARN_UNUSED_RESULT; +// Run `func()` and return a promise for its result. `func()` executes before `evalNow()` returns. +// If `func()` throws an exception, the exception is caught and wrapped in a promise -- this is the +// main reason why `evalNow()` is useful. + +template +Promise> joinPromises(Array>&& promises); +// Join an array of promises into a promise for an array. + +// ======================================================================================= +// Hack for creating a lambda that holds an owned pointer. + +template +class CaptureByMove { +public: + inline CaptureByMove(Func&& func, MovedParam&& param) + : func(kj::mv(func)), param(kj::mv(param)) {} + + template + inline auto operator()(Params&&... params) + -> decltype(kj::instance()(kj::instance(), kj::fwd(params)...)) { + return func(kj::mv(param), kj::fwd(params)...); + } + +private: + Func func; + MovedParam param; +}; + +template +inline CaptureByMove> mvCapture(MovedParam&& param, Func&& func) { + // Hack to create a "lambda" which captures a variable by moving it rather than copying or + // referencing. C++14 generalized captures should make this obsolete, but for now in C++11 this + // is commonly needed for Promise continuations that own their state. Example usage: + // + // Own ptr = makeFoo(); + // Promise promise = callRpc(); + // promise.then(mvCapture(ptr, [](Own&& ptr, int result) { + // return ptr->finish(result); + // })); + + return CaptureByMove>(kj::fwd(func), kj::mv(param)); +} + +// ======================================================================================= +// Advanced promise construction + +template +class PromiseFulfiller { + // A callback which can be used to fulfill a promise. Only the first call to fulfill() or + // reject() matters; subsequent calls are ignored. + +public: + virtual void fulfill(T&& value) = 0; + // Fulfill the promise with the given value. + + virtual void reject(Exception&& exception) = 0; + // Reject the promise with an error. + + virtual bool isWaiting() = 0; + // Returns true if the promise is still unfulfilled and someone is potentially waiting for it. + // Returns false if fulfill()/reject() has already been called *or* if the promise to be + // fulfilled has been discarded and therefore the result will never be used anyway. + + template + bool rejectIfThrows(Func&& func); + // Call the function (with no arguments) and return true. If an exception is thrown, call + // `fulfiller.reject()` and then return false. When compiled with exceptions disabled, + // non-fatal exceptions are still detected and handled correctly. +}; + +template <> +class PromiseFulfiller { + // Specialization of PromiseFulfiller for void promises. See PromiseFulfiller. + +public: + virtual void fulfill(_::Void&& value = _::Void()) = 0; + // Call with zero parameters. The parameter is a dummy that only exists so that subclasses don't + // have to specialize for . + + virtual void reject(Exception&& exception) = 0; + virtual bool isWaiting() = 0; + + template + bool rejectIfThrows(Func&& func); +}; + +template +Promise newAdaptedPromise(Params&&... adapterConstructorParams); +// Creates a new promise which owns an instance of `Adapter` which encapsulates the operation +// that will eventually fulfill the promise. This is primarily useful for adapting non-KJ +// asynchronous APIs to use promises. +// +// An instance of `Adapter` will be allocated and owned by the returned `Promise`. A +// `PromiseFulfiller&` will be passed as the first parameter to the adapter's constructor, +// and `adapterConstructorParams` will be forwarded as the subsequent parameters. The adapter +// is expected to perform some asynchronous operation and call the `PromiseFulfiller` once +// it is finished. +// +// The adapter is destroyed when its owning Promise is destroyed. This may occur before the +// Promise has been fulfilled. In this case, the adapter's destructor should cancel the +// asynchronous operation. Once the adapter is destroyed, the fulfillment callback cannot be +// called. +// +// An adapter implementation should be carefully written to ensure that it cannot accidentally +// be left unfulfilled permanently because of an exception. Consider making liberal use of +// `PromiseFulfiller::rejectIfThrows()`. + +template +struct PromiseFulfillerPair { + Promise<_::JoinPromises> promise; + Own> fulfiller; +}; + +template +PromiseFulfillerPair newPromiseAndFulfiller(); +// Construct a Promise and a separate PromiseFulfiller which can be used to fulfill the promise. +// If the PromiseFulfiller is destroyed before either of its methods are called, the Promise is +// implicitly rejected. +// +// Although this function is easier to use than `newAdaptedPromise()`, it has the serious drawback +// that there is no way to handle cancellation (i.e. detect when the Promise is discarded). +// +// You can arrange to fulfill a promise with another promise by using a promise type for T. E.g. +// `newPromiseAndFulfiller>()` will produce a promise of type `Promise` but the +// fulfiller will be of type `PromiseFulfiller>`. Thus you pass a `Promise` to the +// `fulfill()` callback, and the promises are chained. + +// ======================================================================================= +// TaskSet + +class TaskSet { + // Holds a collection of Promises and ensures that each executes to completion. Memory + // associated with each promise is automatically freed when the promise completes. Destroying + // the TaskSet itself automatically cancels all unfinished promises. + // + // This is useful for "daemon" objects that perform background tasks which aren't intended to + // fulfill any particular external promise, but which may need to be canceled (and thus can't + // use `Promise::detach()`). The daemon object holds a TaskSet to collect these tasks it is + // working on. This way, if the daemon itself is destroyed, the TaskSet is detroyed as well, + // and everything the daemon is doing is canceled. + +public: + class ErrorHandler { + public: + virtual void taskFailed(kj::Exception&& exception) = 0; + }; + + TaskSet(ErrorHandler& errorHandler); + // `loop` will be used to wait on promises. `errorHandler` will be executed any time a task + // throws an exception, and will execute within the given EventLoop. + + ~TaskSet() noexcept(false); + + void add(Promise&& promise); + + kj::String trace(); + // Return debug info about all promises currently in the TaskSet. + +private: + Own<_::TaskSetImpl> impl; +}; + +// ======================================================================================= +// The EventLoop class + +class EventPort { + // Interfaces between an `EventLoop` and events originating from outside of the loop's thread. + // All such events come in through the `EventPort` implementation. + // + // An `EventPort` implementation may interface with low-level operating system APIs and/or other + // threads. You can also write an `EventPort` which wraps some other (non-KJ) event loop + // framework, allowing the two to coexist in a single thread. + +public: + virtual bool wait() = 0; + // Wait for an external event to arrive, sleeping if necessary. Once at least one event has + // arrived, queue it to the event loop (e.g. by fulfilling a promise) and return. + // + // This is called during `Promise::wait()` whenever the event queue becomes empty, in order to + // wait for new events to populate the queue. + // + // It is safe to return even if nothing has actually been queued, so long as calling `wait()` in + // a loop will eventually sleep. (That is to say, false positives are fine.) + // + // Returns true if wake() has been called from another thread. (Precisely, returns true if + // no previous call to wait `wait()` nor `poll()` has returned true since `wake()` was last + // called.) + + virtual bool poll() = 0; + // Check if any external events have arrived, but do not sleep. If any events have arrived, + // add them to the event queue (e.g. by fulfilling promises) before returning. + // + // This may be called during `Promise::wait()` when the EventLoop has been executing for a while + // without a break but is still non-empty. + // + // Returns true if wake() has been called from another thread. (Precisely, returns true if + // no previous call to wait `wait()` nor `poll()` has returned true since `wake()` was last + // called.) + + virtual void setRunnable(bool runnable); + // Called to notify the `EventPort` when the `EventLoop` has work to do; specifically when it + // transitions from empty -> runnable or runnable -> empty. This is typically useful when + // integrating with an external event loop; if the loop is currently runnable then you should + // arrange to call run() on it soon. The default implementation does nothing. + + virtual void wake() const; + // Wake up the EventPort's thread from another thread. + // + // Unlike all other methods on this interface, `wake()` may be called from another thread, hence + // it is `const`. + // + // Technically speaking, `wake()` causes the target thread to cease sleeping and not to sleep + // again until `wait()` or `poll()` has returned true at least once. + // + // The default implementation throws an UNIMPLEMENTED exception. +}; + +class EventLoop { + // Represents a queue of events being executed in a loop. Most code won't interact with + // EventLoop directly, but instead use `Promise`s to interact with it indirectly. See the + // documentation for `Promise`. + // + // Each thread can have at most one current EventLoop. To make an `EventLoop` current for + // the thread, create a `WaitScope`. Async APIs require that the thread has a current EventLoop, + // or they will throw exceptions. APIs that use `Promise::wait()` additionally must explicitly + // be passed a reference to the `WaitScope` to make the caller aware that they might block. + // + // Generally, you will want to construct an `EventLoop` at the top level of your program, e.g. + // in the main() function, or in the start function of a thread. You can then use it to + // construct some promises and wait on the result. Example: + // + // int main() { + // // `loop` becomes the official EventLoop for the thread. + // MyEventPort eventPort; + // EventLoop loop(eventPort); + // + // // Now we can call an async function. + // Promise textPromise = getHttp("http://example.com"); + // + // // And we can wait for the promise to complete. Note that you can only use `wait()` + // // from the top level, not from inside a promise callback. + // String text = textPromise.wait(); + // print(text); + // return 0; + // } + // + // Most applications that do I/O will prefer to use `setupAsyncIo()` from `async-io.h` rather + // than allocate an `EventLoop` directly. + +public: + EventLoop(); + // Construct an `EventLoop` which does not receive external events at all. + + explicit EventLoop(EventPort& port); + // Construct an `EventLoop` which receives external events through the given `EventPort`. + + ~EventLoop() noexcept(false); + + void run(uint maxTurnCount = maxValue); + // Run the event loop for `maxTurnCount` turns or until there is nothing left to be done, + // whichever comes first. This never calls the `EventPort`'s `sleep()` or `poll()`. It will + // call the `EventPort`'s `setRunnable(false)` if the queue becomes empty. + + bool isRunnable(); + // Returns true if run() would currently do anything, or false if the queue is empty. + +private: + EventPort& port; + + bool running = false; + // True while looping -- wait() is then not allowed. + + bool lastRunnableState = false; + // What did we last pass to port.setRunnable()? + + _::Event* head = nullptr; + _::Event** tail = &head; + _::Event** depthFirstInsertPoint = &head; + + Own<_::TaskSetImpl> daemons; + + bool turn(); + void setRunnable(bool runnable); + void enterScope(); + void leaveScope(); + + friend void _::detach(kj::Promise&& promise); + friend void _::waitImpl(Own<_::PromiseNode>&& node, _::ExceptionOrValue& result, + WaitScope& waitScope); + friend class _::Event; + friend class WaitScope; +}; + +class WaitScope { + // Represents a scope in which asynchronous programming can occur. A `WaitScope` should usually + // be allocated on the stack and serves two purposes: + // * While the `WaitScope` exists, its `EventLoop` is registered as the current loop for the + // thread. Most operations dealing with `Promise` (including all of its methods) do not work + // unless the thread has a current `EventLoop`. + // * `WaitScope` may be passed to `Promise::wait()` to synchronously wait for a particular + // promise to complete. See `Promise::wait()` for an extended discussion. + +public: + inline explicit WaitScope(EventLoop& loop): loop(loop) { loop.enterScope(); } + inline ~WaitScope() { loop.leaveScope(); } + KJ_DISALLOW_COPY(WaitScope); + +private: + EventLoop& loop; + friend class EventLoop; + friend void _::waitImpl(Own<_::PromiseNode>&& node, _::ExceptionOrValue& result, + WaitScope& waitScope); +}; + +} // namespace kj + +#include "async-inl.h" + +#endif // KJ_ASYNC_H_ diff --git a/phonelibs/capnp-cpp/include/kj/common.h b/phonelibs/capnp-cpp/include/kj/common.h new file mode 100644 index 00000000000000..4a908ae0007fd7 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/common.h @@ -0,0 +1,1400 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// Header that should be #included by everyone. +// +// This defines very simple utilities that are widely applicable. + +#ifndef KJ_COMMON_H_ +#define KJ_COMMON_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#ifndef KJ_NO_COMPILER_CHECK +#if __cplusplus < 201103L && !__CDT_PARSER__ && !_MSC_VER + #error "This code requires C++11. Either your compiler does not support it or it is not enabled." + #ifdef __GNUC__ + // Compiler claims compatibility with GCC, so presumably supports -std. + #error "Pass -std=c++11 on the compiler command line to enable C++11." + #endif +#endif + +#ifdef __GNUC__ + #if __clang__ + #if __clang_major__ < 3 || (__clang_major__ == 3 && __clang_minor__ < 2) + #warning "This library requires at least Clang 3.2." + #elif defined(__apple_build_version__) && __apple_build_version__ <= 4250028 + #warning "This library requires at least Clang 3.2. XCode 4.6's Clang, which claims to be "\ + "version 4.2 (wat?), is actually built from some random SVN revision between 3.1 "\ + "and 3.2. Unfortunately, it is insufficient for compiling this library. You can "\ + "download the real Clang 3.2 (or newer) from the Clang web site. Step-by-step "\ + "instructions can be found in Cap'n Proto's documentation: "\ + "http://kentonv.github.io/capnproto/install.html#clang_32_on_mac_osx" + #elif __cplusplus >= 201103L && !__has_include() + #warning "Your compiler supports C++11 but your C++ standard library does not. If your "\ + "system has libc++ installed (as should be the case on e.g. Mac OSX), try adding "\ + "-stdlib=libc++ to your CXXFLAGS." + #endif + #else + #if __GNUC__ < 4 || (__GNUC__ == 4 && __GNUC_MINOR__ < 7) + #warning "This library requires at least GCC 4.7." + #endif + #endif +#elif defined(_MSC_VER) + #if _MSC_VER < 1900 + #error "You need Visual Studio 2015 or better to compile this code." + #endif +#else + #warning "I don't recognize your compiler. As of this writing, Clang and GCC are the only "\ + "known compilers with enough C++11 support for this library. "\ + "#define KJ_NO_COMPILER_CHECK to make this warning go away." +#endif +#endif + +#include +#include + +#if __linux__ && __cplusplus > 201200L +// Hack around stdlib bug with C++14 that exists on some Linux systems. +// Apparently in this mode the C library decides not to define gets() but the C++ library still +// tries to import it into the std namespace. This bug has been fixed at the source but is still +// widely present in the wild e.g. on Ubuntu 14.04. +#undef _GLIBCXX_HAVE_GETS +#endif + +#if defined(_MSC_VER) +#ifndef NOMINMAX +#define NOMINMAX 1 +#endif +#include // __popcnt +#endif + +// ======================================================================================= + +namespace kj { + +typedef unsigned int uint; +typedef unsigned char byte; + +// ======================================================================================= +// Common macros, especially for common yet compiler-specific features. + +// Detect whether RTTI and exceptions are enabled, assuming they are unless we have specific +// evidence to the contrary. Clients can always define KJ_NO_RTTI or KJ_NO_EXCEPTIONS explicitly +// to override these checks. +#ifdef __GNUC__ + #if !defined(KJ_NO_RTTI) && !__GXX_RTTI + #define KJ_NO_RTTI 1 + #endif + #if !defined(KJ_NO_EXCEPTIONS) && !__EXCEPTIONS + #define KJ_NO_EXCEPTIONS 1 + #endif +#elif defined(_MSC_VER) + #if !defined(KJ_NO_RTTI) && !defined(_CPPRTTI) + #define KJ_NO_RTTI 1 + #endif + #if !defined(KJ_NO_EXCEPTIONS) && !defined(_CPPUNWIND) + #define KJ_NO_EXCEPTIONS 1 + #endif +#endif + +#if !defined(KJ_DEBUG) && !defined(KJ_NDEBUG) +// Heuristically decide whether to enable debug mode. If DEBUG or NDEBUG is defined, use that. +// Otherwise, fall back to checking whether optimization is enabled. +#if defined(DEBUG) || defined(_DEBUG) +#define KJ_DEBUG +#elif defined(NDEBUG) +#define KJ_NDEBUG +#elif __OPTIMIZE__ +#define KJ_NDEBUG +#else +#define KJ_DEBUG +#endif +#endif + +#define KJ_DISALLOW_COPY(classname) \ + classname(const classname&) = delete; \ + classname& operator=(const classname&) = delete +// Deletes the implicit copy constructor and assignment operator. + +#ifdef __GNUC__ +#define KJ_LIKELY(condition) __builtin_expect(condition, true) +#define KJ_UNLIKELY(condition) __builtin_expect(condition, false) +// Branch prediction macros. Evaluates to the condition given, but also tells the compiler that we +// expect the condition to be true/false enough of the time that it's worth hard-coding branch +// prediction. +#else +#define KJ_LIKELY(condition) (condition) +#define KJ_UNLIKELY(condition) (condition) +#endif + +#if defined(KJ_DEBUG) || __NO_INLINE__ +#define KJ_ALWAYS_INLINE(...) inline __VA_ARGS__ +// Don't force inline in debug mode. +#else +#if defined(_MSC_VER) +#define KJ_ALWAYS_INLINE(...) __forceinline __VA_ARGS__ +#else +#define KJ_ALWAYS_INLINE(...) inline __VA_ARGS__ __attribute__((always_inline)) +#endif +// Force a function to always be inlined. Apply only to the prototype, not to the definition. +#endif + +#if defined(_MSC_VER) +#define KJ_NOINLINE __declspec(noinline) +#else +#define KJ_NOINLINE __attribute__((noinline)) +#endif + +#if defined(_MSC_VER) +#define KJ_NORETURN(prototype) __declspec(noreturn) prototype +#define KJ_UNUSED +#define KJ_WARN_UNUSED_RESULT +// TODO(msvc): KJ_WARN_UNUSED_RESULT can use _Check_return_ on MSVC, but it's a prefix, so +// wrapping the whole prototype is needed. http://msdn.microsoft.com/en-us/library/jj159529.aspx +// Similarly, KJ_UNUSED could use __pragma(warning(suppress:...)), but again that's a prefix. +#else +#define KJ_NORETURN(prototype) prototype __attribute__((noreturn)) +#define KJ_UNUSED __attribute__((unused)) +#define KJ_WARN_UNUSED_RESULT __attribute__((warn_unused_result)) +#endif + +#if __clang__ +#define KJ_UNUSED_MEMBER __attribute__((unused)) +// Inhibits "unused" warning for member variables. Only Clang produces such a warning, while GCC +// complains if the attribute is set on members. +#else +#define KJ_UNUSED_MEMBER +#endif + +#if __clang__ +#define KJ_DEPRECATED(reason) \ + __attribute__((deprecated(reason))) +#define KJ_UNAVAILABLE(reason) \ + __attribute__((unavailable(reason))) +#elif __GNUC__ +#define KJ_DEPRECATED(reason) \ + __attribute__((deprecated)) +#define KJ_UNAVAILABLE(reason) +#else +#define KJ_DEPRECATED(reason) +#define KJ_UNAVAILABLE(reason) +// TODO(msvc): Again, here, MSVC prefers a prefix, __declspec(deprecated). +#endif + +namespace _ { // private + +KJ_NORETURN(void inlineRequireFailure( + const char* file, int line, const char* expectation, const char* macroArgs, + const char* message = nullptr)); + +KJ_NORETURN(void unreachable()); + +} // namespace _ (private) + +#ifdef KJ_DEBUG +#if _MSC_VER +#define KJ_IREQUIRE(condition, ...) \ + if (KJ_LIKELY(condition)); else ::kj::_::inlineRequireFailure( \ + __FILE__, __LINE__, #condition, "" #__VA_ARGS__, __VA_ARGS__) +// Version of KJ_DREQUIRE() which is safe to use in headers that are #included by users. Used to +// check preconditions inside inline methods. KJ_IREQUIRE is particularly useful in that +// it will be enabled depending on whether the application is compiled in debug mode rather than +// whether libkj is. +#else +#define KJ_IREQUIRE(condition, ...) \ + if (KJ_LIKELY(condition)); else ::kj::_::inlineRequireFailure( \ + __FILE__, __LINE__, #condition, #__VA_ARGS__, ##__VA_ARGS__) +// Version of KJ_DREQUIRE() which is safe to use in headers that are #included by users. Used to +// check preconditions inside inline methods. KJ_IREQUIRE is particularly useful in that +// it will be enabled depending on whether the application is compiled in debug mode rather than +// whether libkj is. +#endif +#else +#define KJ_IREQUIRE(condition, ...) +#endif + +#define KJ_IASSERT KJ_IREQUIRE + +#define KJ_UNREACHABLE ::kj::_::unreachable(); +// Put this on code paths that cannot be reached to suppress compiler warnings about missing +// returns. + +#if __clang__ +#define KJ_CLANG_KNOWS_THIS_IS_UNREACHABLE_BUT_GCC_DOESNT +#else +#define KJ_CLANG_KNOWS_THIS_IS_UNREACHABLE_BUT_GCC_DOESNT KJ_UNREACHABLE +#endif + +// #define KJ_STACK_ARRAY(type, name, size, minStack, maxStack) +// +// Allocate an array, preferably on the stack, unless it is too big. On GCC this will use +// variable-sized arrays. For other compilers we could just use a fixed-size array. `minStack` +// is the stack array size to use if variable-width arrays are not supported. `maxStack` is the +// maximum stack array size if variable-width arrays *are* supported. +#if __GNUC__ && !__clang__ +#define KJ_STACK_ARRAY(type, name, size, minStack, maxStack) \ + size_t name##_size = (size); \ + bool name##_isOnStack = name##_size <= (maxStack); \ + type name##_stack[name##_isOnStack ? size : 0]; \ + ::kj::Array name##_heap = name##_isOnStack ? \ + nullptr : kj::heapArray(name##_size); \ + ::kj::ArrayPtr name = name##_isOnStack ? \ + kj::arrayPtr(name##_stack, name##_size) : name##_heap +#else +#define KJ_STACK_ARRAY(type, name, size, minStack, maxStack) \ + size_t name##_size = (size); \ + bool name##_isOnStack = name##_size <= (minStack); \ + type name##_stack[minStack]; \ + ::kj::Array name##_heap = name##_isOnStack ? \ + nullptr : kj::heapArray(name##_size); \ + ::kj::ArrayPtr name = name##_isOnStack ? \ + kj::arrayPtr(name##_stack, name##_size) : name##_heap +#endif + +#define KJ_CONCAT_(x, y) x##y +#define KJ_CONCAT(x, y) KJ_CONCAT_(x, y) +#define KJ_UNIQUE_NAME(prefix) KJ_CONCAT(prefix, __LINE__) +// Create a unique identifier name. We use concatenate __LINE__ rather than __COUNTER__ so that +// the name can be used multiple times in the same macro. + +#if _MSC_VER + +#define KJ_CONSTEXPR(...) __VA_ARGS__ +// Use in cases where MSVC barfs on constexpr. A replacement keyword (e.g. "const") can be +// provided, or just leave blank to remove the keyword entirely. +// +// TODO(msvc): Remove this hack once MSVC fully supports constexpr. + +#ifndef __restrict__ +#define __restrict__ __restrict +// TODO(msvc): Would it be better to define a KJ_RESTRICT macro? +#endif + +#pragma warning(disable: 4521 4522) +// This warning complains when there are two copy constructors, one for a const reference and +// one for a non-const reference. It is often quite necessary to do this in wrapper templates, +// therefore this warning is dumb and we disable it. + +#pragma warning(disable: 4458) +// Warns when a parameter name shadows a class member. Unfortunately my code does this a lot, +// since I don't use a special name format for members. + +#else // _MSC_VER +#define KJ_CONSTEXPR(...) constexpr +#endif + +// ======================================================================================= +// Template metaprogramming helpers. + +template struct NoInfer_ { typedef T Type; }; +template using NoInfer = typename NoInfer_::Type; +// Use NoInfer::Type in place of T for a template function parameter to prevent inference of +// the type based on the parameter value. + +template struct RemoveConst_ { typedef T Type; }; +template struct RemoveConst_ { typedef T Type; }; +template using RemoveConst = typename RemoveConst_::Type; + +template struct IsLvalueReference_ { static constexpr bool value = false; }; +template struct IsLvalueReference_ { static constexpr bool value = true; }; +template +inline constexpr bool isLvalueReference() { return IsLvalueReference_::value; } + +template struct Decay_ { typedef T Type; }; +template struct Decay_ { typedef typename Decay_::Type Type; }; +template struct Decay_ { typedef typename Decay_::Type Type; }; +template struct Decay_ { typedef typename Decay_::Type Type; }; +template struct Decay_ { typedef typename Decay_::Type Type; }; +template struct Decay_ { typedef typename Decay_::Type Type; }; +template struct Decay_ { typedef typename Decay_::Type Type; }; +template struct Decay_ { typedef typename Decay_::Type Type; }; +template struct Decay_ { typedef typename Decay_::Type Type; }; +template using Decay = typename Decay_::Type; + +template struct EnableIf_; +template <> struct EnableIf_ { typedef void Type; }; +template using EnableIf = typename EnableIf_::Type; +// Use like: +// +// template ()> +// void func(T&& t); + +template struct VoidSfinae_ { using Type = void; }; +template using VoidSfinae = typename VoidSfinae_::Type; +// Note: VoidSfinae is std::void_t from C++17. + +template +T instance() noexcept; +// Like std::declval, but doesn't transform T into an rvalue reference. If you want that, specify +// instance(). + +struct DisallowConstCopy { + // Inherit from this, or declare a member variable of this type, to prevent the class from being + // copyable from a const reference -- instead, it will only be copyable from non-const references. + // This is useful for enforcing transitive constness of contained pointers. + // + // For example, say you have a type T which contains a pointer. T has non-const methods which + // modify the value at that pointer, but T's const methods are designed to allow reading only. + // Unfortunately, if T has a regular copy constructor, someone can simply make a copy of T and + // then use it to modify the pointed-to value. However, if T inherits DisallowConstCopy, then + // callers will only be able to copy non-const instances of T. Ideally, there is some + // parallel type ImmutableT which is like a version of T that only has const methods, and can + // be copied from a const T. + // + // Note that due to C++ rules about implicit copy constructors and assignment operators, any + // type that contains or inherits from a type that disallows const copies will also automatically + // disallow const copies. Hey, cool, that's exactly what we want. + +#if CAPNP_DEBUG_TYPES + // Alas! Declaring a defaulted non-const copy constructor tickles a bug which causes GCC and + // Clang to disagree on ABI, using different calling conventions to pass this type, leading to + // immediate segfaults. See: + // https://bugs.llvm.org/show_bug.cgi?id=23764 + // https://gcc.gnu.org/bugzilla/show_bug.cgi?id=58074 + // + // Because of this, we can't use this technique. We guard it by CAPNP_DEBUG_TYPES so that it + // still applies to the Cap'n Proto developers during internal testing. + + DisallowConstCopy() = default; + DisallowConstCopy(DisallowConstCopy&) = default; + DisallowConstCopy(DisallowConstCopy&&) = default; + DisallowConstCopy& operator=(DisallowConstCopy&) = default; + DisallowConstCopy& operator=(DisallowConstCopy&&) = default; +#endif +}; + +#if _MSC_VER + +#define KJ_CPCAP(obj) obj=::kj::cp(obj) +// TODO(msvc): MSVC refuses to invoke non-const versions of copy constructors in by-value lambda +// captures. Wrap your captured object in this macro to force the compiler to perform a copy. +// Example: +// +// struct Foo: DisallowConstCopy {}; +// Foo foo; +// auto lambda = [KJ_CPCAP(foo)] {}; + +#else + +#define KJ_CPCAP(obj) obj +// Clang and gcc both already perform copy capturing correctly with non-const copy constructors. + +#endif + +template +struct DisallowConstCopyIfNotConst: public DisallowConstCopy { + // Inherit from this when implementing a template that contains a pointer to T and which should + // enforce transitive constness. If T is a const type, this has no effect. Otherwise, it is + // an alias for DisallowConstCopy. +}; + +template +struct DisallowConstCopyIfNotConst {}; + +template struct IsConst_ { static constexpr bool value = false; }; +template struct IsConst_ { static constexpr bool value = true; }; +template constexpr bool isConst() { return IsConst_::value; } + +template struct EnableIfNotConst_ { typedef T Type; }; +template struct EnableIfNotConst_; +template using EnableIfNotConst = typename EnableIfNotConst_::Type; + +template struct EnableIfConst_; +template struct EnableIfConst_ { typedef T Type; }; +template using EnableIfConst = typename EnableIfConst_::Type; + +template struct RemoveConstOrDisable_ { struct Type; }; +template struct RemoveConstOrDisable_ { typedef T Type; }; +template using RemoveConstOrDisable = typename RemoveConstOrDisable_::Type; + +template struct IsReference_ { static constexpr bool value = false; }; +template struct IsReference_ { static constexpr bool value = true; }; +template constexpr bool isReference() { return IsReference_::value; } + +template +struct PropagateConst_ { typedef To Type; }; +template +struct PropagateConst_ { typedef const To Type; }; +template +using PropagateConst = typename PropagateConst_::Type; + +namespace _ { // private + +template +T refIfLvalue(T&&); + +} // namespace _ (private) + +#define KJ_DECLTYPE_REF(exp) decltype(::kj::_::refIfLvalue(exp)) +// Like decltype(exp), but if exp is an lvalue, produces a reference type. +// +// int i; +// decltype(i) i1(i); // i1 has type int. +// KJ_DECLTYPE_REF(i + 1) i2(i + 1); // i2 has type int. +// KJ_DECLTYPE_REF(i) i3(i); // i3 has type int&. +// KJ_DECLTYPE_REF(kj::mv(i)) i4(kj::mv(i)); // i4 has type int. + +template +struct CanConvert_ { + static int sfinae(T); + static bool sfinae(...); +}; + +template +constexpr bool canConvert() { + return sizeof(CanConvert_::sfinae(instance())) == sizeof(int); +} + +#if __GNUC__ && !__clang__ && __GNUC__ < 5 +template +constexpr bool canMemcpy() { + // Returns true if T can be copied using memcpy instead of using the copy constructor or + // assignment operator. + + // GCC 4 does not have __is_trivially_constructible and friends, and there doesn't seem to be + // any reliable alternative. __has_trivial_copy() and __has_trivial_assign() return the right + // thing at one point but later on they changed such that a deleted copy constructor was + // considered "trivial" (apparently technically correct, though useless). So, on GCC 4 we give up + // and assume we can't memcpy() at all, and must explicitly copy-construct everything. + return false; +} +#define KJ_ASSERT_CAN_MEMCPY(T) +#else +template +constexpr bool canMemcpy() { + // Returns true if T can be copied using memcpy instead of using the copy constructor or + // assignment operator. + + return __is_trivially_constructible(T, const T&) && __is_trivially_assignable(T, const T&); +} +#define KJ_ASSERT_CAN_MEMCPY(T) \ + static_assert(kj::canMemcpy(), "this code expects this type to be memcpy()-able"); +#endif + +// ======================================================================================= +// Equivalents to std::move() and std::forward(), since these are very commonly needed and the +// std header pulls in lots of other stuff. +// +// We use abbreviated names mv and fwd because these helpers (especially mv) are so commonly used +// that the cost of typing more letters outweighs the cost of being slightly harder to understand +// when first encountered. + +template constexpr T&& mv(T& t) noexcept { return static_cast(t); } +template constexpr T&& fwd(NoInfer& t) noexcept { return static_cast(t); } + +template constexpr T cp(T& t) noexcept { return t; } +template constexpr T cp(const T& t) noexcept { return t; } +// Useful to force a copy, particularly to pass into a function that expects T&&. + +template struct ChooseType_; +template struct ChooseType_ { typedef T Type; }; +template struct ChooseType_ { typedef T Type; }; +template struct ChooseType_ { typedef U Type; }; + +template +using WiderType = typename ChooseType_= sizeof(U)>::Type; + +template +inline constexpr auto min(T&& a, U&& b) -> WiderType, Decay> { + return a < b ? WiderType, Decay>(a) : WiderType, Decay>(b); +} + +template +inline constexpr auto max(T&& a, U&& b) -> WiderType, Decay> { + return a > b ? WiderType, Decay>(a) : WiderType, Decay>(b); +} + +template +inline constexpr size_t size(T (&arr)[s]) { return s; } +template +inline constexpr size_t size(T&& arr) { return arr.size(); } +// Returns the size of the parameter, whether the parameter is a regular C array or a container +// with a `.size()` method. + +class MaxValue_ { +private: + template + inline constexpr T maxSigned() const { + return (1ull << (sizeof(T) * 8 - 1)) - 1; + } + template + inline constexpr T maxUnsigned() const { + return ~static_cast(0u); + } + +public: +#define _kJ_HANDLE_TYPE(T) \ + inline constexpr operator signed T() const { return MaxValue_::maxSigned < signed T>(); } \ + inline constexpr operator unsigned T() const { return MaxValue_::maxUnsigned(); } + _kJ_HANDLE_TYPE(char) + _kJ_HANDLE_TYPE(short) + _kJ_HANDLE_TYPE(int) + _kJ_HANDLE_TYPE(long) + _kJ_HANDLE_TYPE(long long) +#undef _kJ_HANDLE_TYPE + + inline constexpr operator char() const { + // `char` is different from both `signed char` and `unsigned char`, and may be signed or + // unsigned on different platforms. Ugh. + return char(-1) < 0 ? MaxValue_::maxSigned() + : MaxValue_::maxUnsigned(); + } +}; + +class MinValue_ { +private: + template + inline constexpr T minSigned() const { + return 1ull << (sizeof(T) * 8 - 1); + } + template + inline constexpr T minUnsigned() const { + return 0u; + } + +public: +#define _kJ_HANDLE_TYPE(T) \ + inline constexpr operator signed T() const { return MinValue_::minSigned < signed T>(); } \ + inline constexpr operator unsigned T() const { return MinValue_::minUnsigned(); } + _kJ_HANDLE_TYPE(char) + _kJ_HANDLE_TYPE(short) + _kJ_HANDLE_TYPE(int) + _kJ_HANDLE_TYPE(long) + _kJ_HANDLE_TYPE(long long) +#undef _kJ_HANDLE_TYPE + + inline constexpr operator char() const { + // `char` is different from both `signed char` and `unsigned char`, and may be signed or + // unsigned on different platforms. Ugh. + return char(-1) < 0 ? MinValue_::minSigned() + : MinValue_::minUnsigned(); + } +}; + +static KJ_CONSTEXPR(const) MaxValue_ maxValue = MaxValue_(); +// A special constant which, when cast to an integer type, takes on the maximum possible value of +// that type. This is useful to use as e.g. a parameter to a function because it will be robust +// in the face of changes to the parameter's type. +// +// `char` is not supported, but `signed char` and `unsigned char` are. + +static KJ_CONSTEXPR(const) MinValue_ minValue = MinValue_(); +// A special constant which, when cast to an integer type, takes on the minimum possible value +// of that type. This is useful to use as e.g. a parameter to a function because it will be robust +// in the face of changes to the parameter's type. +// +// `char` is not supported, but `signed char` and `unsigned char` are. + +template +inline bool operator==(T t, MaxValue_) { return t == Decay(maxValue); } +template +inline bool operator==(T t, MinValue_) { return t == Decay(minValue); } + +template +inline constexpr unsigned long long maxValueForBits() { + // Get the maximum integer representable in the given number of bits. + + // 1ull << 64 is unfortunately undefined. + return (bits == 64 ? 0 : (1ull << bits)) - 1; +} + +struct ThrowOverflow { + // Functor which throws an exception complaining about integer overflow. Usually this is used + // with the interfaces in units.h, but is defined here because Cap'n Proto wants to avoid + // including units.h when not using CAPNP_DEBUG_TYPES. + void operator()() const; +}; + +#if __GNUC__ +inline constexpr float inf() { return __builtin_huge_valf(); } +inline constexpr float nan() { return __builtin_nanf(""); } + +#elif _MSC_VER + +// Do what MSVC math.h does +#pragma warning(push) +#pragma warning(disable: 4756) // "overflow in constant arithmetic" +inline constexpr float inf() { return (float)(1e300 * 1e300); } +#pragma warning(pop) + +float nan(); +// Unfortunatley, inf() * 0.0f produces a NaN with the sign bit set, whereas our preferred +// canonical NaN should not have the sign bit set. std::numeric_limits::quiet_NaN() +// returns the correct NaN, but we don't want to #include that here. So, we give up and make +// this out-of-line on MSVC. +// +// TODO(msvc): Can we do better? + +#else +#error "Not sure how to support your compiler." +#endif + +inline constexpr bool isNaN(float f) { return f != f; } +inline constexpr bool isNaN(double f) { return f != f; } + +inline int popCount(unsigned int x) { +#if defined(_MSC_VER) + return __popcnt(x); + // Note: __popcnt returns unsigned int, but the value is clearly guaranteed to fit into an int +#else + return __builtin_popcount(x); +#endif +} + +// ======================================================================================= +// Useful fake containers + +template +class Range { +public: + inline constexpr Range(const T& begin, const T& end): begin_(begin), end_(end) {} + inline explicit constexpr Range(const T& end): begin_(0), end_(end) {} + + class Iterator { + public: + Iterator() = default; + inline Iterator(const T& value): value(value) {} + + inline const T& operator* () const { return value; } + inline const T& operator[](size_t index) const { return value + index; } + inline Iterator& operator++() { ++value; return *this; } + inline Iterator operator++(int) { return Iterator(value++); } + inline Iterator& operator--() { --value; return *this; } + inline Iterator operator--(int) { return Iterator(value--); } + inline Iterator& operator+=(ptrdiff_t amount) { value += amount; return *this; } + inline Iterator& operator-=(ptrdiff_t amount) { value -= amount; return *this; } + inline Iterator operator+ (ptrdiff_t amount) const { return Iterator(value + amount); } + inline Iterator operator- (ptrdiff_t amount) const { return Iterator(value - amount); } + inline ptrdiff_t operator- (const Iterator& other) const { return value - other.value; } + + inline bool operator==(const Iterator& other) const { return value == other.value; } + inline bool operator!=(const Iterator& other) const { return value != other.value; } + inline bool operator<=(const Iterator& other) const { return value <= other.value; } + inline bool operator>=(const Iterator& other) const { return value >= other.value; } + inline bool operator< (const Iterator& other) const { return value < other.value; } + inline bool operator> (const Iterator& other) const { return value > other.value; } + + private: + T value; + }; + + inline Iterator begin() const { return Iterator(begin_); } + inline Iterator end() const { return Iterator(end_); } + + inline auto size() const -> decltype(instance() - instance()) { return end_ - begin_; } + +private: + T begin_; + T end_; +}; + +template +inline constexpr Range, Decay>> range(T begin, U end) { + return Range, Decay>>(begin, end); +} + +template +inline constexpr Range> range(T begin, T end) { return Range>(begin, end); } +// Returns a fake iterable container containing all values of T from `begin` (inclusive) to `end` +// (exclusive). Example: +// +// // Prints 1, 2, 3, 4, 5, 6, 7, 8, 9. +// for (int i: kj::range(1, 10)) { print(i); } + +template +inline constexpr Range> zeroTo(T end) { return Range>(end); } +// Returns a fake iterable container containing all values of T from zero (inclusive) to `end` +// (exclusive). Example: +// +// // Prints 0, 1, 2, 3, 4, 5, 6, 7, 8, 9. +// for (int i: kj::zeroTo(10)) { print(i); } + +template +inline constexpr Range indices(T&& container) { + // Shortcut for iterating over the indices of a container: + // + // for (size_t i: kj::indices(myArray)) { handle(myArray[i]); } + + return range(0, kj::size(container)); +} + +template +class Repeat { +public: + inline constexpr Repeat(const T& value, size_t count): value(value), count(count) {} + + class Iterator { + public: + Iterator() = default; + inline Iterator(const T& value, size_t index): value(value), index(index) {} + + inline const T& operator* () const { return value; } + inline const T& operator[](ptrdiff_t index) const { return value; } + inline Iterator& operator++() { ++index; return *this; } + inline Iterator operator++(int) { return Iterator(value, index++); } + inline Iterator& operator--() { --index; return *this; } + inline Iterator operator--(int) { return Iterator(value, index--); } + inline Iterator& operator+=(ptrdiff_t amount) { index += amount; return *this; } + inline Iterator& operator-=(ptrdiff_t amount) { index -= amount; return *this; } + inline Iterator operator+ (ptrdiff_t amount) const { return Iterator(value, index + amount); } + inline Iterator operator- (ptrdiff_t amount) const { return Iterator(value, index - amount); } + inline ptrdiff_t operator- (const Iterator& other) const { return index - other.index; } + + inline bool operator==(const Iterator& other) const { return index == other.index; } + inline bool operator!=(const Iterator& other) const { return index != other.index; } + inline bool operator<=(const Iterator& other) const { return index <= other.index; } + inline bool operator>=(const Iterator& other) const { return index >= other.index; } + inline bool operator< (const Iterator& other) const { return index < other.index; } + inline bool operator> (const Iterator& other) const { return index > other.index; } + + private: + T value; + size_t index; + }; + + inline Iterator begin() const { return Iterator(value, 0); } + inline Iterator end() const { return Iterator(value, count); } + + inline size_t size() const { return count; } + inline const T& operator[](ptrdiff_t) const { return value; } + +private: + T value; + size_t count; +}; + +template +inline constexpr Repeat> repeat(T&& value, size_t count) { + // Returns a fake iterable which contains `count` repeats of `value`. Useful for e.g. creating + // a bunch of spaces: `kj::repeat(' ', indent * 2)` + + return Repeat>(value, count); +} + +// ======================================================================================= +// Manually invoking constructors and destructors +// +// ctor(x, ...) and dtor(x) invoke x's constructor or destructor, respectively. + +// We want placement new, but we don't want to #include . operator new cannot be defined in +// a namespace, and defining it globally conflicts with the definition in . So we have to +// define a dummy type and an operator new that uses it. + +namespace _ { // private +struct PlacementNew {}; +} // namespace _ (private) +} // namespace kj + +inline void* operator new(size_t, kj::_::PlacementNew, void* __p) noexcept { + return __p; +} + +inline void operator delete(void*, kj::_::PlacementNew, void* __p) noexcept {} + +namespace kj { + +template +inline void ctor(T& location, Params&&... params) { + new (_::PlacementNew(), &location) T(kj::fwd(params)...); +} + +template +inline void dtor(T& location) { + location.~T(); +} + +// ======================================================================================= +// Maybe +// +// Use in cases where you want to indicate that a value may be null. Using Maybe instead of T* +// forces the caller to handle the null case in order to satisfy the compiler, thus reliably +// preventing null pointer dereferences at runtime. +// +// Maybe can be implicitly constructed from T and from nullptr. Additionally, it can be +// implicitly constructed from T*, in which case the pointer is checked for nullness at runtime. +// To read the value of a Maybe, do: +// +// KJ_IF_MAYBE(value, someFuncReturningMaybe()) { +// doSomething(*value); +// } else { +// maybeWasNull(); +// } +// +// KJ_IF_MAYBE's first parameter is a variable name which will be defined within the following +// block. The variable will behave like a (guaranteed non-null) pointer to the Maybe's value, +// though it may or may not actually be a pointer. +// +// Note that Maybe actually just wraps a pointer, whereas Maybe wraps a T and a boolean +// indicating nullness. + +template +class Maybe; + +namespace _ { // private + +template +class NullableValue { + // Class whose interface behaves much like T*, but actually contains an instance of T and a + // boolean flag indicating nullness. + +public: + inline NullableValue(NullableValue&& other) noexcept(noexcept(T(instance()))) + : isSet(other.isSet) { + if (isSet) { + ctor(value, kj::mv(other.value)); + } + } + inline NullableValue(const NullableValue& other) + : isSet(other.isSet) { + if (isSet) { + ctor(value, other.value); + } + } + inline NullableValue(NullableValue& other) + : isSet(other.isSet) { + if (isSet) { + ctor(value, other.value); + } + } + inline ~NullableValue() +#if _MSC_VER + // TODO(msvc): MSVC has a hard time with noexcept specifier expressions that are more complex + // than `true` or `false`. We had a workaround for VS2015, but VS2017 regressed. + noexcept(false) +#else + noexcept(noexcept(instance().~T())) +#endif + { + if (isSet) { + dtor(value); + } + } + + inline T& operator*() & { return value; } + inline const T& operator*() const & { return value; } + inline T&& operator*() && { return kj::mv(value); } + inline const T&& operator*() const && { return kj::mv(value); } + inline T* operator->() { return &value; } + inline const T* operator->() const { return &value; } + inline operator T*() { return isSet ? &value : nullptr; } + inline operator const T*() const { return isSet ? &value : nullptr; } + + template + inline T& emplace(Params&&... params) { + if (isSet) { + isSet = false; + dtor(value); + } + ctor(value, kj::fwd(params)...); + isSet = true; + return value; + } + +private: // internal interface used by friends only + inline NullableValue() noexcept: isSet(false) {} + inline NullableValue(T&& t) noexcept(noexcept(T(instance()))) + : isSet(true) { + ctor(value, kj::mv(t)); + } + inline NullableValue(T& t) + : isSet(true) { + ctor(value, t); + } + inline NullableValue(const T& t) + : isSet(true) { + ctor(value, t); + } + inline NullableValue(const T* t) + : isSet(t != nullptr) { + if (isSet) ctor(value, *t); + } + template + inline NullableValue(NullableValue&& other) noexcept(noexcept(T(instance()))) + : isSet(other.isSet) { + if (isSet) { + ctor(value, kj::mv(other.value)); + } + } + template + inline NullableValue(const NullableValue& other) + : isSet(other.isSet) { + if (isSet) { + ctor(value, other.value); + } + } + template + inline NullableValue(const NullableValue& other) + : isSet(other.isSet) { + if (isSet) { + ctor(value, *other.ptr); + } + } + inline NullableValue(decltype(nullptr)): isSet(false) {} + + inline NullableValue& operator=(NullableValue&& other) { + if (&other != this) { + // Careful about throwing destructors/constructors here. + if (isSet) { + isSet = false; + dtor(value); + } + if (other.isSet) { + ctor(value, kj::mv(other.value)); + isSet = true; + } + } + return *this; + } + + inline NullableValue& operator=(NullableValue& other) { + if (&other != this) { + // Careful about throwing destructors/constructors here. + if (isSet) { + isSet = false; + dtor(value); + } + if (other.isSet) { + ctor(value, other.value); + isSet = true; + } + } + return *this; + } + + inline NullableValue& operator=(const NullableValue& other) { + if (&other != this) { + // Careful about throwing destructors/constructors here. + if (isSet) { + isSet = false; + dtor(value); + } + if (other.isSet) { + ctor(value, other.value); + isSet = true; + } + } + return *this; + } + + inline bool operator==(decltype(nullptr)) const { return !isSet; } + inline bool operator!=(decltype(nullptr)) const { return isSet; } + +private: + bool isSet; + +#if _MSC_VER +#pragma warning(push) +#pragma warning(disable: 4624) +// Warns that the anonymous union has a deleted destructor when T is non-trivial. This warning +// seems broken. +#endif + + union { + T value; + }; + +#if _MSC_VER +#pragma warning(pop) +#endif + + friend class kj::Maybe; + template + friend NullableValue&& readMaybe(Maybe&& maybe); +}; + +template +inline NullableValue&& readMaybe(Maybe&& maybe) { return kj::mv(maybe.ptr); } +template +inline T* readMaybe(Maybe& maybe) { return maybe.ptr; } +template +inline const T* readMaybe(const Maybe& maybe) { return maybe.ptr; } +template +inline T* readMaybe(Maybe&& maybe) { return maybe.ptr; } +template +inline T* readMaybe(const Maybe& maybe) { return maybe.ptr; } + +template +inline T* readMaybe(T* ptr) { return ptr; } +// Allow KJ_IF_MAYBE to work on regular pointers. + +} // namespace _ (private) + +#define KJ_IF_MAYBE(name, exp) if (auto name = ::kj::_::readMaybe(exp)) + +template +class Maybe { + // A T, or nullptr. + + // IF YOU CHANGE THIS CLASS: Note that there is a specialization of it in memory.h. + +public: + Maybe(): ptr(nullptr) {} + Maybe(T&& t) noexcept(noexcept(T(instance()))): ptr(kj::mv(t)) {} + Maybe(T& t): ptr(t) {} + Maybe(const T& t): ptr(t) {} + Maybe(const T* t) noexcept: ptr(t) {} + Maybe(Maybe&& other) noexcept(noexcept(T(instance()))): ptr(kj::mv(other.ptr)) {} + Maybe(const Maybe& other): ptr(other.ptr) {} + Maybe(Maybe& other): ptr(other.ptr) {} + + template + Maybe(Maybe&& other) noexcept(noexcept(T(instance()))) { + KJ_IF_MAYBE(val, kj::mv(other)) { + ptr.emplace(kj::mv(*val)); + } + } + template + Maybe(const Maybe& other) { + KJ_IF_MAYBE(val, other) { + ptr.emplace(*val); + } + } + + Maybe(decltype(nullptr)) noexcept: ptr(nullptr) {} + + template + inline T& emplace(Params&&... params) { + // Replace this Maybe's content with a new value constructed by passing the given parametrs to + // T's constructor. This can be used to initialize a Maybe without copying or even moving a T. + // Returns a reference to the newly-constructed value. + + return ptr.emplace(kj::fwd(params)...); + } + + inline Maybe& operator=(Maybe&& other) { ptr = kj::mv(other.ptr); return *this; } + inline Maybe& operator=(Maybe& other) { ptr = other.ptr; return *this; } + inline Maybe& operator=(const Maybe& other) { ptr = other.ptr; return *this; } + + inline bool operator==(decltype(nullptr)) const { return ptr == nullptr; } + inline bool operator!=(decltype(nullptr)) const { return ptr != nullptr; } + + T& orDefault(T& defaultValue) { + if (ptr == nullptr) { + return defaultValue; + } else { + return *ptr; + } + } + const T& orDefault(const T& defaultValue) const { + if (ptr == nullptr) { + return defaultValue; + } else { + return *ptr; + } + } + + template + auto map(Func&& f) & -> Maybe()))> { + if (ptr == nullptr) { + return nullptr; + } else { + return f(*ptr); + } + } + + template + auto map(Func&& f) const & -> Maybe()))> { + if (ptr == nullptr) { + return nullptr; + } else { + return f(*ptr); + } + } + + template + auto map(Func&& f) && -> Maybe()))> { + if (ptr == nullptr) { + return nullptr; + } else { + return f(kj::mv(*ptr)); + } + } + + template + auto map(Func&& f) const && -> Maybe()))> { + if (ptr == nullptr) { + return nullptr; + } else { + return f(kj::mv(*ptr)); + } + } + +private: + _::NullableValue ptr; + + template + friend class Maybe; + template + friend _::NullableValue&& _::readMaybe(Maybe&& maybe); + template + friend U* _::readMaybe(Maybe& maybe); + template + friend const U* _::readMaybe(const Maybe& maybe); +}; + +template +class Maybe: public DisallowConstCopyIfNotConst { +public: + Maybe() noexcept: ptr(nullptr) {} + Maybe(T& t) noexcept: ptr(&t) {} + Maybe(T* t) noexcept: ptr(t) {} + + template + inline Maybe(Maybe& other) noexcept: ptr(other.ptr) {} + template + inline Maybe(const Maybe& other) noexcept: ptr(other.ptr) {} + inline Maybe(decltype(nullptr)) noexcept: ptr(nullptr) {} + + inline Maybe& operator=(T& other) noexcept { ptr = &other; return *this; } + inline Maybe& operator=(T* other) noexcept { ptr = other; return *this; } + template + inline Maybe& operator=(Maybe& other) noexcept { ptr = other.ptr; return *this; } + template + inline Maybe& operator=(const Maybe& other) noexcept { ptr = other.ptr; return *this; } + + inline bool operator==(decltype(nullptr)) const { return ptr == nullptr; } + inline bool operator!=(decltype(nullptr)) const { return ptr != nullptr; } + + T& orDefault(T& defaultValue) { + if (ptr == nullptr) { + return defaultValue; + } else { + return *ptr; + } + } + const T& orDefault(const T& defaultValue) const { + if (ptr == nullptr) { + return defaultValue; + } else { + return *ptr; + } + } + + template + auto map(Func&& f) -> Maybe()))> { + if (ptr == nullptr) { + return nullptr; + } else { + return f(*ptr); + } + } + +private: + T* ptr; + + template + friend class Maybe; + template + friend U* _::readMaybe(Maybe&& maybe); + template + friend U* _::readMaybe(const Maybe& maybe); +}; + +// ======================================================================================= +// ArrayPtr +// +// So common that we put it in common.h rather than array.h. + +template +class ArrayPtr: public DisallowConstCopyIfNotConst { + // A pointer to an array. Includes a size. Like any pointer, it doesn't own the target data, + // and passing by value only copies the pointer, not the target. + +public: + inline constexpr ArrayPtr(): ptr(nullptr), size_(0) {} + inline constexpr ArrayPtr(decltype(nullptr)): ptr(nullptr), size_(0) {} + inline constexpr ArrayPtr(T* ptr, size_t size): ptr(ptr), size_(size) {} + inline constexpr ArrayPtr(T* begin, T* end): ptr(begin), size_(end - begin) {} + inline KJ_CONSTEXPR() ArrayPtr(::std::initializer_list> init) + : ptr(init.begin()), size_(init.size()) {} + + template + inline constexpr ArrayPtr(T (&native)[size]): ptr(native), size_(size) {} + // Construct an ArrayPtr from a native C-style array. + + inline operator ArrayPtr() const { + return ArrayPtr(ptr, size_); + } + inline ArrayPtr asConst() const { + return ArrayPtr(ptr, size_); + } + + inline size_t size() const { return size_; } + inline const T& operator[](size_t index) const { + KJ_IREQUIRE(index < size_, "Out-of-bounds ArrayPtr access."); + return ptr[index]; + } + inline T& operator[](size_t index) { + KJ_IREQUIRE(index < size_, "Out-of-bounds ArrayPtr access."); + return ptr[index]; + } + + inline T* begin() { return ptr; } + inline T* end() { return ptr + size_; } + inline T& front() { return *ptr; } + inline T& back() { return *(ptr + size_ - 1); } + inline const T* begin() const { return ptr; } + inline const T* end() const { return ptr + size_; } + inline const T& front() const { return *ptr; } + inline const T& back() const { return *(ptr + size_ - 1); } + + inline ArrayPtr slice(size_t start, size_t end) const { + KJ_IREQUIRE(start <= end && end <= size_, "Out-of-bounds ArrayPtr::slice()."); + return ArrayPtr(ptr + start, end - start); + } + inline ArrayPtr slice(size_t start, size_t end) { + KJ_IREQUIRE(start <= end && end <= size_, "Out-of-bounds ArrayPtr::slice()."); + return ArrayPtr(ptr + start, end - start); + } + + inline ArrayPtr> asBytes() const { + // Reinterpret the array as a byte array. This is explicitly legal under C++ aliasing + // rules. + return { reinterpret_cast*>(ptr), size_ * sizeof(T) }; + } + inline ArrayPtr> asChars() const { + // Reinterpret the array as a char array. This is explicitly legal under C++ aliasing + // rules. + return { reinterpret_cast*>(ptr), size_ * sizeof(T) }; + } + + inline bool operator==(decltype(nullptr)) const { return size_ == 0; } + inline bool operator!=(decltype(nullptr)) const { return size_ != 0; } + + inline bool operator==(const ArrayPtr& other) const { + if (size_ != other.size_) return false; + for (size_t i = 0; i < size_; i++) { + if (ptr[i] != other[i]) return false; + } + return true; + } + inline bool operator!=(const ArrayPtr& other) const { return !(*this == other); } + +private: + T* ptr; + size_t size_; +}; + +template +inline constexpr ArrayPtr arrayPtr(T* ptr, size_t size) { + // Use this function to construct ArrayPtrs without writing out the type name. + return ArrayPtr(ptr, size); +} + +template +inline constexpr ArrayPtr arrayPtr(T* begin, T* end) { + // Use this function to construct ArrayPtrs without writing out the type name. + return ArrayPtr(begin, end); +} + +// ======================================================================================= +// Casts + +template +To implicitCast(From&& from) { + // `implicitCast(value)` casts `value` to type `T` only if the conversion is implicit. Useful + // for e.g. resolving ambiguous overloads without sacrificing type-safety. + return kj::fwd(from); +} + +template +Maybe dynamicDowncastIfAvailable(From& from) { + // If RTTI is disabled, always returns nullptr. Otherwise, works like dynamic_cast. Useful + // in situations where dynamic_cast could allow an optimization, but isn't strictly necessary + // for correctness. It is highly recommended that you try to arrange all your dynamic_casts + // this way, as a dynamic_cast that is necessary for correctness implies a flaw in the interface + // design. + + // Force a compile error if To is not a subtype of From. Cross-casting is rare; if it is needed + // we should have a separate cast function like dynamicCrosscastIfAvailable(). + if (false) { + kj::implicitCast(kj::implicitCast(nullptr)); + } + +#if KJ_NO_RTTI + return nullptr; +#else + return dynamic_cast(&from); +#endif +} + +template +To& downcast(From& from) { + // Down-cast a value to a sub-type, asserting that the cast is valid. In opt mode this is a + // static_cast, but in debug mode (when RTTI is enabled) a dynamic_cast will be used to verify + // that the value really has the requested type. + + // Force a compile error if To is not a subtype of From. + if (false) { + kj::implicitCast(kj::implicitCast(nullptr)); + } + +#if !KJ_NO_RTTI + KJ_IREQUIRE(dynamic_cast(&from) != nullptr, "Value cannot be downcast() to requested type."); +#endif + + return static_cast(from); +} + +// ======================================================================================= +// Defer + +namespace _ { // private + +template +class Deferred { +public: + inline Deferred(Func&& func): func(kj::fwd(func)), canceled(false) {} + inline ~Deferred() noexcept(false) { if (!canceled) func(); } + KJ_DISALLOW_COPY(Deferred); + + // This move constructor is usually optimized away by the compiler. + inline Deferred(Deferred&& other): func(kj::mv(other.func)), canceled(false) { + other.canceled = true; + } +private: + Func func; + bool canceled; +}; + +} // namespace _ (private) + +template +_::Deferred defer(Func&& func) { + // Returns an object which will invoke the given functor in its destructor. The object is not + // copyable but is movable with the semantics you'd expect. Since the return type is private, + // you need to assign to an `auto` variable. + // + // The KJ_DEFER macro provides slightly more convenient syntax for the common case where you + // want some code to run at current scope exit. + + return _::Deferred(kj::fwd(func)); +} + +#define KJ_DEFER(code) auto KJ_UNIQUE_NAME(_kjDefer) = ::kj::defer([&](){code;}) +// Run the given code when the function exits, whether by return or exception. + +} // namespace kj + +#endif // KJ_COMMON_H_ diff --git a/phonelibs/capnp-cpp/include/kj/compat/gtest.h b/phonelibs/capnp-cpp/include/kj/compat/gtest.h new file mode 100644 index 00000000000000..016dbdfac322ee --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/compat/gtest.h @@ -0,0 +1,122 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_COMPAT_GTEST_H_ +#define KJ_COMPAT_GTEST_H_ +// This file defines compatibility macros converting Google Test tests into KJ tests. +// +// This is only intended to cover the most common functionality. Many tests will likely need +// additional tweaks. For instance: +// - Using operator<< to print information on failure is not supported. Instead, switch to +// KJ_ASSERT/KJ_EXPECT and pass in stuff to print as additional parameters. +// - Test fixtures are not supported. Allocate your "test fixture" on the stack instead. Do setup +// in the constructor, teardown in the destructor. + +#include "../test.h" + +namespace kj { + +namespace _ { // private + +template +T abs(T value) { return value < 0 ? -value : value; } + +inline bool floatAlmostEqual(float a, float b) { + return a == b || abs(a - b) < (abs(a) + abs(b)) * 1e-5; +} + +inline bool doubleAlmostEqual(double a, double b) { + return a == b || abs(a - b) < (abs(a) + abs(b)) * 1e-12; +} + +} // namespace _ (private) + +#define EXPECT_FALSE(x) KJ_EXPECT(!(x)) +#define EXPECT_TRUE(x) KJ_EXPECT(x) +#define EXPECT_EQ(x, y) KJ_EXPECT((x) == (y), x, y) +#define EXPECT_NE(x, y) KJ_EXPECT((x) != (y), x, y) +#define EXPECT_LE(x, y) KJ_EXPECT((x) <= (y), x, y) +#define EXPECT_GE(x, y) KJ_EXPECT((x) >= (y), x, y) +#define EXPECT_LT(x, y) KJ_EXPECT((x) < (y), x, y) +#define EXPECT_GT(x, y) KJ_EXPECT((x) > (y), x, y) +#define EXPECT_STREQ(x, y) KJ_EXPECT(::strcmp(x, y) == 0, x, y) +#define EXPECT_FLOAT_EQ(x, y) KJ_EXPECT(::kj::_::floatAlmostEqual(y, x), y, x); +#define EXPECT_DOUBLE_EQ(x, y) KJ_EXPECT(::kj::_::doubleAlmostEqual(y, x), y, x); + +#define ASSERT_FALSE(x) KJ_ASSERT(!(x)) +#define ASSERT_TRUE(x) KJ_ASSERT(x) +#define ASSERT_EQ(x, y) KJ_ASSERT((x) == (y), x, y) +#define ASSERT_NE(x, y) KJ_ASSERT((x) != (y), x, y) +#define ASSERT_LE(x, y) KJ_ASSERT((x) <= (y), x, y) +#define ASSERT_GE(x, y) KJ_ASSERT((x) >= (y), x, y) +#define ASSERT_LT(x, y) KJ_ASSERT((x) < (y), x, y) +#define ASSERT_GT(x, y) KJ_ASSERT((x) > (y), x, y) +#define ASSERT_STREQ(x, y) KJ_ASSERT(::strcmp(x, y) == 0, x, y) +#define ASSERT_FLOAT_EQ(x, y) KJ_ASSERT(::kj::_::floatAlmostEqual(y, x), y, x); +#define ASSERT_DOUBLE_EQ(x, y) KJ_ASSERT(::kj::_::doubleAlmostEqual(y, x), y, x); + +class AddFailureAdapter { +public: + AddFailureAdapter(const char* file, int line): file(file), line(line) {} + + ~AddFailureAdapter() { + if (!handled) { + _::Debug::log(file, line, LogSeverity::ERROR, "expectation failed"); + } + } + + template + void operator<<(T&& info) { + handled = true; + _::Debug::log(file, line, LogSeverity::ERROR, "\"expectation failed\", info", + "expectation failed", kj::fwd(info)); + } + +private: + bool handled = false; + const char* file; + int line; +}; + +#define ADD_FAILURE() ::kj::AddFailureAdapter(__FILE__, __LINE__) + +#if KJ_NO_EXCEPTIONS +#define EXPECT_ANY_THROW(code) \ + KJ_EXPECT(::kj::_::expectFatalThrow(nullptr, nullptr, [&]() { code; })) +#else +#define EXPECT_ANY_THROW(code) \ + KJ_EXPECT(::kj::runCatchingExceptions([&]() { code; }) != nullptr) +#endif + +#define EXPECT_NONFATAL_FAILURE(code) \ + EXPECT_TRUE(kj::runCatchingExceptions([&]() { code; }) != nullptr); + +#ifdef KJ_DEBUG +#define EXPECT_DEBUG_ANY_THROW EXPECT_ANY_THROW +#else +#define EXPECT_DEBUG_ANY_THROW(EXP) +#endif + +#define TEST(x, y) KJ_TEST("legacy test: " #x "/" #y) + +} // namespace kj + +#endif // KJ_COMPAT_GTEST_H_ diff --git a/phonelibs/capnp-cpp/include/kj/compat/http.h b/phonelibs/capnp-cpp/include/kj/compat/http.h new file mode 100644 index 00000000000000..8d455cc2588543 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/compat/http.h @@ -0,0 +1,636 @@ +// Copyright (c) 2017 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_COMPAT_HTTP_H_ +#define KJ_COMPAT_HTTP_H_ +// The KJ HTTP client/server library. +// +// This is a simple library which can be used to implement an HTTP client or server. Properties +// of this library include: +// - Uses KJ async framework. +// - Agnostic to transport layer -- you can provide your own. +// - Header parsing is zero-copy -- it results in strings that point directly into the buffer +// received off the wire. +// - Application code which reads and writes headers refers to headers by symbolic names, not by +// string literals, with lookups being array-index-based, not map-based. To make this possible, +// the application announces what headers it cares about in advance, in order to assign numeric +// values to them. +// - Methods are identified by an enum. + +#include +#include +#include +#include +#include + +namespace kj { + +#define KJ_HTTP_FOR_EACH_METHOD(MACRO) \ + MACRO(GET) \ + MACRO(HEAD) \ + MACRO(POST) \ + MACRO(PUT) \ + MACRO(DELETE) \ + MACRO(PATCH) \ + MACRO(PURGE) \ + MACRO(OPTIONS) \ + MACRO(TRACE) \ + /* standard methods */ \ + /* */ \ + /* (CONNECT is intentionally omitted since it is handled specially in HttpHandler) */ \ + \ + MACRO(COPY) \ + MACRO(LOCK) \ + MACRO(MKCOL) \ + MACRO(MOVE) \ + MACRO(PROPFIND) \ + MACRO(PROPPATCH) \ + MACRO(SEARCH) \ + MACRO(UNLOCK) \ + /* WebDAV */ \ + \ + MACRO(REPORT) \ + MACRO(MKACTIVITY) \ + MACRO(CHECKOUT) \ + MACRO(MERGE) \ + /* Subversion */ \ + \ + MACRO(MSEARCH) \ + MACRO(NOTIFY) \ + MACRO(SUBSCRIBE) \ + MACRO(UNSUBSCRIBE) + /* UPnP */ + +#define KJ_HTTP_FOR_EACH_CONNECTION_HEADER(MACRO) \ + MACRO(connection, "Connection") \ + MACRO(contentLength, "Content-Length") \ + MACRO(keepAlive, "Keep-Alive") \ + MACRO(te, "TE") \ + MACRO(trailer, "Trailer") \ + MACRO(transferEncoding, "Transfer-Encoding") \ + MACRO(upgrade, "Upgrade") + +enum class HttpMethod { + // Enum of known HTTP methods. + // + // We use an enum rather than a string to allow for faster parsing and switching and to reduce + // ambiguity. + +#define DECLARE_METHOD(id) id, +KJ_HTTP_FOR_EACH_METHOD(DECLARE_METHOD) +#undef DECLARE_METHOD +}; + +kj::StringPtr KJ_STRINGIFY(HttpMethod method); +kj::Maybe tryParseHttpMethod(kj::StringPtr name); + +class HttpHeaderTable; + +class HttpHeaderId { + // Identifies an HTTP header by numeric ID that indexes into an HttpHeaderTable. + // + // The KJ HTTP API prefers that headers be identified by these IDs for a few reasons: + // - Integer lookups are much more efficient than string lookups. + // - Case-insensitivity is awkward to deal with when const strings are being passed to the lookup + // method. + // - Writing out strings less often means fewer typos. + // + // See HttpHeaderTable for usage hints. + +public: + HttpHeaderId() = default; + + inline bool operator==(const HttpHeaderId& other) const { return id == other.id; } + inline bool operator!=(const HttpHeaderId& other) const { return id != other.id; } + inline bool operator< (const HttpHeaderId& other) const { return id < other.id; } + inline bool operator> (const HttpHeaderId& other) const { return id > other.id; } + inline bool operator<=(const HttpHeaderId& other) const { return id <= other.id; } + inline bool operator>=(const HttpHeaderId& other) const { return id >= other.id; } + + inline size_t hashCode() const { return id; } + + kj::StringPtr toString() const; + + void requireFrom(HttpHeaderTable& table) const; + // In debug mode, throws an exception if the HttpHeaderId is not from the given table. + // + // In opt mode, no-op. + +#define KJ_HTTP_FOR_EACH_BUILTIN_HEADER(MACRO) \ + MACRO(HOST, "Host") \ + MACRO(DATE, "Date") \ + MACRO(LOCATION, "Location") \ + MACRO(CONTENT_TYPE, "Content-Type") + // For convenience, these very-common headers are valid for all HttpHeaderTables. You can refer + // to them like: + // + // HttpHeaderId::HOST + // + // TODO(0.7): Fill this out with more common headers. + +#define DECLARE_HEADER(id, name) \ + static const HttpHeaderId id; + // Declare a constant for each builtin header, e.g.: HttpHeaderId::CONNECTION + + KJ_HTTP_FOR_EACH_BUILTIN_HEADER(DECLARE_HEADER); +#undef DECLARE_HEADER + +private: + HttpHeaderTable* table; + uint id; + + inline explicit constexpr HttpHeaderId(HttpHeaderTable* table, uint id): table(table), id(id) {} + friend class HttpHeaderTable; + friend class HttpHeaders; +}; + +class HttpHeaderTable { + // Construct an HttpHeaderTable to declare which headers you'll be interested in later on, and + // to manufacture IDs for them. + // + // Example: + // + // // Build a header table with the headers we are interested in. + // kj::HttpHeaderTable::Builder builder; + // const HttpHeaderId accept = builder.add("Accept"); + // const HttpHeaderId contentType = builder.add("Content-Type"); + // kj::HttpHeaderTable table(kj::mv(builder)); + // + // // Create an HTTP client. + // auto client = kj::newHttpClient(table, network); + // + // // Get http://example.com. + // HttpHeaders headers(table); + // headers.set(accept, "text/html"); + // auto response = client->send(kj::HttpMethod::GET, "http://example.com", headers) + // .wait(waitScope); + // auto msg = kj::str("Response content type: ", response.headers.get(contentType)); + + struct IdsByNameMap; + +public: + HttpHeaderTable(); + // Constructs a table that only contains the builtin headers. + + class Builder { + public: + Builder(); + HttpHeaderId add(kj::StringPtr name); + Own build(); + + HttpHeaderTable& getFutureTable(); + // Get the still-unbuilt header table. You cannot actually use it until build() has been + // called. + // + // This method exists to help when building a shared header table -- the Builder may be passed + // to several components, each of which will register the headers they need and get a reference + // to the future table. + + private: + kj::Own table; + }; + + KJ_DISALLOW_COPY(HttpHeaderTable); // Can't copy because HttpHeaderId points to the table. + ~HttpHeaderTable() noexcept(false); + + uint idCount(); + // Return the number of IDs in the table. + + kj::Maybe stringToId(kj::StringPtr name); + // Try to find an ID for the given name. The matching is case-insensitive, per the HTTP spec. + // + // Note: if `name` contains characters that aren't allowed in HTTP header names, this may return + // a bogus value rather than null, due to optimizations used in case-insensitive matching. + + kj::StringPtr idToString(HttpHeaderId id); + // Get the canonical string name for the given ID. + +private: + kj::Vector namesById; + kj::Own idsByName; +}; + +class HttpHeaders { + // Represents a set of HTTP headers. + // + // This class guards against basic HTTP header injection attacks: Trying to set a header name or + // value containing a newline, carriage return, or other invalid character will throw an + // exception. + +public: + explicit HttpHeaders(HttpHeaderTable& table); + + KJ_DISALLOW_COPY(HttpHeaders); + HttpHeaders(HttpHeaders&&) = default; + HttpHeaders& operator=(HttpHeaders&&) = default; + + void clear(); + // Clears all contents, as if the object was freshly-allocated. However, calling this rather + // than actually re-allocating the object may avoid re-allocation of internal objects. + + HttpHeaders clone() const; + // Creates a deep clone of the HttpHeaders. The returned object owns all strings it references. + + HttpHeaders cloneShallow() const; + // Creates a shallow clone of the HttpHeaders. The returned object references the same strings + // as the original, owning none of them. + + kj::Maybe get(HttpHeaderId id) const; + // Read a header. + + template + void forEach(Func&& func) const; + // Calls `func(name, value)` for each header in the set -- including headers that aren't mapped + // to IDs in the header table. Both inputs are of type kj::StringPtr. + + void set(HttpHeaderId id, kj::StringPtr value); + void set(HttpHeaderId id, kj::String&& value); + // Sets a header value, overwriting the existing value. + // + // The String&& version is equivalent to calling the other version followed by takeOwnership(). + // + // WARNING: It is the caller's responsibility to ensure that `value` remains valid until the + // HttpHeaders object is destroyed. This allows string literals to be passed without making a + // copy, but complicates the use of dynamic values. Hint: Consider using `takeOwnership()`. + + void add(kj::StringPtr name, kj::StringPtr value); + void add(kj::StringPtr name, kj::String&& value); + void add(kj::String&& name, kj::String&& value); + // Append a header. `name` will be looked up in the header table, but if it's not mapped, the + // header will be added to the list of unmapped headers. + // + // The String&& versions are equivalent to calling the other version followed by takeOwnership(). + // + // WARNING: It is the caller's responsibility to ensure that `name` and `value` remain valid + // until the HttpHeaders object is destroyed. This allows string literals to be passed without + // making a copy, but complicates the use of dynamic values. Hint: Consider using + // `takeOwnership()`. + + void unset(HttpHeaderId id); + // Removes a header. + // + // It's not possible to remove a header by string name because non-indexed headers would take + // O(n) time to remove. Instead, construct a new HttpHeaders object and copy contents. + + void takeOwnership(kj::String&& string); + void takeOwnership(kj::Array&& chars); + void takeOwnership(HttpHeaders&& otherHeaders); + // Takes overship of a string so that it lives until the HttpHeaders object is destroyed. Useful + // when you've passed a dynamic value to set() or add() or parse*(). + + struct ConnectionHeaders { + // These headers govern details of the specific HTTP connection or framing of the content. + // Hence, they are managed internally within the HTTP library, and never appear in an + // HttpHeaders structure. + +#define DECLARE_HEADER(id, name) \ + kj::StringPtr id; + KJ_HTTP_FOR_EACH_CONNECTION_HEADER(DECLARE_HEADER) +#undef DECLARE_HEADER + }; + + struct Request { + HttpMethod method; + kj::StringPtr url; + ConnectionHeaders connectionHeaders; + }; + struct Response { + uint statusCode; + kj::StringPtr statusText; + ConnectionHeaders connectionHeaders; + }; + + kj::Maybe tryParseRequest(kj::ArrayPtr content); + kj::Maybe tryParseResponse(kj::ArrayPtr content); + // Parse an HTTP header blob and add all the headers to this object. + // + // `content` should be all text from the start of the request to the first occurrance of two + // newlines in a row -- including the first of these two newlines, but excluding the second. + // + // The parse is performed with zero copies: The callee clobbers `content` with '\0' characters + // to split it into a bunch of shorter strings. The caller must keep `content` valid until the + // `HttpHeaders` is destroyed, or pass it to `takeOwnership()`. + + kj::String serializeRequest(HttpMethod method, kj::StringPtr url, + const ConnectionHeaders& connectionHeaders) const; + kj::String serializeResponse(uint statusCode, kj::StringPtr statusText, + const ConnectionHeaders& connectionHeaders) const; + // Serialize the headers as a complete request or response blob. The blob uses '\r\n' newlines + // and includes the double-newline to indicate the end of the headers. + + kj::String toString() const; + +private: + HttpHeaderTable* table; + + kj::Array indexedHeaders; + // Size is always table->idCount(). + + struct Header { + kj::StringPtr name; + kj::StringPtr value; + }; + kj::Vector

unindexedHeaders; + + kj::Vector> ownedStrings; + + kj::Maybe addNoCheck(kj::StringPtr name, kj::StringPtr value); + + kj::StringPtr cloneToOwn(kj::StringPtr str); + + kj::String serialize(kj::ArrayPtr word1, + kj::ArrayPtr word2, + kj::ArrayPtr word3, + const ConnectionHeaders& connectionHeaders) const; + + bool parseHeaders(char* ptr, char* end, ConnectionHeaders& connectionHeaders); + + // TODO(perf): Arguably we should store a map, but header sets are never very long + // TODO(perf): We could optimize for common headers by storing them directly as fields. We could + // also add direct accessors for those headers. +}; + +class WebSocket { +public: + WebSocket(kj::Own stream); + // Create a WebSocket wrapping the given I/O stream. + + kj::Promise send(kj::ArrayPtr message); + kj::Promise send(kj::ArrayPtr message); +}; + +class HttpClient { + // Interface to the client end of an HTTP connection. + // + // There are two kinds of clients: + // * Host clients are used when talking to a specific host. The `url` specified in a request + // is actually just a path. (A `Host` header is still required in all requests.) + // * Proxy clients are used when the target could be any arbitrary host on the internet. + // The `url` specified in a request is a full URL including protocol and hostname. + +public: + struct Response { + uint statusCode; + kj::StringPtr statusText; + const HttpHeaders* headers; + kj::Own body; + // `statusText` and `headers` remain valid until `body` is dropped. + }; + + struct Request { + kj::Own body; + // Write the request entity body to this stream, then drop it when done. + // + // May be null for GET and HEAD requests (which have no body) and requests that have + // Content-Length: 0. + + kj::Promise response; + // Promise for the eventual respnose. + }; + + virtual Request request(HttpMethod method, kj::StringPtr url, const HttpHeaders& headers, + kj::Maybe expectedBodySize = nullptr) = 0; + // Perform an HTTP request. + // + // `url` may be a full URL (with protocol and host) or it may be only the path part of the URL, + // depending on whether the client is a proxy client or a host client. + // + // `url` and `headers` need only remain valid until `request()` returns (they can be + // stack-allocated). + // + // `expectedBodySize`, if provided, must be exactly the number of bytes that will be written to + // the body. This will trigger use of the `Content-Length` connection header. Otherwise, + // `Transfer-Encoding: chunked` will be used. + + struct WebSocketResponse { + uint statusCode; + kj::StringPtr statusText; + const HttpHeaders* headers; + kj::OneOf, kj::Own> upstreamOrBody; + // `statusText` and `headers` remain valid until `upstreamOrBody` is dropped. + }; + virtual kj::Promise openWebSocket( + kj::StringPtr url, const HttpHeaders& headers, kj::Own downstream); + // Tries to open a WebSocket. Default implementation calls send() and never returns a WebSocket. + // + // `url` and `headers` are invalidated when the returned promise resolves. + + virtual kj::Promise> connect(kj::String host); + // Handles CONNECT requests. Only relevant for proxy clients. Default implementation throws + // UNIMPLEMENTED. +}; + +class HttpService { + // Interface which HTTP services should implement. + // + // This interface is functionally equivalent to HttpClient, but is intended for applications to + // implement rather than call. The ergonomics and performance of the method signatures are + // optimized for the serving end. + // + // As with clients, there are two kinds of services: + // * Host services are used when talking to a specific host. The `url` specified in a request + // is actually just a path. (A `Host` header is still required in all requests, and the service + // may in fact serve multiple origins via this header.) + // * Proxy services are used when the target could be any arbitrary host on the internet, i.e. to + // implement an HTTP proxy. The `url` specified in a request is a full URL including protocol + // and hostname. + +public: + class Response { + public: + virtual kj::Own send( + uint statusCode, kj::StringPtr statusText, const HttpHeaders& headers, + kj::Maybe expectedBodySize = nullptr) = 0; + // Begin the response. + // + // `statusText` and `headers` need only remain valid until send() returns (they can be + // stack-allocated). + }; + + virtual kj::Promise request( + HttpMethod method, kj::StringPtr url, const HttpHeaders& headers, + kj::AsyncInputStream& requestBody, Response& response) = 0; + // Perform an HTTP request. + // + // `url` may be a full URL (with protocol and host) or it may be only the path part of the URL, + // depending on whether the service is a proxy service or a host service. + // + // `url` and `headers` are invalidated on the first read from `requestBody` or when the returned + // promise resolves, whichever comes first. + + class WebSocketResponse: public Response { + public: + kj::Own startWebSocket( + uint statusCode, kj::StringPtr statusText, const HttpHeaders& headers, + WebSocket& upstream); + // Begin the response. + // + // `statusText` and `headers` need only remain valid until startWebSocket() returns (they can + // be stack-allocated). + }; + + virtual kj::Promise openWebSocket( + kj::StringPtr url, const HttpHeaders& headers, WebSocketResponse& response); + // Tries to open a WebSocket. Default implementation calls request() and never returns a + // WebSocket. + // + // `url` and `headers` are invalidated when the returned promise resolves. + + virtual kj::Promise> connect(kj::String host); + // Handles CONNECT requests. Only relevant for proxy services. Default implementation throws + // UNIMPLEMENTED. +}; + +kj::Own newHttpClient(HttpHeaderTable& responseHeaderTable, kj::Network& network, + kj::Maybe tlsNetwork = nullptr); +// Creates a proxy HttpClient that connects to hosts over the given network. +// +// `responseHeaderTable` is used when parsing HTTP responses. Requests can use any header table. +// +// `tlsNetwork` is required to support HTTPS destination URLs. Otherwise, only HTTP URLs can be +// fetched. + +kj::Own newHttpClient(HttpHeaderTable& responseHeaderTable, kj::AsyncIoStream& stream); +// Creates an HttpClient that speaks over the given pre-established connection. The client may +// be used as a proxy client or a host client depending on whether the peer is operating as +// a proxy. +// +// Note that since this client has only one stream to work with, it will try to pipeline all +// requests on this stream. If one request or response has an I/O failure, all subsequent requests +// fail as well. If the destination server chooses to close the connection after a response, +// subsequent requests will fail. If a response takes a long time, it blocks subsequent responses. +// If a WebSocket is opened successfully, all subsequent requests fail. + +kj::Own newHttpClient(HttpService& service); +kj::Own newHttpService(HttpClient& client); +// Adapts an HttpClient to an HttpService and vice versa. + +struct HttpServerSettings { + kj::Duration headerTimeout = 15 * kj::SECONDS; + // After initial connection open, or after receiving the first byte of a pipelined request, + // the client must send the complete request within this time. + + kj::Duration pipelineTimeout = 5 * kj::SECONDS; + // After one request/response completes, we'll wait up to this long for a pipelined request to + // arrive. +}; + +class HttpServer: private kj::TaskSet::ErrorHandler { + // Class which listens for requests on ports or connections and sends them to an HttpService. + +public: + typedef HttpServerSettings Settings; + + HttpServer(kj::Timer& timer, HttpHeaderTable& requestHeaderTable, HttpService& service, + Settings settings = Settings()); + // Set up an HttpServer that directs incoming connections to the given service. The service + // may be a host service or a proxy service depending on whether you are intending to implement + // an HTTP server or an HTTP proxy. + + kj::Promise drain(); + // Stop accepting new connections or new requests on existing connections. Finish any requests + // that are already executing, then close the connections. Returns once no more requests are + // in-flight. + + kj::Promise listenHttp(kj::ConnectionReceiver& port); + // Accepts HTTP connections on the given port and directs them to the handler. + // + // The returned promise never completes normally. It may throw if port.accept() throws. Dropping + // the returned promise will cause the server to stop listening on the port, but already-open + // connections will continue to be served. Destroy the whole HttpServer to cancel all I/O. + + kj::Promise listenHttp(kj::Own connection); + // Reads HTTP requests from the given connection and directs them to the handler. A successful + // completion of the promise indicates that all requests received on the connection resulted in + // a complete response, and the client closed the connection gracefully or drain() was called. + // The promise throws if an unparseable request is received or if some I/O error occurs. Dropping + // the returned promise will cancel all I/O on the connection and cancel any in-flight requests. + +private: + class Connection; + + kj::Timer& timer; + HttpHeaderTable& requestHeaderTable; + HttpService& service; + Settings settings; + + bool draining = false; + kj::ForkedPromise onDrain; + kj::Own> drainFulfiller; + + uint connectionCount = 0; + kj::Maybe>> zeroConnectionsFulfiller; + + kj::TaskSet tasks; + + HttpServer(kj::Timer& timer, HttpHeaderTable& requestHeaderTable, HttpService& service, + Settings settings, kj::PromiseFulfillerPair paf); + + kj::Promise listenLoop(kj::ConnectionReceiver& port); + + void taskFailed(kj::Exception&& exception) override; +}; + +// ======================================================================================= +// inline implementation + +inline void HttpHeaderId::requireFrom(HttpHeaderTable& table) const { + KJ_IREQUIRE(this->table == nullptr || this->table == &table, + "the provided HttpHeaderId is from the wrong HttpHeaderTable"); +} + +inline kj::Own HttpHeaderTable::Builder::build() { return kj::mv(table); } +inline HttpHeaderTable& HttpHeaderTable::Builder::getFutureTable() { return *table; } + +inline uint HttpHeaderTable::idCount() { return namesById.size(); } + +inline kj::StringPtr HttpHeaderTable::idToString(HttpHeaderId id) { + id.requireFrom(*this); + return namesById[id.id]; +} + +inline kj::Maybe HttpHeaders::get(HttpHeaderId id) const { + id.requireFrom(*table); + auto result = indexedHeaders[id.id]; + return result == nullptr ? kj::Maybe(nullptr) : result; +} + +inline void HttpHeaders::unset(HttpHeaderId id) { + id.requireFrom(*table); + indexedHeaders[id.id] = nullptr; +} + +template +inline void HttpHeaders::forEach(Func&& func) const { + for (auto i: kj::indices(indexedHeaders)) { + if (indexedHeaders[i] != nullptr) { + func(table->idToString(HttpHeaderId(table, i)), indexedHeaders[i]); + } + } + + for (auto& header: unindexedHeaders) { + func(header.name, header.value); + } +} + +} // namespace kj + +#endif // KJ_COMPAT_HTTP_H_ diff --git a/phonelibs/capnp-cpp/include/kj/debug.h b/phonelibs/capnp-cpp/include/kj/debug.h new file mode 100644 index 00000000000000..fff7f98bc02bb5 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/debug.h @@ -0,0 +1,555 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file declares convenient macros for debug logging and error handling. The macros make +// it excessively easy to extract useful context information from code. Example: +// +// KJ_ASSERT(a == b, a, b, "a and b must be the same."); +// +// On failure, this will throw an exception whose description looks like: +// +// myfile.c++:43: bug in code: expected a == b; a = 14; b = 72; a and b must be the same. +// +// As you can see, all arguments after the first provide additional context. +// +// The macros available are: +// +// * `KJ_LOG(severity, ...)`: Just writes a log message, to stderr by default (but you can +// intercept messages by implementing an ExceptionCallback). `severity` is `INFO`, `WARNING`, +// `ERROR`, or `FATAL`. By default, `INFO` logs are not written, but for command-line apps the +// user should be able to pass a flag like `--verbose` to enable them. Other log levels are +// enabled by default. Log messages -- like exceptions -- can be intercepted by registering an +// ExceptionCallback. +// +// * `KJ_DBG(...)`: Like `KJ_LOG`, but intended specifically for temporary log lines added while +// debugging a particular problem. Calls to `KJ_DBG` should always be deleted before committing +// code. It is suggested that you set up a pre-commit hook that checks for this. +// +// * `KJ_ASSERT(condition, ...)`: Throws an exception if `condition` is false, or aborts if +// exceptions are disabled. This macro should be used to check for bugs in the surrounding code +// and its dependencies, but NOT to check for invalid input. The macro may be followed by a +// brace-delimited code block; if so, the block will be executed in the case where the assertion +// fails, before throwing the exception. If control jumps out of the block (e.g. with "break", +// "return", or "goto"), then the error is considered "recoverable" -- in this case, if +// exceptions are disabled, execution will continue normally rather than aborting (but if +// exceptions are enabled, an exception will still be thrown on exiting the block). A "break" +// statement in particular will jump to the code immediately after the block (it does not break +// any surrounding loop or switch). Example: +// +// KJ_ASSERT(value >= 0, "Value cannot be negative.", value) { +// // Assertion failed. Set value to zero to "recover". +// value = 0; +// // Don't abort if exceptions are disabled. Continue normally. +// // (Still throw an exception if they are enabled, though.) +// break; +// } +// // When exceptions are disabled, we'll get here even if the assertion fails. +// // Otherwise, we get here only if the assertion passes. +// +// * `KJ_REQUIRE(condition, ...)`: Like `KJ_ASSERT` but used to check preconditions -- e.g. to +// validate parameters passed from a caller. A failure indicates that the caller is buggy. +// +// * `KJ_SYSCALL(code, ...)`: Executes `code` assuming it makes a system call. A negative result +// is considered an error, with error code reported via `errno`. EINTR is handled by retrying. +// Other errors are handled by throwing an exception. If you need to examine the return code, +// assign it to a variable like so: +// +// int fd; +// KJ_SYSCALL(fd = open(filename, O_RDONLY), filename); +// +// `KJ_SYSCALL` can be followed by a recovery block, just like `KJ_ASSERT`. +// +// * `KJ_NONBLOCKING_SYSCALL(code, ...)`: Like KJ_SYSCALL, but will not throw an exception on +// EAGAIN/EWOULDBLOCK. The calling code should check the syscall's return value to see if it +// indicates an error; in this case, it can assume the error was EAGAIN because any other error +// would have caused an exception to be thrown. +// +// * `KJ_CONTEXT(...)`: Notes additional contextual information relevant to any exceptions thrown +// from within the current scope. That is, until control exits the block in which KJ_CONTEXT() +// is used, if any exception is generated, it will contain the given information in its context +// chain. This is helpful because it can otherwise be very difficult to come up with error +// messages that make sense within low-level helper code. Note that the parameters to +// KJ_CONTEXT() are only evaluated if an exception is thrown. This implies that any variables +// used must remain valid until the end of the scope. +// +// Notes: +// * Do not write expressions with side-effects in the message content part of the macro, as the +// message will not necessarily be evaluated. +// * For every macro `FOO` above except `LOG`, there is also a `FAIL_FOO` macro used to report +// failures that already happened. For the macros that check a boolean condition, `FAIL_FOO` +// omits the first parameter and behaves like it was `false`. `FAIL_SYSCALL` and +// `FAIL_RECOVERABLE_SYSCALL` take a string and an OS error number as the first two parameters. +// The string should be the name of the failed system call. +// * For every macro `FOO` above, there is a `DFOO` version (or `RECOVERABLE_DFOO`) which is only +// executed in debug mode, i.e. when KJ_DEBUG is defined. KJ_DEBUG is defined automatically +// by common.h when compiling without optimization (unless NDEBUG is defined), but you can also +// define it explicitly (e.g. -DKJ_DEBUG). Generally, production builds should NOT use KJ_DEBUG +// as it may enable expensive checks that are unlikely to fail. + +#ifndef KJ_DEBUG_H_ +#define KJ_DEBUG_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "string.h" +#include "exception.h" + +#ifdef ERROR +// This is problematic because windows.h #defines ERROR, which we use in an enum here. +#error "Make sure to to undefine ERROR (or just #include ) before this file" +#endif + +namespace kj { + +#if _MSC_VER +// MSVC does __VA_ARGS__ differently from GCC: +// - A trailing comma before an empty __VA_ARGS__ is removed automatically, whereas GCC wants +// you to request this behavior with "##__VA_ARGS__". +// - If __VA_ARGS__ is passed directly as an argument to another macro, it will be treated as a +// *single* argument rather than an argument list. This can be worked around by wrapping the +// outer macro call in KJ_EXPAND(), which appraently forces __VA_ARGS__ to be expanded before +// the macro is evaluated. I don't understand the C preprocessor. +// - Using "#__VA_ARGS__" to stringify __VA_ARGS__ expands to zero tokens when __VA_ARGS__ is +// empty, rather than expanding to an empty string literal. We can work around by concatenating +// with an empty string literal. + +#define KJ_EXPAND(X) X + +#define KJ_LOG(severity, ...) \ + if (!::kj::_::Debug::shouldLog(::kj::LogSeverity::severity)) {} else \ + ::kj::_::Debug::log(__FILE__, __LINE__, ::kj::LogSeverity::severity, \ + "" #__VA_ARGS__, __VA_ARGS__) + +#define KJ_DBG(...) KJ_EXPAND(KJ_LOG(DBG, __VA_ARGS__)) + +#define KJ_REQUIRE(cond, ...) \ + if (KJ_LIKELY(cond)) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, ::kj::Exception::Type::FAILED, \ + #cond, "" #__VA_ARGS__, __VA_ARGS__);; f.fatal()) + +#define KJ_FAIL_REQUIRE(...) \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, ::kj::Exception::Type::FAILED, \ + nullptr, "" #__VA_ARGS__, __VA_ARGS__);; f.fatal()) + +#define KJ_SYSCALL(call, ...) \ + if (auto _kjSyscallResult = ::kj::_::Debug::syscall([&](){return (call);}, false)) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + _kjSyscallResult.getErrorNumber(), #call, "" #__VA_ARGS__, __VA_ARGS__);; f.fatal()) + +#define KJ_NONBLOCKING_SYSCALL(call, ...) \ + if (auto _kjSyscallResult = ::kj::_::Debug::syscall([&](){return (call);}, true)) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + _kjSyscallResult.getErrorNumber(), #call, "" #__VA_ARGS__, __VA_ARGS__);; f.fatal()) + +#define KJ_FAIL_SYSCALL(code, errorNumber, ...) \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + errorNumber, code, "" #__VA_ARGS__, __VA_ARGS__);; f.fatal()) + +#if _WIN32 + +#define KJ_WIN32(call, ...) \ + if (::kj::_::Debug::isWin32Success(call)) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + ::kj::_::Debug::getWin32Error(), #call, "" #__VA_ARGS__, __VA_ARGS__);; f.fatal()) + +#define KJ_WINSOCK(call, ...) \ + if ((call) != SOCKET_ERROR) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + ::kj::_::Debug::getWin32Error(), #call, "" #__VA_ARGS__, __VA_ARGS__);; f.fatal()) + +#define KJ_FAIL_WIN32(code, errorNumber, ...) \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + ::kj::_::Debug::Win32Error(errorNumber), code, "" #__VA_ARGS__, __VA_ARGS__);; f.fatal()) + +#endif + +#define KJ_UNIMPLEMENTED(...) \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, ::kj::Exception::Type::UNIMPLEMENTED, \ + nullptr, "" #__VA_ARGS__, __VA_ARGS__);; f.fatal()) + +// TODO(msvc): MSVC mis-deduces `ContextImpl` as `ContextImpl` in some edge +// cases, such as inside nested lambdas inside member functions. Wrapping the type in +// `decltype(instance<...>())` helps it deduce the context function's type correctly. +#define KJ_CONTEXT(...) \ + auto KJ_UNIQUE_NAME(_kjContextFunc) = [&]() -> ::kj::_::Debug::Context::Value { \ + return ::kj::_::Debug::Context::Value(__FILE__, __LINE__, \ + ::kj::_::Debug::makeDescription("" #__VA_ARGS__, __VA_ARGS__)); \ + }; \ + decltype(::kj::instance<::kj::_::Debug::ContextImpl>()) \ + KJ_UNIQUE_NAME(_kjContext)(KJ_UNIQUE_NAME(_kjContextFunc)) + +#define KJ_REQUIRE_NONNULL(value, ...) \ + (*[&] { \ + auto _kj_result = ::kj::_::readMaybe(value); \ + if (KJ_UNLIKELY(!_kj_result)) { \ + ::kj::_::Debug::Fault(__FILE__, __LINE__, ::kj::Exception::Type::FAILED, \ + #value " != nullptr", "" #__VA_ARGS__, __VA_ARGS__).fatal(); \ + } \ + return _kj_result; \ + }()) + +#define KJ_EXCEPTION(type, ...) \ + ::kj::Exception(::kj::Exception::Type::type, __FILE__, __LINE__, \ + ::kj::_::Debug::makeDescription("" #__VA_ARGS__, __VA_ARGS__)) + +#else + +#define KJ_LOG(severity, ...) \ + if (!::kj::_::Debug::shouldLog(::kj::LogSeverity::severity)) {} else \ + ::kj::_::Debug::log(__FILE__, __LINE__, ::kj::LogSeverity::severity, \ + #__VA_ARGS__, ##__VA_ARGS__) + +#define KJ_DBG(...) KJ_LOG(DBG, ##__VA_ARGS__) + +#define KJ_REQUIRE(cond, ...) \ + if (KJ_LIKELY(cond)) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, ::kj::Exception::Type::FAILED, \ + #cond, #__VA_ARGS__, ##__VA_ARGS__);; f.fatal()) + +#define KJ_FAIL_REQUIRE(...) \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, ::kj::Exception::Type::FAILED, \ + nullptr, #__VA_ARGS__, ##__VA_ARGS__);; f.fatal()) + +#define KJ_SYSCALL(call, ...) \ + if (auto _kjSyscallResult = ::kj::_::Debug::syscall([&](){return (call);}, false)) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + _kjSyscallResult.getErrorNumber(), #call, #__VA_ARGS__, ##__VA_ARGS__);; f.fatal()) + +#define KJ_NONBLOCKING_SYSCALL(call, ...) \ + if (auto _kjSyscallResult = ::kj::_::Debug::syscall([&](){return (call);}, true)) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + _kjSyscallResult.getErrorNumber(), #call, #__VA_ARGS__, ##__VA_ARGS__);; f.fatal()) + +#define KJ_FAIL_SYSCALL(code, errorNumber, ...) \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + errorNumber, code, #__VA_ARGS__, ##__VA_ARGS__);; f.fatal()) + +#if _WIN32 + +#define KJ_WIN32(call, ...) \ + if (::kj::_::Debug::isWin32Success(call)) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + ::kj::_::Debug::getWin32Error(), #call, #__VA_ARGS__, ##__VA_ARGS__);; f.fatal()) + +#define KJ_WINSOCK(call, ...) \ + if ((call) != SOCKET_ERROR) {} else \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + ::kj::_::Debug::getWin32Error(), #call, #__VA_ARGS__, ##__VA_ARGS__);; f.fatal()) + +#define KJ_FAIL_WIN32(code, errorNumber, ...) \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, \ + ::kj::_::Debug::Win32Error(errorNumber), code, #__VA_ARGS__, ##__VA_ARGS__);; f.fatal()) + +#endif + +#define KJ_UNIMPLEMENTED(...) \ + for (::kj::_::Debug::Fault f(__FILE__, __LINE__, ::kj::Exception::Type::UNIMPLEMENTED, \ + nullptr, #__VA_ARGS__, ##__VA_ARGS__);; f.fatal()) + +#define KJ_CONTEXT(...) \ + auto KJ_UNIQUE_NAME(_kjContextFunc) = [&]() -> ::kj::_::Debug::Context::Value { \ + return ::kj::_::Debug::Context::Value(__FILE__, __LINE__, \ + ::kj::_::Debug::makeDescription(#__VA_ARGS__, ##__VA_ARGS__)); \ + }; \ + ::kj::_::Debug::ContextImpl \ + KJ_UNIQUE_NAME(_kjContext)(KJ_UNIQUE_NAME(_kjContextFunc)) + +#define KJ_REQUIRE_NONNULL(value, ...) \ + (*({ \ + auto _kj_result = ::kj::_::readMaybe(value); \ + if (KJ_UNLIKELY(!_kj_result)) { \ + ::kj::_::Debug::Fault(__FILE__, __LINE__, ::kj::Exception::Type::FAILED, \ + #value " != nullptr", #__VA_ARGS__, ##__VA_ARGS__).fatal(); \ + } \ + kj::mv(_kj_result); \ + })) + +#define KJ_EXCEPTION(type, ...) \ + ::kj::Exception(::kj::Exception::Type::type, __FILE__, __LINE__, \ + ::kj::_::Debug::makeDescription(#__VA_ARGS__, ##__VA_ARGS__)) + +#endif + +#define KJ_SYSCALL_HANDLE_ERRORS(call) \ + if (int _kjSyscallError = ::kj::_::Debug::syscallError([&](){return (call);}, false)) \ + switch (int error = _kjSyscallError) +// Like KJ_SYSCALL, but doesn't throw. Instead, the block after the macro is a switch block on the +// error. Additionally, the int value `error` is defined within the block. So you can do: +// +// KJ_SYSCALL_HANDLE_ERRORS(foo()) { +// case ENOENT: +// handleNoSuchFile(); +// break; +// case EEXIST: +// handleExists(); +// break; +// default: +// KJ_FAIL_SYSCALL("foo()", error); +// } else { +// handleSuccessCase(); +// } + +#define KJ_ASSERT KJ_REQUIRE +#define KJ_FAIL_ASSERT KJ_FAIL_REQUIRE +#define KJ_ASSERT_NONNULL KJ_REQUIRE_NONNULL +// Use "ASSERT" in place of "REQUIRE" when the problem is local to the immediate surrounding code. +// That is, if the assert ever fails, it indicates that the immediate surrounding code is broken. + +#ifdef KJ_DEBUG +#define KJ_DLOG KJ_LOG +#define KJ_DASSERT KJ_ASSERT +#define KJ_DREQUIRE KJ_REQUIRE +#else +#define KJ_DLOG(...) do {} while (false) +#define KJ_DASSERT(...) do {} while (false) +#define KJ_DREQUIRE(...) do {} while (false) +#endif + +namespace _ { // private + +class Debug { +public: + Debug() = delete; + + typedef LogSeverity Severity; // backwards-compatibility + +#if _WIN32 + struct Win32Error { + // Hack for overloading purposes. + uint number; + inline explicit Win32Error(uint number): number(number) {} + }; +#endif + + static inline bool shouldLog(LogSeverity severity) { return severity >= minSeverity; } + // Returns whether messages of the given severity should be logged. + + static inline void setLogLevel(LogSeverity severity) { minSeverity = severity; } + // Set the minimum message severity which will be logged. + // + // TODO(someday): Expose publicly. + + template + static void log(const char* file, int line, LogSeverity severity, const char* macroArgs, + Params&&... params); + + class Fault { + public: + template + Fault(const char* file, int line, Code code, + const char* condition, const char* macroArgs, Params&&... params); + Fault(const char* file, int line, Exception::Type type, + const char* condition, const char* macroArgs); + Fault(const char* file, int line, int osErrorNumber, + const char* condition, const char* macroArgs); +#if _WIN32 + Fault(const char* file, int line, Win32Error osErrorNumber, + const char* condition, const char* macroArgs); +#endif + ~Fault() noexcept(false); + + KJ_NOINLINE KJ_NORETURN(void fatal()); + // Throw the exception. + + private: + void init(const char* file, int line, Exception::Type type, + const char* condition, const char* macroArgs, ArrayPtr argValues); + void init(const char* file, int line, int osErrorNumber, + const char* condition, const char* macroArgs, ArrayPtr argValues); +#if _WIN32 + void init(const char* file, int line, Win32Error osErrorNumber, + const char* condition, const char* macroArgs, ArrayPtr argValues); +#endif + + Exception* exception; + }; + + class SyscallResult { + public: + inline SyscallResult(int errorNumber): errorNumber(errorNumber) {} + inline operator void*() { return errorNumber == 0 ? this : nullptr; } + inline int getErrorNumber() { return errorNumber; } + + private: + int errorNumber; + }; + + template + static SyscallResult syscall(Call&& call, bool nonblocking); + template + static int syscallError(Call&& call, bool nonblocking); + +#if _WIN32 + static bool isWin32Success(int boolean); + static bool isWin32Success(void* handle); + static Win32Error getWin32Error(); +#endif + + class Context: public ExceptionCallback { + public: + Context(); + KJ_DISALLOW_COPY(Context); + virtual ~Context() noexcept(false); + + struct Value { + const char* file; + int line; + String description; + + inline Value(const char* file, int line, String&& description) + : file(file), line(line), description(mv(description)) {} + }; + + virtual Value evaluate() = 0; + + virtual void onRecoverableException(Exception&& exception) override; + virtual void onFatalException(Exception&& exception) override; + virtual void logMessage(LogSeverity severity, const char* file, int line, int contextDepth, + String&& text) override; + + private: + bool logged; + Maybe value; + + Value ensureInitialized(); + }; + + template + class ContextImpl: public Context { + public: + inline ContextImpl(Func& func): func(func) {} + KJ_DISALLOW_COPY(ContextImpl); + + Value evaluate() override { + return func(); + } + private: + Func& func; + }; + + template + static String makeDescription(const char* macroArgs, Params&&... params); + +private: + static LogSeverity minSeverity; + + static void logInternal(const char* file, int line, LogSeverity severity, const char* macroArgs, + ArrayPtr argValues); + static String makeDescriptionInternal(const char* macroArgs, ArrayPtr argValues); + + static int getOsErrorNumber(bool nonblocking); + // Get the error code of the last error (e.g. from errno). Returns -1 on EINTR. +}; + +template +void Debug::log(const char* file, int line, LogSeverity severity, const char* macroArgs, + Params&&... params) { + String argValues[sizeof...(Params)] = {str(params)...}; + logInternal(file, line, severity, macroArgs, arrayPtr(argValues, sizeof...(Params))); +} + +template <> +inline void Debug::log<>(const char* file, int line, LogSeverity severity, const char* macroArgs) { + logInternal(file, line, severity, macroArgs, nullptr); +} + +template +Debug::Fault::Fault(const char* file, int line, Code code, + const char* condition, const char* macroArgs, Params&&... params) + : exception(nullptr) { + String argValues[sizeof...(Params)] = {str(params)...}; + init(file, line, code, condition, macroArgs, + arrayPtr(argValues, sizeof...(Params))); +} + +inline Debug::Fault::Fault(const char* file, int line, int osErrorNumber, + const char* condition, const char* macroArgs) + : exception(nullptr) { + init(file, line, osErrorNumber, condition, macroArgs, nullptr); +} + +inline Debug::Fault::Fault(const char* file, int line, kj::Exception::Type type, + const char* condition, const char* macroArgs) + : exception(nullptr) { + init(file, line, type, condition, macroArgs, nullptr); +} + +#if _WIN32 +inline Debug::Fault::Fault(const char* file, int line, Win32Error osErrorNumber, + const char* condition, const char* macroArgs) + : exception(nullptr) { + init(file, line, osErrorNumber, condition, macroArgs, nullptr); +} + +inline bool Debug::isWin32Success(int boolean) { + return boolean; +} +inline bool Debug::isWin32Success(void* handle) { + // Assume null and INVALID_HANDLE_VALUE mean failure. + return handle != nullptr && handle != (void*)-1; +} +#endif + +template +Debug::SyscallResult Debug::syscall(Call&& call, bool nonblocking) { + while (call() < 0) { + int errorNum = getOsErrorNumber(nonblocking); + // getOsErrorNumber() returns -1 to indicate EINTR. + // Also, if nonblocking is true, then it returns 0 on EAGAIN, which will then be treated as a + // non-error. + if (errorNum != -1) { + return SyscallResult(errorNum); + } + } + return SyscallResult(0); +} + +template +int Debug::syscallError(Call&& call, bool nonblocking) { + while (call() < 0) { + int errorNum = getOsErrorNumber(nonblocking); + // getOsErrorNumber() returns -1 to indicate EINTR. + // Also, if nonblocking is true, then it returns 0 on EAGAIN, which will then be treated as a + // non-error. + if (errorNum != -1) { + return errorNum; + } + } + return 0; +} + +template +String Debug::makeDescription(const char* macroArgs, Params&&... params) { + String argValues[sizeof...(Params)] = {str(params)...}; + return makeDescriptionInternal(macroArgs, arrayPtr(argValues, sizeof...(Params))); +} + +template <> +inline String Debug::makeDescription<>(const char* macroArgs) { + return makeDescriptionInternal(macroArgs, nullptr); +} + +} // namespace _ (private) +} // namespace kj + +#endif // KJ_DEBUG_H_ diff --git a/phonelibs/capnp-cpp/include/kj/exception.h b/phonelibs/capnp-cpp/include/kj/exception.h new file mode 100644 index 00000000000000..f6c0b2daa61eeb --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/exception.h @@ -0,0 +1,363 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_EXCEPTION_H_ +#define KJ_EXCEPTION_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "memory.h" +#include "array.h" +#include "string.h" + +namespace kj { + +class ExceptionImpl; + +class Exception { + // Exception thrown in case of fatal errors. + // + // Actually, a subclass of this which also implements std::exception will be thrown, but we hide + // that fact from the interface to avoid #including . + +public: + enum class Type { + // What kind of failure? + + FAILED = 0, + // Something went wrong. This is the usual error type. KJ_ASSERT and KJ_REQUIRE throw this + // error type. + + OVERLOADED = 1, + // The call failed because of a temporary lack of resources. This could be space resources + // (out of memory, out of disk space) or time resources (request queue overflow, operation + // timed out). + // + // The operation might work if tried again, but it should NOT be repeated immediately as this + // may simply exacerbate the problem. + + DISCONNECTED = 2, + // The call required communication over a connection that has been lost. The callee will need + // to re-establish connections and try again. + + UNIMPLEMENTED = 3 + // The requested method is not implemented. The caller may wish to revert to a fallback + // approach based on other methods. + + // IF YOU ADD A NEW VALUE: + // - Update the stringifier. + // - Update Cap'n Proto's RPC protocol's Exception.Type enum. + }; + + Exception(Type type, const char* file, int line, String description = nullptr) noexcept; + Exception(Type type, String file, int line, String description = nullptr) noexcept; + Exception(const Exception& other) noexcept; + Exception(Exception&& other) = default; + ~Exception() noexcept; + + const char* getFile() const { return file; } + int getLine() const { return line; } + Type getType() const { return type; } + StringPtr getDescription() const { return description; } + ArrayPtr getStackTrace() const { return arrayPtr(trace, traceCount); } + + struct Context { + // Describes a bit about what was going on when the exception was thrown. + + const char* file; + int line; + String description; + Maybe> next; + + Context(const char* file, int line, String&& description, Maybe>&& next) + : file(file), line(line), description(mv(description)), next(mv(next)) {} + Context(const Context& other) noexcept; + }; + + inline Maybe getContext() const { + KJ_IF_MAYBE(c, context) { + return **c; + } else { + return nullptr; + } + } + + void wrapContext(const char* file, int line, String&& description); + // Wraps the context in a new node. This becomes the head node returned by getContext() -- it + // is expected that contexts will be added in reverse order as the exception passes up the + // callback stack. + + KJ_NOINLINE void extendTrace(uint ignoreCount); + // Append the current stack trace to the exception's trace, ignoring the first `ignoreCount` + // frames (see `getStackTrace()` for discussion of `ignoreCount`). + + KJ_NOINLINE void truncateCommonTrace(); + // Remove the part of the stack trace which the exception shares with the caller of this method. + // This is used by the async library to remove the async infrastructure from the stack trace + // before replacing it with the async trace. + + void addTrace(void* ptr); + // Append the given pointer to the backtrace, if it is not already full. This is used by the + // async library to trace through the promise chain that led to the exception. + +private: + String ownFile; + const char* file; + int line; + Type type; + String description; + Maybe> context; + void* trace[32]; + uint traceCount; + + friend class ExceptionImpl; +}; + +StringPtr KJ_STRINGIFY(Exception::Type type); +String KJ_STRINGIFY(const Exception& e); + +// ======================================================================================= + +enum class LogSeverity { + INFO, // Information describing what the code is up to, which users may request to see + // with a flag like `--verbose`. Does not indicate a problem. Not printed by + // default; you must call setLogLevel(INFO) to enable. + WARNING, // A problem was detected but execution can continue with correct output. + ERROR, // Something is wrong, but execution can continue with garbage output. + FATAL, // Something went wrong, and execution cannot continue. + DBG // Temporary debug logging. See KJ_DBG. + + // Make sure to update the stringifier if you add a new severity level. +}; + +StringPtr KJ_STRINGIFY(LogSeverity severity); + +class ExceptionCallback { + // If you don't like C++ exceptions, you may implement and register an ExceptionCallback in order + // to perform your own exception handling. For example, a reasonable thing to do is to have + // onRecoverableException() set a flag indicating that an error occurred, and then check for that + // flag just before writing to storage and/or returning results to the user. If the flag is set, + // discard whatever you have and return an error instead. + // + // ExceptionCallbacks must always be allocated on the stack. When an exception is thrown, the + // newest ExceptionCallback on the calling thread's stack is called. The default implementation + // of each method calls the next-oldest ExceptionCallback for that thread. Thus the callbacks + // behave a lot like try/catch blocks, except that they are called before any stack unwinding + // occurs. + +public: + ExceptionCallback(); + KJ_DISALLOW_COPY(ExceptionCallback); + virtual ~ExceptionCallback() noexcept(false); + + virtual void onRecoverableException(Exception&& exception); + // Called when an exception has been raised, but the calling code has the ability to continue by + // producing garbage output. This method _should_ throw the exception, but is allowed to simply + // return if garbage output is acceptable. + // + // The global default implementation throws an exception unless the library was compiled with + // -fno-exceptions, in which case it logs an error and returns. + + virtual void onFatalException(Exception&& exception); + // Called when an exception has been raised and the calling code cannot continue. If this method + // returns normally, abort() will be called. The method must throw the exception to avoid + // aborting. + // + // The global default implementation throws an exception unless the library was compiled with + // -fno-exceptions, in which case it logs an error and returns. + + virtual void logMessage(LogSeverity severity, const char* file, int line, int contextDepth, + String&& text); + // Called when something wants to log some debug text. `contextDepth` indicates how many levels + // of context the message passed through; it may make sense to indent the message accordingly. + // + // The global default implementation writes the text to stderr. + + enum class StackTraceMode { + FULL, + // Stringifying a stack trace will attempt to determine source file and line numbers. This may + // be expensive. For example, on Linux, this shells out to `addr2line`. + // + // This is the default in debug builds. + + ADDRESS_ONLY, + // Stringifying a stack trace will only generate a list of code addresses. + // + // This is the default in release builds. + + NONE + // Generating a stack trace will always return an empty array. + // + // This avoids ever unwinding the stack. On Windows in particular, the stack unwinding library + // has been observed to be pretty slow, so exception-heavy code might benefit significantly + // from this setting. (But exceptions should be rare...) + }; + + virtual StackTraceMode stackTraceMode(); + // Returns the current preferred stack trace mode. + +protected: + ExceptionCallback& next; + +private: + ExceptionCallback(ExceptionCallback& next); + + class RootExceptionCallback; + friend ExceptionCallback& getExceptionCallback(); +}; + +ExceptionCallback& getExceptionCallback(); +// Returns the current exception callback. + +KJ_NOINLINE KJ_NORETURN(void throwFatalException(kj::Exception&& exception, uint ignoreCount = 0)); +// Invoke the exception callback to throw the given fatal exception. If the exception callback +// returns, abort. + +KJ_NOINLINE void throwRecoverableException(kj::Exception&& exception, uint ignoreCount = 0); +// Invoke the exception callback to throw the given recoverable exception. If the exception +// callback returns, return normally. + +// ======================================================================================= + +namespace _ { class Runnable; } + +template +Maybe runCatchingExceptions(Func&& func) noexcept; +// Executes the given function (usually, a lambda returning nothing) catching any exceptions that +// are thrown. Returns the Exception if there was one, or null if the operation completed normally. +// Non-KJ exceptions will be wrapped. +// +// If exception are disabled (e.g. with -fno-exceptions), this will still detect whether any +// recoverable exceptions occurred while running the function and will return those. + +class UnwindDetector { + // Utility for detecting when a destructor is called due to unwind. Useful for: + // - Avoiding throwing exceptions in this case, which would terminate the program. + // - Detecting whether to commit or roll back a transaction. + // + // To use this class, either inherit privately from it or declare it as a member. The detector + // works by comparing the exception state against that when the constructor was called, so for + // an object that was actually constructed during exception unwind, it will behave as if no + // unwind is taking place. This is usually the desired behavior. + +public: + UnwindDetector(); + + bool isUnwinding() const; + // Returns true if the current thread is in a stack unwind that it wasn't in at the time the + // object was constructed. + + template + void catchExceptionsIfUnwinding(Func&& func) const; + // Runs the given function (e.g., a lambda). If isUnwinding() is true, any exceptions are + // caught and treated as secondary faults, meaning they are considered to be side-effects of the + // exception that is unwinding the stack. Otherwise, exceptions are passed through normally. + +private: + uint uncaughtCount; + + void catchExceptionsAsSecondaryFaults(_::Runnable& runnable) const; +}; + +namespace _ { // private + +class Runnable { +public: + virtual void run() = 0; +}; + +template +class RunnableImpl: public Runnable { +public: + RunnableImpl(Func&& func): func(kj::mv(func)) {} + void run() override { + func(); + } +private: + Func func; +}; + +Maybe runCatchingExceptions(Runnable& runnable) noexcept; + +} // namespace _ (private) + +template +Maybe runCatchingExceptions(Func&& func) noexcept { + _::RunnableImpl> runnable(kj::fwd(func)); + return _::runCatchingExceptions(runnable); +} + +template +void UnwindDetector::catchExceptionsIfUnwinding(Func&& func) const { + if (isUnwinding()) { + _::RunnableImpl> runnable(kj::fwd(func)); + catchExceptionsAsSecondaryFaults(runnable); + } else { + func(); + } +} + +#define KJ_ON_SCOPE_SUCCESS(code) \ + ::kj::UnwindDetector KJ_UNIQUE_NAME(_kjUnwindDetector); \ + KJ_DEFER(if (!KJ_UNIQUE_NAME(_kjUnwindDetector).isUnwinding()) { code; }) +// Runs `code` if the current scope is exited normally (not due to an exception). + +#define KJ_ON_SCOPE_FAILURE(code) \ + ::kj::UnwindDetector KJ_UNIQUE_NAME(_kjUnwindDetector); \ + KJ_DEFER(if (KJ_UNIQUE_NAME(_kjUnwindDetector).isUnwinding()) { code; }) +// Runs `code` if the current scope is exited due to an exception. + +// ======================================================================================= + +KJ_NOINLINE ArrayPtr getStackTrace(ArrayPtr space, uint ignoreCount); +// Attempt to get the current stack trace, returning a list of pointers to instructions. The +// returned array is a slice of `space`. Provide a larger `space` to get a deeper stack trace. +// If the platform doesn't support stack traces, returns an empty array. +// +// `ignoreCount` items will be truncated from the front of the trace. This is useful for chopping +// off a prefix of the trace that is uninteresting to the developer because it's just locations +// inside the debug infrastructure that is requesting the trace. Be careful to mark functions as +// KJ_NOINLINE if you intend to count them in `ignoreCount`. Note that, unfortunately, the +// ignored entries will still waste space in the `space` array (and the returned array's `begin()` +// is never exactly equal to `space.begin()` due to this effect, even if `ignoreCount` is zero +// since `getStackTrace()` needs to ignore its own internal frames). + +String stringifyStackTrace(ArrayPtr); +// Convert the stack trace to a string with file names and line numbers. This may involve executing +// suprocesses. + +String getStackTrace(); +// Get a stack trace right now and stringify it. Useful for debugging. + +void printStackTraceOnCrash(); +// Registers signal handlers on common "crash" signals like SIGSEGV that will (attempt to) print +// a stack trace. You should call this as early as possible on program startup. Programs using +// KJ_MAIN get this automatically. + +kj::StringPtr trimSourceFilename(kj::StringPtr filename); +// Given a source code file name, trim off noisy prefixes like "src/" or +// "/ekam-provider/canonical/". + +} // namespace kj + +#endif // KJ_EXCEPTION_H_ diff --git a/phonelibs/capnp-cpp/include/kj/function.h b/phonelibs/capnp-cpp/include/kj/function.h new file mode 100644 index 00000000000000..ba6601b560cd8e --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/function.h @@ -0,0 +1,277 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_FUNCTION_H_ +#define KJ_FUNCTION_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "memory.h" + +namespace kj { + +template +class Function; +// Function wrapper using virtual-based polymorphism. Use this when template polymorphism is +// not possible. You can, for example, accept a Function as a parameter: +// +// void setFilter(Function filter); +// +// The caller of `setFilter()` may then pass any callable object as the parameter. The callable +// object does not have to have the exact signature specified, just one that is "compatible" -- +// i.e. the return type is covariant and the parameters are contravariant. +// +// Unlike `std::function`, `kj::Function`s are movable but not copyable, just like `kj::Own`. This +// is to avoid unexpected heap allocation or slow atomic reference counting. +// +// When a `Function` is constructed from an lvalue, it captures only a reference to the value. +// When constructed from an rvalue, it invokes the value's move constructor. So, for example: +// +// struct AddN { +// int n; +// int operator(int i) { return i + n; } +// } +// +// Function f1 = AddN{2}; +// // f1 owns an instance of AddN. It may safely be moved out +// // of the local scope. +// +// AddN adder(2); +// Function f2 = adder; +// // f2 contains a reference to `adder`. Thus, it becomes invalid +// // when `adder` goes out-of-scope. +// +// AddN adder2(2); +// Function f3 = kj::mv(adder2); +// // f3 owns an insatnce of AddN moved from `adder2`. f3 may safely +// // be moved out of the local scope. +// +// Additionally, a Function may be bound to a class method using KJ_BIND_METHOD(object, methodName). +// For example: +// +// class Printer { +// public: +// void print(int i); +// void print(kj::StringPtr s); +// }; +// +// Printer p; +// +// Function intPrinter = KJ_BIND_METHOD(p, print); +// // Will call Printer::print(int). +// +// Function strPrinter = KJ_BIND_METHOD(p, print); +// // Will call Printer::print(kj::StringPtr). +// +// Notice how KJ_BIND_METHOD is able to figure out which overload to use depending on the kind of +// Function it is binding to. + +template +class ConstFunction; +// Like Function, but wraps a "const" (i.e. thread-safe) call. + +template +class Function { +public: + template + inline Function(F&& f): impl(heap>(kj::fwd(f))) {} + Function() = default; + + // Make sure people don't accidentally end up wrapping a reference when they meant to return + // a function. + KJ_DISALLOW_COPY(Function); + Function(Function&) = delete; + Function& operator=(Function&) = delete; + template Function(const Function&) = delete; + template Function& operator=(const Function&) = delete; + template Function(const ConstFunction&) = delete; + template Function& operator=(const ConstFunction&) = delete; + Function(Function&&) = default; + Function& operator=(Function&&) = default; + + inline Return operator()(Params... params) { + return (*impl)(kj::fwd(params)...); + } + + Function reference() { + // Forms a new Function of the same type that delegates to this Function by reference. + // Therefore, this Function must outlive the returned Function, but otherwise they behave + // exactly the same. + + return *impl; + } + +private: + class Iface { + public: + virtual Return operator()(Params... params) = 0; + }; + + template + class Impl final: public Iface { + public: + explicit Impl(F&& f): f(kj::fwd(f)) {} + + Return operator()(Params... params) override { + return f(kj::fwd(params)...); + } + + private: + F f; + }; + + Own impl; +}; + +template +class ConstFunction { +public: + template + inline ConstFunction(F&& f): impl(heap>(kj::fwd(f))) {} + ConstFunction() = default; + + // Make sure people don't accidentally end up wrapping a reference when they meant to return + // a function. + KJ_DISALLOW_COPY(ConstFunction); + ConstFunction(ConstFunction&) = delete; + ConstFunction& operator=(ConstFunction&) = delete; + template ConstFunction(const ConstFunction&) = delete; + template ConstFunction& operator=(const ConstFunction&) = delete; + template ConstFunction(const Function&) = delete; + template ConstFunction& operator=(const Function&) = delete; + ConstFunction(ConstFunction&&) = default; + ConstFunction& operator=(ConstFunction&&) = default; + + inline Return operator()(Params... params) const { + return (*impl)(kj::fwd(params)...); + } + + ConstFunction reference() const { + // Forms a new ConstFunction of the same type that delegates to this ConstFunction by reference. + // Therefore, this ConstFunction must outlive the returned ConstFunction, but otherwise they + // behave exactly the same. + + return *impl; + } + +private: + class Iface { + public: + virtual Return operator()(Params... params) const = 0; + }; + + template + class Impl final: public Iface { + public: + explicit Impl(F&& f): f(kj::fwd(f)) {} + + Return operator()(Params... params) const override { + return f(kj::fwd(params)...); + } + + private: + F f; + }; + + Own impl; +}; + +#if 1 + +namespace _ { // private + +template +class BoundMethod; + +template ::*method)(Params...)> +class BoundMethod::*)(Params...), method> { +public: + BoundMethod(T&& t): t(kj::fwd(t)) {} + + Return operator()(Params&&... params) { + return (t.*method)(kj::fwd(params)...); + } + +private: + T t; +}; + +template ::*method)(Params...) const> +class BoundMethod::*)(Params...) const, method> { +public: + BoundMethod(T&& t): t(kj::fwd(t)) {} + + Return operator()(Params&&... params) const { + return (t.*method)(kj::fwd(params)...); + } + +private: + T t; +}; + +} // namespace _ (private) + +#define KJ_BIND_METHOD(obj, method) \ + ::kj::_::BoundMethod::method), \ + &::kj::Decay::method>(obj) +// Macro that produces a functor object which forwards to the method `obj.name`. If `obj` is an +// lvalue, the functor will hold a reference to it. If `obj` is an rvalue, the functor will +// contain a copy (by move) of it. +// +// The current implementation requires that the method is not overloaded. +// +// TODO(someday): C++14's generic lambdas may be able to simplify this code considerably, and +// probably make it work with overloaded methods. + +#else +// Here's a better implementation of the above that doesn't work with GCC (but does with Clang) +// because it uses a local class with a template method. Sigh. This implementation supports +// overloaded methods. + +#define KJ_BIND_METHOD(obj, method) \ + ({ \ + typedef KJ_DECLTYPE_REF(obj) T; \ + class F { \ + public: \ + inline F(T&& t): t(::kj::fwd(t)) {} \ + template \ + auto operator()(Params&&... params) \ + -> decltype(::kj::instance().method(::kj::fwd(params)...)) { \ + return t.method(::kj::fwd(params)...); \ + } \ + private: \ + T t; \ + }; \ + (F(obj)); \ + }) +// Macro that produces a functor object which forwards to the method `obj.name`. If `obj` is an +// lvalue, the functor will hold a reference to it. If `obj` is an rvalue, the functor will +// contain a copy (by move) of it. + +#endif + +} // namespace kj + +#endif // KJ_FUNCTION_H_ diff --git a/phonelibs/capnp-cpp/include/kj/io.h b/phonelibs/capnp-cpp/include/kj/io.h new file mode 100644 index 00000000000000..f5c03bfe7b8a39 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/io.h @@ -0,0 +1,419 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_IO_H_ +#define KJ_IO_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include +#include "common.h" +#include "array.h" +#include "exception.h" + +namespace kj { + +// ======================================================================================= +// Abstract interfaces + +class InputStream { +public: + virtual ~InputStream() noexcept(false); + + size_t read(void* buffer, size_t minBytes, size_t maxBytes); + // Reads at least minBytes and at most maxBytes, copying them into the given buffer. Returns + // the size read. Throws an exception on errors. Implemented in terms of tryRead(). + // + // maxBytes is the number of bytes the caller really wants, but minBytes is the minimum amount + // needed by the caller before it can start doing useful processing. If the stream returns less + // than maxBytes, the caller will usually call read() again later to get the rest. Returning + // less than maxBytes is useful when it makes sense for the caller to parallelize processing + // with I/O. + // + // Never blocks if minBytes is zero. If minBytes is zero and maxBytes is non-zero, this may + // attempt a non-blocking read or may just return zero. To force a read, use a non-zero minBytes. + // To detect EOF without throwing an exception, use tryRead(). + // + // If the InputStream can't produce minBytes, it MUST throw an exception, as the caller is not + // expected to understand how to deal with partial reads. + + virtual size_t tryRead(void* buffer, size_t minBytes, size_t maxBytes) = 0; + // Like read(), but may return fewer than minBytes on EOF. + + inline void read(void* buffer, size_t bytes) { read(buffer, bytes, bytes); } + // Convenience method for reading an exact number of bytes. + + virtual void skip(size_t bytes); + // Skips past the given number of bytes, discarding them. The default implementation read()s + // into a scratch buffer. +}; + +class OutputStream { +public: + virtual ~OutputStream() noexcept(false); + + virtual void write(const void* buffer, size_t size) = 0; + // Always writes the full size. Throws exception on error. + + virtual void write(ArrayPtr> pieces); + // Equivalent to write()ing each byte array in sequence, which is what the default implementation + // does. Override if you can do something better, e.g. use writev() to do the write in a single + // syscall. +}; + +class BufferedInputStream: public InputStream { + // An input stream which buffers some bytes in memory to reduce system call overhead. + // - OR - + // An input stream that actually reads from some in-memory data structure and wants to give its + // caller a direct pointer to that memory to potentially avoid a copy. + +public: + virtual ~BufferedInputStream() noexcept(false); + + ArrayPtr getReadBuffer(); + // Get a direct pointer into the read buffer, which contains the next bytes in the input. If the + // caller consumes any bytes, it should then call skip() to indicate this. This always returns a + // non-empty buffer or throws an exception. Implemented in terms of tryGetReadBuffer(). + + virtual ArrayPtr tryGetReadBuffer() = 0; + // Like getReadBuffer() but may return an empty buffer on EOF. +}; + +class BufferedOutputStream: public OutputStream { + // An output stream which buffers some bytes in memory to reduce system call overhead. + // - OR - + // An output stream that actually writes into some in-memory data structure and wants to give its + // caller a direct pointer to that memory to potentially avoid a copy. + +public: + virtual ~BufferedOutputStream() noexcept(false); + + virtual ArrayPtr getWriteBuffer() = 0; + // Get a direct pointer into the write buffer. The caller may choose to fill in some prefix of + // this buffer and then pass it to write(), in which case write() may avoid a copy. It is + // incorrect to pass to write any slice of this buffer which is not a prefix. +}; + +// ======================================================================================= +// Buffered streams implemented as wrappers around regular streams + +class BufferedInputStreamWrapper: public BufferedInputStream { + // Implements BufferedInputStream in terms of an InputStream. + // + // Note that the underlying stream's position is unpredictable once the wrapper is destroyed, + // unless the entire stream was consumed. To read a predictable number of bytes in a buffered + // way without going over, you'd need this wrapper to wrap some other wrapper which itself + // implements an artificial EOF at the desired point. Such a stream should be trivial to write + // but is not provided by the library at this time. + +public: + explicit BufferedInputStreamWrapper(InputStream& inner, ArrayPtr buffer = nullptr); + // Creates a buffered stream wrapping the given non-buffered stream. No guarantee is made about + // the position of the inner stream after a buffered wrapper has been created unless the entire + // input is read. + // + // If the second parameter is non-null, the stream uses the given buffer instead of allocating + // its own. This may improve performance if the buffer can be reused. + + KJ_DISALLOW_COPY(BufferedInputStreamWrapper); + ~BufferedInputStreamWrapper() noexcept(false); + + // implements BufferedInputStream ---------------------------------- + ArrayPtr tryGetReadBuffer() override; + size_t tryRead(void* buffer, size_t minBytes, size_t maxBytes) override; + void skip(size_t bytes) override; + +private: + InputStream& inner; + Array ownedBuffer; + ArrayPtr buffer; + ArrayPtr bufferAvailable; +}; + +class BufferedOutputStreamWrapper: public BufferedOutputStream { + // Implements BufferedOutputStream in terms of an OutputStream. Note that writes to the + // underlying stream may be delayed until flush() is called or the wrapper is destroyed. + +public: + explicit BufferedOutputStreamWrapper(OutputStream& inner, ArrayPtr buffer = nullptr); + // Creates a buffered stream wrapping the given non-buffered stream. + // + // If the second parameter is non-null, the stream uses the given buffer instead of allocating + // its own. This may improve performance if the buffer can be reused. + + KJ_DISALLOW_COPY(BufferedOutputStreamWrapper); + ~BufferedOutputStreamWrapper() noexcept(false); + + void flush(); + // Force the wrapper to write any remaining bytes in its buffer to the inner stream. Note that + // this only flushes this object's buffer; this object has no idea how to flush any other buffers + // that may be present in the underlying stream. + + // implements BufferedOutputStream --------------------------------- + ArrayPtr getWriteBuffer() override; + void write(const void* buffer, size_t size) override; + +private: + OutputStream& inner; + Array ownedBuffer; + ArrayPtr buffer; + byte* bufferPos; + UnwindDetector unwindDetector; +}; + +// ======================================================================================= +// Array I/O + +class ArrayInputStream: public BufferedInputStream { +public: + explicit ArrayInputStream(ArrayPtr array); + KJ_DISALLOW_COPY(ArrayInputStream); + ~ArrayInputStream() noexcept(false); + + // implements BufferedInputStream ---------------------------------- + ArrayPtr tryGetReadBuffer() override; + size_t tryRead(void* buffer, size_t minBytes, size_t maxBytes) override; + void skip(size_t bytes) override; + +private: + ArrayPtr array; +}; + +class ArrayOutputStream: public BufferedOutputStream { +public: + explicit ArrayOutputStream(ArrayPtr array); + KJ_DISALLOW_COPY(ArrayOutputStream); + ~ArrayOutputStream() noexcept(false); + + ArrayPtr getArray() { + // Get the portion of the array which has been filled in. + return arrayPtr(array.begin(), fillPos); + } + + // implements BufferedInputStream ---------------------------------- + ArrayPtr getWriteBuffer() override; + void write(const void* buffer, size_t size) override; + +private: + ArrayPtr array; + byte* fillPos; +}; + +class VectorOutputStream: public BufferedOutputStream { +public: + explicit VectorOutputStream(size_t initialCapacity = 4096); + KJ_DISALLOW_COPY(VectorOutputStream); + ~VectorOutputStream() noexcept(false); + + ArrayPtr getArray() { + // Get the portion of the array which has been filled in. + return arrayPtr(vector.begin(), fillPos); + } + + // implements BufferedInputStream ---------------------------------- + ArrayPtr getWriteBuffer() override; + void write(const void* buffer, size_t size) override; + +private: + Array vector; + byte* fillPos; + + void grow(size_t minSize); +}; + +// ======================================================================================= +// File descriptor I/O + +class AutoCloseFd { + // A wrapper around a file descriptor which automatically closes the descriptor when destroyed. + // The wrapper supports move construction for transferring ownership of the descriptor. If + // close() returns an error, the destructor throws an exception, UNLESS the destructor is being + // called during unwind from another exception, in which case the close error is ignored. + // + // If your code is not exception-safe, you should not use AutoCloseFd. In this case you will + // have to call close() yourself and handle errors appropriately. + +public: + inline AutoCloseFd(): fd(-1) {} + inline AutoCloseFd(decltype(nullptr)): fd(-1) {} + inline explicit AutoCloseFd(int fd): fd(fd) {} + inline AutoCloseFd(AutoCloseFd&& other) noexcept: fd(other.fd) { other.fd = -1; } + KJ_DISALLOW_COPY(AutoCloseFd); + ~AutoCloseFd() noexcept(false); + + inline AutoCloseFd& operator=(AutoCloseFd&& other) { + AutoCloseFd old(kj::mv(*this)); + fd = other.fd; + other.fd = -1; + return *this; + } + + inline AutoCloseFd& operator=(decltype(nullptr)) { + AutoCloseFd old(kj::mv(*this)); + return *this; + } + + inline operator int() const { return fd; } + inline int get() const { return fd; } + + operator bool() const = delete; + // Deleting this operator prevents accidental use in boolean contexts, which + // the int conversion operator above would otherwise allow. + + inline bool operator==(decltype(nullptr)) { return fd < 0; } + inline bool operator!=(decltype(nullptr)) { return fd >= 0; } + +private: + int fd; + UnwindDetector unwindDetector; +}; + +inline auto KJ_STRINGIFY(const AutoCloseFd& fd) + -> decltype(kj::toCharSequence(implicitCast(fd))) { + return kj::toCharSequence(implicitCast(fd)); +} + +class FdInputStream: public InputStream { + // An InputStream wrapping a file descriptor. + +public: + explicit FdInputStream(int fd): fd(fd) {} + explicit FdInputStream(AutoCloseFd fd): fd(fd), autoclose(mv(fd)) {} + KJ_DISALLOW_COPY(FdInputStream); + ~FdInputStream() noexcept(false); + + size_t tryRead(void* buffer, size_t minBytes, size_t maxBytes) override; + + inline int getFd() const { return fd; } + +private: + int fd; + AutoCloseFd autoclose; +}; + +class FdOutputStream: public OutputStream { + // An OutputStream wrapping a file descriptor. + +public: + explicit FdOutputStream(int fd): fd(fd) {} + explicit FdOutputStream(AutoCloseFd fd): fd(fd), autoclose(mv(fd)) {} + KJ_DISALLOW_COPY(FdOutputStream); + ~FdOutputStream() noexcept(false); + + void write(const void* buffer, size_t size) override; + void write(ArrayPtr> pieces) override; + + inline int getFd() const { return fd; } + +private: + int fd; + AutoCloseFd autoclose; +}; + +// ======================================================================================= +// Win32 Handle I/O + +#ifdef _WIN32 + +class AutoCloseHandle { + // A wrapper around a Win32 HANDLE which automatically closes the handle when destroyed. + // The wrapper supports move construction for transferring ownership of the handle. If + // CloseHandle() returns an error, the destructor throws an exception, UNLESS the destructor is + // being called during unwind from another exception, in which case the close error is ignored. + // + // If your code is not exception-safe, you should not use AutoCloseHandle. In this case you will + // have to call close() yourself and handle errors appropriately. + +public: + inline AutoCloseHandle(): handle((void*)-1) {} + inline AutoCloseHandle(decltype(nullptr)): handle((void*)-1) {} + inline explicit AutoCloseHandle(void* handle): handle(handle) {} + inline AutoCloseHandle(AutoCloseHandle&& other) noexcept: handle(other.handle) { + other.handle = (void*)-1; + } + KJ_DISALLOW_COPY(AutoCloseHandle); + ~AutoCloseHandle() noexcept(false); + + inline AutoCloseHandle& operator=(AutoCloseHandle&& other) { + AutoCloseHandle old(kj::mv(*this)); + handle = other.handle; + other.handle = (void*)-1; + return *this; + } + + inline AutoCloseHandle& operator=(decltype(nullptr)) { + AutoCloseHandle old(kj::mv(*this)); + return *this; + } + + inline operator void*() const { return handle; } + inline void* get() const { return handle; } + + operator bool() const = delete; + // Deleting this operator prevents accidental use in boolean contexts, which + // the void* conversion operator above would otherwise allow. + + inline bool operator==(decltype(nullptr)) { return handle != (void*)-1; } + inline bool operator!=(decltype(nullptr)) { return handle == (void*)-1; } + +private: + void* handle; // -1 (aka INVALID_HANDLE_VALUE) if not valid. +}; + +class HandleInputStream: public InputStream { + // An InputStream wrapping a Win32 HANDLE. + +public: + explicit HandleInputStream(void* handle): handle(handle) {} + explicit HandleInputStream(AutoCloseHandle handle): handle(handle), autoclose(mv(handle)) {} + KJ_DISALLOW_COPY(HandleInputStream); + ~HandleInputStream() noexcept(false); + + size_t tryRead(void* buffer, size_t minBytes, size_t maxBytes) override; + +private: + void* handle; + AutoCloseHandle autoclose; +}; + +class HandleOutputStream: public OutputStream { + // An OutputStream wrapping a Win32 HANDLE. + +public: + explicit HandleOutputStream(void* handle): handle(handle) {} + explicit HandleOutputStream(AutoCloseHandle handle): handle(handle), autoclose(mv(handle)) {} + KJ_DISALLOW_COPY(HandleOutputStream); + ~HandleOutputStream() noexcept(false); + + void write(const void* buffer, size_t size) override; + +private: + void* handle; + AutoCloseHandle autoclose; +}; + +#endif // _WIN32 + +} // namespace kj + +#endif // KJ_IO_H_ diff --git a/phonelibs/capnp-cpp/include/kj/main.h b/phonelibs/capnp-cpp/include/kj/main.h new file mode 100644 index 00000000000000..4dcd804fd4d224 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/main.h @@ -0,0 +1,407 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_MAIN_H_ +#define KJ_MAIN_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "array.h" +#include "string.h" +#include "vector.h" +#include "function.h" + +namespace kj { + +class ProcessContext { + // Context for command-line programs. + +public: + virtual StringPtr getProgramName() = 0; + // Get argv[0] as passed to main(). + + KJ_NORETURN(virtual void exit()) = 0; + // Indicates program completion. The program is considered successful unless `error()` was + // called. Typically this exits with _Exit(), meaning that the stack is not unwound, buffers + // are not flushed, etc. -- it is the responsibility of the caller to flush any buffers that + // matter. However, an alternate context implementation e.g. for unit testing purposes could + // choose to throw an exception instead. + // + // At first this approach may sound crazy. Isn't it much better to shut down cleanly? What if + // you lose data? However, it turns out that if you look at each common class of program, _Exit() + // is almost always preferable. Let's break it down: + // + // * Commands: A typical program you might run from the command line is single-threaded and + // exits quickly and deterministically. Commands often use buffered I/O and need to flush + // those buffers before exit. However, most of the work performed by destructors is not + // flushing buffers, but rather freeing up memory, placing objects into freelists, and closing + // file descriptors. All of this is irrelevant if the process is about to exit anyway, and + // for a command that runs quickly, time wasted freeing heap space may make a real difference + // in the overall runtime of a script. Meanwhile, it is usually easy to determine exactly what + // resources need to be flushed before exit, and easy to tell if they are not being flushed + // (because the command fails to produce the expected output). Therefore, it is reasonably + // easy for commands to explicitly ensure all output is flushed before exiting, and it is + // probably a good idea for them to do so anyway, because write failures should be detected + // and handled. For commands, a good strategy is to allocate any objects that require clean + // destruction on the stack, and allow them to go out of scope before the command exits. + // Meanwhile, any resources which do not need to be cleaned up should be allocated as members + // of the command's main class, whose destructor normally will not be called. + // + // * Interactive apps: Programs that interact with the user (whether they be graphical apps + // with windows or console-based apps like emacs) generally exit only when the user asks them + // to. Such applications may store large data structures in memory which need to be synced + // to disk, such as documents or user preferences. However, relying on stack unwind or global + // destructors as the mechanism for ensuring such syncing occurs is probably wrong. First of + // all, it's 2013, and applications ought to be actively syncing changes to non-volatile + // storage the moment those changes are made. Applications can crash at any time and a crash + // should never lose data that is more than half a second old. Meanwhile, if a user actually + // does try to close an application while unsaved changes exist, the application UI should + // prompt the user to decide what to do. Such a UI mechanism is obviously too high level to + // be implemented via destructors, so KJ's use of _Exit() shouldn't make a difference here. + // + // * Servers: A good server is fault-tolerant, prepared for the possibility that at any time + // it could crash, the OS could decide to kill it off, or the machine it is running on could + // just die. So, using _Exit() should be no problem. In fact, servers generally never even + // call exit anyway; they are killed externally. + // + // * Batch jobs: A long-running batch job is something between a command and a server. It + // probably knows exactly what needs to be flushed before exiting, and it probably should be + // fault-tolerant. + // + // Meanwhile, regardless of program type, if you are adhering to KJ style, then the use of + // _Exit() shouldn't be a problem anyway: + // + // * KJ style forbids global mutable state (singletons) in general and global constructors and + // destructors in particular. Therefore, everything that could possibly need cleanup either + // lives on the stack or is transitively owned by something living on the stack. + // + // * Calling exit() simply means "Don't clean up anything older than this stack frame.". If you + // have resources that require cleanup before exit, make sure they are owned by stack frames + // beyond the one that eventually calls exit(). To be as safe as possible, don't place any + // state in your program's main class, and don't call exit() yourself. Then, runMainAndExit() + // will do it, and the only thing on the stack at that time will be your main class, which + // has no state anyway. + // + // TODO(someday): Perhaps we should use the new std::quick_exit(), so that at_quick_exit() is + // available for those who really think they need it. Unfortunately, it is not yet available + // on many platforms. + + virtual void warning(StringPtr message) = 0; + // Print the given message to standard error. A newline is printed after the message if it + // doesn't already have one. + + virtual void error(StringPtr message) = 0; + // Like `warning()`, but also sets a flag indicating that the process has failed, and that when + // it eventually exits it should indicate an error status. + + KJ_NORETURN(virtual void exitError(StringPtr message)) = 0; + // Equivalent to `error(message)` followed by `exit()`. + + KJ_NORETURN(virtual void exitInfo(StringPtr message)) = 0; + // Displays the given non-error message to the user and then calls `exit()`. This is used to + // implement things like --help. + + virtual void increaseLoggingVerbosity() = 0; + // Increase the level of detail produced by the debug logging system. `MainBuilder` invokes + // this if the caller uses the -v flag. + + // TODO(someday): Add interfaces representing standard OS resources like the filesystem, so that + // these things can be mocked out. +}; + +class TopLevelProcessContext final: public ProcessContext { + // A ProcessContext implementation appropriate for use at the actual entry point of a process + // (as opposed to when you are trying to call a program's main function from within some other + // program). This implementation writes errors to stderr, and its `exit()` method actually + // calls the C `quick_exit()` function. + +public: + explicit TopLevelProcessContext(StringPtr programName); + + struct CleanShutdownException { int exitCode; }; + // If the environment variable KJ_CLEAN_SHUTDOWN is set, then exit() will actually throw this + // exception rather than exiting. `kj::runMain()` catches this exception and returns normally. + // This is useful primarily for testing purposes, to assist tools like memory leak checkers that + // are easily confused by quick_exit(). + + StringPtr getProgramName() override; + KJ_NORETURN(void exit() override); + void warning(StringPtr message) override; + void error(StringPtr message) override; + KJ_NORETURN(void exitError(StringPtr message) override); + KJ_NORETURN(void exitInfo(StringPtr message) override); + void increaseLoggingVerbosity() override; + +private: + StringPtr programName; + bool cleanShutdown; + bool hadErrors = false; +}; + +typedef Function params)> MainFunc; + +int runMainAndExit(ProcessContext& context, MainFunc&& func, int argc, char* argv[]); +// Runs the given main function and then exits using the given context. If an exception is thrown, +// this will catch it, report it via the context and exit with an error code. +// +// Normally this function does not return, because returning would probably lead to wasting time +// on cleanup when the process is just going to exit anyway. However, to facilitate memory leak +// checkers and other tools that require a clean shutdown to do their job, if the environment +// variable KJ_CLEAN_SHUTDOWN is set, the function will in fact return an exit code, which should +// then be returned from main(). +// +// Most users will use the KJ_MAIN() macro rather than call this function directly. + +#define KJ_MAIN(MainClass) \ + int main(int argc, char* argv[]) { \ + ::kj::TopLevelProcessContext context(argv[0]); \ + MainClass mainObject(context); \ + return ::kj::runMainAndExit(context, mainObject.getMain(), argc, argv); \ + } +// Convenience macro for declaring a main function based on the given class. The class must have +// a constructor that accepts a ProcessContext& and a method getMain() which returns +// kj::MainFunc (probably building it using a MainBuilder). + +class MainBuilder { + // Builds a main() function with nice argument parsing. As options and arguments are parsed, + // corresponding callbacks are called, so that you never have to write a massive switch() + // statement to interpret arguments. Additionally, this approach encourages you to write + // main classes that have a reasonable API that can be used as an alternative to their + // command-line interface. + // + // All StringPtrs passed to MainBuilder must remain valid until option parsing completes. The + // assumption is that these strings will all be literals, making this an easy requirement. If + // not, consider allocating them in an Arena. + // + // Some flags are automatically recognized by the main functions built by this class: + // --help: Prints help text and exits. The help text is constructed based on the + // information you provide to the builder as you define each flag. + // --verbose: Increase logging verbosity. + // --version: Print version information and exit. + // + // Example usage: + // + // class FooMain { + // public: + // FooMain(kj::ProcessContext& context): context(context) {} + // + // bool setAll() { all = true; return true; } + // // Enable the --all flag. + // + // kj::MainBuilder::Validity setOutput(kj::StringPtr name) { + // // Set the output file. + // + // if (name.endsWith(".foo")) { + // outputFile = name; + // return true; + // } else { + // return "Output file must have extension .foo."; + // } + // } + // + // kj::MainBuilder::Validity processInput(kj::StringPtr name) { + // // Process an input file. + // + // if (!exists(name)) { + // return kj::str(name, ": file not found"); + // } + // // ... process the input file ... + // return true; + // } + // + // kj::MainFunc getMain() { + // return MainBuilder(context, "Foo Builder v1.5", "Reads s and builds a Foo.") + // .addOption({'a', "all"}, KJ_BIND_METHOD(*this, setAll), + // "Frob all the widgets. Otherwise, only some widgets are frobbed.") + // .addOptionWithArg({'o', "output"}, KJ_BIND_METHOD(*this, setOutput), + // "", "Output to . Must be a .foo file.") + // .expectOneOrMoreArgs("", KJ_BIND_METHOD(*this, processInput)) + // .build(); + // } + // + // private: + // bool all = false; + // kj::StringPtr outputFile; + // kj::ProcessContext& context; + // }; + +public: + MainBuilder(ProcessContext& context, StringPtr version, + StringPtr briefDescription, StringPtr extendedDescription = nullptr); + ~MainBuilder() noexcept(false); + + class OptionName { + public: + OptionName() = default; + inline OptionName(char shortName): isLong(false), shortName(shortName) {} + inline OptionName(const char* longName): isLong(true), longName(longName) {} + + private: + bool isLong; + union { + char shortName; + const char* longName; + }; + friend class MainBuilder; + }; + + class Validity { + public: + inline Validity(bool valid) { + if (!valid) errorMessage = heapString("invalid argument"); + } + inline Validity(const char* errorMessage) + : errorMessage(heapString(errorMessage)) {} + inline Validity(String&& errorMessage) + : errorMessage(kj::mv(errorMessage)) {} + + inline const Maybe& getError() const { return errorMessage; } + inline Maybe releaseError() { return kj::mv(errorMessage); } + + private: + Maybe errorMessage; + friend class MainBuilder; + }; + + MainBuilder& addOption(std::initializer_list names, Function callback, + StringPtr helpText); + // Defines a new option (flag). `names` is a list of characters and strings that can be used to + // specify the option on the command line. Single-character names are used with "-" while string + // names are used with "--". `helpText` is a natural-language description of the flag. + // + // `callback` is called when the option is seen. Its return value indicates whether the option + // was accepted. If not, further option processing stops, and error is written, and the process + // exits. + // + // Example: + // + // builder.addOption({'a', "all"}, KJ_BIND_METHOD(*this, showAll), "Show all files."); + // + // This option could be specified in the following ways: + // + // -a + // --all + // + // Note that single-character option names can be combined into a single argument. For example, + // `-abcd` is equivalent to `-a -b -c -d`. + // + // The help text for this option would look like: + // + // -a, --all + // Show all files. + // + // Note that help text is automatically word-wrapped. + + MainBuilder& addOptionWithArg(std::initializer_list names, + Function callback, + StringPtr argumentTitle, StringPtr helpText); + // Like `addOption()`, but adds an option which accepts an argument. `argumentTitle` is used in + // the help text. The argument text is passed to the callback. + // + // Example: + // + // builder.addOptionWithArg({'o', "output"}, KJ_BIND_METHOD(*this, setOutput), + // "", "Output to ."); + // + // This option could be specified with an argument of "foo" in the following ways: + // + // -ofoo + // -o foo + // --output=foo + // --output foo + // + // Note that single-character option names can be combined, but only the last option can have an + // argument, since the characters after the option letter are interpreted as the argument. E.g. + // `-abofoo` would be equivalent to `-a -b -o foo`. + // + // The help text for this option would look like: + // + // -o FILENAME, --output=FILENAME + // Output to FILENAME. + + MainBuilder& addSubCommand(StringPtr name, Function getSubParser, + StringPtr briefHelpText); + // If exactly the given name is seen as an argument, invoke getSubParser() and then pass all + // remaining arguments to the parser it returns. This is useful for implementing commands which + // have lots of sub-commands, like "git" (which has sub-commands "checkout", "branch", "pull", + // etc.). + // + // `getSubParser` is only called if the command is seen. This avoids building main functions + // for commands that aren't used. + // + // `briefHelpText` should be brief enough to show immediately after the command name on a single + // line. It will not be wrapped. Users can use the built-in "help" command to get extended + // help on a particular command. + + MainBuilder& expectArg(StringPtr title, Function callback); + MainBuilder& expectOptionalArg(StringPtr title, Function callback); + MainBuilder& expectZeroOrMoreArgs(StringPtr title, Function callback); + MainBuilder& expectOneOrMoreArgs(StringPtr title, Function callback); + // Set callbacks to handle arguments. `expectArg()` and `expectOptionalArg()` specify positional + // arguments with special handling, while `expect{Zero,One}OrMoreArgs()` specifies a handler for + // an argument list (the handler is called once for each argument in the list). `title` + // specifies how the argument should be represented in the usage text. + // + // All options callbacks are called before argument callbacks, regardless of their ordering on + // the command line. This matches GNU getopt's behavior of permuting non-flag arguments to the + // end of the argument list. Also matching getopt, the special option "--" indicates that the + // rest of the command line is all arguments, not options, even if they start with '-'. + // + // The interpretation of positional arguments is fairly flexible. The non-optional arguments can + // be expected at the beginning, end, or in the middle. If more arguments are specified than + // the number of non-optional args, they are assigned to the optional argument handlers in the + // order of registration. + // + // For example, say you called: + // builder.expectArg("", ...); + // builder.expectOptionalArg("", ...); + // builder.expectArg("", ...); + // builder.expectZeroOrMoreArgs("", ...); + // builder.expectArg("", ...); + // + // This command requires at least three arguments: foo, baz, and corge. If four arguments are + // given, the second is assigned to bar. If five or more arguments are specified, then the + // arguments between the third and last are assigned to qux. Note that it never makes sense + // to call `expect*OrMoreArgs()` more than once since only the first call would ever be used. + // + // In practice, you probably shouldn't create such complicated commands as in the above example. + // But, this flexibility seems necessary to support commands where the first argument is special + // as well as commands (like `cp`) where the last argument is special. + + MainBuilder& callAfterParsing(Function callback); + // Call the given function after all arguments have been parsed. + + MainFunc build(); + // Build the "main" function, which simply parses the arguments. Once this returns, the + // `MainBuilder` is no longer valid. + +private: + struct Impl; + Own impl; + + class MainImpl; +}; + +} // namespace kj + +#endif // KJ_MAIN_H_ diff --git a/phonelibs/capnp-cpp/include/kj/memory.h b/phonelibs/capnp-cpp/include/kj/memory.h new file mode 100644 index 00000000000000..60912b0a344fce --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/memory.h @@ -0,0 +1,406 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_MEMORY_H_ +#define KJ_MEMORY_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "common.h" + +namespace kj { + +// ======================================================================================= +// Disposer -- Implementation details. + +class Disposer { + // Abstract interface for a thing that "disposes" of objects, where "disposing" usually means + // calling the destructor followed by freeing the underlying memory. `Own` encapsulates an + // object pointer with corresponding Disposer. + // + // Few developers will ever touch this interface. It is primarily useful for those implementing + // custom memory allocators. + +protected: + // Do not declare a destructor, as doing so will force a global initializer for each HeapDisposer + // instance. Eww! + + virtual void disposeImpl(void* pointer) const = 0; + // Disposes of the object, given a pointer to the beginning of the object. If the object is + // polymorphic, this pointer is determined by dynamic_cast(). For non-polymorphic types, + // Own does not allow any casting, so the pointer exactly matches the original one given to + // Own. + +public: + + template + void dispose(T* object) const; + // Helper wrapper around disposeImpl(). + // + // If T is polymorphic, calls `disposeImpl(dynamic_cast(object))`, otherwise calls + // `disposeImpl(implicitCast(object))`. + // + // Callers must not call dispose() on the same pointer twice, even if the first call throws + // an exception. + +private: + template + struct Dispose_; +}; + +template +class DestructorOnlyDisposer: public Disposer { + // A disposer that merely calls the type's destructor and nothing else. + +public: + static const DestructorOnlyDisposer instance; + + void disposeImpl(void* pointer) const override { + reinterpret_cast(pointer)->~T(); + } +}; + +template +const DestructorOnlyDisposer DestructorOnlyDisposer::instance = DestructorOnlyDisposer(); + +class NullDisposer: public Disposer { + // A disposer that does nothing. + +public: + static const NullDisposer instance; + + void disposeImpl(void* pointer) const override {} +}; + +// ======================================================================================= +// Own -- An owned pointer. + +template +class Own { + // A transferrable title to a T. When an Own goes out of scope, the object's Disposer is + // called to dispose of it. An Own can be efficiently passed by move, without relocating the + // underlying object; this transfers ownership. + // + // This is much like std::unique_ptr, except: + // - You cannot release(). An owned object is not necessarily allocated with new (see next + // point), so it would be hard to use release() correctly. + // - The deleter is made polymorphic by virtual call rather than by template. This is much + // more powerful -- it allows the use of custom allocators, freelists, etc. This could + // _almost_ be accomplished with unique_ptr by forcing everyone to use something like + // std::unique_ptr, except that things get hairy in the presence of multiple + // inheritance and upcasting, and anyway if you force everyone to use a custom deleter + // then you've lost any benefit to interoperating with the "standard" unique_ptr. + +public: + KJ_DISALLOW_COPY(Own); + inline Own(): disposer(nullptr), ptr(nullptr) {} + inline Own(Own&& other) noexcept + : disposer(other.disposer), ptr(other.ptr) { other.ptr = nullptr; } + inline Own(Own>&& other) noexcept + : disposer(other.disposer), ptr(other.ptr) { other.ptr = nullptr; } + template ()>> + inline Own(Own&& other) noexcept + : disposer(other.disposer), ptr(other.ptr) { + static_assert(__is_polymorphic(T), + "Casting owned pointers requires that the target type is polymorphic."); + other.ptr = nullptr; + } + inline Own(T* ptr, const Disposer& disposer) noexcept: disposer(&disposer), ptr(ptr) {} + + ~Own() noexcept(false) { dispose(); } + + inline Own& operator=(Own&& other) { + // Move-assingnment operator. + + // Careful, this might own `other`. Therefore we have to transfer the pointers first, then + // dispose. + const Disposer* disposerCopy = disposer; + T* ptrCopy = ptr; + disposer = other.disposer; + ptr = other.ptr; + other.ptr = nullptr; + if (ptrCopy != nullptr) { + disposerCopy->dispose(const_cast*>(ptrCopy)); + } + return *this; + } + + inline Own& operator=(decltype(nullptr)) { + dispose(); + return *this; + } + + template + Own downcast() { + // Downcast the pointer to Own, destroying the original pointer. If this pointer does not + // actually point at an instance of U, the results are undefined (throws an exception in debug + // mode if RTTI is enabled, otherwise you're on your own). + + Own result; + if (ptr != nullptr) { + result.ptr = &kj::downcast(*ptr); + result.disposer = disposer; + ptr = nullptr; + } + return result; + } + +#define NULLCHECK KJ_IREQUIRE(ptr != nullptr, "null Own<> dereference") + inline T* operator->() { NULLCHECK; return ptr; } + inline const T* operator->() const { NULLCHECK; return ptr; } + inline T& operator*() { NULLCHECK; return *ptr; } + inline const T& operator*() const { NULLCHECK; return *ptr; } +#undef NULLCHECK + inline T* get() { return ptr; } + inline const T* get() const { return ptr; } + inline operator T*() { return ptr; } + inline operator const T*() const { return ptr; } + +private: + const Disposer* disposer; // Only valid if ptr != nullptr. + T* ptr; + + inline explicit Own(decltype(nullptr)): disposer(nullptr), ptr(nullptr) {} + + inline bool operator==(decltype(nullptr)) { return ptr == nullptr; } + inline bool operator!=(decltype(nullptr)) { return ptr != nullptr; } + // Only called by Maybe>. + + inline void dispose() { + // Make sure that if an exception is thrown, we are left with a null ptr, so we won't possibly + // dispose again. + T* ptrCopy = ptr; + if (ptrCopy != nullptr) { + ptr = nullptr; + disposer->dispose(const_cast*>(ptrCopy)); + } + } + + template + friend class Own; + friend class Maybe>; +}; + +namespace _ { // private + +template +class OwnOwn { +public: + inline OwnOwn(Own&& value) noexcept: value(kj::mv(value)) {} + + inline Own& operator*() & { return value; } + inline const Own& operator*() const & { return value; } + inline Own&& operator*() && { return kj::mv(value); } + inline const Own&& operator*() const && { return kj::mv(value); } + inline Own* operator->() { return &value; } + inline const Own* operator->() const { return &value; } + inline operator Own*() { return value ? &value : nullptr; } + inline operator const Own*() const { return value ? &value : nullptr; } + +private: + Own value; +}; + +template +OwnOwn readMaybe(Maybe>&& maybe) { return OwnOwn(kj::mv(maybe.ptr)); } +template +Own* readMaybe(Maybe>& maybe) { return maybe.ptr ? &maybe.ptr : nullptr; } +template +const Own* readMaybe(const Maybe>& maybe) { return maybe.ptr ? &maybe.ptr : nullptr; } + +} // namespace _ (private) + +template +class Maybe> { +public: + inline Maybe(): ptr(nullptr) {} + inline Maybe(Own&& t) noexcept: ptr(kj::mv(t)) {} + inline Maybe(Maybe&& other) noexcept: ptr(kj::mv(other.ptr)) {} + + template + inline Maybe(Maybe>&& other): ptr(mv(other.ptr)) {} + template + inline Maybe(Own&& other): ptr(mv(other)) {} + + inline Maybe(decltype(nullptr)) noexcept: ptr(nullptr) {} + + inline operator Maybe() { return ptr.get(); } + inline operator Maybe() const { return ptr.get(); } + + inline Maybe& operator=(Maybe&& other) { ptr = kj::mv(other.ptr); return *this; } + + inline bool operator==(decltype(nullptr)) const { return ptr == nullptr; } + inline bool operator!=(decltype(nullptr)) const { return ptr != nullptr; } + + Own& orDefault(Own& defaultValue) { + if (ptr == nullptr) { + return defaultValue; + } else { + return ptr; + } + } + const Own& orDefault(const Own& defaultValue) const { + if (ptr == nullptr) { + return defaultValue; + } else { + return ptr; + } + } + + template + auto map(Func&& f) & -> Maybe&>()))> { + if (ptr == nullptr) { + return nullptr; + } else { + return f(ptr); + } + } + + template + auto map(Func&& f) const & -> Maybe&>()))> { + if (ptr == nullptr) { + return nullptr; + } else { + return f(ptr); + } + } + + template + auto map(Func&& f) && -> Maybe&&>()))> { + if (ptr == nullptr) { + return nullptr; + } else { + return f(kj::mv(ptr)); + } + } + + template + auto map(Func&& f) const && -> Maybe&&>()))> { + if (ptr == nullptr) { + return nullptr; + } else { + return f(kj::mv(ptr)); + } + } + +private: + Own ptr; + + template + friend class Maybe; + template + friend _::OwnOwn _::readMaybe(Maybe>&& maybe); + template + friend Own* _::readMaybe(Maybe>& maybe); + template + friend const Own* _::readMaybe(const Maybe>& maybe); +}; + +namespace _ { // private + +template +class HeapDisposer final: public Disposer { +public: + virtual void disposeImpl(void* pointer) const override { delete reinterpret_cast(pointer); } + + static const HeapDisposer instance; +}; + +template +const HeapDisposer HeapDisposer::instance = HeapDisposer(); + +} // namespace _ (private) + +template +Own heap(Params&&... params) { + // heap(...) allocates a T on the heap, forwarding the parameters to its constructor. The + // exact heap implementation is unspecified -- for now it is operator new, but you should not + // assume this. (Since we know the object size at delete time, we could actually implement an + // allocator that is more efficient than operator new.) + + return Own(new T(kj::fwd(params)...), _::HeapDisposer::instance); +} + +template +Own> heap(T&& orig) { + // Allocate a copy (or move) of the argument on the heap. + // + // The purpose of this overload is to allow you to omit the template parameter as there is only + // one argument and the purpose is to copy it. + + typedef Decay T2; + return Own(new T2(kj::fwd(orig)), _::HeapDisposer::instance); +} + +// ======================================================================================= +// SpaceFor -- assists in manual allocation + +template +class SpaceFor { + // A class which has the same size and alignment as T but does not call its constructor or + // destructor automatically. Instead, call construct() to construct a T in the space, which + // returns an Own which will take care of calling T's destructor later. + +public: + inline SpaceFor() {} + inline ~SpaceFor() {} + + template + Own construct(Params&&... params) { + ctor(value, kj::fwd(params)...); + return Own(&value, DestructorOnlyDisposer::instance); + } + +private: + union { + T value; + }; +}; + +// ======================================================================================= +// Inline implementation details + +template +struct Disposer::Dispose_ { + static void dispose(T* object, const Disposer& disposer) { + // Note that dynamic_cast does not require RTTI to be enabled, because the offset to + // the top of the object is in the vtable -- as it obviously needs to be to correctly implement + // operator delete. + disposer.disposeImpl(dynamic_cast(object)); + } +}; +template +struct Disposer::Dispose_ { + static void dispose(T* object, const Disposer& disposer) { + disposer.disposeImpl(static_cast(object)); + } +}; + +template +void Disposer::dispose(T* object) const { + Dispose_::dispose(object, *this); +} + +} // namespace kj + +#endif // KJ_MEMORY_H_ diff --git a/phonelibs/capnp-cpp/include/kj/mutex.h b/phonelibs/capnp-cpp/include/kj/mutex.h new file mode 100644 index 00000000000000..d211ebfeb1c603 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/mutex.h @@ -0,0 +1,369 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_MUTEX_H_ +#define KJ_MUTEX_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "memory.h" +#include + +#if __linux__ && !defined(KJ_USE_FUTEX) +#define KJ_USE_FUTEX 1 +#endif + +#if !KJ_USE_FUTEX && !_WIN32 +// On Linux we use futex. On other platforms we wrap pthreads. +// TODO(someday): Write efficient low-level locking primitives for other platforms. +#include +#endif + +namespace kj { + +// ======================================================================================= +// Private details -- public interfaces follow below. + +namespace _ { // private + +class Mutex { + // Internal implementation details. See `MutexGuarded`. + +public: + Mutex(); + ~Mutex(); + KJ_DISALLOW_COPY(Mutex); + + enum Exclusivity { + EXCLUSIVE, + SHARED + }; + + void lock(Exclusivity exclusivity); + void unlock(Exclusivity exclusivity); + + void assertLockedByCaller(Exclusivity exclusivity); + // In debug mode, assert that the mutex is locked by the calling thread, or if that is + // non-trivial, assert that the mutex is locked (which should be good enough to catch problems + // in unit tests). In non-debug builds, do nothing. + +private: +#if KJ_USE_FUTEX + uint futex; + // bit 31 (msb) = set if exclusive lock held + // bit 30 (msb) = set if threads are waiting for exclusive lock + // bits 0-29 = count of readers; If an exclusive lock is held, this is the count of threads + // waiting for a read lock, otherwise it is the count of threads that currently hold a read + // lock. + + static constexpr uint EXCLUSIVE_HELD = 1u << 31; + static constexpr uint EXCLUSIVE_REQUESTED = 1u << 30; + static constexpr uint SHARED_COUNT_MASK = EXCLUSIVE_REQUESTED - 1; + +#elif _WIN32 + uintptr_t srwLock; // Actually an SRWLOCK, but don't want to #include in header. + +#else + mutable pthread_rwlock_t mutex; +#endif +}; + +class Once { + // Internal implementation details. See `Lazy`. + +public: +#if KJ_USE_FUTEX + inline Once(bool startInitialized = false) + : futex(startInitialized ? INITIALIZED : UNINITIALIZED) {} +#else + Once(bool startInitialized = false); + ~Once(); +#endif + KJ_DISALLOW_COPY(Once); + + class Initializer { + public: + virtual void run() = 0; + }; + + void runOnce(Initializer& init); + +#if _WIN32 // TODO(perf): Can we make this inline on win32 somehow? + bool isInitialized() noexcept; + +#else + inline bool isInitialized() noexcept { + // Fast path check to see if runOnce() would simply return immediately. +#if KJ_USE_FUTEX + return __atomic_load_n(&futex, __ATOMIC_ACQUIRE) == INITIALIZED; +#else + return __atomic_load_n(&state, __ATOMIC_ACQUIRE) == INITIALIZED; +#endif + } +#endif + + void reset(); + // Returns the state from initialized to uninitialized. It is an error to call this when + // not already initialized, or when runOnce() or isInitialized() might be called concurrently in + // another thread. + +private: +#if KJ_USE_FUTEX + uint futex; + + enum State { + UNINITIALIZED, + INITIALIZING, + INITIALIZING_WITH_WAITERS, + INITIALIZED + }; + +#elif _WIN32 + uintptr_t initOnce; // Actually an INIT_ONCE, but don't want to #include in header. + +#else + enum State { + UNINITIALIZED, + INITIALIZED + }; + State state; + pthread_mutex_t mutex; +#endif +}; + +} // namespace _ (private) + +// ======================================================================================= +// Public interface + +template +class Locked { + // Return type for `MutexGuarded::lock()`. `Locked` provides access to the bounded object + // and unlocks the mutex when it goes out of scope. + +public: + KJ_DISALLOW_COPY(Locked); + inline Locked(): mutex(nullptr), ptr(nullptr) {} + inline Locked(Locked&& other): mutex(other.mutex), ptr(other.ptr) { + other.mutex = nullptr; + other.ptr = nullptr; + } + inline ~Locked() { + if (mutex != nullptr) mutex->unlock(isConst() ? _::Mutex::SHARED : _::Mutex::EXCLUSIVE); + } + + inline Locked& operator=(Locked&& other) { + if (mutex != nullptr) mutex->unlock(isConst() ? _::Mutex::SHARED : _::Mutex::EXCLUSIVE); + mutex = other.mutex; + ptr = other.ptr; + other.mutex = nullptr; + other.ptr = nullptr; + return *this; + } + + inline void release() { + if (mutex != nullptr) mutex->unlock(isConst() ? _::Mutex::SHARED : _::Mutex::EXCLUSIVE); + mutex = nullptr; + ptr = nullptr; + } + + inline T* operator->() { return ptr; } + inline const T* operator->() const { return ptr; } + inline T& operator*() { return *ptr; } + inline const T& operator*() const { return *ptr; } + inline T* get() { return ptr; } + inline const T* get() const { return ptr; } + inline operator T*() { return ptr; } + inline operator const T*() const { return ptr; } + +private: + _::Mutex* mutex; + T* ptr; + + inline Locked(_::Mutex& mutex, T& value): mutex(&mutex), ptr(&value) {} + + template + friend class MutexGuarded; +}; + +template +class MutexGuarded { + // An object of type T, bounded by a mutex. In order to access the object, you must lock it. + // + // Write locks are not "recursive" -- trying to lock again in a thread that already holds a lock + // will deadlock. Recursive write locks are usually a sign of bad design. + // + // Unfortunately, **READ LOCKS ARE NOT RECURSIVE** either. Common sense says they should be. + // But on many operating systems (BSD, OSX), recursively read-locking a pthread_rwlock is + // actually unsafe. The problem is that writers are "prioritized" over readers, so a read lock + // request will block if any write lock requests are outstanding. So, if thread A takes a read + // lock, thread B requests a write lock (and starts waiting), and then thread A tries to take + // another read lock recursively, the result is deadlock. + +public: + template + explicit MutexGuarded(Params&&... params); + // Initialize the mutex-bounded object by passing the given parameters to its constructor. + + Locked lockExclusive() const; + // Exclusively locks the object and returns it. The returned `Locked` can be passed by + // move, similar to `Own`. + // + // This method is declared `const` in accordance with KJ style rules which say that constness + // should be used to indicate thread-safety. It is safe to share a const pointer between threads, + // but it is not safe to share a mutable pointer. Since the whole point of MutexGuarded is to + // be shared between threads, its methods should be const, even though locking it produces a + // non-const pointer to the contained object. + + Locked lockShared() const; + // Lock the value for shared access. Multiple shared locks can be taken concurrently, but cannot + // be held at the same time as a non-shared lock. + + inline const T& getWithoutLock() const { return value; } + inline T& getWithoutLock() { return value; } + // Escape hatch for cases where some external factor guarantees that it's safe to get the + // value. You should treat these like const_cast -- be highly suspicious of any use. + + inline const T& getAlreadyLockedShared() const; + inline T& getAlreadyLockedShared(); + inline T& getAlreadyLockedExclusive() const; + // Like `getWithoutLock()`, but asserts that the lock is already held by the calling thread. + +private: + mutable _::Mutex mutex; + mutable T value; +}; + +template +class MutexGuarded { + // MutexGuarded cannot guard a const type. This would be pointless anyway, and would complicate + // the implementation of Locked, which uses constness to decide what kind of lock it holds. + static_assert(sizeof(T) < 0, "MutexGuarded's type cannot be const."); +}; + +template +class Lazy { + // A lazily-initialized value. + +public: + template + T& get(Func&& init); + template + const T& get(Func&& init) const; + // The first thread to call get() will invoke the given init function to construct the value. + // Other threads will block until construction completes, then return the same value. + // + // `init` is a functor(typically a lambda) which takes `SpaceFor&` as its parameter and returns + // `Own`. If `init` throws an exception, the exception is propagated out of that thread's + // call to `get()`, and subsequent calls behave as if `get()` hadn't been called at all yet -- + // in other words, subsequent calls retry initialization until it succeeds. + +private: + mutable _::Once once; + mutable SpaceFor space; + mutable Own value; + + template + class InitImpl; +}; + +// ======================================================================================= +// Inline implementation details + +template +template +inline MutexGuarded::MutexGuarded(Params&&... params) + : value(kj::fwd(params)...) {} + +template +inline Locked MutexGuarded::lockExclusive() const { + mutex.lock(_::Mutex::EXCLUSIVE); + return Locked(mutex, value); +} + +template +inline Locked MutexGuarded::lockShared() const { + mutex.lock(_::Mutex::SHARED); + return Locked(mutex, value); +} + +template +inline const T& MutexGuarded::getAlreadyLockedShared() const { +#ifdef KJ_DEBUG + mutex.assertLockedByCaller(_::Mutex::SHARED); +#endif + return value; +} +template +inline T& MutexGuarded::getAlreadyLockedShared() { +#ifdef KJ_DEBUG + mutex.assertLockedByCaller(_::Mutex::SHARED); +#endif + return value; +} +template +inline T& MutexGuarded::getAlreadyLockedExclusive() const { +#ifdef KJ_DEBUG + mutex.assertLockedByCaller(_::Mutex::EXCLUSIVE); +#endif + return const_cast(value); +} + +template +template +class Lazy::InitImpl: public _::Once::Initializer { +public: + inline InitImpl(const Lazy& lazy, Func&& func): lazy(lazy), func(kj::fwd(func)) {} + + void run() override { + lazy.value = func(lazy.space); + } + +private: + const Lazy& lazy; + Func func; +}; + +template +template +inline T& Lazy::get(Func&& init) { + if (!once.isInitialized()) { + InitImpl initImpl(*this, kj::fwd(init)); + once.runOnce(initImpl); + } + return *value; +} + +template +template +inline const T& Lazy::get(Func&& init) const { + if (!once.isInitialized()) { + InitImpl initImpl(*this, kj::fwd(init)); + once.runOnce(initImpl); + } + return *value; +} + +} // namespace kj + +#endif // KJ_MUTEX_H_ diff --git a/phonelibs/capnp-cpp/include/kj/one-of.h b/phonelibs/capnp-cpp/include/kj/one-of.h new file mode 100644 index 00000000000000..6e143c44cf26dd --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/one-of.h @@ -0,0 +1,155 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_ONE_OF_H_ +#define KJ_ONE_OF_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "common.h" + +namespace kj { + +namespace _ { // private + +template +struct TypeIndex_ { static constexpr uint value = TypeIndex_::value; }; +template +struct TypeIndex_ { static constexpr uint value = i; }; + +} // namespace _ (private) + +template +class OneOf { + template + static inline constexpr uint typeIndex() { return _::TypeIndex_<1, Key, Variants...>::value; } + // Get the 1-based index of Key within the type list Types. + +public: + inline OneOf(): tag(0) {} + OneOf(const OneOf& other) { copyFrom(other); } + OneOf(OneOf&& other) { moveFrom(other); } + ~OneOf() { destroy(); } + + OneOf& operator=(const OneOf& other) { if (tag != 0) destroy(); copyFrom(other); return *this; } + OneOf& operator=(OneOf&& other) { if (tag != 0) destroy(); moveFrom(other); return *this; } + + inline bool operator==(decltype(nullptr)) const { return tag == 0; } + inline bool operator!=(decltype(nullptr)) const { return tag != 0; } + + template + bool is() const { + return tag == typeIndex(); + } + + template + T& get() { + KJ_IREQUIRE(is(), "Must check OneOf::is() before calling get()."); + return *reinterpret_cast(space); + } + template + const T& get() const { + KJ_IREQUIRE(is(), "Must check OneOf::is() before calling get()."); + return *reinterpret_cast(space); + } + + template + T& init(Params&&... params) { + if (tag != 0) destroy(); + ctor(*reinterpret_cast(space), kj::fwd(params)...); + tag = typeIndex(); + return *reinterpret_cast(space); + } + +private: + uint tag; + + static inline constexpr size_t maxSize(size_t a) { + return a; + } + template + static inline constexpr size_t maxSize(size_t a, size_t b, Rest... rest) { + return maxSize(kj::max(a, b), rest...); + } + // Returns the maximum of all the parameters. + // TODO(someday): Generalize the above template and make it common. I tried, but C++ decided to + // be difficult so I cut my losses. + + static constexpr auto spaceSize = maxSize(sizeof(Variants)...); + // TODO(msvc): This constant could just as well go directly inside space's bracket's, where it's + // used, but MSVC suffers a parse error on `...`. + + union { + byte space[spaceSize]; + + void* forceAligned; + // TODO(someday): Use C++11 alignas() once we require GCC 4.8 / Clang 3.3. + }; + + template + inline void doAll(T... t) {} + + template + inline bool destroyVariant() { + if (tag == typeIndex()) { + tag = 0; + dtor(*reinterpret_cast(space)); + } + return false; + } + void destroy() { + doAll(destroyVariant()...); + } + + template + inline bool copyVariantFrom(const OneOf& other) { + if (other.is()) { + ctor(*reinterpret_cast(space), other.get()); + } + return false; + } + void copyFrom(const OneOf& other) { + // Initialize as a copy of `other`. Expects that `this` starts out uninitialized, so the tag + // is invalid. + tag = other.tag; + doAll(copyVariantFrom(other)...); + } + + template + inline bool moveVariantFrom(OneOf& other) { + if (other.is()) { + ctor(*reinterpret_cast(space), kj::mv(other.get())); + } + return false; + } + void moveFrom(OneOf& other) { + // Initialize as a copy of `other`. Expects that `this` starts out uninitialized, so the tag + // is invalid. + tag = other.tag; + doAll(moveVariantFrom(other)...); + } +}; + +} // namespace kj + +#endif // KJ_ONE_OF_H_ diff --git a/phonelibs/capnp-cpp/include/kj/parse/char.h b/phonelibs/capnp-cpp/include/kj/parse/char.h new file mode 100644 index 00000000000000..2e6d51921d86ce --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/parse/char.h @@ -0,0 +1,361 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file contains parsers useful for character stream inputs, including parsers to parse +// common kinds of tokens like identifiers, numbers, and quoted strings. + +#ifndef KJ_PARSE_CHAR_H_ +#define KJ_PARSE_CHAR_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "common.h" +#include "../string.h" +#include + +namespace kj { +namespace parse { + +// ======================================================================================= +// Exact char/string. + +class ExactString_ { +public: + constexpr inline ExactString_(const char* str): str(str) {} + + template + Maybe> operator()(Input& input) const { + const char* ptr = str; + + while (*ptr != '\0') { + if (input.atEnd() || input.current() != *ptr) return nullptr; + input.next(); + ++ptr; + } + + return Tuple<>(); + } + +private: + const char* str; +}; + +constexpr inline ExactString_ exactString(const char* str) { + return ExactString_(str); +} + +template +constexpr ExactlyConst_ exactChar() { + // Returns a parser that matches exactly the character given by the template argument (returning + // no result). + return ExactlyConst_(); +} + +// ======================================================================================= +// Char ranges / sets + +class CharGroup_ { +public: + constexpr inline CharGroup_(): bits{0, 0, 0, 0} {} + + constexpr inline CharGroup_ orRange(unsigned char first, unsigned char last) const { + return CharGroup_(bits[0] | (oneBits(last + 1) & ~oneBits(first )), + bits[1] | (oneBits(last - 63) & ~oneBits(first - 64)), + bits[2] | (oneBits(last - 127) & ~oneBits(first - 128)), + bits[3] | (oneBits(last - 191) & ~oneBits(first - 192))); + } + + constexpr inline CharGroup_ orAny(const char* chars) const { + return *chars == 0 ? *this : orChar(*chars).orAny(chars + 1); + } + + constexpr inline CharGroup_ orChar(unsigned char c) const { + return CharGroup_(bits[0] | bit(c), + bits[1] | bit(c - 64), + bits[2] | bit(c - 128), + bits[3] | bit(c - 256)); + } + + constexpr inline CharGroup_ orGroup(CharGroup_ other) const { + return CharGroup_(bits[0] | other.bits[0], + bits[1] | other.bits[1], + bits[2] | other.bits[2], + bits[3] | other.bits[3]); + } + + constexpr inline CharGroup_ invert() const { + return CharGroup_(~bits[0], ~bits[1], ~bits[2], ~bits[3]); + } + + constexpr inline bool contains(unsigned char c) const { + return (bits[c / 64] & (1ll << (c % 64))) != 0; + } + + template + Maybe operator()(Input& input) const { + if (input.atEnd()) return nullptr; + unsigned char c = input.current(); + if (contains(c)) { + input.next(); + return c; + } else { + return nullptr; + } + } + +private: + typedef unsigned long long Bits64; + + constexpr inline CharGroup_(Bits64 a, Bits64 b, Bits64 c, Bits64 d): bits{a, b, c, d} {} + Bits64 bits[4]; + + static constexpr inline Bits64 oneBits(int count) { + return count <= 0 ? 0ll : count >= 64 ? -1ll : ((1ll << count) - 1); + } + static constexpr inline Bits64 bit(int index) { + return index < 0 ? 0 : index >= 64 ? 0 : (1ll << index); + } +}; + +constexpr inline CharGroup_ charRange(char first, char last) { + // Create a parser which accepts any character in the range from `first` to `last`, inclusive. + // For example: `charRange('a', 'z')` matches all lower-case letters. The parser's result is the + // character matched. + // + // The returned object has methods which can be used to match more characters. The following + // produces a parser which accepts any letter as well as '_', '+', '-', and '.'. + // + // charRange('a', 'z').orRange('A', 'Z').orChar('_').orAny("+-.") + // + // You can also use `.invert()` to match the opposite set of characters. + + return CharGroup_().orRange(first, last); +} + +#if _MSC_VER +#define anyOfChars(chars) CharGroup_().orAny(chars) +// TODO(msvc): MSVC ICEs on the proper definition of `anyOfChars()`, which in turn prevents us from +// building the compiler or schema parser. We don't know why this happens, but Harris found that +// this horrible, horrible hack makes things work. This is awful, but it's better than nothing. +// Hopefully, MSVC will get fixed soon and we'll be able to remove this. +#else +constexpr inline CharGroup_ anyOfChars(const char* chars) { + // Returns a parser that accepts any of the characters in the given string (which should usually + // be a literal). The returned parser is of the same type as returned by `charRange()` -- see + // that function for more info. + + return CharGroup_().orAny(chars); +} +#endif + +// ======================================================================================= + +namespace _ { // private + +struct ArrayToString { + inline String operator()(const Array& arr) const { + return heapString(arr); + } +}; + +} // namespace _ (private) + +template +constexpr inline auto charsToString(SubParser&& subParser) + -> decltype(transform(kj::fwd(subParser), _::ArrayToString())) { + // Wraps a parser that returns Array such that it returns String instead. + return parse::transform(kj::fwd(subParser), _::ArrayToString()); +} + +// ======================================================================================= +// Basic character classes. + +constexpr auto alpha = charRange('a', 'z').orRange('A', 'Z'); +constexpr auto digit = charRange('0', '9'); +constexpr auto alphaNumeric = alpha.orGroup(digit); +constexpr auto nameStart = alpha.orChar('_'); +constexpr auto nameChar = alphaNumeric.orChar('_'); +constexpr auto hexDigit = charRange('0', '9').orRange('a', 'f').orRange('A', 'F'); +constexpr auto octDigit = charRange('0', '7'); +constexpr auto whitespaceChar = anyOfChars(" \f\n\r\t\v"); +constexpr auto controlChar = charRange(0, 0x1f).invert().orGroup(whitespaceChar).invert(); + +constexpr auto whitespace = many(anyOfChars(" \f\n\r\t\v")); + +constexpr auto discardWhitespace = discard(many(discard(anyOfChars(" \f\n\r\t\v")))); +// Like discard(whitespace) but avoids some memory allocation. + +// ======================================================================================= +// Identifiers + +namespace _ { // private + +struct IdentifierToString { + inline String operator()(char first, const Array& rest) const { + String result = heapString(rest.size() + 1); + result[0] = first; + memcpy(result.begin() + 1, rest.begin(), rest.size()); + return result; + } +}; + +} // namespace _ (private) + +constexpr auto identifier = transform(sequence(nameStart, many(nameChar)), _::IdentifierToString()); +// Parses an identifier (e.g. a C variable name). + +// ======================================================================================= +// Integers + +namespace _ { // private + +inline char parseDigit(char c) { + if (c < 'A') return c - '0'; + if (c < 'a') return c - 'A' + 10; + return c - 'a' + 10; +} + +template +struct ParseInteger { + inline uint64_t operator()(const Array& digits) const { + return operator()('0', digits); + } + uint64_t operator()(char first, const Array& digits) const { + uint64_t result = parseDigit(first); + for (char digit: digits) { + result = result * base + parseDigit(digit); + } + return result; + } +}; + + +} // namespace _ (private) + +constexpr auto integer = sequence( + oneOf( + transform(sequence(exactChar<'0'>(), exactChar<'x'>(), oneOrMore(hexDigit)), _::ParseInteger<16>()), + transform(sequence(exactChar<'0'>(), many(octDigit)), _::ParseInteger<8>()), + transform(sequence(charRange('1', '9'), many(digit)), _::ParseInteger<10>())), + notLookingAt(alpha.orAny("_."))); + +// ======================================================================================= +// Numbers (i.e. floats) + +namespace _ { // private + +struct ParseFloat { + double operator()(const Array& digits, + const Maybe>& fraction, + const Maybe, Array>>& exponent) const; +}; + +} // namespace _ (private) + +constexpr auto number = transform( + sequence( + oneOrMore(digit), + optional(sequence(exactChar<'.'>(), many(digit))), + optional(sequence(discard(anyOfChars("eE")), optional(anyOfChars("+-")), many(digit))), + notLookingAt(alpha.orAny("_."))), + _::ParseFloat()); + +// ======================================================================================= +// Quoted strings + +namespace _ { // private + +struct InterpretEscape { + char operator()(char c) const { + switch (c) { + case 'a': return '\a'; + case 'b': return '\b'; + case 'f': return '\f'; + case 'n': return '\n'; + case 'r': return '\r'; + case 't': return '\t'; + case 'v': return '\v'; + default: return c; + } + } +}; + +struct ParseHexEscape { + inline char operator()(char first, char second) const { + return (parseDigit(first) << 4) | parseDigit(second); + } +}; + +struct ParseHexByte { + inline byte operator()(char first, char second) const { + return (parseDigit(first) << 4) | parseDigit(second); + } +}; + +struct ParseOctEscape { + inline char operator()(char first, Maybe second, Maybe third) const { + char result = first - '0'; + KJ_IF_MAYBE(digit1, second) { + result = (result << 3) | (*digit1 - '0'); + KJ_IF_MAYBE(digit2, third) { + result = (result << 3) | (*digit2 - '0'); + } + } + return result; + } +}; + +} // namespace _ (private) + +constexpr auto escapeSequence = + sequence(exactChar<'\\'>(), oneOf( + transform(anyOfChars("abfnrtv'\"\\\?"), _::InterpretEscape()), + transform(sequence(exactChar<'x'>(), hexDigit, hexDigit), _::ParseHexEscape()), + transform(sequence(octDigit, optional(octDigit), optional(octDigit)), + _::ParseOctEscape()))); +// A parser that parses a C-string-style escape sequence (starting with a backslash). Returns +// a char. + +constexpr auto doubleQuotedString = charsToString(sequence( + exactChar<'\"'>(), + many(oneOf(anyOfChars("\\\n\"").invert(), escapeSequence)), + exactChar<'\"'>())); +// Parses a C-style double-quoted string. + +constexpr auto singleQuotedString = charsToString(sequence( + exactChar<'\''>(), + many(oneOf(anyOfChars("\\\n\'").invert(), escapeSequence)), + exactChar<'\''>())); +// Parses a C-style single-quoted string. + +constexpr auto doubleQuotedHexBinary = sequence( + exactChar<'0'>(), exactChar<'x'>(), exactChar<'\"'>(), + oneOrMore(transform(sequence(discardWhitespace, hexDigit, hexDigit), _::ParseHexByte())), + discardWhitespace, + exactChar<'\"'>()); +// Parses a double-quoted hex binary literal. Returns Array. + +} // namespace parse +} // namespace kj + +#endif // KJ_PARSE_CHAR_H_ diff --git a/phonelibs/capnp-cpp/include/kj/parse/common.h b/phonelibs/capnp-cpp/include/kj/parse/common.h new file mode 100644 index 00000000000000..3af3a8760d5e7e --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/parse/common.h @@ -0,0 +1,824 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// Parser combinator framework! +// +// This file declares several functions which construct parsers, usually taking other parsers as +// input, thus making them parser combinators. +// +// A valid parser is any functor which takes a reference to an input cursor (defined below) as its +// input and returns a Maybe. The parser returns null on parse failure, or returns the parsed +// result on success. +// +// An "input cursor" is any type which implements the same interface as IteratorInput, below. Such +// a type acts as a pointer to the current input location. When a parser returns successfully, it +// will have updated the input cursor to point to the position just past the end of what was parsed. +// On failure, the cursor position is unspecified. + +#ifndef KJ_PARSE_COMMON_H_ +#define KJ_PARSE_COMMON_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "../common.h" +#include "../memory.h" +#include "../array.h" +#include "../tuple.h" +#include "../vector.h" +#if _MSC_VER +#include // result_of_t +#endif + +namespace kj { +namespace parse { + +template +class IteratorInput { + // A parser input implementation based on an iterator range. + +public: + IteratorInput(Iterator begin, Iterator end) + : parent(nullptr), pos(begin), end(end), best(begin) {} + explicit IteratorInput(IteratorInput& parent) + : parent(&parent), pos(parent.pos), end(parent.end), best(parent.pos) {} + ~IteratorInput() { + if (parent != nullptr) { + parent->best = kj::max(kj::max(pos, best), parent->best); + } + } + KJ_DISALLOW_COPY(IteratorInput); + + void advanceParent() { + parent->pos = pos; + } + void forgetParent() { + parent = nullptr; + } + + bool atEnd() { return pos == end; } + auto current() -> decltype(*instance()) { + KJ_IREQUIRE(!atEnd()); + return *pos; + } + auto consume() -> decltype(*instance()) { + KJ_IREQUIRE(!atEnd()); + return *pos++; + } + void next() { + KJ_IREQUIRE(!atEnd()); + ++pos; + } + + Iterator getBest() { return kj::max(pos, best); } + + Iterator getPosition() { return pos; } + +private: + IteratorInput* parent; + Iterator pos; + Iterator end; + Iterator best; // furthest we got with any sub-input +}; + +template struct OutputType_; +template struct OutputType_> { typedef T Type; }; +template +using OutputType = typename OutputType_< +#if _MSC_VER + std::result_of_t + // The instance() based version below results in: + // C2064: term does not evaluate to a function taking 1 arguments +#else + decltype(instance()(instance())) +#endif + >::Type; +// Synonym for the output type of a parser, given the parser type and the input type. + +// ======================================================================================= + +template +class ParserRef { + // Acts as a reference to some other parser, with simplified type. The referenced parser + // is polymorphic by virtual call rather than templates. For grammars of non-trivial size, + // it is important to inject refs into the grammar here and there to prevent the parser types + // from becoming ridiculous. Using too many of them can hurt performance, though. + +public: + ParserRef(): parser(nullptr), wrapper(nullptr) {} + ParserRef(const ParserRef&) = default; + ParserRef(ParserRef&&) = default; + ParserRef& operator=(const ParserRef& other) = default; + ParserRef& operator=(ParserRef&& other) = default; + + template + constexpr ParserRef(Other&& other) + : parser(&other), wrapper(&WrapperImplInstance>::instance) { + static_assert(kj::isReference(), "ParserRef should not be assigned to a temporary."); + } + + template + inline ParserRef& operator=(Other&& other) { + static_assert(kj::isReference(), "ParserRef should not be assigned to a temporary."); + parser = &other; + wrapper = &WrapperImplInstance>::instance; + return *this; + } + + KJ_ALWAYS_INLINE(Maybe operator()(Input& input) const) { + // Always inline in the hopes that this allows branch prediction to kick in so the virtual call + // doesn't hurt so much. + return wrapper->parse(parser, input); + } + +private: + struct Wrapper { + virtual Maybe parse(const void* parser, Input& input) const = 0; + }; + template + struct WrapperImpl: public Wrapper { + Maybe parse(const void* parser, Input& input) const override { + return (*reinterpret_cast(parser))(input); + } + }; + template + struct WrapperImplInstance { +#if _MSC_VER + // TODO(msvc): MSVC currently fails to initialize vtable pointers for constexpr values so + // we have to make this just const instead. + static const WrapperImpl instance; +#else + static constexpr WrapperImpl instance = WrapperImpl(); +#endif + }; + + const void* parser; + const Wrapper* wrapper; +}; + +template +template +#if _MSC_VER +const typename ParserRef::template WrapperImpl +ParserRef::WrapperImplInstance::instance = WrapperImpl(); +#else +constexpr typename ParserRef::template WrapperImpl +ParserRef::WrapperImplInstance::instance; +#endif + +template +constexpr ParserRef> ref(ParserImpl& impl) { + // Constructs a ParserRef. You must specify the input type explicitly, e.g. + // `ref(myParser)`. + + return ParserRef>(impl); +} + +// ------------------------------------------------------------------- +// any +// Output = one token + +class Any_ { +public: + template + Maybe().consume())>> operator()(Input& input) const { + if (input.atEnd()) { + return nullptr; + } else { + return input.consume(); + } + } +}; + +constexpr Any_ any = Any_(); +// A parser which matches any token and simply returns it. + +// ------------------------------------------------------------------- +// exactly() +// Output = Tuple<> + +template +class Exactly_ { +public: + explicit constexpr Exactly_(T&& expected): expected(expected) {} + + template + Maybe> operator()(Input& input) const { + if (input.atEnd() || input.current() != expected) { + return nullptr; + } else { + input.next(); + return Tuple<>(); + } + } + +private: + T expected; +}; + +template +constexpr Exactly_ exactly(T&& expected) { + // Constructs a parser which succeeds when the input is exactly the token specified. The + // result is always the empty tuple. + + return Exactly_(kj::fwd(expected)); +} + +// ------------------------------------------------------------------- +// exactlyConst() +// Output = Tuple<> + +template +class ExactlyConst_ { +public: + explicit constexpr ExactlyConst_() {} + + template + Maybe> operator()(Input& input) const { + if (input.atEnd() || input.current() != expected) { + return nullptr; + } else { + input.next(); + return Tuple<>(); + } + } +}; + +template +constexpr ExactlyConst_ exactlyConst() { + // Constructs a parser which succeeds when the input is exactly the token specified. The + // result is always the empty tuple. This parser is templated on the token value which may cause + // it to perform better -- or worse. Be sure to measure. + + return ExactlyConst_(); +} + +// ------------------------------------------------------------------- +// constResult() + +template +class ConstResult_ { +public: + explicit constexpr ConstResult_(SubParser&& subParser, Result&& result) + : subParser(kj::fwd(subParser)), result(kj::fwd(result)) {} + + template + Maybe operator()(Input& input) const { + if (subParser(input) == nullptr) { + return nullptr; + } else { + return result; + } + } + +private: + SubParser subParser; + Result result; +}; + +template +constexpr ConstResult_ constResult(SubParser&& subParser, Result&& result) { + // Constructs a parser which returns exactly `result` if `subParser` is successful. + return ConstResult_(kj::fwd(subParser), kj::fwd(result)); +} + +template +constexpr ConstResult_> discard(SubParser&& subParser) { + // Constructs a parser which wraps `subParser` but discards the result. + return constResult(kj::fwd(subParser), Tuple<>()); +} + +// ------------------------------------------------------------------- +// sequence() +// Output = Flattened Tuple of outputs of sub-parsers. + +template class Sequence_; + +template +class Sequence_ { +public: + template + explicit constexpr Sequence_(T&& firstSubParser, U&&... rest) + : first(kj::fwd(firstSubParser)), rest(kj::fwd(rest)...) {} + + // TODO(msvc): The trailing return types on `operator()` and `parseNext()` expose at least two + // bugs in MSVC: + // + // 1. An ICE. + // 2. 'error C2672: 'operator __surrogate_func': no matching overloaded function found)', + // which crops up in numerous places when trying to build the capnp command line tools. + // + // The only workaround I found for both bugs is to omit the trailing return types and instead + // rely on C++14's return type deduction. + + template + auto operator()(Input& input) const +#ifndef _MSC_VER + -> Maybe>(), + instance>()...))> +#endif + { + return parseNext(input); + } + + template + auto parseNext(Input& input, InitialParams&&... initialParams) const +#ifndef _MSC_VER + -> Maybe(initialParams)..., + instance>(), + instance>()...))> +#endif + { + KJ_IF_MAYBE(firstResult, first(input)) { + return rest.parseNext(input, kj::fwd(initialParams)..., + kj::mv(*firstResult)); + } else { + // TODO(msvc): MSVC depends on return type deduction to compile this function, so we need to + // help it deduce the right type on this code path. + return Maybe(initialParams)..., + instance>(), + instance>()...))>{nullptr}; + } + } + +private: + FirstSubParser first; + Sequence_ rest; +}; + +template <> +class Sequence_<> { +public: + template + Maybe> operator()(Input& input) const { + return parseNext(input); + } + + template + auto parseNext(Input& input, Params&&... params) const -> + Maybe(params)...))> { + return tuple(kj::fwd(params)...); + } +}; + +template +constexpr Sequence_ sequence(SubParsers&&... subParsers) { + // Constructs a parser that executes each of the parameter parsers in sequence and returns a + // tuple of their results. + + return Sequence_(kj::fwd(subParsers)...); +} + +// ------------------------------------------------------------------- +// many() +// Output = Array of output of sub-parser, or just a uint count if the sub-parser returns Tuple<>. + +template +class Many_ { + template > + struct Impl; +public: + explicit constexpr Many_(SubParser&& subParser) + : subParser(kj::fwd(subParser)) {} + + template + auto operator()(Input& input) const + -> decltype(Impl::apply(instance(), input)); + +private: + SubParser subParser; +}; + +template +template +struct Many_::Impl { + static Maybe> apply(const SubParser& subParser, Input& input) { + typedef Vector> Results; + Results results; + + while (!input.atEnd()) { + Input subInput(input); + + KJ_IF_MAYBE(subResult, subParser(subInput)) { + subInput.advanceParent(); + results.add(kj::mv(*subResult)); + } else { + break; + } + } + + if (atLeastOne && results.empty()) { + return nullptr; + } + + return results.releaseAsArray(); + } +}; + +template +template +struct Many_::Impl> { + // If the sub-parser output is Tuple<>, just return a count. + + static Maybe apply(const SubParser& subParser, Input& input) { + uint count = 0; + + while (!input.atEnd()) { + Input subInput(input); + + KJ_IF_MAYBE(subResult, subParser(subInput)) { + subInput.advanceParent(); + ++count; + } else { + break; + } + } + + if (atLeastOne && count == 0) { + return nullptr; + } + + return count; + } +}; + +template +template +auto Many_::operator()(Input& input) const + -> decltype(Impl::apply(instance(), input)) { + return Impl>::apply(subParser, input); +} + +template +constexpr Many_ many(SubParser&& subParser) { + // Constructs a parser that repeatedly executes the given parser until it fails, returning an + // Array of the results (or a uint count if `subParser` returns an empty tuple). + return Many_(kj::fwd(subParser)); +} + +template +constexpr Many_ oneOrMore(SubParser&& subParser) { + // Like `many()` but the parser must parse at least one item to be successful. + return Many_(kj::fwd(subParser)); +} + +// ------------------------------------------------------------------- +// times() +// Output = Array of output of sub-parser, or Tuple<> if sub-parser returns Tuple<>. + +template +class Times_ { + template > + struct Impl; +public: + explicit constexpr Times_(SubParser&& subParser, uint count) + : subParser(kj::fwd(subParser)), count(count) {} + + template + auto operator()(Input& input) const + -> decltype(Impl::apply(instance(), instance(), input)); + +private: + SubParser subParser; + uint count; +}; + +template +template +struct Times_::Impl { + static Maybe> apply(const SubParser& subParser, uint count, Input& input) { + auto results = heapArrayBuilder>(count); + + while (results.size() < count) { + if (input.atEnd()) { + return nullptr; + } else KJ_IF_MAYBE(subResult, subParser(input)) { + results.add(kj::mv(*subResult)); + } else { + return nullptr; + } + } + + return results.finish(); + } +}; + +template +template +struct Times_::Impl> { + // If the sub-parser output is Tuple<>, just return a count. + + static Maybe> apply(const SubParser& subParser, uint count, Input& input) { + uint actualCount = 0; + + while (actualCount < count) { + if (input.atEnd()) { + return nullptr; + } else KJ_IF_MAYBE(subResult, subParser(input)) { + ++actualCount; + } else { + return nullptr; + } + } + + return tuple(); + } +}; + +template +template +auto Times_::operator()(Input& input) const + -> decltype(Impl::apply(instance(), instance(), input)) { + return Impl>::apply(subParser, count, input); +} + +template +constexpr Times_ times(SubParser&& subParser, uint count) { + // Constructs a parser that repeats the subParser exactly `count` times. + return Times_(kj::fwd(subParser), count); +} + +// ------------------------------------------------------------------- +// optional() +// Output = Maybe + +template +class Optional_ { +public: + explicit constexpr Optional_(SubParser&& subParser) + : subParser(kj::fwd(subParser)) {} + + template + Maybe>> operator()(Input& input) const { + typedef Maybe> Result; + + Input subInput(input); + KJ_IF_MAYBE(subResult, subParser(subInput)) { + subInput.advanceParent(); + return Result(kj::mv(*subResult)); + } else { + return Result(nullptr); + } + } + +private: + SubParser subParser; +}; + +template +constexpr Optional_ optional(SubParser&& subParser) { + // Constructs a parser that accepts zero or one of the given sub-parser, returning a Maybe + // of the sub-parser's result. + return Optional_(kj::fwd(subParser)); +} + +// ------------------------------------------------------------------- +// oneOf() +// All SubParsers must have same output type, which becomes the output type of the +// OneOfParser. + +template +class OneOf_; + +template +class OneOf_ { +public: + explicit constexpr OneOf_(FirstSubParser&& firstSubParser, SubParsers&&... rest) + : first(kj::fwd(firstSubParser)), rest(kj::fwd(rest)...) {} + + template + Maybe> operator()(Input& input) const { + { + Input subInput(input); + Maybe> firstResult = first(subInput); + + if (firstResult != nullptr) { + subInput.advanceParent(); + return kj::mv(firstResult); + } + } + + // Hoping for some tail recursion here... + return rest(input); + } + +private: + FirstSubParser first; + OneOf_ rest; +}; + +template <> +class OneOf_<> { +public: + template + decltype(nullptr) operator()(Input& input) const { + return nullptr; + } +}; + +template +constexpr OneOf_ oneOf(SubParsers&&... parsers) { + // Constructs a parser that accepts one of a set of options. The parser behaves as the first + // sub-parser in the list which returns successfully. All of the sub-parsers must return the + // same type. + return OneOf_(kj::fwd(parsers)...); +} + +// ------------------------------------------------------------------- +// transform() +// Output = Result of applying transform functor to input value. If input is a tuple, it is +// unpacked to form the transformation parameters. + +template +struct Span { +public: + inline const Position& begin() const { return begin_; } + inline const Position& end() const { return end_; } + + Span() = default; + inline constexpr Span(Position&& begin, Position&& end): begin_(mv(begin)), end_(mv(end)) {} + +private: + Position begin_; + Position end_; +}; + +template +constexpr Span> span(Position&& start, Position&& end) { + return Span>(kj::fwd(start), kj::fwd(end)); +} + +template +class Transform_ { +public: + explicit constexpr Transform_(SubParser&& subParser, TransformFunc&& transform) + : subParser(kj::fwd(subParser)), transform(kj::fwd(transform)) {} + + template + Maybe(), + instance&&>()))> + operator()(Input& input) const { + KJ_IF_MAYBE(subResult, subParser(input)) { + return kj::apply(transform, kj::mv(*subResult)); + } else { + return nullptr; + } + } + +private: + SubParser subParser; + TransformFunc transform; +}; + +template +class TransformOrReject_ { +public: + explicit constexpr TransformOrReject_(SubParser&& subParser, TransformFunc&& transform) + : subParser(kj::fwd(subParser)), transform(kj::fwd(transform)) {} + + template + decltype(kj::apply(instance(), instance&&>())) + operator()(Input& input) const { + KJ_IF_MAYBE(subResult, subParser(input)) { + return kj::apply(transform, kj::mv(*subResult)); + } else { + return nullptr; + } + } + +private: + SubParser subParser; + TransformFunc transform; +}; + +template +class TransformWithLocation_ { +public: + explicit constexpr TransformWithLocation_(SubParser&& subParser, TransformFunc&& transform) + : subParser(kj::fwd(subParser)), transform(kj::fwd(transform)) {} + + template + Maybe(), + instance().getPosition())>>>(), + instance&&>()))> + operator()(Input& input) const { + auto start = input.getPosition(); + KJ_IF_MAYBE(subResult, subParser(input)) { + return kj::apply(transform, Span(kj::mv(start), input.getPosition()), + kj::mv(*subResult)); + } else { + return nullptr; + } + } + +private: + SubParser subParser; + TransformFunc transform; +}; + +template +constexpr Transform_ transform( + SubParser&& subParser, TransformFunc&& functor) { + // Constructs a parser which executes some other parser and then transforms the result by invoking + // `functor` on it. Typically `functor` is a lambda. It is invoked using `kj::apply`, + // meaning tuples will be unpacked as arguments. + return Transform_( + kj::fwd(subParser), kj::fwd(functor)); +} + +template +constexpr TransformOrReject_ transformOrReject( + SubParser&& subParser, TransformFunc&& functor) { + // Like `transform()` except that `functor` returns a `Maybe`. If it returns null, parsing fails, + // otherwise the parser's result is the content of the `Maybe`. + return TransformOrReject_( + kj::fwd(subParser), kj::fwd(functor)); +} + +template +constexpr TransformWithLocation_ transformWithLocation( + SubParser&& subParser, TransformFunc&& functor) { + // Like `transform` except that `functor` also takes a `Span` as its first parameter specifying + // the location of the parsed content. The span's position type is whatever the parser input's + // getPosition() returns. + return TransformWithLocation_( + kj::fwd(subParser), kj::fwd(functor)); +} + +// ------------------------------------------------------------------- +// notLookingAt() +// Fails if the given parser succeeds at the current location. + +template +class NotLookingAt_ { +public: + explicit constexpr NotLookingAt_(SubParser&& subParser) + : subParser(kj::fwd(subParser)) {} + + template + Maybe> operator()(Input& input) const { + Input subInput(input); + subInput.forgetParent(); + if (subParser(subInput) == nullptr) { + return Tuple<>(); + } else { + return nullptr; + } + } + +private: + SubParser subParser; +}; + +template +constexpr NotLookingAt_ notLookingAt(SubParser&& subParser) { + // Constructs a parser which fails at any position where the given parser succeeds. Otherwise, + // it succeeds without consuming any input and returns an empty tuple. + return NotLookingAt_(kj::fwd(subParser)); +} + +// ------------------------------------------------------------------- +// endOfInput() +// Output = Tuple<>, only succeeds if at end-of-input + +class EndOfInput_ { +public: + template + Maybe> operator()(Input& input) const { + if (input.atEnd()) { + return Tuple<>(); + } else { + return nullptr; + } + } +}; + +constexpr EndOfInput_ endOfInput = EndOfInput_(); +// A parser that succeeds only if it is called with no input. + +} // namespace parse +} // namespace kj + +#endif // KJ_PARSE_COMMON_H_ diff --git a/phonelibs/capnp-cpp/include/kj/refcount.h b/phonelibs/capnp-cpp/include/kj/refcount.h new file mode 100644 index 00000000000000..a24e4bf5b95e7d --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/refcount.h @@ -0,0 +1,107 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#include "memory.h" + +#ifndef KJ_REFCOUNT_H_ +#define KJ_REFCOUNT_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +namespace kj { + +class Refcounted: private Disposer { + // Subclass this to create a class that contains a reference count. Then, use + // `kj::refcounted()` to allocate a new refcounted pointer. + // + // Do NOT use this lightly. Refcounting is a crutch. Good designs should strive to make object + // ownership clear, so that refcounting is not necessary. All that said, reference counting can + // sometimes simplify code that would otherwise become convoluted with explicit ownership, even + // when ownership relationships are clear at an abstract level. + // + // NOT THREADSAFE: This refcounting implementation assumes that an object's references are + // manipulated only in one thread, because atomic (thread-safe) refcounting is surprisingly slow. + // + // In general, abstract classes should _not_ subclass this. The concrete class at the bottom + // of the hierarchy should be the one to decide how it implements refcounting. Interfaces should + // expose only an `addRef()` method that returns `Own`. There are two reasons for + // this rule: + // 1. Interfaces would need to virtually inherit Refcounted, otherwise two refcounted interfaces + // could not be inherited by the same subclass. Virtual inheritance is awkward and + // inefficient. + // 2. An implementation may decide that it would rather return a copy than a refcount, or use + // some other strategy. + // + // TODO(cleanup): Rethink above. Virtual inheritance is not necessarily that bad. OTOH, a + // virtual function call for every refcount is sad in its own way. A Ref type to replace + // Own could also be nice. + +public: + virtual ~Refcounted() noexcept(false); + + inline bool isShared() const { return refcount > 1; } + // Check if there are multiple references to this object. This is sometimes useful for deciding + // whether it's safe to modify the object vs. make a copy. + +private: + mutable uint refcount = 0; + // "mutable" because disposeImpl() is const. Bleh. + + void disposeImpl(void* pointer) const override; + template + static Own addRefInternal(T* object); + + template + friend Own addRef(T& object); + template + friend Own refcounted(Params&&... params); +}; + +template +inline Own refcounted(Params&&... params) { + // Allocate a new refcounted instance of T, passing `params` to its constructor. Returns an + // initial reference to the object. More references can be created with `kj::addRef()`. + + return Refcounted::addRefInternal(new T(kj::fwd(params)...)); +} + +template +Own addRef(T& object) { + // Return a new reference to `object`, which must subclass Refcounted and have been allocated + // using `kj::refcounted<>()`. It is suggested that subclasses implement a non-static addRef() + // method which wraps this and returns the appropriate type. + + KJ_IREQUIRE(object.Refcounted::refcount > 0, "Object not allocated with kj::refcounted()."); + return Refcounted::addRefInternal(&object); +} + +template +Own Refcounted::addRefInternal(T* object) { + Refcounted* refcounted = object; + ++refcounted->refcount; + return Own(object, *refcounted); +} + +} // namespace kj + +#endif // KJ_REFCOUNT_H_ diff --git a/phonelibs/capnp-cpp/include/kj/std/iostream.h b/phonelibs/capnp-cpp/include/kj/std/iostream.h new file mode 100644 index 00000000000000..627e0fcf8622fe --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/std/iostream.h @@ -0,0 +1,88 @@ +// Copyright (c) 2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +/* + * Compatibility layer for stdlib iostream + */ + +#ifndef KJ_STD_IOSTREAM_H_ +#define KJ_STD_IOSTREAM_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "../io.h" +#include + +namespace kj { +namespace std { + +class StdOutputStream: public kj::OutputStream { + +public: + explicit StdOutputStream(::std::ostream& stream) : stream_(stream) {} + ~StdOutputStream() noexcept(false) {} + + virtual void write(const void* src, size_t size) override { + // Always writes the full size. + + stream_.write((char*)src, size); + } + + virtual void write(ArrayPtr> pieces) override { + // Equivalent to write()ing each byte array in sequence, which is what the + // default implementation does. Override if you can do something better, + // e.g. use writev() to do the write in a single syscall. + + for (auto piece : pieces) { + write(piece.begin(), piece.size()); + } + } + +private: + ::std::ostream& stream_; + +}; + +class StdInputStream: public kj::InputStream { + +public: + explicit StdInputStream(::std::istream& stream) : stream_(stream) {} + ~StdInputStream() noexcept(false) {} + + virtual size_t tryRead( + void* buffer, size_t minBytes, size_t maxBytes) override { + // Like read(), but may return fewer than minBytes on EOF. + + stream_.read((char*)buffer, maxBytes); + return stream_.gcount(); + } + +private: + ::std::istream& stream_; + +}; + +} // namespace std +} // namespace kj + +#endif // KJ_STD_IOSTREAM_H_ diff --git a/phonelibs/capnp-cpp/include/kj/string-tree.h b/phonelibs/capnp-cpp/include/kj/string-tree.h new file mode 100644 index 00000000000000..70a46319ef82a5 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/string-tree.h @@ -0,0 +1,212 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_STRING_TREE_H_ +#define KJ_STRING_TREE_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "string.h" + +namespace kj { + +class StringTree { + // A long string, represented internally as a tree of strings. This data structure is like a + // String, but optimized for concatenation and iteration at the expense of seek time. The + // structure is intended to be used for building large text blobs from many small pieces, where + // repeatedly concatenating smaller strings into larger ones would waste copies. This structure + // is NOT intended for use cases requiring random access or computing substrings. For those, + // you should use a Rope, which is a much more complicated data structure. + // + // The proper way to construct a StringTree is via kj::strTree(...), which works just like + // kj::str(...) but returns a StringTree rather than a String. + // + // KJ_STRINGIFY() functions that construct large strings from many smaller strings are encouraged + // to return StringTree rather than a flat char container. + +public: + inline StringTree(): size_(0) {} + inline StringTree(String&& text): size_(text.size()), text(kj::mv(text)) {} + + StringTree(Array&& pieces, StringPtr delim); + // Build a StringTree by concatenating the given pieces, delimited by the given delimiter + // (e.g. ", "). + + inline size_t size() const { return size_; } + + template + void visit(Func&& func) const; + + String flatten() const; + // Return the contents as a string. + + // TODO(someday): flatten() when *this is an rvalue and when branches.size() == 0 could simply + // return `kj::mv(text)`. Requires reference qualifiers (Clang 3.3 / GCC 4.8). + + void flattenTo(char* __restrict__ target) const; + // Copy the contents to the given character array. Does not add a NUL terminator. + +private: + size_t size_; + String text; + + struct Branch; + Array branches; // In order. + + inline void fill(char* pos, size_t branchIndex); + template + void fill(char* pos, size_t branchIndex, First&& first, Rest&&... rest); + template + void fill(char* pos, size_t branchIndex, StringTree&& first, Rest&&... rest); + template + void fill(char* pos, size_t branchIndex, Array&& first, Rest&&... rest); + template + void fill(char* pos, size_t branchIndex, String&& first, Rest&&... rest); + + template + static StringTree concat(Params&&... params); + static StringTree&& concat(StringTree&& param) { return kj::mv(param); } + + template + static inline size_t flatSize(const T& t) { return t.size(); } + static inline size_t flatSize(String&& s) { return 0; } + static inline size_t flatSize(StringTree&& s) { return 0; } + + template + static inline size_t branchCount(const T& t) { return 0; } + static inline size_t branchCount(String&& s) { return 1; } + static inline size_t branchCount(StringTree&& s) { return 1; } + + template + friend StringTree strTree(Params&&... params); +}; + +inline StringTree&& KJ_STRINGIFY(StringTree&& tree) { return kj::mv(tree); } +inline const StringTree& KJ_STRINGIFY(const StringTree& tree) { return tree; } + +inline StringTree KJ_STRINGIFY(Array&& trees) { return StringTree(kj::mv(trees), ""); } + +template +StringTree strTree(Params&&... params); +// Build a StringTree by stringifying the given parameters and concatenating the results. +// If any of the parameters stringify to StringTree rvalues, they will be incorporated as +// branches to avoid a copy. + +// ======================================================================================= +// Inline implementation details + +namespace _ { // private + +template +char* fill(char* __restrict__ target, const StringTree& first, Rest&&... rest) { + // Make str() work with stringifiers that return StringTree by patching fill(). + + first.flattenTo(target); + return fill(target + first.size(), kj::fwd(rest)...); +} + +template constexpr bool isStringTree() { return false; } +template <> constexpr bool isStringTree() { return true; } + +inline StringTree&& toStringTreeOrCharSequence(StringTree&& tree) { return kj::mv(tree); } +inline StringTree toStringTreeOrCharSequence(String&& str) { return StringTree(kj::mv(str)); } + +template +inline auto toStringTreeOrCharSequence(T&& value) + -> decltype(toCharSequence(kj::fwd(value))) { + static_assert(!isStringTree>(), + "When passing a StringTree into kj::strTree(), either pass it by rvalue " + "(use kj::mv(value)) or explicitly call value.flatten() to make a copy."); + + return toCharSequence(kj::fwd(value)); +} + +} // namespace _ (private) + +struct StringTree::Branch { + size_t index; + // Index in `text` where this branch should be inserted. + + StringTree content; +}; + +template +void StringTree::visit(Func&& func) const { + size_t pos = 0; + for (auto& branch: branches) { + if (branch.index > pos) { + func(text.slice(pos, branch.index)); + pos = branch.index; + } + branch.content.visit(func); + } + if (text.size() > pos) { + func(text.slice(pos, text.size())); + } +} + +inline void StringTree::fill(char* pos, size_t branchIndex) { + KJ_IREQUIRE(pos == text.end() && branchIndex == branches.size(), + kj::str(text.end() - pos, ' ', branches.size() - branchIndex).cStr()); +} + +template +void StringTree::fill(char* pos, size_t branchIndex, First&& first, Rest&&... rest) { + pos = _::fill(pos, kj::fwd(first)); + fill(pos, branchIndex, kj::fwd(rest)...); +} + +template +void StringTree::fill(char* pos, size_t branchIndex, StringTree&& first, Rest&&... rest) { + branches[branchIndex].index = pos - text.begin(); + branches[branchIndex].content = kj::mv(first); + fill(pos, branchIndex + 1, kj::fwd(rest)...); +} + +template +void StringTree::fill(char* pos, size_t branchIndex, String&& first, Rest&&... rest) { + branches[branchIndex].index = pos - text.begin(); + branches[branchIndex].content = StringTree(kj::mv(first)); + fill(pos, branchIndex + 1, kj::fwd(rest)...); +} + +template +StringTree StringTree::concat(Params&&... params) { + StringTree result; + result.size_ = _::sum({params.size()...}); + result.text = heapString( + _::sum({StringTree::flatSize(kj::fwd(params))...})); + result.branches = heapArray( + _::sum({StringTree::branchCount(kj::fwd(params))...})); + result.fill(result.text.begin(), 0, kj::fwd(params)...); + return result; +} + +template +StringTree strTree(Params&&... params) { + return StringTree::concat(_::toStringTreeOrCharSequence(kj::fwd(params))...); +} + +} // namespace kj + +#endif // KJ_STRING_TREE_H_ diff --git a/phonelibs/capnp-cpp/include/kj/string.h b/phonelibs/capnp-cpp/include/kj/string.h new file mode 100644 index 00000000000000..9048be24170e5b --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/string.h @@ -0,0 +1,534 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_STRING_H_ +#define KJ_STRING_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include +#include "array.h" +#include + +namespace kj { + +class StringPtr; +class String; + +class StringTree; // string-tree.h + +// Our STL string SFINAE trick does not work with GCC 4.7, but it works with Clang and GCC 4.8, so +// we'll just preprocess it out if not supported. +#if __clang__ || __GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8) || _MSC_VER +#define KJ_COMPILER_SUPPORTS_STL_STRING_INTEROP 1 +#endif + +// ======================================================================================= +// StringPtr -- A NUL-terminated ArrayPtr containing UTF-8 text. +// +// NUL bytes are allowed to appear before the end of the string. The only requirement is that +// a NUL byte appear immediately after the last byte of the content. This terminator byte is not +// counted in the string's size. + +class StringPtr { +public: + inline StringPtr(): content("", 1) {} + inline StringPtr(decltype(nullptr)): content("", 1) {} + inline StringPtr(const char* value): content(value, strlen(value) + 1) {} + inline StringPtr(const char* value, size_t size): content(value, size + 1) { + KJ_IREQUIRE(value[size] == '\0', "StringPtr must be NUL-terminated."); + } + inline StringPtr(const char* begin, const char* end): StringPtr(begin, end - begin) {} + inline StringPtr(const String& value); + +#if KJ_COMPILER_SUPPORTS_STL_STRING_INTEROP + template ().c_str())> + inline StringPtr(const T& t): StringPtr(t.c_str()) {} + // Allow implicit conversion from any class that has a c_str() method (namely, std::string). + // We use a template trick to detect std::string in order to avoid including the header for + // those who don't want it. + + template ().c_str())> + inline operator T() const { return cStr(); } + // Allow implicit conversion to any class that has a c_str() method (namely, std::string). + // We use a template trick to detect std::string in order to avoid including the header for + // those who don't want it. +#endif + + inline operator ArrayPtr() const; + inline ArrayPtr asArray() const; + inline ArrayPtr asBytes() const { return asArray().asBytes(); } + // Result does not include NUL terminator. + + inline const char* cStr() const { return content.begin(); } + // Returns NUL-terminated string. + + inline size_t size() const { return content.size() - 1; } + // Result does not include NUL terminator. + + inline char operator[](size_t index) const { return content[index]; } + + inline const char* begin() const { return content.begin(); } + inline const char* end() const { return content.end() - 1; } + + inline bool operator==(decltype(nullptr)) const { return content.size() <= 1; } + inline bool operator!=(decltype(nullptr)) const { return content.size() > 1; } + + inline bool operator==(const StringPtr& other) const; + inline bool operator!=(const StringPtr& other) const { return !(*this == other); } + inline bool operator< (const StringPtr& other) const; + inline bool operator> (const StringPtr& other) const { return other < *this; } + inline bool operator<=(const StringPtr& other) const { return !(other < *this); } + inline bool operator>=(const StringPtr& other) const { return !(*this < other); } + + inline StringPtr slice(size_t start) const; + inline ArrayPtr slice(size_t start, size_t end) const; + // A string slice is only NUL-terminated if it is a suffix, so slice() has a one-parameter + // version that assumes end = size(). + + inline bool startsWith(const StringPtr& other) const; + inline bool endsWith(const StringPtr& other) const; + + inline Maybe findFirst(char c) const; + inline Maybe findLast(char c) const; + + template + T parseAs() const; + // Parse string as template number type. + // Integer numbers prefixed by "0x" and "0X" are parsed in base 16 (like strtoi with base 0). + // Integer numbers prefixed by "0" are parsed in base 10 (unlike strtoi with base 0). + // Overflowed integer numbers throw exception. + // Overflowed floating numbers return inf. + +private: + inline StringPtr(ArrayPtr content): content(content) {} + + ArrayPtr content; +}; + +inline bool operator==(const char* a, const StringPtr& b) { return b == a; } +inline bool operator!=(const char* a, const StringPtr& b) { return b != a; } + +template <> char StringPtr::parseAs() const; +template <> signed char StringPtr::parseAs() const; +template <> unsigned char StringPtr::parseAs() const; +template <> short StringPtr::parseAs() const; +template <> unsigned short StringPtr::parseAs() const; +template <> int StringPtr::parseAs() const; +template <> unsigned StringPtr::parseAs() const; +template <> long StringPtr::parseAs() const; +template <> unsigned long StringPtr::parseAs() const; +template <> long long StringPtr::parseAs() const; +template <> unsigned long long StringPtr::parseAs() const; +template <> float StringPtr::parseAs() const; +template <> double StringPtr::parseAs() const; + +// ======================================================================================= +// String -- A NUL-terminated Array containing UTF-8 text. +// +// NUL bytes are allowed to appear before the end of the string. The only requirement is that +// a NUL byte appear immediately after the last byte of the content. This terminator byte is not +// counted in the string's size. +// +// To allocate a String, you must call kj::heapString(). We do not implement implicit copying to +// the heap because this hides potential inefficiency from the developer. + +class String { +public: + String() = default; + inline String(decltype(nullptr)): content(nullptr) {} + inline String(char* value, size_t size, const ArrayDisposer& disposer); + // Does not copy. `size` does not include NUL terminator, but `value` must be NUL-terminated. + inline explicit String(Array buffer); + // Does not copy. Requires `buffer` ends with `\0`. + + inline operator ArrayPtr(); + inline operator ArrayPtr() const; + inline ArrayPtr asArray(); + inline ArrayPtr asArray() const; + inline ArrayPtr asBytes() { return asArray().asBytes(); } + inline ArrayPtr asBytes() const { return asArray().asBytes(); } + // Result does not include NUL terminator. + + inline Array releaseArray() { return kj::mv(content); } + // Disowns the backing array (which includes the NUL terminator) and returns it. The String value + // is clobbered (as if moved away). + + inline const char* cStr() const; + + inline size_t size() const; + // Result does not include NUL terminator. + + inline char operator[](size_t index) const; + inline char& operator[](size_t index); + + inline char* begin(); + inline char* end(); + inline const char* begin() const; + inline const char* end() const; + + inline bool operator==(decltype(nullptr)) const { return content.size() <= 1; } + inline bool operator!=(decltype(nullptr)) const { return content.size() > 1; } + + inline bool operator==(const StringPtr& other) const { return StringPtr(*this) == other; } + inline bool operator!=(const StringPtr& other) const { return StringPtr(*this) != other; } + inline bool operator< (const StringPtr& other) const { return StringPtr(*this) < other; } + inline bool operator> (const StringPtr& other) const { return StringPtr(*this) > other; } + inline bool operator<=(const StringPtr& other) const { return StringPtr(*this) <= other; } + inline bool operator>=(const StringPtr& other) const { return StringPtr(*this) >= other; } + + inline bool startsWith(const StringPtr& other) const { return StringPtr(*this).startsWith(other);} + inline bool endsWith(const StringPtr& other) const { return StringPtr(*this).endsWith(other); } + + inline StringPtr slice(size_t start) const { return StringPtr(*this).slice(start); } + inline ArrayPtr slice(size_t start, size_t end) const { + return StringPtr(*this).slice(start, end); + } + + inline Maybe findFirst(char c) const { return StringPtr(*this).findFirst(c); } + inline Maybe findLast(char c) const { return StringPtr(*this).findLast(c); } + + template + T parseAs() const { return StringPtr(*this).parseAs(); } + // Parse as number + +private: + Array content; +}; + +inline bool operator==(const char* a, const String& b) { return b == a; } +inline bool operator!=(const char* a, const String& b) { return b != a; } + +String heapString(size_t size); +// Allocate a String of the given size on the heap, not including NUL terminator. The NUL +// terminator will be initialized automatically but the rest of the content is not initialized. + +String heapString(const char* value); +String heapString(const char* value, size_t size); +String heapString(StringPtr value); +String heapString(const String& value); +String heapString(ArrayPtr value); +// Allocates a copy of the given value on the heap. + +// ======================================================================================= +// Magic str() function which transforms parameters to text and concatenates them into one big +// String. + +namespace _ { // private + +inline size_t sum(std::initializer_list nums) { + size_t result = 0; + for (auto num: nums) { + result += num; + } + return result; +} + +inline char* fill(char* ptr) { return ptr; } + +template +char* fill(char* __restrict__ target, const StringTree& first, Rest&&... rest); +// Make str() work with stringifiers that return StringTree by patching fill(). +// +// Defined in string-tree.h. + +template +char* fill(char* __restrict__ target, const First& first, Rest&&... rest) { + auto i = first.begin(); + auto end = first.end(); + while (i != end) { + *target++ = *i++; + } + return fill(target, kj::fwd(rest)...); +} + +template +String concat(Params&&... params) { + // Concatenate a bunch of containers into a single Array. The containers can be anything that + // is iterable and whose elements can be converted to `char`. + + String result = heapString(sum({params.size()...})); + fill(result.begin(), kj::fwd(params)...); + return result; +} + +inline String concat(String&& arr) { + return kj::mv(arr); +} + +struct Stringifier { + // This is a dummy type with only one instance: STR (below). To make an arbitrary type + // stringifiable, define `operator*(Stringifier, T)` to return an iterable container of `char`. + // The container type must have a `size()` method. Be sure to declare the operator in the same + // namespace as `T` **or** in the global scope. + // + // A more usual way to accomplish what we're doing here would be to require that you define + // a function like `toString(T)` and then rely on argument-dependent lookup. However, this has + // the problem that it pollutes other people's namespaces and even the global namespace. For + // example, some other project may already have functions called `toString` which do something + // different. Declaring `operator*` with `Stringifier` as the left operand cannot conflict with + // anything. + + inline ArrayPtr operator*(ArrayPtr s) const { return s; } + inline ArrayPtr operator*(ArrayPtr s) const { return s; } + inline ArrayPtr operator*(const Array& s) const { return s; } + inline ArrayPtr operator*(const Array& s) const { return s; } + template + inline ArrayPtr operator*(const CappedArray& s) const { return s; } + template + inline ArrayPtr operator*(const FixedArray& s) const { return s; } + inline ArrayPtr operator*(const char* s) const { return arrayPtr(s, strlen(s)); } + inline ArrayPtr operator*(const String& s) const { return s.asArray(); } + inline ArrayPtr operator*(const StringPtr& s) const { return s.asArray(); } + + inline Range operator*(const Range& r) const { return r; } + inline Repeat operator*(const Repeat& r) const { return r; } + + inline FixedArray operator*(char c) const { + FixedArray result; + result[0] = c; + return result; + } + + StringPtr operator*(decltype(nullptr)) const; + StringPtr operator*(bool b) const; + + CappedArray operator*(signed char i) const; + CappedArray operator*(unsigned char i) const; + CappedArray operator*(short i) const; + CappedArray operator*(unsigned short i) const; + CappedArray operator*(int i) const; + CappedArray operator*(unsigned int i) const; + CappedArray operator*(long i) const; + CappedArray operator*(unsigned long i) const; + CappedArray operator*(long long i) const; + CappedArray operator*(unsigned long long i) const; + CappedArray operator*(float f) const; + CappedArray operator*(double f) const; + CappedArray operator*(const void* s) const; + + template + String operator*(ArrayPtr arr) const; + template + String operator*(const Array& arr) const; + +#if KJ_COMPILER_SUPPORTS_STL_STRING_INTEROP // supports expression SFINAE? + template ().toString())> + inline Result operator*(T&& value) const { return kj::fwd(value).toString(); } +#endif +}; +static KJ_CONSTEXPR(const) Stringifier STR = Stringifier(); + +} // namespace _ (private) + +template +auto toCharSequence(T&& value) -> decltype(_::STR * kj::fwd(value)) { + // Returns an iterable of chars that represent a textual representation of the value, suitable + // for debugging. + // + // Most users should use str() instead, but toCharSequence() may occasionally be useful to avoid + // heap allocation overhead that str() implies. + // + // To specialize this function for your type, see KJ_STRINGIFY. + + return _::STR * kj::fwd(value); +} + +CappedArray hex(unsigned char i); +CappedArray hex(unsigned short i); +CappedArray hex(unsigned int i); +CappedArray hex(unsigned long i); +CappedArray hex(unsigned long long i); + +template +String str(Params&&... params) { + // Magic function which builds a string from a bunch of arbitrary values. Example: + // str(1, " / ", 2, " = ", 0.5) + // returns: + // "1 / 2 = 0.5" + // To teach `str` how to stringify a type, see `Stringifier`. + + return _::concat(toCharSequence(kj::fwd(params))...); +} + +inline String str(String&& s) { return mv(s); } +// Overload to prevent redundant allocation. + +template +String strArray(T&& arr, const char* delim) { + size_t delimLen = strlen(delim); + KJ_STACK_ARRAY(decltype(_::STR * arr[0]), pieces, kj::size(arr), 8, 32); + size_t size = 0; + for (size_t i = 0; i < kj::size(arr); i++) { + if (i > 0) size += delimLen; + pieces[i] = _::STR * arr[i]; + size += pieces[i].size(); + } + + String result = heapString(size); + char* pos = result.begin(); + for (size_t i = 0; i < kj::size(arr); i++) { + if (i > 0) { + memcpy(pos, delim, delimLen); + pos += delimLen; + } + pos = _::fill(pos, pieces[i]); + } + return result; +} + +namespace _ { // private + +template +inline String Stringifier::operator*(ArrayPtr arr) const { + return strArray(arr, ", "); +} + +template +inline String Stringifier::operator*(const Array& arr) const { + return strArray(arr, ", "); +} + +} // namespace _ (private) + +#define KJ_STRINGIFY(...) operator*(::kj::_::Stringifier, __VA_ARGS__) +// Defines a stringifier for a custom type. Example: +// +// class Foo {...}; +// inline StringPtr KJ_STRINGIFY(const Foo& foo) { return foo.name(); } +// +// This allows Foo to be passed to str(). +// +// The function should be declared either in the same namespace as the target type or in the global +// namespace. It can return any type which is an iterable container of chars. + +// ======================================================================================= +// Inline implementation details. + +inline StringPtr::StringPtr(const String& value): content(value.begin(), value.size() + 1) {} + +inline StringPtr::operator ArrayPtr() const { + return content.slice(0, content.size() - 1); +} + +inline ArrayPtr StringPtr::asArray() const { + return content.slice(0, content.size() - 1); +} + +inline bool StringPtr::operator==(const StringPtr& other) const { + return content.size() == other.content.size() && + memcmp(content.begin(), other.content.begin(), content.size() - 1) == 0; +} + +inline bool StringPtr::operator<(const StringPtr& other) const { + bool shorter = content.size() < other.content.size(); + int cmp = memcmp(content.begin(), other.content.begin(), + shorter ? content.size() : other.content.size()); + return cmp < 0 || (cmp == 0 && shorter); +} + +inline StringPtr StringPtr::slice(size_t start) const { + return StringPtr(content.slice(start, content.size())); +} +inline ArrayPtr StringPtr::slice(size_t start, size_t end) const { + return content.slice(start, end); +} + +inline bool StringPtr::startsWith(const StringPtr& other) const { + return other.content.size() <= content.size() && + memcmp(content.begin(), other.content.begin(), other.size()) == 0; +} +inline bool StringPtr::endsWith(const StringPtr& other) const { + return other.content.size() <= content.size() && + memcmp(end() - other.size(), other.content.begin(), other.size()) == 0; +} + +inline Maybe StringPtr::findFirst(char c) const { + const char* pos = reinterpret_cast(memchr(content.begin(), c, size())); + if (pos == nullptr) { + return nullptr; + } else { + return pos - content.begin(); + } +} + +inline Maybe StringPtr::findLast(char c) const { + for (size_t i = size(); i > 0; --i) { + if (content[i-1] == c) { + return i-1; + } + } + return nullptr; +} + +inline String::operator ArrayPtr() { + return content == nullptr ? ArrayPtr(nullptr) : content.slice(0, content.size() - 1); +} +inline String::operator ArrayPtr() const { + return content == nullptr ? ArrayPtr(nullptr) : content.slice(0, content.size() - 1); +} + +inline ArrayPtr String::asArray() { + return content == nullptr ? ArrayPtr(nullptr) : content.slice(0, content.size() - 1); +} +inline ArrayPtr String::asArray() const { + return content == nullptr ? ArrayPtr(nullptr) : content.slice(0, content.size() - 1); +} + +inline const char* String::cStr() const { return content == nullptr ? "" : content.begin(); } + +inline size_t String::size() const { return content == nullptr ? 0 : content.size() - 1; } + +inline char String::operator[](size_t index) const { return content[index]; } +inline char& String::operator[](size_t index) { return content[index]; } + +inline char* String::begin() { return content == nullptr ? nullptr : content.begin(); } +inline char* String::end() { return content == nullptr ? nullptr : content.end() - 1; } +inline const char* String::begin() const { return content == nullptr ? nullptr : content.begin(); } +inline const char* String::end() const { return content == nullptr ? nullptr : content.end() - 1; } + +inline String::String(char* value, size_t size, const ArrayDisposer& disposer) + : content(value, size + 1, disposer) { + KJ_IREQUIRE(value[size] == '\0', "String must be NUL-terminated."); +} + +inline String::String(Array buffer): content(kj::mv(buffer)) { + KJ_IREQUIRE(content.size() > 0 && content.back() == '\0', "String must be NUL-terminated."); +} + +inline String heapString(const char* value) { + return heapString(value, strlen(value)); +} +inline String heapString(StringPtr value) { + return heapString(value.begin(), value.size()); +} +inline String heapString(const String& value) { + return heapString(value.begin(), value.size()); +} +inline String heapString(ArrayPtr value) { + return heapString(value.begin(), value.size()); +} + +} // namespace kj + +#endif // KJ_STRING_H_ diff --git a/phonelibs/capnp-cpp/include/kj/test.h b/phonelibs/capnp-cpp/include/kj/test.h new file mode 100644 index 00000000000000..69e1c80840b85d --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/test.h @@ -0,0 +1,167 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_TEST_H_ +#define KJ_TEST_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "debug.h" +#include "vector.h" +#include "function.h" + +namespace kj { + +class TestRunner; + +class TestCase { +public: + TestCase(const char* file, uint line, const char* description); + ~TestCase(); + + virtual void run() = 0; + +private: + const char* file; + uint line; + const char* description; + TestCase* next; + TestCase** prev; + bool matchedFilter; + + friend class TestRunner; +}; + +#define KJ_TEST(description) \ + /* Make sure the linker fails if tests are not in anonymous namespaces. */ \ + extern int KJ_CONCAT(YouMustWrapTestsInAnonymousNamespace, __COUNTER__) KJ_UNUSED; \ + class KJ_UNIQUE_NAME(TestCase): public ::kj::TestCase { \ + public: \ + KJ_UNIQUE_NAME(TestCase)(): ::kj::TestCase(__FILE__, __LINE__, description) {} \ + void run() override; \ + } KJ_UNIQUE_NAME(testCase); \ + void KJ_UNIQUE_NAME(TestCase)::run() + +#if _MSC_VER +#define KJ_INDIRECT_EXPAND(m, vargs) m vargs +#define KJ_FAIL_EXPECT(...) \ + KJ_INDIRECT_EXPAND(KJ_LOG, (ERROR , __VA_ARGS__)); +#define KJ_EXPECT(cond, ...) \ + if (cond); else KJ_INDIRECT_EXPAND(KJ_FAIL_EXPECT, ("failed: expected " #cond , __VA_ARGS__)) +#else +#define KJ_FAIL_EXPECT(...) \ + KJ_LOG(ERROR, ##__VA_ARGS__); +#define KJ_EXPECT(cond, ...) \ + if (cond); else KJ_FAIL_EXPECT("failed: expected " #cond, ##__VA_ARGS__) +#endif + +#define KJ_EXPECT_THROW_RECOVERABLE(type, code) \ + do { \ + KJ_IF_MAYBE(e, ::kj::runCatchingExceptions([&]() { code; })) { \ + KJ_EXPECT(e->getType() == ::kj::Exception::Type::type, \ + "code threw wrong exception type: " #code, e->getType()); \ + } else { \ + KJ_FAIL_EXPECT("code did not throw: " #code); \ + } \ + } while (false) + +#define KJ_EXPECT_THROW_RECOVERABLE_MESSAGE(message, code) \ + do { \ + KJ_IF_MAYBE(e, ::kj::runCatchingExceptions([&]() { code; })) { \ + KJ_EXPECT(::kj::_::hasSubstring(e->getDescription(), message), \ + "exception description didn't contain expected substring", e->getDescription()); \ + } else { \ + KJ_FAIL_EXPECT("code did not throw: " #code); \ + } \ + } while (false) + +#if KJ_NO_EXCEPTIONS +#define KJ_EXPECT_THROW(type, code) \ + do { \ + KJ_EXPECT(::kj::_::expectFatalThrow(type, nullptr, [&]() { code; })); \ + } while (false) +#define KJ_EXPECT_THROW_MESSAGE(message, code) \ + do { \ + KJ_EXPECT(::kj::_::expectFatalThrow(nullptr, kj::StringPtr(message), [&]() { code; })); \ + } while (false) +#else +#define KJ_EXPECT_THROW KJ_EXPECT_THROW_RECOVERABLE +#define KJ_EXPECT_THROW_MESSAGE KJ_EXPECT_THROW_RECOVERABLE_MESSAGE +#endif + +#define KJ_EXPECT_LOG(level, substring) \ + ::kj::_::LogExpectation KJ_UNIQUE_NAME(_kjLogExpectation)(::kj::LogSeverity::level, substring) +// Expects that a log message with the given level and substring text will be printed within +// the current scope. This message will not cause the test to fail, even if it is an error. + +// ======================================================================================= + +namespace _ { // private + +bool hasSubstring(kj::StringPtr haystack, kj::StringPtr needle); + +#if KJ_NO_EXCEPTIONS +bool expectFatalThrow(Maybe type, Maybe message, + Function code); +// Expects that the given code will throw a fatal exception matching the given type and/or message. +// Since exceptions are disabled, the test will fork() and run in a subprocess. On Windows, where +// fork() is not available, this always returns true. +#endif + +class LogExpectation: public ExceptionCallback { +public: + LogExpectation(LogSeverity severity, StringPtr substring); + ~LogExpectation(); + + void logMessage(LogSeverity severity, const char* file, int line, int contextDepth, + String&& text) override; + +private: + LogSeverity severity; + StringPtr substring; + bool seen; + UnwindDetector unwindDetector; +}; + +class GlobFilter { + // Implements glob filters for the --filter flag. + // + // Exposed in header only for testing. + +public: + explicit GlobFilter(const char* pattern); + explicit GlobFilter(ArrayPtr pattern); + + bool matches(StringPtr name); + +private: + String pattern; + Vector states; + + void applyState(char c, int state); +}; + +} // namespace _ (private) +} // namespace kj + +#endif // KJ_TEST_H_ diff --git a/phonelibs/capnp-cpp/include/kj/thread.h b/phonelibs/capnp-cpp/include/kj/thread.h new file mode 100644 index 00000000000000..b17b88c520a2d8 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/thread.h @@ -0,0 +1,82 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_THREAD_H_ +#define KJ_THREAD_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "common.h" +#include "function.h" +#include "exception.h" + +namespace kj { + +class Thread { + // A thread! Pass a lambda to the constructor, and it runs in the thread. The destructor joins + // the thread. If the function throws an exception, it is rethrown from the thread's destructor + // (if not unwinding from another exception). + +public: + explicit Thread(Function func); + KJ_DISALLOW_COPY(Thread); + + ~Thread() noexcept(false); + +#if !_WIN32 + void sendSignal(int signo); + // Send a Unix signal to the given thread, using pthread_kill or an equivalent. +#endif + + void detach(); + // Don't join the thread in ~Thread(). + +private: + struct ThreadState { + Function func; + kj::Maybe exception; + + unsigned int refcount; + // Owned by the parent thread and the child thread. + + void unref(); + }; + ThreadState* state; + +#if _WIN32 + void* threadHandle; +#else + unsigned long long threadId; // actually pthread_t +#endif + bool detached = false; + +#if _WIN32 + static unsigned long __stdcall runThread(void* ptr); +#else + static void* runThread(void* ptr); +#endif +}; + +} // namespace kj + +#endif // KJ_THREAD_H_ diff --git a/phonelibs/capnp-cpp/include/kj/threadlocal.h b/phonelibs/capnp-cpp/include/kj/threadlocal.h new file mode 100644 index 00000000000000..67d0db60ef7d6c --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/threadlocal.h @@ -0,0 +1,136 @@ +// Copyright (c) 2014, Jason Choy +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_THREADLOCAL_H_ +#define KJ_THREADLOCAL_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif +// This file declares a macro `KJ_THREADLOCAL_PTR` for declaring thread-local pointer-typed +// variables. Use like: +// KJ_THREADLOCAL_PTR(MyType) foo = nullptr; +// This is equivalent to: +// thread_local MyType* foo = nullptr; +// This can only be used at the global scope. +// +// AVOID USING THIS. Use of thread-locals is discouraged because they often have many of the same +// properties as singletons: http://www.object-oriented-security.org/lets-argue/singletons +// +// Also, thread-locals tend to be hostile to event-driven code, which can be particularly +// surprising when using fibers (all fibers in the same thread will share the same threadlocals, +// even though they do not share a stack). +// +// That said, thread-locals are sometimes needed for runtime logistics in the KJ framework. For +// example, the current exception callback and current EventLoop are stored as thread-local +// pointers. Since KJ only ever needs to store pointers, not values, we avoid the question of +// whether these values' destructors need to be run, and we avoid the need for heap allocation. + +#include "common.h" + +#if !defined(KJ_USE_PTHREAD_THREADLOCAL) && defined(__APPLE__) +#include "TargetConditionals.h" +#if TARGET_OS_IPHONE +// iOS apparently does not support __thread (nor C++11 thread_local). +#define KJ_USE_PTHREAD_TLS 1 +#endif +#endif + +#if KJ_USE_PTHREAD_TLS +#include +#endif + +namespace kj { + +#if KJ_USE_PTHREAD_TLS +// If __thread is unavailable, we'll fall back to pthreads. + +#define KJ_THREADLOCAL_PTR(type) \ + namespace { struct KJ_UNIQUE_NAME(_kj_TlpTag); } \ + static ::kj::_::ThreadLocalPtr< type, KJ_UNIQUE_NAME(_kj_TlpTag)> +// Hack: In order to ensure each thread-local results in a unique template instance, we declare +// a one-off dummy type to use as the second type parameter. + +namespace _ { // private + +template +class ThreadLocalPtr { + // Hacky type to emulate __thread T*. We need a separate instance of the ThreadLocalPtr template + // for every thread-local variable, because we don't want to require a global constructor, and in + // order to initialize the TLS on first use we need to use a local static variable (in getKey()). + // Each template instance will get a separate such local static variable, fulfilling our need. + +public: + ThreadLocalPtr() = default; + constexpr ThreadLocalPtr(decltype(nullptr)) {} + // Allow initialization to nullptr without a global constructor. + + inline ThreadLocalPtr& operator=(T* val) { + pthread_setspecific(getKey(), val); + return *this; + } + + inline operator T*() const { + return get(); + } + + inline T& operator*() const { + return *get(); + } + + inline T* operator->() const { + return get(); + } + +private: + inline T* get() const { + return reinterpret_cast(pthread_getspecific(getKey())); + } + + inline static pthread_key_t getKey() { + static pthread_key_t key = createKey(); + return key; + } + + static pthread_key_t createKey() { + pthread_key_t key; + pthread_key_create(&key, 0); + return key; + } +}; + +} // namespace _ (private) + +#elif __GNUC__ + +#define KJ_THREADLOCAL_PTR(type) static __thread type* +// GCC's __thread is lighter-weight than thread_local and is good enough for our purposes. + +#else + +#define KJ_THREADLOCAL_PTR(type) static thread_local type* + +#endif // KJ_USE_PTHREAD_TLS + +} // namespace kj + +#endif // KJ_THREADLOCAL_H_ diff --git a/phonelibs/capnp-cpp/include/kj/time.h b/phonelibs/capnp-cpp/include/kj/time.h new file mode 100644 index 00000000000000..37d7b8a90eea91 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/time.h @@ -0,0 +1,174 @@ +// Copyright (c) 2014 Google Inc. (contributed by Remy Blank ) +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_TIME_H_ +#define KJ_TIME_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "async.h" +#include "units.h" +#include + +namespace kj { +namespace _ { // private + +class NanosecondLabel; +class TimeLabel; +class DateLabel; + +} // namespace _ (private) + +using Duration = Quantity; +// A time value, in nanoseconds. + +constexpr Duration NANOSECONDS = unit(); +constexpr Duration MICROSECONDS = 1000 * NANOSECONDS; +constexpr Duration MILLISECONDS = 1000 * MICROSECONDS; +constexpr Duration SECONDS = 1000 * MILLISECONDS; +constexpr Duration MINUTES = 60 * SECONDS; +constexpr Duration HOURS = 60 * MINUTES; +constexpr Duration DAYS = 24 * HOURS; + +using TimePoint = Absolute; +// An absolute time measured by some particular instance of `Timer`. `Time`s from two different +// `Timer`s may be measured from different origins and so are not necessarily compatible. + +using Date = Absolute; +// A point in real-world time, measured relative to the Unix epoch (Jan 1, 1970 00:00:00 UTC). + +constexpr Date UNIX_EPOCH = origin(); +// The `Date` representing Jan 1, 1970 00:00:00 UTC. + +class Clock { + // Interface to read the current date and time. +public: + virtual Date now() = 0; +}; + +Clock& nullClock(); +// A clock which always returns UNIX_EPOCH as the current time. Useful when you don't care about +// time. + +class Timer { + // Interface to time and timer functionality. + // + // Each `Timer` may have a different origin, and some `Timer`s may in fact tick at a different + // rate than real time (e.g. a `Timer` could represent CPU time consumed by a thread). However, + // all `Timer`s are monotonic: time will never appear to move backwards, even if the calendar + // date as tracked by the system is manually modified. + +public: + virtual TimePoint now() = 0; + // Returns the current value of a clock that moves steadily forward, independent of any + // changes in the wall clock. The value is updated every time the event loop waits, + // and is constant in-between waits. + + virtual Promise atTime(TimePoint time) = 0; + // Returns a promise that returns as soon as now() >= time. + + virtual Promise afterDelay(Duration delay) = 0; + // Equivalent to atTime(now() + delay). + + template + Promise timeoutAt(TimePoint time, Promise&& promise) KJ_WARN_UNUSED_RESULT; + // Return a promise equivalent to `promise` but which throws an exception (and cancels the + // original promise) if it hasn't completed by `time`. The thrown exception is of type + // "OVERLOADED". + + template + Promise timeoutAfter(Duration delay, Promise&& promise) KJ_WARN_UNUSED_RESULT; + // Return a promise equivalent to `promise` but which throws an exception (and cancels the + // original promise) if it hasn't completed after `delay` from now. The thrown exception is of + // type "OVERLOADED". + +private: + static kj::Exception makeTimeoutException(); +}; + +class TimerImpl final: public Timer { + // Implementation of Timer that expects an external caller -- usually, the EventPort + // implementation -- to tell it when time has advanced. + +public: + TimerImpl(TimePoint startTime); + ~TimerImpl() noexcept(false); + + Maybe nextEvent(); + // Returns the time at which the next scheduled timer event will occur, or null if no timer + // events are scheduled. + + Maybe timeoutToNextEvent(TimePoint start, Duration unit, uint64_t max); + // Convenience method which computes a timeout value to pass to an event-waiting system call to + // cause it to time out when the next timer event occurs. + // + // `start` is the time at which the timeout starts counting. This is typically not the same as + // now() since some time may have passed since the last time advanceTo() was called. + // + // `unit` is the time unit in which the timeout is measured. This is often MILLISECONDS. Note + // that this method will fractional values *up*, to guarantee that the returned timeout waits + // until just *after* the time the event is scheduled. + // + // The timeout will be clamped to `max`. Use this to avoid an overflow if e.g. the OS wants a + // 32-bit value or a signed value. + // + // Returns nullptr if there are no future events. + + void advanceTo(TimePoint newTime); + // Set the time to `time` and fire any at() events that have been passed. + + // implements Timer ---------------------------------------------------------- + TimePoint now() override; + Promise atTime(TimePoint time) override; + Promise afterDelay(Duration delay) override; + +private: + struct Impl; + class TimerPromiseAdapter; + TimePoint time; + Own impl; +}; + +// ======================================================================================= +// inline implementation details + +template +Promise Timer::timeoutAt(TimePoint time, Promise&& promise) { + return promise.exclusiveJoin(atTime(time).then([]() -> kj::Promise { + return makeTimeoutException(); + })); +} + +template +Promise Timer::timeoutAfter(Duration delay, Promise&& promise) { + return promise.exclusiveJoin(afterDelay(delay).then([]() -> kj::Promise { + return makeTimeoutException(); + })); +} + +inline TimePoint TimerImpl::now() { return time; } + +} // namespace kj + +#endif // KJ_TIME_H_ diff --git a/phonelibs/capnp-cpp/include/kj/tuple.h b/phonelibs/capnp-cpp/include/kj/tuple.h new file mode 100644 index 00000000000000..2ea7276ec5af9a --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/tuple.h @@ -0,0 +1,364 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file defines a notion of tuples that is simpler that `std::tuple`. It works as follows: +// - `kj::Tuple is the type of a tuple of an A, a B, and a C. +// - `kj::tuple(a, b, c)` returns a tuple containing a, b, and c. If any of these are themselves +// tuples, they are flattened, so `tuple(a, tuple(b, c), d)` is equivalent to `tuple(a, b, c, d)`. +// - `kj::get(myTuple)` returns the element of `myTuple` at index n. +// - `kj::apply(func, ...)` calls func on the following arguments after first expanding any tuples +// in the argument list. So `kj::apply(foo, a, tuple(b, c), d)` would call `foo(a, b, c, d)`. +// +// Note that: +// - The type `Tuple` is a synonym for T. This is why `get` and `apply` are not members of the +// type. +// - It is illegal for an element of `Tuple` to itself be a tuple, as tuples are meant to be +// flattened. +// - It is illegal for an element of `Tuple` to be a reference, due to problems this would cause +// with type inference and `tuple()`. + +#ifndef KJ_TUPLE_H_ +#define KJ_TUPLE_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "common.h" + +namespace kj { +namespace _ { // private + +template +struct TypeByIndex_; +template +struct TypeByIndex_<0, First, Rest...> { + typedef First Type; +}; +template +struct TypeByIndex_ + : public TypeByIndex_ {}; +template +struct TypeByIndex_ { + static_assert(index != index, "Index out-of-range."); +}; +template +using TypeByIndex = typename TypeByIndex_::Type; +// Chose a particular type out of a list of types, by index. + +template +struct Indexes {}; +// Dummy helper type that just encapsulates a sequential list of indexes, so that we can match +// templates against them and unpack them with '...'. + +template +struct MakeIndexes_: public MakeIndexes_ {}; +template +struct MakeIndexes_<0, prefix...> { + typedef Indexes Type; +}; +template +using MakeIndexes = typename MakeIndexes_::Type; +// Equivalent to Indexes<0, 1, 2, ..., end>. + +template +class Tuple; +template +inline TypeByIndex& getImpl(Tuple& tuple); +template +inline TypeByIndex&& getImpl(Tuple&& tuple); +template +inline const TypeByIndex& getImpl(const Tuple& tuple); + +template +struct TupleElement { + // Encapsulates one element of a tuple. The actual tuple implementation multiply-inherits + // from a TupleElement for each element, which is more efficient than a recursive definition. + + T value; + TupleElement() = default; + constexpr inline TupleElement(const T& value): value(value) {} + constexpr inline TupleElement(T&& value): value(kj::mv(value)) {} +}; + +template +struct TupleElement { + // If tuples contained references, one of the following would have to be true: + // - `auto x = tuple(y, z)` would cause x to be a tuple of references to y and z, which is + // probably not what you expected. + // - `Tuple x = tuple(a, b)` would not work, because `tuple()` returned + // Tuple. + static_assert(sizeof(T*) == 0, "Sorry, tuples cannot contain references."); +}; + +template +struct TupleElement> { + static_assert(sizeof(Tuple*) == 0, + "Tuples cannot contain other tuples -- they should be flattened."); +}; + +template +struct TupleImpl; + +template +struct TupleImpl, Types...> + : public TupleElement... { + // Implementation of Tuple. The only reason we need this rather than rolling this into class + // Tuple (below) is so that we can get "indexes" as an unpackable list. + + static_assert(sizeof...(indexes) == sizeof...(Types), "Incorrect use of TupleImpl."); + + template + inline TupleImpl(Params&&... params) + : TupleElement(kj::fwd(params))... { + // Work around Clang 3.2 bug 16303 where this is not detected. (Unfortunately, Clang sometimes + // segfaults instead.) + static_assert(sizeof...(params) == sizeof...(indexes), + "Wrong number of parameters to Tuple constructor."); + } + + template + constexpr inline TupleImpl(Tuple&& other) + : TupleElement(kj::mv(getImpl(other)))... {} + template + constexpr inline TupleImpl(Tuple& other) + : TupleElement(getImpl(other))... {} + template + constexpr inline TupleImpl(const Tuple& other) + : TupleElement(getImpl(other))... {} +}; + +struct MakeTupleFunc; + +template +class Tuple { + // The actual Tuple class (used for tuples of size other than 1). + +public: + template + constexpr inline Tuple(Tuple&& other): impl(kj::mv(other)) {} + template + constexpr inline Tuple(Tuple& other): impl(other) {} + template + constexpr inline Tuple(const Tuple& other): impl(other) {} + +private: + template + constexpr Tuple(Params&&... params): impl(kj::fwd(params)...) {} + + TupleImpl, T...> impl; + + template + friend inline TypeByIndex& getImpl(Tuple& tuple); + template + friend inline TypeByIndex&& getImpl(Tuple&& tuple); + template + friend inline const TypeByIndex& getImpl(const Tuple& tuple); + friend struct MakeTupleFunc; +}; + +template <> +class Tuple<> { + // Simplified zero-member version of Tuple. In particular this is important to make sure that + // Tuple<>() is constexpr. +}; + +template +class Tuple; +// Single-element tuple should never be used. The public API should ensure this. + +template +inline TypeByIndex& getImpl(Tuple& tuple) { + // Get member of a Tuple by index, e.g. `get<2>(myTuple)`. + static_assert(index < sizeof...(T), "Tuple element index out-of-bounds."); + return implicitCast>&>(tuple.impl).value; +} +template +inline TypeByIndex&& getImpl(Tuple&& tuple) { + // Get member of a Tuple by index, e.g. `get<2>(myTuple)`. + static_assert(index < sizeof...(T), "Tuple element index out-of-bounds."); + return kj::mv(implicitCast>&>(tuple.impl).value); +} +template +inline const TypeByIndex& getImpl(const Tuple& tuple) { + // Get member of a Tuple by index, e.g. `get<2>(myTuple)`. + static_assert(index < sizeof...(T), "Tuple element index out-of-bounds."); + return implicitCast>&>(tuple.impl).value; +} +template +inline T&& getImpl(T&& value) { + // Get member of a Tuple by index, e.g. `getImpl<2>(myTuple)`. + + // Non-tuples are equivalent to one-element tuples. + static_assert(index == 0, "Tuple element index out-of-bounds."); + return kj::fwd(value); +} + + +template +struct ExpandAndApplyResult_; +// Template which computes the return type of applying Func to T... after flattening tuples. +// SoFar starts as Tuple<> and accumulates the flattened parameter types -- so after this template +// is recursively expanded, T... is empty and SoFar is a Tuple containing all the parameters. + +template +struct ExpandAndApplyResult_, First, Rest...> + : public ExpandAndApplyResult_, Rest...> {}; +template +struct ExpandAndApplyResult_, Tuple, Rest...> + : public ExpandAndApplyResult_, FirstTypes&&..., Rest...> {}; +template +struct ExpandAndApplyResult_, Tuple&, Rest...> + : public ExpandAndApplyResult_, FirstTypes&..., Rest...> {}; +template +struct ExpandAndApplyResult_, const Tuple&, Rest...> + : public ExpandAndApplyResult_, const FirstTypes&..., Rest...> {}; +template +struct ExpandAndApplyResult_> { + typedef decltype(instance()(instance()...)) Type; +}; +template +using ExpandAndApplyResult = typename ExpandAndApplyResult_, T...>::Type; +// Computes the expected return type of `expandAndApply()`. + +template +inline auto expandAndApply(Func&& func) -> ExpandAndApplyResult { + return func(); +} + +template +struct ExpandAndApplyFunc { + Func&& func; + First&& first; + ExpandAndApplyFunc(Func&& func, First&& first) + : func(kj::fwd(func)), first(kj::fwd(first)) {} + template + auto operator()(T&&... params) + -> decltype(this->func(kj::fwd(first), kj::fwd(params)...)) { + return this->func(kj::fwd(first), kj::fwd(params)...); + } +}; + +template +inline auto expandAndApply(Func&& func, First&& first, Rest&&... rest) + -> ExpandAndApplyResult { + + return expandAndApply( + ExpandAndApplyFunc(kj::fwd(func), kj::fwd(first)), + kj::fwd(rest)...); +} + +template +inline auto expandAndApply(Func&& func, Tuple&& first, Rest&&... rest) + -> ExpandAndApplyResult { + return expandAndApplyWithIndexes(MakeIndexes(), + kj::fwd(func), kj::mv(first), kj::fwd(rest)...); +} + +template +inline auto expandAndApply(Func&& func, Tuple& first, Rest&&... rest) + -> ExpandAndApplyResult { + return expandAndApplyWithIndexes(MakeIndexes(), + kj::fwd(func), first, kj::fwd(rest)...); +} + +template +inline auto expandAndApply(Func&& func, const Tuple& first, Rest&&... rest) + -> ExpandAndApplyResult { + return expandAndApplyWithIndexes(MakeIndexes(), + kj::fwd(func), first, kj::fwd(rest)...); +} + +template +inline auto expandAndApplyWithIndexes( + Indexes, Func&& func, Tuple&& first, Rest&&... rest) + -> ExpandAndApplyResult { + return expandAndApply(kj::fwd(func), kj::mv(getImpl(first))..., + kj::fwd(rest)...); +} + +template +inline auto expandAndApplyWithIndexes( + Indexes, Func&& func, const Tuple& first, Rest&&... rest) + -> ExpandAndApplyResult { + return expandAndApply(kj::fwd(func), getImpl(first)..., + kj::fwd(rest)...); +} + +struct MakeTupleFunc { + template + Tuple...> operator()(Params&&... params) { + return Tuple...>(kj::fwd(params)...); + } + template + Decay operator()(Param&& param) { + return kj::fwd(param); + } +}; + +} // namespace _ (private) + +template struct Tuple_ { typedef _::Tuple Type; }; +template struct Tuple_ { typedef T Type; }; + +template using Tuple = typename Tuple_::Type; +// Tuple type. `Tuple` (i.e. a single-element tuple) is a synonym for `T`. Tuples of size +// other than 1 expand to an internal type. Either way, you can construct a Tuple using +// `kj::tuple(...)`, get an element by index `i` using `kj::get(myTuple)`, and expand the tuple +// as arguments to a function using `kj::apply(func, myTuple)`. +// +// Tuples are always flat -- that is, no element of a Tuple is ever itself a Tuple. If you +// construct a tuple from other tuples, the elements are flattened and concatenated. + +template +inline auto tuple(Params&&... params) + -> decltype(_::expandAndApply(_::MakeTupleFunc(), kj::fwd(params)...)) { + // Construct a new tuple from the given values. Any tuples in the argument list will be + // flattened into the result. + return _::expandAndApply(_::MakeTupleFunc(), kj::fwd(params)...); +} + +template +inline auto get(Tuple&& tuple) -> decltype(_::getImpl(kj::fwd(tuple))) { + // Unpack and return the tuple element at the given index. The index is specified as a template + // parameter, e.g. `kj::get<3>(myTuple)`. + return _::getImpl(kj::fwd(tuple)); +} + +template +inline auto apply(Func&& func, Params&&... params) + -> decltype(_::expandAndApply(kj::fwd(func), kj::fwd(params)...)) { + // Apply a function to some arguments, expanding tuples into separate arguments. + return _::expandAndApply(kj::fwd(func), kj::fwd(params)...); +} + +template struct TupleSize_ { static constexpr size_t size = 1; }; +template struct TupleSize_<_::Tuple> { + static constexpr size_t size = sizeof...(T); +}; + +template +constexpr size_t tupleSize() { return TupleSize_::size; } +// Returns size of the tuple T. + +} // namespace kj + +#endif // KJ_TUPLE_H_ diff --git a/phonelibs/capnp-cpp/include/kj/units.h b/phonelibs/capnp-cpp/include/kj/units.h new file mode 100644 index 00000000000000..8bba40338bcc05 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/units.h @@ -0,0 +1,1172 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +// This file contains types which are intended to help detect incorrect usage at compile +// time, but should then be optimized down to basic primitives (usually, integers) by the +// compiler. + +#ifndef KJ_UNITS_H_ +#define KJ_UNITS_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "common.h" +#include + +namespace kj { + +// ======================================================================================= +// IDs + +template +struct Id { + // A type-safe numeric ID. `UnderlyingType` is the underlying integer representation. `Label` + // distinguishes this Id from other Id types. Sample usage: + // + // class Foo; + // typedef Id FooId; + // + // class Bar; + // typedef Id BarId; + // + // You can now use the FooId and BarId types without any possibility of accidentally using a + // FooId when you really wanted a BarId or vice-versa. + + UnderlyingType value; + + inline constexpr Id(): value(0) {} + inline constexpr explicit Id(int value): value(value) {} + + inline constexpr bool operator==(const Id& other) const { return value == other.value; } + inline constexpr bool operator!=(const Id& other) const { return value != other.value; } + inline constexpr bool operator<=(const Id& other) const { return value <= other.value; } + inline constexpr bool operator>=(const Id& other) const { return value >= other.value; } + inline constexpr bool operator< (const Id& other) const { return value < other.value; } + inline constexpr bool operator> (const Id& other) const { return value > other.value; } +}; + +// ======================================================================================= +// Quantity and UnitRatio -- implement unit analysis via the type system + +struct Unsafe_ {}; +constexpr Unsafe_ unsafe = Unsafe_(); +// Use as a parameter to constructors that are unsafe to indicate that you really do mean it. + +template +class Bounded; +template +class BoundedConst; + +template constexpr bool isIntegral() { return false; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } +template <> constexpr bool isIntegral() { return true; } + +template +struct IsIntegralOrBounded_ { static constexpr bool value = isIntegral(); }; +template +struct IsIntegralOrBounded_> { static constexpr bool value = true; }; +template +struct IsIntegralOrBounded_> { static constexpr bool value = true; }; + +template +inline constexpr bool isIntegralOrBounded() { return IsIntegralOrBounded_::value; } + +template +class UnitRatio { + // A multiplier used to convert Quantities of one unit to Quantities of another unit. See + // Quantity, below. + // + // Construct this type by dividing one Quantity by another of a different unit. Use this type + // by multiplying it by a Quantity, or dividing a Quantity by it. + + static_assert(isIntegralOrBounded(), + "Underlying type for UnitRatio must be integer."); + +public: + inline UnitRatio() {} + + constexpr UnitRatio(Number unit1PerUnit2, decltype(unsafe)): unit1PerUnit2(unit1PerUnit2) {} + // This constructor was intended to be private, but GCC complains about it being private in a + // bunch of places that don't appear to even call it, so I made it public. Oh well. + + template + inline constexpr UnitRatio(const UnitRatio& other) + : unit1PerUnit2(other.unit1PerUnit2) {} + + template + inline constexpr UnitRatio + operator+(UnitRatio other) const { + return UnitRatio( + unit1PerUnit2 + other.unit1PerUnit2, unsafe); + } + template + inline constexpr UnitRatio + operator-(UnitRatio other) const { + return UnitRatio( + unit1PerUnit2 - other.unit1PerUnit2, unsafe); + } + + template + inline constexpr UnitRatio + operator*(UnitRatio other) const { + // U1 / U2 * U3 / U1 = U3 / U2 + return UnitRatio( + unit1PerUnit2 * other.unit1PerUnit2, unsafe); + } + template + inline constexpr UnitRatio + operator*(UnitRatio other) const { + // U1 / U2 * U2 / U3 = U1 / U3 + return UnitRatio( + unit1PerUnit2 * other.unit1PerUnit2, unsafe); + } + + template + inline constexpr UnitRatio + operator/(UnitRatio other) const { + // (U1 / U2) / (U1 / U3) = U3 / U2 + return UnitRatio( + unit1PerUnit2 / other.unit1PerUnit2, unsafe); + } + template + inline constexpr UnitRatio + operator/(UnitRatio other) const { + // (U1 / U2) / (U3 / U2) = U1 / U3 + return UnitRatio( + unit1PerUnit2 / other.unit1PerUnit2, unsafe); + } + + template + inline decltype(Number() / OtherNumber()) + operator/(UnitRatio other) const { + return unit1PerUnit2 / other.unit1PerUnit2; + } + + inline bool operator==(UnitRatio other) const { return unit1PerUnit2 == other.unit1PerUnit2; } + inline bool operator!=(UnitRatio other) const { return unit1PerUnit2 != other.unit1PerUnit2; } + +private: + Number unit1PerUnit2; + + template + friend class Quantity; + template + friend class UnitRatio; + + template + friend inline constexpr UnitRatio + operator*(N1, UnitRatio); +}; + +template () && isIntegralOrBounded()>> +inline constexpr UnitRatio + operator*(N1 n, UnitRatio r) { + return UnitRatio(n * r.unit1PerUnit2, unsafe); +} + +template +class Quantity { + // A type-safe numeric quantity, specified in terms of some unit. Two Quantities cannot be used + // in arithmetic unless they use the same unit. The `Unit` type parameter is only used to prevent + // accidental mixing of units; this type is never instantiated and can very well be incomplete. + // `Number` is the underlying primitive numeric type. + // + // Quantities support most basic arithmetic operators, intelligently handling units, and + // automatically casting the underlying type in the same way that the compiler would. + // + // To convert a primitive number to a Quantity, multiply it by unit>(). + // To convert a Quantity to a primitive number, divide it by unit>(). + // To convert a Quantity of one unit to another unit, multiply or divide by a UnitRatio. + // + // The Quantity class is not well-suited to hardcore physics as it does not allow multiplying + // one quantity by another. For example, multiplying meters by meters won't get you square + // meters; it will get you a compiler error. It would be interesting to see if template + // metaprogramming could properly deal with such things but this isn't needed for the present + // use case. + // + // Sample usage: + // + // class SecondsLabel; + // typedef Quantity Seconds; + // constexpr Seconds SECONDS = unit(); + // + // class MinutesLabel; + // typedef Quantity Minutes; + // constexpr Minutes MINUTES = unit(); + // + // constexpr UnitRatio SECONDS_PER_MINUTE = + // 60 * SECONDS / MINUTES; + // + // void waitFor(Seconds seconds) { + // sleep(seconds / SECONDS); + // } + // void waitFor(Minutes minutes) { + // waitFor(minutes * SECONDS_PER_MINUTE); + // } + // + // void waitThreeMinutes() { + // waitFor(3 * MINUTES); + // } + + static_assert(isIntegralOrBounded(), + "Underlying type for Quantity must be integer."); + +public: + inline constexpr Quantity() = default; + + inline constexpr Quantity(MaxValue_): value(maxValue) {} + inline constexpr Quantity(MinValue_): value(minValue) {} + // Allow initialization from maxValue and minValue. + // TODO(msvc): decltype(maxValue) and decltype(minValue) deduce unknown-type for these function + // parameters, causing the compiler to complain of a duplicate constructor definition, so we + // specify MaxValue_ and MinValue_ types explicitly. + + inline constexpr Quantity(Number value, decltype(unsafe)): value(value) {} + // This constructor was intended to be private, but GCC complains about it being private in a + // bunch of places that don't appear to even call it, so I made it public. Oh well. + + template + inline constexpr Quantity(const Quantity& other) + : value(other.value) {} + + template + inline Quantity& operator=(const Quantity& other) { + value = other.value; + return *this; + } + + template + inline constexpr Quantity + operator+(const Quantity& other) const { + return Quantity(value + other.value, unsafe); + } + template + inline constexpr Quantity + operator-(const Quantity& other) const { + return Quantity(value - other.value, unsafe); + } + template ()>> + inline constexpr Quantity + operator*(OtherNumber other) const { + return Quantity(value * other, unsafe); + } + template ()>> + inline constexpr Quantity + operator/(OtherNumber other) const { + return Quantity(value / other, unsafe); + } + template + inline constexpr decltype(Number() / OtherNumber()) + operator/(const Quantity& other) const { + return value / other.value; + } + template + inline constexpr Quantity + operator%(const Quantity& other) const { + return Quantity(value % other.value, unsafe); + } + + template + inline constexpr Quantity + operator*(UnitRatio ratio) const { + return Quantity( + value * ratio.unit1PerUnit2, unsafe); + } + template + inline constexpr Quantity + operator/(UnitRatio ratio) const { + return Quantity( + value / ratio.unit1PerUnit2, unsafe); + } + template + inline constexpr Quantity + operator%(UnitRatio ratio) const { + return Quantity( + value % ratio.unit1PerUnit2, unsafe); + } + template + inline constexpr UnitRatio + operator/(Quantity other) const { + return UnitRatio( + value / other.value, unsafe); + } + + template + inline constexpr bool operator==(const Quantity& other) const { + return value == other.value; + } + template + inline constexpr bool operator!=(const Quantity& other) const { + return value != other.value; + } + template + inline constexpr bool operator<=(const Quantity& other) const { + return value <= other.value; + } + template + inline constexpr bool operator>=(const Quantity& other) const { + return value >= other.value; + } + template + inline constexpr bool operator<(const Quantity& other) const { + return value < other.value; + } + template + inline constexpr bool operator>(const Quantity& other) const { + return value > other.value; + } + + template + inline Quantity& operator+=(const Quantity& other) { + value += other.value; + return *this; + } + template + inline Quantity& operator-=(const Quantity& other) { + value -= other.value; + return *this; + } + template + inline Quantity& operator*=(OtherNumber other) { + value *= other; + return *this; + } + template + inline Quantity& operator/=(OtherNumber other) { + value /= other.value; + return *this; + } + +private: + Number value; + + template + friend class Quantity; + + template + friend inline constexpr auto operator*(Number1 a, Quantity b) + -> Quantity; +}; + +template struct Unit_ { + static inline constexpr T get() { return T(1); } +}; +template +struct Unit_> { + static inline constexpr Quantity::get()), U> get() { + return Quantity::get()), U>(Unit_::get(), unsafe); + } +}; + +template +inline constexpr auto unit() -> decltype(Unit_::get()) { return Unit_::get(); } +// unit>() returns a Quantity of value 1. It also, intentionally, works on basic +// numeric types. + +template +inline constexpr auto operator*(Number1 a, Quantity b) + -> Quantity { + return Quantity(a * b.value, unsafe); +} + +template +inline constexpr auto operator*(UnitRatio ratio, + Quantity measure) + -> decltype(measure * ratio) { + return measure * ratio; +} + +// ======================================================================================= +// Absolute measures + +template +class Absolute { + // Wraps some other value -- typically a Quantity -- but represents a value measured based on + // some absolute origin. For example, if `Duration` is a type representing a time duration, + // Absolute might be a calendar date. + // + // Since Absolute represents measurements relative to some arbitrary origin, the only sensible + // arithmetic to perform on them is addition and subtraction. + + // TODO(someday): Do the same automatic expansion of integer width that Quantity does? Doesn't + // matter for our time use case, where we always use 64-bit anyway. Note that fixing this + // would implicitly allow things like multiplying an Absolute by a UnitRatio to change its + // units, which is actually totally logical and kind of neat. + +public: + inline constexpr Absolute operator+(const T& other) const { return Absolute(value + other); } + inline constexpr Absolute operator-(const T& other) const { return Absolute(value - other); } + inline constexpr T operator-(const Absolute& other) const { return value - other.value; } + + inline Absolute& operator+=(const T& other) { value += other; return *this; } + inline Absolute& operator-=(const T& other) { value -= other; return *this; } + + inline constexpr bool operator==(const Absolute& other) const { return value == other.value; } + inline constexpr bool operator!=(const Absolute& other) const { return value != other.value; } + inline constexpr bool operator<=(const Absolute& other) const { return value <= other.value; } + inline constexpr bool operator>=(const Absolute& other) const { return value >= other.value; } + inline constexpr bool operator< (const Absolute& other) const { return value < other.value; } + inline constexpr bool operator> (const Absolute& other) const { return value > other.value; } + +private: + T value; + + explicit constexpr Absolute(T value): value(value) {} + + template + friend inline constexpr U origin(); +}; + +template +inline constexpr Absolute operator+(const T& a, const Absolute& b) { + return b + a; +} + +template struct UnitOf_ { typedef T Type; }; +template struct UnitOf_> { typedef T Type; }; +template +using UnitOf = typename UnitOf_::Type; +// UnitOf> is T. UnitOf is AnythingElse. + +template +inline constexpr T origin() { return T(0 * unit>()); } +// origin>() returns an Absolute of value 0. It also, intentionally, works on basic +// numeric types. + +// ======================================================================================= +// Overflow avoidance + +template +struct BitCount_ { + static constexpr uint value = BitCount_<(n >> 1), accum + 1>::value; +}; +template +struct BitCount_<0, accum> { + static constexpr uint value = accum; +}; + +template +inline constexpr uint bitCount() { return BitCount_::value; } +// Number of bits required to represent the number `n`. + +template struct AtLeastUInt_ { + static_assert(bitCountBitCount < 7, "don't know how to represent integers over 64 bits"); +}; +template <> struct AtLeastUInt_<0> { typedef uint8_t Type; }; +template <> struct AtLeastUInt_<1> { typedef uint8_t Type; }; +template <> struct AtLeastUInt_<2> { typedef uint8_t Type; }; +template <> struct AtLeastUInt_<3> { typedef uint8_t Type; }; +template <> struct AtLeastUInt_<4> { typedef uint16_t Type; }; +template <> struct AtLeastUInt_<5> { typedef uint32_t Type; }; +template <> struct AtLeastUInt_<6> { typedef uint64_t Type; }; + +template +using AtLeastUInt = typename AtLeastUInt_()>::Type; +// AtLeastUInt is an unsigned integer of at least n bits. E.g. AtLeastUInt<12> is uint16_t. + +// ------------------------------------------------------------------- + +template +class BoundedConst { + // A constant integer value on which we can do bit size analysis. + +public: + BoundedConst() = default; + + inline constexpr uint unwrap() const { return value; } + +#define OP(op, check) \ + template \ + inline constexpr BoundedConst<(value op other)> \ + operator op(BoundedConst) const { \ + static_assert(check, "overflow in BoundedConst arithmetic"); \ + return BoundedConst<(value op other)>(); \ + } +#define COMPARE_OP(op) \ + template \ + inline constexpr bool operator op(BoundedConst) const { \ + return value op other; \ + } + + OP(+, value + other >= value) + OP(-, value - other <= value) + OP(*, value * other / other == value) + OP(/, true) // div by zero already errors out; no other division ever overflows + OP(%, true) // mod by zero already errors out; no other modulus ever overflows + OP(<<, value << other >= value) + OP(>>, true) // right shift can't overflow + OP(&, true) // bitwise ops can't overflow + OP(|, true) // bitwise ops can't overflow + + COMPARE_OP(==) + COMPARE_OP(!=) + COMPARE_OP(< ) + COMPARE_OP(> ) + COMPARE_OP(<=) + COMPARE_OP(>=) +#undef OP +#undef COMPARE_OP +}; + +template +struct Unit_> { + static inline constexpr BoundedConst<1> get() { return BoundedConst<1>(); } +}; + +template +struct Unit_> { + static inline constexpr BoundedConst<1> get() { return BoundedConst<1>(); } +}; + +template +inline constexpr BoundedConst bounded() { + return BoundedConst(); +} + +template +static constexpr uint64_t boundedAdd() { + static_assert(a + b >= a, "possible overflow detected"); + return a + b; +} +template +static constexpr uint64_t boundedSub() { + static_assert(a - b <= a, "possible underflow detected"); + return a - b; +} +template +static constexpr uint64_t boundedMul() { + static_assert(a * b / b == a, "possible overflow detected"); + return a * b; +} +template +static constexpr uint64_t boundedLShift() { + static_assert(a << b >= a, "possible overflow detected"); + return a << b; +} + +template +inline constexpr BoundedConst min(BoundedConst, BoundedConst) { + return bounded(); +} +template +inline constexpr BoundedConst max(BoundedConst, BoundedConst) { + return bounded(); +} +// We need to override min() and max() between constants because the ternary operator in the +// default implementation would complain. + +// ------------------------------------------------------------------- + +template +class Bounded { +public: + static_assert(maxN <= T(kj::maxValue), "possible overflow detected"); + + Bounded() = default; + + Bounded(const Bounded& other) = default; + template ()>> + inline constexpr Bounded(OtherInt value): value(value) { + static_assert(OtherInt(maxValue) <= maxN, "possible overflow detected"); + } + template + inline constexpr Bounded(const Bounded& other) + : value(other.value) { + static_assert(otherMax <= maxN, "possible overflow detected"); + } + template + inline constexpr Bounded(BoundedConst) + : value(otherValue) { + static_assert(otherValue <= maxN, "overflow detected"); + } + + Bounded& operator=(const Bounded& other) = default; + template ()>> + Bounded& operator=(OtherInt other) { + static_assert(OtherInt(maxValue) <= maxN, "possible overflow detected"); + value = other; + return *this; + } + template + inline Bounded& operator=(const Bounded& other) { + static_assert(otherMax <= maxN, "possible overflow detected"); + value = other.value; + return *this; + } + template + inline Bounded& operator=(BoundedConst) { + static_assert(otherValue <= maxN, "overflow detected"); + value = otherValue; + return *this; + } + + inline constexpr T unwrap() const { return value; } + +#define OP(op, newMax) \ + template \ + inline constexpr Bounded \ + operator op(const Bounded& other) const { \ + return Bounded(value op other.value, unsafe); \ + } +#define COMPARE_OP(op) \ + template \ + inline constexpr bool operator op(const Bounded& other) const { \ + return value op other.value; \ + } + + OP(+, (boundedAdd())) + OP(*, (boundedMul())) + OP(/, maxN) + OP(%, otherMax - 1) + + // operator- is intentionally omitted because we mostly use this with unsigned types, and + // subtraction requires proof that subtrahend is not greater than the minuend. + + COMPARE_OP(==) + COMPARE_OP(!=) + COMPARE_OP(< ) + COMPARE_OP(> ) + COMPARE_OP(<=) + COMPARE_OP(>=) + +#undef OP +#undef COMPARE_OP + + template + inline Bounded assertMax(ErrorFunc&& func) const { + // Assert that the number is no more than `newMax`. Otherwise, call `func`. + static_assert(newMax < maxN, "this bounded size assertion is redundant"); + if (KJ_UNLIKELY(value > newMax)) func(); + return Bounded(value, unsafe); + } + + template + inline Bounded subtractChecked( + const Bounded& other, ErrorFunc&& func) const { + // Subtract a number, calling func() if the result would underflow. + if (KJ_UNLIKELY(value < other.value)) func(); + return Bounded(value - other.value, unsafe); + } + + template + inline Bounded subtractChecked( + BoundedConst, ErrorFunc&& func) const { + // Subtract a number, calling func() if the result would underflow. + static_assert(otherValue <= maxN, "underflow detected"); + if (KJ_UNLIKELY(value < otherValue)) func(); + return Bounded(value - otherValue, unsafe); + } + + template + inline Maybe> trySubtract( + const Bounded& other) const { + // Subtract a number, calling func() if the result would underflow. + if (value < other.value) { + return nullptr; + } else { + return Bounded(value - other.value, unsafe); + } + } + + template + inline Maybe> trySubtract(BoundedConst) const { + // Subtract a number, calling func() if the result would underflow. + if (value < otherValue) { + return nullptr; + } else { + return Bounded(value - otherValue, unsafe); + } + } + + inline constexpr Bounded(T value, decltype(unsafe)): value(value) {} + template + inline constexpr Bounded(Bounded value, decltype(unsafe)) + : value(value.value) {} + // Mainly for internal use. + // + // Only use these as a last resort, with ample commentary on why you think it's safe. + +private: + T value; + + template + friend class Bounded; +}; + +template +inline constexpr Bounded bounded(Number value) { + return Bounded(value, unsafe); +} + +inline constexpr Bounded<1, uint8_t> bounded(bool value) { + return Bounded<1, uint8_t>(value, unsafe); +} + +template +inline constexpr Bounded(), Number> assumeBits(Number value) { + return Bounded(), Number>(value, unsafe); +} + +template +inline constexpr Bounded(), T> assumeBits(Bounded value) { + return Bounded(), T>(value, unsafe); +} + +template +inline constexpr auto assumeBits(Quantity value) + -> Quantity(value / unit>())), Unit> { + return Quantity(value / unit>())), Unit>( + assumeBits(value / unit>()), unsafe); +} + +template +inline constexpr Bounded assumeMax(Number value) { + return Bounded(value, unsafe); +} + +template +inline constexpr Bounded assumeMax(Bounded value) { + return Bounded(value, unsafe); +} + +template +inline constexpr auto assumeMax(Quantity value) + -> Quantity(value / unit>())), Unit> { + return Quantity(value / unit>())), Unit>( + assumeMax(value / unit>()), unsafe); +} + +template +inline constexpr Bounded assumeMax(BoundedConst, Number value) { + return assumeMax(value); +} + +template +inline constexpr Bounded assumeMax(BoundedConst, Bounded value) { + return assumeMax(value); +} + +template +inline constexpr auto assumeMax(Quantity, Unit>, Quantity value) + -> decltype(assumeMax(value)) { + return assumeMax(value); +} + +template +inline Bounded assertMax(Bounded value, ErrorFunc&& errorFunc) { + // Assert that the bounded value is less than or equal to the given maximum, calling errorFunc() + // if not. + static_assert(newMax < maxN, "this bounded size assertion is redundant"); + return value.template assertMax(kj::fwd(errorFunc)); +} + +template +inline Quantity, Unit> assertMax( + Quantity, Unit> value, ErrorFunc&& errorFunc) { + // Assert that the bounded value is less than or equal to the given maximum, calling errorFunc() + // if not. + static_assert(newMax < maxN, "this bounded size assertion is redundant"); + return (value / unit()).template assertMax( + kj::fwd(errorFunc)) * unit(); +} + +template +inline Bounded assertMax( + BoundedConst, Bounded value, ErrorFunc&& errorFunc) { + return assertMax(value, kj::mv(errorFunc)); +} + +template +inline Quantity, Unit> assertMax( + Quantity, Unit>, + Quantity, Unit> value, ErrorFunc&& errorFunc) { + return assertMax(value, kj::mv(errorFunc)); +} + +template +inline Bounded(), T> assertMaxBits( + Bounded value, ErrorFunc&& errorFunc = ErrorFunc()) { + // Assert that the bounded value requires no more than the given number of bits, calling + // errorFunc() if not. + return assertMax()>(value, kj::fwd(errorFunc)); +} + +template +inline Quantity(), T>, Unit> assertMaxBits( + Quantity, Unit> value, ErrorFunc&& errorFunc = ErrorFunc()) { + // Assert that the bounded value requires no more than the given number of bits, calling + // errorFunc() if not. + return assertMax()>(value, kj::fwd(errorFunc)); +} + +template +inline constexpr Bounded upgradeBound(Bounded value) { + return value; +} + +template +inline constexpr Quantity, Unit> upgradeBound( + Quantity, Unit> value) { + return value; +} + +template +inline auto subtractChecked(Bounded value, Other other, ErrorFunc&& errorFunc) + -> decltype(value.subtractChecked(other, kj::fwd(errorFunc))) { + return value.subtractChecked(other, kj::fwd(errorFunc)); +} + +template +inline auto subtractChecked(Quantity value, Quantity other, ErrorFunc&& errorFunc) + -> Quantity(errorFunc))), Unit> { + return subtractChecked(value / unit>(), + other / unit>(), + kj::fwd(errorFunc)) + * unit>(); +} + +template +inline auto trySubtract(Bounded value, Other other) + -> decltype(value.trySubtract(other)) { + return value.trySubtract(other); +} + +template +inline auto trySubtract(Quantity value, Quantity other) + -> Maybe> { + return trySubtract(value / unit>(), + other / unit>()) + .map([](decltype(subtractChecked(T(), U(), int())) x) { + return x * unit>(); + }); +} + +template +inline constexpr Bounded> +min(Bounded a, Bounded b) { + return Bounded>(kj::min(a.unwrap(), b.unwrap()), unsafe); +} +template +inline constexpr Bounded> +max(Bounded a, Bounded b) { + return Bounded>(kj::max(a.unwrap(), b.unwrap()), unsafe); +} +// We need to override min() and max() because: +// 1) WiderType<> might not choose the correct bounds. +// 2) One of the two sides of the ternary operator in the default implementation would fail to +// typecheck even though it is OK in practice. + +// ------------------------------------------------------------------- +// Operators between Bounded and BoundedConst + +#define OP(op, newMax) \ +template \ +inline constexpr Bounded<(newMax), decltype(T() op uint())> operator op( \ + Bounded value, BoundedConst) { \ + return Bounded<(newMax), decltype(T() op uint())>(value.unwrap() op cvalue, unsafe); \ +} + +#define REVERSE_OP(op, newMax) \ +template \ +inline constexpr Bounded<(newMax), decltype(uint() op T())> operator op( \ + BoundedConst, Bounded value) { \ + return Bounded<(newMax), decltype(uint() op T())>(cvalue op value.unwrap(), unsafe); \ +} + +#define COMPARE_OP(op) \ +template \ +inline constexpr bool operator op(Bounded value, BoundedConst) { \ + return value.unwrap() op cvalue; \ +} \ +template \ +inline constexpr bool operator op(BoundedConst, Bounded value) { \ + return cvalue op value.unwrap(); \ +} + +OP(+, (boundedAdd())) +REVERSE_OP(+, (boundedAdd())) + +OP(*, (boundedMul())) +REVERSE_OP(*, (boundedAdd())) + +OP(/, maxN / cvalue) +REVERSE_OP(/, cvalue) // denominator could be 1 + +OP(%, cvalue - 1) +REVERSE_OP(%, maxN - 1) + +OP(<<, (boundedLShift())) +REVERSE_OP(<<, (boundedLShift())) + +OP(>>, maxN >> cvalue) +REVERSE_OP(>>, cvalue >> maxN) + +OP(&, maxValueForBits()>() & cvalue) +REVERSE_OP(&, maxValueForBits()>() & cvalue) + +OP(|, maxN | cvalue) +REVERSE_OP(|, maxN | cvalue) + +COMPARE_OP(==) +COMPARE_OP(!=) +COMPARE_OP(< ) +COMPARE_OP(> ) +COMPARE_OP(<=) +COMPARE_OP(>=) + +#undef OP +#undef REVERSE_OP +#undef COMPARE_OP + +template +inline constexpr Bounded + operator-(BoundedConst, Bounded value) { + // We allow subtraction of a variable from a constant only if the constant is greater than or + // equal to the maximum possible value of the variable. Since the variable could be zero, the + // result can be as large as the constant. + // + // We do not allow subtraction of a constant from a variable because there's never a guarantee it + // won't underflow (unless the constant is zero, which is silly). + static_assert(cvalue >= maxN, "possible underflow detected"); + return Bounded(cvalue - value.unwrap(), unsafe); +} + +template +inline constexpr Bounded min(Bounded a, BoundedConst) { + return Bounded(kj::min(b, a.unwrap()), unsafe); +} +template +inline constexpr Bounded min(BoundedConst, Bounded a) { + return Bounded(kj::min(a.unwrap(), b), unsafe); +} +template +inline constexpr Bounded max(Bounded a, BoundedConst) { + return Bounded(kj::max(b, a.unwrap()), unsafe); +} +template +inline constexpr Bounded max(BoundedConst, Bounded a) { + return Bounded(kj::max(a.unwrap(), b), unsafe); +} +// We need to override min() between a Bounded and a constant since: +// 1) WiderType<> might choose BoundedConst over a 1-byte Bounded, which is wrong. +// 2) To clamp the bounds of the output type. +// 3) Same ternary operator typechecking issues. + +// ------------------------------------------------------------------- + +template +class SafeUnwrapper { +public: + inline explicit constexpr SafeUnwrapper(Bounded value): value(value.unwrap()) {} + + template ()>> + inline constexpr operator U() const { + static_assert(maxN <= U(maxValue), "possible truncation detected"); + return value; + } + + inline constexpr operator bool() const { + static_assert(maxN <= 1, "possible truncation detected"); + return value; + } + +private: + T value; +}; + +template +inline constexpr SafeUnwrapper unbound(Bounded bounded) { + // Unwraps the bounded value, returning a value that can be implicitly cast to any integer type. + // If this implicit cast could truncate, a compile-time error will be raised. + return SafeUnwrapper(bounded); +} + +template +class SafeConstUnwrapper { +public: + template ()>> + inline constexpr operator T() const { + static_assert(value <= T(maxValue), "this operation will truncate"); + return value; + } + + inline constexpr operator bool() const { + static_assert(value <= 1, "this operation will truncate"); + return value; + } +}; + +template +inline constexpr SafeConstUnwrapper unbound(BoundedConst) { + return SafeConstUnwrapper(); +} + +template +inline constexpr T unboundAs(U value) { + return unbound(value); +} + +template +inline constexpr T unboundMax(Bounded value) { + // Explicitly ungaurd expecting a value that is at most `maxN`. + static_assert(maxN <= requestedMax, "possible overflow detected"); + return value.unwrap(); +} + +template +inline constexpr uint unboundMax(BoundedConst) { + // Explicitly ungaurd expecting a value that is at most `maxN`. + static_assert(value <= requestedMax, "overflow detected"); + return value; +} + +template +inline constexpr auto unboundMaxBits(T value) -> + decltype(unboundMax()>(value)) { + // Explicitly ungaurd expecting a value that fits into `bits` bits. + return unboundMax()>(value); +} + +#define OP(op) \ +template \ +inline constexpr auto operator op(T a, SafeUnwrapper b) -> decltype(a op (T)b) { \ + return a op (AtLeastUInt)b; \ +} \ +template \ +inline constexpr auto operator op(SafeUnwrapper b, T a) -> decltype((T)b op a) { \ + return (AtLeastUInt)b op a; \ +} \ +template \ +inline constexpr auto operator op(T a, SafeConstUnwrapper b) -> decltype(a op (T)b) { \ + return a op (AtLeastUInt)b; \ +} \ +template \ +inline constexpr auto operator op(SafeConstUnwrapper b, T a) -> decltype((T)b op a) { \ + return (AtLeastUInt)b op a; \ +} + +OP(+) +OP(-) +OP(*) +OP(/) +OP(%) +OP(<<) +OP(>>) +OP(&) +OP(|) +OP(==) +OP(!=) +OP(<=) +OP(>=) +OP(<) +OP(>) + +#undef OP + +// ------------------------------------------------------------------- + +template +class Range> { +public: + inline constexpr Range(Bounded begin, Bounded end) + : inner(unbound(begin), unbound(end)) {} + inline explicit constexpr Range(Bounded end) + : inner(unbound(end)) {} + + class Iterator { + public: + Iterator() = default; + inline explicit Iterator(typename Range::Iterator inner): inner(inner) {} + + inline Bounded operator* () const { return Bounded(*inner, unsafe); } + inline Iterator& operator++() { ++inner; return *this; } + + inline bool operator==(const Iterator& other) const { return inner == other.inner; } + inline bool operator!=(const Iterator& other) const { return inner != other.inner; } + + private: + typename Range::Iterator inner; + }; + + inline Iterator begin() const { return Iterator(inner.begin()); } + inline Iterator end() const { return Iterator(inner.end()); } + +private: + Range inner; +}; + +template +class Range> { +public: + inline constexpr Range(Quantity begin, Quantity end) + : inner(begin / unit>(), end / unit>()) {} + inline explicit constexpr Range(Quantity end) + : inner(end / unit>()) {} + + class Iterator { + public: + Iterator() = default; + inline explicit Iterator(typename Range::Iterator inner): inner(inner) {} + + inline Quantity operator* () const { return *inner * unit>(); } + inline Iterator& operator++() { ++inner; return *this; } + + inline bool operator==(const Iterator& other) const { return inner == other.inner; } + inline bool operator!=(const Iterator& other) const { return inner != other.inner; } + + private: + typename Range::Iterator inner; + }; + + inline Iterator begin() const { return Iterator(inner.begin()); } + inline Iterator end() const { return Iterator(inner.end()); } + +private: + Range inner; +}; + +template +inline constexpr Range> zeroTo(BoundedConst end) { + return Range>(end); +} + +template +inline constexpr Range, Unit>> + zeroTo(Quantity, Unit> end) { + return Range, Unit>>(end); +} + +} // namespace kj + +#endif // KJ_UNITS_H_ diff --git a/phonelibs/capnp-cpp/include/kj/vector.h b/phonelibs/capnp-cpp/include/kj/vector.h new file mode 100644 index 00000000000000..44613f333173cd --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/vector.h @@ -0,0 +1,144 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_VECTOR_H_ +#define KJ_VECTOR_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#include "array.h" + +namespace kj { + +template +class Vector { + // Similar to std::vector, but based on KJ framework. + // + // This implementation always uses move constructors when growing the backing array. If the + // move constructor throws, the Vector is left in an inconsistent state. This is acceptable + // under KJ exception theory which assumes that exceptions leave things in inconsistent states. + + // TODO(someday): Allow specifying a custom allocator. + +public: + inline Vector() = default; + inline explicit Vector(size_t capacity): builder(heapArrayBuilder(capacity)) {} + + inline operator ArrayPtr() { return builder; } + inline operator ArrayPtr() const { return builder; } + inline ArrayPtr asPtr() { return builder.asPtr(); } + inline ArrayPtr asPtr() const { return builder.asPtr(); } + + inline size_t size() const { return builder.size(); } + inline bool empty() const { return size() == 0; } + inline size_t capacity() const { return builder.capacity(); } + inline T& operator[](size_t index) const { return builder[index]; } + + inline const T* begin() const { return builder.begin(); } + inline const T* end() const { return builder.end(); } + inline const T& front() const { return builder.front(); } + inline const T& back() const { return builder.back(); } + inline T* begin() { return builder.begin(); } + inline T* end() { return builder.end(); } + inline T& front() { return builder.front(); } + inline T& back() { return builder.back(); } + + inline Array releaseAsArray() { + // TODO(perf): Avoid a copy/move by allowing Array to point to incomplete space? + if (!builder.isFull()) { + setCapacity(size()); + } + return builder.finish(); + } + + template + inline T& add(Params&&... params) { + if (builder.isFull()) grow(); + return builder.add(kj::fwd(params)...); + } + + template + inline void addAll(Iterator begin, Iterator end) { + size_t needed = builder.size() + (end - begin); + if (needed > builder.capacity()) grow(needed); + builder.addAll(begin, end); + } + + template + inline void addAll(Container&& container) { + addAll(container.begin(), container.end()); + } + + inline void removeLast() { + builder.removeLast(); + } + + inline void resize(size_t size) { + if (size > builder.capacity()) grow(size); + builder.resize(size); + } + + inline void operator=(decltype(nullptr)) { + builder = nullptr; + } + + inline void clear() { + while (builder.size() > 0) { + builder.removeLast(); + } + } + + inline void truncate(size_t size) { + builder.truncate(size); + } + + inline void reserve(size_t size) { + if (size > builder.capacity()) { + setCapacity(size); + } + } + +private: + ArrayBuilder builder; + + void grow(size_t minCapacity = 0) { + setCapacity(kj::max(minCapacity, capacity() == 0 ? 4 : capacity() * 2)); + } + void setCapacity(size_t newSize) { + if (builder.size() > newSize) { + builder.truncate(newSize); + } + ArrayBuilder newBuilder = heapArrayBuilder(newSize); + newBuilder.addAll(kj::mv(builder)); + builder = kj::mv(newBuilder); + } +}; + +template +inline auto KJ_STRINGIFY(const Vector& v) -> decltype(toCharSequence(v.asPtr())) { + return toCharSequence(v.asPtr()); +} + +} // namespace kj + +#endif // KJ_VECTOR_H_ diff --git a/phonelibs/capnp-cpp/include/kj/windows-sanity.h b/phonelibs/capnp-cpp/include/kj/windows-sanity.h new file mode 100644 index 00000000000000..766ba2cbd67047 --- /dev/null +++ b/phonelibs/capnp-cpp/include/kj/windows-sanity.h @@ -0,0 +1,41 @@ +// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors +// Licensed under the MIT License: +// +// Permission is hereby granted, free of charge, to any person obtaining a copy +// of this software and associated documentation files (the "Software"), to deal +// in the Software without restriction, including without limitation the rights +// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell +// copies of the Software, and to permit persons to whom the Software is +// furnished to do so, subject to the following conditions: +// +// The above copyright notice and this permission notice shall be included in +// all copies or substantial portions of the Software. +// +// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN +// THE SOFTWARE. + +#ifndef KJ_WINDOWS_SANITY_H_ +#define KJ_WINDOWS_SANITY_H_ + +#if defined(__GNUC__) && !KJ_HEADER_WARNINGS +#pragma GCC system_header +#endif + +#ifndef _INC_WINDOWS +#error "windows.h needs to be included before kj/windows-sanity.h (or perhaps you don't need either?)" +#endif + +namespace win32 { + const auto ERROR_ = ERROR; +#undef ERROR + const auto ERROR = ERROR_; +} + +using win32::ERROR; + +#endif // KJ_WINDOWS_SANITY_H_ diff --git a/requirements_openpilot.txt b/requirements_openpilot.txt index a005faace75e00..69f135c2608da2 100644 --- a/requirements_openpilot.txt +++ b/requirements_openpilot.txt @@ -2,7 +2,7 @@ Cython==0.24.1 bitstring==3.1.5 fastcluster==1.1.21 libusb1==1.5.0 -pycapnp==0.5.9 +pycapnp==0.6.3 pyzmq==15.4.0 raven==5.23.0 requests==2.10.0 @@ -16,3 +16,4 @@ filterpy==1.0.0 smbus2==0.2.0 pyflakes==1.5.0 -e git+https://github.com/commaai/le_python.git#egg=Logentries +Flask==1.0.1 diff --git a/selfdrive/assets/img_spinner_comma.png b/selfdrive/assets/img_spinner_comma.png new file mode 100644 index 00000000000000..16109557f85911 Binary files /dev/null and b/selfdrive/assets/img_spinner_comma.png differ diff --git a/selfdrive/assets/img_spinner_track.png b/selfdrive/assets/img_spinner_track.png new file mode 100644 index 00000000000000..931c17e8367cef Binary files /dev/null and b/selfdrive/assets/img_spinner_track.png differ diff --git a/selfdrive/boardd/boardd.cc b/selfdrive/boardd/boardd.cc index 6da41e182dc9ed..771ea7d99fe186 100644 --- a/selfdrive/boardd/boardd.cc +++ b/selfdrive/boardd/boardd.cc @@ -37,6 +37,7 @@ #define SAFETY_ELM327 0xE327 #define SAFETY_GM 3 #define SAFETY_HONDA_BOSCH 4 +#define SAFETY_FORD 5 #define SAFETY_TOYOTA_NOLIMITS 0x1336 #define SAFETY_ALLOUTPUT 0x1337 @@ -105,6 +106,9 @@ void *safety_setter_thread(void *s) { case (int)cereal::CarParams::SafetyModels::HONDA_BOSCH: safety_setting = SAFETY_HONDA_BOSCH; break; + case (int)cereal::CarParams::SafetyModels::FORD: + safety_setting = SAFETY_FORD; + break; default: LOGE("unknown safety model: %d", safety_model); } diff --git a/selfdrive/can/Makefile b/selfdrive/can/Makefile index a1f12619634454..b140aa5f87e2a1 100644 --- a/selfdrive/can/Makefile +++ b/selfdrive/can/Makefile @@ -28,6 +28,7 @@ else ifeq ($(UNAME_M),x86_64) else ifeq ($(UNAME_M),aarch64) ZMQ_FLAGS = -I$(PHONELIBS)/zmq/aarch64/include ZMQ_LIBS = -L$(PHONELIBS)/zmq/aarch64/lib -l:libzmq.a + CXXFLAGS += -lgnustl_shared endif OPENDBC_PATH := $(shell python -c 'import opendbc; print opendbc.DBC_PATH') diff --git a/selfdrive/car/__init__.py b/selfdrive/car/__init__.py index 388af85f9f63ff..5029ba2c5346c3 100644 --- a/selfdrive/car/__init__.py +++ b/selfdrive/car/__init__.py @@ -5,7 +5,7 @@ from selfdrive.swaglog import cloudlog import selfdrive.messaging as messaging -from common.fingerprints import HONDA, TOYOTA, GM +from common.fingerprints import HONDA, TOYOTA, GM, FORD def load_interfaces(x): ret = {} @@ -22,7 +22,8 @@ def load_interfaces(x): interfaces = load_interfaces({ 'honda': [HONDA.CIVIC, HONDA.ACURA_ILX, HONDA.CRV, HONDA.ODYSSEY, HONDA.ACURA_RDX, HONDA.PILOT, HONDA.RIDGELINE], 'toyota': [TOYOTA.PRIUS, TOYOTA.RAV4, TOYOTA.RAV4H, TOYOTA.COROLLA, TOYOTA.LEXUS_RXH], - 'gm': [GM.VOLT], + 'gm': [GM.VOLT, GM.CADILLAC_CT6], + 'ford': [FORD.FUSION], 'simulator2': ['simulator2'], 'mock': ['mock']}) diff --git a/selfdrive/car/honda/interface.py b/selfdrive/car/honda/interface.py index 1f053d283a4a6e..7beaa6b5b8330c 100755 --- a/selfdrive/car/honda/interface.py +++ b/selfdrive/car/honda/interface.py @@ -257,6 +257,7 @@ def get_params(candidate, fingerprint): raise ValueError("unsupported car %s" % candidate) ret.steerKf = 0. # TODO: investigate FF steer control for Honda + ret.steerControlType = car.CarParams.SteerControlType.torque # min speed to enable ACC. if car can do stop and go, then set enabling speed # to a negative value, so it won't matter. Otherwise, add 0.5 mph margin to not diff --git a/selfdrive/car/toyota/carcontroller.py b/selfdrive/car/toyota/carcontroller.py index 50ce557faa334d..7752add1b23c2a 100644 --- a/selfdrive/car/toyota/carcontroller.py +++ b/selfdrive/car/toyota/carcontroller.py @@ -67,6 +67,7 @@ def process_hud_alert(hud_alert, audible_alert): return steer, fcw, sound1, sound2 + def ipas_state_transition(steer_angle_enabled, enabled, ipas_active, ipas_reset_counter): if enabled and not steer_angle_enabled: diff --git a/selfdrive/car/toyota/interface.py b/selfdrive/car/toyota/interface.py index 49e6455faec2e3..55310d7ab72dda 100755 --- a/selfdrive/car/toyota/interface.py +++ b/selfdrive/car/toyota/interface.py @@ -136,6 +136,7 @@ def get_params(candidate, fingerprint): # no rear steering, at least on the listed cars above ret.steerRatioRear = 0. + ret.steerControlType = car.CarParams.SteerControlType.torque # steer, gas, brake limitations VS speed ret.steerMaxBP = [16. * CV.KPH_TO_MS, 45. * CV.KPH_TO_MS] # breakpoints at 1 and 40 kph diff --git a/selfdrive/common/touch.c b/selfdrive/common/touch.c index a6dc226053e14a..2367d8d98c264f 100644 --- a/selfdrive/common/touch.c +++ b/selfdrive/common/touch.c @@ -89,9 +89,9 @@ int touch_poll(TouchState *s, int* out_x, int* out_y) { } } if (up) { - // adjust for landscape - *out_x = 1920 - s->last_y; - *out_y = s->last_x; + // adjust for flippening + *out_x = s->last_y; + *out_y = 1080 - s->last_x; } return up; } diff --git a/selfdrive/common/version.h b/selfdrive/common/version.h index 0760fbbe9b2226..aa2be407b73705 100644 --- a/selfdrive/common/version.h +++ b/selfdrive/common/version.h @@ -1 +1 @@ -#define COMMA_VERSION "0.4.5.1-release" +#define COMMA_VERSION "0.4.6-release" diff --git a/selfdrive/controls/lib/alertmanager.py b/selfdrive/controls/lib/alertmanager.py index afa79d48a9704e..2fb365518eb66b 100644 --- a/selfdrive/controls/lib/alertmanager.py +++ b/selfdrive/controls/lib/alertmanager.py @@ -88,6 +88,12 @@ class AlertManager(object): AlertStatus.userPrompt, AlertSize.mid, Priority.LOW, "steerRequired", "chimeDouble", .4, 2., 3.), + "steerTempUnavailableMute": Alert( + "TAKE CONTROL", + "Steering Temporarily Unavailable", + AlertStatus.userPrompt, AlertSize.mid, + Priority.LOW, None, None, .2, .2, .2), + "preDriverDistracted": Alert( "TAKE CONTROL", "User Appears Distracted", @@ -124,6 +130,12 @@ class AlertManager(object): AlertStatus.userPrompt, AlertSize.mid, Priority.LOW, None, None, 0., 0., .2), + "debugAlert": Alert( + "DEBUG ALERT", + "", + AlertStatus.userPrompt, AlertSize.mid, + Priority.LOW, None, None, .1, .1, .1), + # Non-entry only alerts "wrongCarModeNoEntry": Alert( "openpilot Unavailable", diff --git a/selfdrive/controls/lib/latcontrol.py b/selfdrive/controls/lib/latcontrol.py index 4d5c67681eaffc..32e7a6a45b7c99 100644 --- a/selfdrive/controls/lib/latcontrol.py +++ b/selfdrive/controls/lib/latcontrol.py @@ -6,6 +6,7 @@ from common.numpy_fast import interp from common.realtime import sec_since_boot from selfdrive.swaglog import cloudlog +from cereal import car # 100ms is a rule of thumb estimation of lag from image processing to actuator command ACTUATORS_DELAY = 0.1 @@ -111,7 +112,9 @@ def update(self, active, v_ego, angle_steers, steer_override, d_poly, angle_offs steers_max = get_steer_max(VM.CP, v_ego) self.pid.pos_limit = steers_max self.pid.neg_limit = -steers_max - steer_feedforward = self.angle_steers_des * v_ego**2 # proportional to realigning tire momentum (~ lateral accel) + steer_feedforward = self.angle_steers_des # feedforward desired angle + if VM.CP.steerControlType == car.CarParams.SteerControlType.torque: + steer_feedforward *= v_ego**2 # proportional to realigning tire momentum (~ lateral accel) output_steer = self.pid.update(self.angle_steers_des, angle_steers, check_saturation=(v_ego > 10), override=steer_override, feedforward=steer_feedforward, speed=v_ego) self.sat_flag = self.pid.saturated diff --git a/selfdrive/controls/radard.py b/selfdrive/controls/radard.py index bf7d14b6f65706..7e9ca6f826dbd0 100755 --- a/selfdrive/controls/radard.py +++ b/selfdrive/controls/radard.py @@ -1,6 +1,7 @@ #!/usr/bin/env python import zmq import numpy as np +import numpy.matlib import importlib from collections import defaultdict from fastcluster import linkage_vector @@ -27,7 +28,7 @@ class EKFV1D(EKF): def __init__(self): super(EKFV1D, self).__init__(False) - self.identity = np.matlib.identity(DIMSV) + self.identity = numpy.matlib.identity(DIMSV) self.state = np.matlib.zeros((DIMSV, 1)) self.var_init = 1e2 # ~ model variance when probability is 70%, so good starting point self.covar = self.identity * self.var_init diff --git a/selfdrive/locationd/ephemeris.py b/selfdrive/locationd/ephemeris.py index 0fbedf52505006..dd8155e19a4507 100644 --- a/selfdrive/locationd/ephemeris.py +++ b/selfdrive/locationd/ephemeris.py @@ -114,12 +114,9 @@ def __init__(self, svId, subframes): self.valid = (iode1 == iode2) and (iode1 == (iodc & 0xff)) self.iode = iode1 - if GET_FIELD_U(subframes[4][2+0], 2, 28) != 1: - raise RuntimeError("subframe 4 not of type 1") - if GET_FIELD_U(subframes[5][2+0], 2, 28) != 1: - raise RuntimeError("subframe 5 not of type 1") - print 'page :', GET_FIELD_U(subframes[4][2+0], 6, 22) - if GET_FIELD_U(subframes[4][2+0], 6, 22) == 56: + if GET_FIELD_U(subframes[4][2+0], 6, 22) == 56 and \ + GET_FIELD_U(subframes[4][2+0], 2, 28) == 1 and \ + GET_FIELD_U(subframes[5][2+0], 2, 28) == 1: a0 = GET_FIELD_S(subframes[4][2], 8, 14) * pow(2, -30) a1 = GET_FIELD_S(subframes[4][2], 8, 6) * pow(2, -27) a2 = GET_FIELD_S(subframes[4][3], 8, 22) * pow(2, -24) diff --git a/selfdrive/loggerd/loggerd b/selfdrive/loggerd/loggerd index 7efc9234d0002b..9c271731d6acdf 100755 Binary files a/selfdrive/loggerd/loggerd and b/selfdrive/loggerd/loggerd differ diff --git a/selfdrive/loggerd/uploader.py b/selfdrive/loggerd/uploader.py index f45303a16e0965..8c97907b7220a6 100644 --- a/selfdrive/loggerd/uploader.py +++ b/selfdrive/loggerd/uploader.py @@ -143,11 +143,11 @@ def next_file_to_upload(self, with_video): def do_upload(self, key, fn): try: - url_resp = api_get("v1.1/"+self.dongle_id+"/upload_url/", timeout=2, path=key, access_token=self.access_token) + url_resp = api_get("v1.2/"+self.dongle_id+"/upload_url/", timeout=2, path=key, access_token=self.access_token) url_resp_json = json.loads(url_resp.text) url = url_resp_json['url'] headers = url_resp_json['headers'] - cloudlog.info("upload_url v1.1 %s %s", url, str(headers)) + cloudlog.info("upload_url v1.2 %s %s", url, str(headers)) if fake_upload: cloudlog.info("*** WARNING, THIS IS A FAKE UPLOAD TO %s ***" % url) diff --git a/selfdrive/manager.py b/selfdrive/manager.py index 6ea25ddca00f49..fd79b2006d51c0 100755 --- a/selfdrive/manager.py +++ b/selfdrive/manager.py @@ -5,9 +5,21 @@ import errno import signal +from common.basedir import BASEDIR +sys.path.append(os.path.join(BASEDIR, "pyextra")) +os.environ['BASEDIR'] = BASEDIR + if __name__ == "__main__": if os.path.isfile("/init.qcom.rc") \ - and (not os.path.isfile("/VERSION") or int(open("/VERSION").read()) < 4): + and (not os.path.isfile("/VERSION") or int(open("/VERSION").read()) < 6): + + # update continue.sh before updating NEOS + if os.path.isfile(os.path.join(BASEDIR, "scripts", "continue.sh")): + from shutil import copyfile + copyfile(os.path.join(BASEDIR, "scripts", "continue.sh"), "/data/data/com.termux/files/continue.sh") + + # run the updater + os.system(os.path.join(BASEDIR, "installer", "updater", "updater")) raise Exception("NEOS outdated") # get a non-blocking stdout @@ -47,9 +59,9 @@ import traceback from multiprocessing import Process -from common.basedir import BASEDIR -sys.path.append(os.path.join(BASEDIR, "pyextra")) -os.environ['BASEDIR'] = BASEDIR +if os.path.exists(os.path.join(BASEDIR, "vpn")): + print "installing vpn" + os.system(os.path.join(BASEDIR, "vpn", "install.sh")) import zmq from setproctitle import setproctitle #pylint: disable=no-name-in-module @@ -617,9 +629,6 @@ def uninstall(): os.system("service call power 16 i32 0 s16 recovery i32 1") def main(): - # the flippening! - os.system('LD_LIBRARY_PATH="" content insert --uri content://settings/system --bind name:s:user_rotation --bind value:i:1') - if os.getenv("NOLOG") is not None: del managed_processes['loggerd'] del managed_processes['tombstoned'] @@ -638,6 +647,10 @@ def main(): del managed_processes['controlsd'] del managed_processes['radard'] + if os.path.isfile('logserver/logserver.py'): + managed_processes["logserver"] = "selfdrive.logserver.wsgi" + persistent_processes.append("logserver") + # support additional internal only extensions try: import selfdrive.manager_extensions @@ -673,7 +686,8 @@ def main(): if os.getenv("PREPAREONLY") is not None: spinner_proc = None else: - spinner_proc = subprocess.Popen(["./spinner", "loading..."], + spinner_text = "chffrplus" if params.get("Passive")=="1" else "openpilot" + spinner_proc = subprocess.Popen(["./spinner", "loading %s"%spinner_text], cwd=os.path.join(BASEDIR, "selfdrive", "ui", "spinner"), close_fds=True) try: diff --git a/selfdrive/orbd/.gitignore b/selfdrive/orbd/.gitignore new file mode 100644 index 00000000000000..829780eb506383 --- /dev/null +++ b/selfdrive/orbd/.gitignore @@ -0,0 +1,8 @@ +orbd +orbd_cpu +test/turbocv_profile +test/turbocv_test +dspout/* +dumb_test +bilinear_lut.h +orb_lut.h diff --git a/selfdrive/orbd/Makefile b/selfdrive/orbd/Makefile index 8847ef5d254bb5..c33a8636bcefe8 100644 --- a/selfdrive/orbd/Makefile +++ b/selfdrive/orbd/Makefile @@ -3,10 +3,16 @@ CC = clang CXX = clang++ +WARN_FLAGS = -Werror=implicit-function-declaration \ + -Werror=incompatible-pointer-types \ + -Werror=int-conversion \ + -Werror=return-type \ + -Werror=format-extra-args + JSON_FLAGS = -I$(PHONELIBS)/json/src -CFLAGS = -std=gnu11 -g -fPIC -O2 $(WARN_FLAGS) -Iinclude $(JSON_FLAGS) -I. -CXXFLAGS = -std=c++11 -g -fPIC -O2 $(WARN_FLAGS) -Iinclude $(JSON_FLAGS) -I. +CFLAGS = -std=gnu11 -g -O2 -fPIC $(WARN_FLAGS) -Iinclude $(JSON_FLAGS) -I. +CXXFLAGS = -std=c++11 -g -O2 -fPIC $(WARN_FLAGS) -Iinclude $(JSON_FLAGS) -I. LDFLAGS = # profile @@ -64,6 +70,7 @@ orbd: orbd_dsp.o $(DEP_OBJS) calculator_stub.o freethedsp.o %.o: %.c @echo "[ CC ] $@" $(CC) $(CFLAGS) \ + $(ZMQ_FLAGS) \ -I../ \ -I../../ \ -c -o '$@' '$<' diff --git a/selfdrive/orbd/dsp/freethedsp.c b/selfdrive/orbd/dsp/freethedsp.c index 9c5ef059837db3..55c20e341f1b58 100644 --- a/selfdrive/orbd/dsp/freethedsp.c +++ b/selfdrive/orbd/dsp/freethedsp.c @@ -22,6 +22,7 @@ #define PATCH_OLD "\x40\x3f\x20\x50" #define PATCH_NEW "\x40\x3f\x00\x5a" #define PATCH_LEN (sizeof(PATCH_OLD)-1) +#define _BITS_IOCTL_H_ // under 100 lines of code begins now #include diff --git a/selfdrive/orbd/dsp/gen/libcalculator_skel.so b/selfdrive/orbd/dsp/gen/libcalculator_skel.so new file mode 100755 index 00000000000000..e48cab48208b0f Binary files /dev/null and b/selfdrive/orbd/dsp/gen/libcalculator_skel.so differ diff --git a/selfdrive/orbd/orbd.cc b/selfdrive/orbd/orbd.cc index 064980e3b05801..b35a38c5a2bf06 100644 --- a/selfdrive/orbd/orbd.cc +++ b/selfdrive/orbd/orbd.cc @@ -96,6 +96,7 @@ int main(int argc, char *argv[]) { #endif uint64_t end = nanos_since_boot(); LOGD("total(%d): %6.2f ms to get %4d features on %d", ret, (end-start)/1000000.0, features->n_corners, extra.frame_id); + assert(ret == 0); if (last_frame_id+1 != extra.frame_id) { LOGW("dropped frame!"); diff --git a/selfdrive/sensord/gpsd b/selfdrive/sensord/gpsd index 1f9d843aa2f420..7513ac78bf58e2 100755 Binary files a/selfdrive/sensord/gpsd and b/selfdrive/sensord/gpsd differ diff --git a/selfdrive/sensord/sensord b/selfdrive/sensord/sensord index 212256ef552e00..a7a275e1aefaad 100755 Binary files a/selfdrive/sensord/sensord and b/selfdrive/sensord/sensord differ diff --git a/selfdrive/service_list.yaml b/selfdrive/service_list.yaml index a5d7fd69c94542..4195ee7b54fdfb 100644 --- a/selfdrive/service_list.yaml +++ b/selfdrive/service_list.yaml @@ -74,6 +74,8 @@ testModel: [8040, false] testLiveLocation: [8045, false] testJoystick: [8056, false] +# 8080 is reserved for slave testing daemon +# 8762 is reserved for logserver # manager -- base process to manage starting and stopping of all others # subscribes: health diff --git a/selfdrive/test/plant/plant.py b/selfdrive/test/plant/plant.py index f77f2a17b0853e..022a576ea7d64a 100755 --- a/selfdrive/test/plant/plant.py +++ b/selfdrive/test/plant/plant.py @@ -36,7 +36,7 @@ def car_plant(pos, speed, grade, gas, brake): speed_base = power_peak/force_peak rolling_res = 0.01 g = 9.81 - #frontal_area = 2.2 TODO: use it! + frontal_area = 2.2 air_density = 1.225 gas_to_peak_linear_slope = 3.33 brake_to_peak_linear_slope = 0.3 @@ -56,7 +56,7 @@ def car_plant(pos, speed, grade, gas, brake): creep_accel = np.interp(speed, creep_accel_bp, creep_accel_v) force_creep = creep_accel * mass - force_resistance = -(rolling_res * mass * g + 0.5 * speed**2 * aero_cd * air_density) + force_resistance = -(rolling_res * mass * g + 0.5 * speed**2 * aero_cd * air_density * frontal_area) force = force_gas + force_brake + force_resistance + force_grade + force_creep acceleration = force / mass diff --git a/selfdrive/ui/spinner/spinner b/selfdrive/ui/spinner/spinner index 7fc8c69170dace..326a377aa3ffde 100755 Binary files a/selfdrive/ui/spinner/spinner and b/selfdrive/ui/spinner/spinner differ diff --git a/selfdrive/ui/spinner/spinner.c b/selfdrive/ui/spinner/spinner.c index f67e310a03b71b..477cfe1cf3abd1 100644 --- a/selfdrive/ui/spinner/spinner.c +++ b/selfdrive/ui/spinner/spinner.c @@ -15,7 +15,6 @@ #include "common/framebuffer.h" - int main(int argc, char** argv) { int err; @@ -35,40 +34,63 @@ int main(int argc, char** argv) { NVGcontext *vg = nvgCreateGLES3(NVG_ANTIALIAS | NVG_STENCIL_STROKES); assert(vg); - int font = nvgCreateFont(vg, "Bold", "../../assets/courbd.ttf"); + int font = nvgCreateFont(vg, "Bold", "../../assets/OpenSans-SemiBold.ttf"); assert(font >= 0); + int spinner_img = nvgCreateImage(vg, "../../assets/img_spinner_track.png", 0); + assert(spinner_img >= 0); + int spinner_img_s = 360; + int spinner_img_x = ((fb_w/2)-(spinner_img_s/2)); + int spinner_img_y = 260; + int spinner_img_xc = (fb_w/2); + int spinner_img_yc = (fb_h/2)-100; + int spinner_comma_img = nvgCreateImage(vg, "../../assets/img_spinner_comma.png", 0); + assert(spinner_comma_img >= 0); + for (int cnt = 0; ; cnt++) { glClearColor(0.1, 0.1, 0.1, 1.0); glClear(GL_STENCIL_BUFFER_BIT | GL_COLOR_BUFFER_BIT); - glEnable(GL_BLEND); glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); nvgBeginFrame(vg, fb_w, fb_h, 1.0f); - - for (int k=0; k<3; k++) { - float ang = (2*M_PI * (float)cnt / 120.0) + (k / 3.0) * 2*M_PI; - - nvgBeginPath(vg); - nvgStrokeColor(vg, nvgRGBA(255, 255, 255, 255)); - nvgStrokeWidth(vg, 5); - - nvgMoveTo(vg, fb_w/2 + 50 * cosf(ang), fb_h/2 + 50 * sinf(ang)); - nvgLineTo(vg, fb_w/2 + 15 * cosf(ang), fb_h/2 + 15 * sinf(ang)); - nvgMoveTo(vg, fb_w/2 - 15 * cosf(ang), fb_h/2 - 15 * sinf(ang)); - nvgLineTo(vg, fb_w/2 - 50 * cosf(ang), fb_h/2 - 50 * sinf(ang)); - nvgStroke(vg); - } - + // background + nvgBeginPath(vg); + NVGpaint bg = nvgLinearGradient(vg, fb_w, 0, fb_w, fb_h, + nvgRGBA(0, 0, 0, 175), nvgRGBA(0, 0, 0, 255)); + nvgFillPaint(vg, bg); + nvgRect(vg, 0, 0, fb_w, fb_h); + nvgFill(vg); + + // spin track + nvgSave(vg); + nvgTranslate(vg, spinner_img_xc, spinner_img_yc); + nvgRotate(vg, (3.75*M_PI * cnt/120.0)); + nvgTranslate(vg, -spinner_img_xc, -spinner_img_yc); + NVGpaint spinner_imgPaint = nvgImagePattern(vg, spinner_img_x, spinner_img_y, + spinner_img_s, spinner_img_s, 0, spinner_img, 0.6f); + nvgBeginPath(vg); + nvgFillPaint(vg, spinner_imgPaint); + nvgRect(vg, spinner_img_x, spinner_img_y, spinner_img_s, spinner_img_s); + nvgFill(vg); + nvgRestore(vg); + + // comma + NVGpaint comma_imgPaint = nvgImagePattern(vg, spinner_img_x, spinner_img_y, + spinner_img_s, spinner_img_s, 0, spinner_comma_img, 1.0f); + nvgBeginPath(vg); + nvgFillPaint(vg, comma_imgPaint); + nvgRect(vg, spinner_img_x, spinner_img_y, spinner_img_s, spinner_img_s); + nvgFill(vg); + + // message if (spintext) { nvgTextAlign(vg, NVG_ALIGN_CENTER | NVG_ALIGN_TOP); nvgFontSize(vg, 96.0f); - nvgText(vg, fb_w / 2, fb_h*2/3, spintext, NULL); + nvgText(vg, fb_w/2, (fb_h*2/3)+24, spintext, NULL); } nvgEndFrame(vg); - eglSwapBuffers(display, surface); assert(glGetError() == GL_NO_ERROR); } diff --git a/selfdrive/ui/ui.c b/selfdrive/ui/ui.c index d29ec18a130283..daac5a1c86b0f8 100644 --- a/selfdrive/ui/ui.c +++ b/selfdrive/ui/ui.c @@ -8,6 +8,7 @@ #include #include +#include #include #include @@ -300,7 +301,7 @@ static const mat4 device_transform = {{ 0.0, 0.0, 0.0, 1.0, }}; -// frame from 4/3 to box size with a 2x zoon +// frame from 4/3 to box size with a 2x zoom static const mat4 frame_transform = {{ 2*(4./3.)/((float)viz_w/box_h), 0.0, 0.0, 0.0, 0.0, 2.0, 0.0, 0.0, @@ -406,7 +407,6 @@ static void ui_init(UIState *s) { } } - // If the intrinsics are in the params entry, this copies them to // intrinsic_matrix and returns true. Otherwise returns false. static bool try_load_intrinsics(mat3 *intrinsic_matrix) { @@ -566,48 +566,9 @@ vec3 car_space_to_full_frame(const UIState *s, vec4 car_space_projective) { return p_image; } -static void draw_cross(UIState *s, float x_in, float y_in, float sz, NVGcolor color) { - const UIScene *scene = &s->scene; - - nvgSave(s->vg); - - // path coords are worked out in rgb-box space - nvgTranslate(s->vg, 240.0f, 0.0); - - // zooom in 2x - nvgTranslate(s->vg, -1440.0f / 2, -1080.0f / 2); - nvgScale(s->vg, 2.0, 2.0); - - nvgScale(s->vg, 1440.0f / s->rgb_width, 1080.0f / s->rgb_height); - - nvgBeginPath(s->vg); - nvgStrokeColor(s->vg, color); - nvgStrokeWidth(s->vg, 5); - - const vec4 p_car_space = (vec4){{x_in, y_in, 0., 1.}}; - const vec3 p_full_frame = car_space_to_full_frame(s, p_car_space); - - // scale with distance - // x_in = 0 -> sz = 30 (max) - // x_in = 90 -> sz = 15 (min) - sz *= 30; - sz /= (x_in / 3 + 30); - if (sz > 30) sz = 30; - if (sz < 15) sz = 15; - - float x = p_full_frame.v[0]; - float y = p_full_frame.v[1]; - if (x >= 0 && y >= 0.) { - nvgMoveTo(s->vg, x-sz, y); - nvgLineTo(s->vg, x+sz, y); - - nvgMoveTo(s->vg, x, y-sz); - nvgLineTo(s->vg, x, y+sz); - - nvgStroke(s->vg); - } - - nvgRestore(s->vg); +// Calculate an interpolation between two numbers at a specific increment +static float lerp(float v0, float v1, float t) { + return (1 - t) * v0 + t * v1; } static void draw_chevron(UIState *s, float x_in, float y_in, float sz, @@ -634,8 +595,8 @@ static void draw_chevron(UIState *s, float x_in, float y_in, float sz, // glow nvgBeginPath(s->vg); - float g_xo = 5; - float g_yo = 2; + float g_xo = sz/5; + float g_yo = sz/10; if (x >= 0 && y >= 0.) { nvgMoveTo(s->vg, x+(sz*1.35)+g_xo, y+sz+g_yo); nvgLineTo(s->vg, x, y-g_xo); @@ -661,39 +622,28 @@ static void draw_chevron(UIState *s, float x_in, float y_in, float sz, nvgRestore(s->vg); } -static void ui_draw_lane_edge(UIState *s, const float *points, float off, - NVGcolor color, int width) { +static void ui_draw_lane_line(UIState *s, const float *points, float off, + NVGcolor color, bool is_ghost) { const UIScene *scene = &s->scene; nvgSave(s->vg); - - // path coords are worked out in rgb-box space - nvgTranslate(s->vg, 240.0f, 0.0); - - // zooom in 2x - nvgTranslate(s->vg, -1440.0f / 2, -1080.0f / 2); + nvgTranslate(s->vg, 240.0f, 0.0); // rgb-box space + nvgTranslate(s->vg, -1440.0f / 2, -1080.0f / 2); // zoom 2x nvgScale(s->vg, 2.0, 2.0); - nvgScale(s->vg, 1440.0f / s->rgb_width, 1080.0f / s->rgb_height); - nvgBeginPath(s->vg); - nvgStrokeColor(s->vg, color); - nvgStrokeWidth(s->vg, width); - bool started = false; - for (int i=0; i<50; i++) { + bool started = false; + for (int i=0; i<49; i++) { float px = (float)i; - float py = points[i] + off; - + float py = points[i] - off; vec4 p_car_space = (vec4){{px, py, 0., 1.}}; vec3 p_full_frame = car_space_to_full_frame(s, p_car_space); - float x = p_full_frame.v[0]; float y = p_full_frame.v[1]; if (x < 0 || y < 0.) { continue; } - if (!started) { nvgMoveTo(s->vg, x, y); started = true; @@ -702,17 +652,31 @@ static void ui_draw_lane_edge(UIState *s, const float *points, float off, } } - nvgStroke(s->vg); + for (int i=49; i>0; i--) { + float px = (float)i; + float py = is_ghost?(points[i]-off):(points[i]+off); + vec4 p_car_space = (vec4){{px, py, 0., 1.}}; + vec3 p_full_frame = car_space_to_full_frame(s, p_car_space); + float x = p_full_frame.v[0]; + float y = p_full_frame.v[1]; + if (x < 0 || y < 0.) { + continue; + } + nvgLineTo(s->vg, x, y); + } + nvgClosePath(s->vg); + nvgFillColor(s->vg, color); + nvgFill(s->vg); nvgRestore(s->vg); } static void ui_draw_lane(UIState *s, const PathData path, NVGcolor color) { - ui_draw_lane_edge(s, path.points, 0.0, color, 5*path.prob); + ui_draw_lane_line(s, path.points, 0.025*path.prob, color, false); float var = min(path.std, 0.7); color.a /= 4; - ui_draw_lane_edge(s, path.points, -var, color, 2); - ui_draw_lane_edge(s, path.points, var, color, 2); + ui_draw_lane_line(s, path.points, -var, color, true); + ui_draw_lane_line(s, path.points, var, color, true); } static void ui_draw_track(UIState *s, bool is_mpc) { @@ -729,25 +693,20 @@ static void ui_draw_track(UIState *s, bool is_mpc) { nvgBeginPath(s->vg); bool started = false; - - int track_start_x = 0; - int track_start_y = 0; - int track_end_x = 0; - int track_end_y = 0; - - int lead_d = (int)scene->lead_d_rel*2.; - int path_height = is_mpc?((lead_d>5)?min(lead_d, 25)-min(lead_d/5,5):20) - :((lead_d>0)?min(lead_d, 50)-min(lead_d/2.5,15):50); float off = is_mpc?0.3:0.5; + float lead_d = scene->lead_d_rel*2.; + float path_height = is_mpc?(lead_d>5.)?min(lead_d, 25.)-min(lead_d*0.35, 10.):20. + :(lead_d>0.)?min(lead_d, 50.)-min(lead_d*0.35, 10.):49.; // left side up - for (int i=0; ivg, x, y); - track_start_x = x; - track_start_y = vwp_h; started = true; } else { nvgLineTo(s->vg, x, y); @@ -770,13 +727,14 @@ static void ui_draw_track(UIState *s, bool is_mpc) { } // right side down - for (int i=path_height-1; i>0; i--) { - float px, py; + for (int i=path_height; i>=0; i--) { + float px, py, mpx; if (is_mpc) { - px = mpc_x_coords[i]; + mpx = i==0?0.0:mpc_x_coords[i]; + px = lerp(mpx+1.0, mpx, i/100.0); py = mpc_y_coords[i] + off; } else { - px = (float)i; + px = lerp(i+1.0, i, i/100.0); py = path.points[i] + off; } @@ -788,26 +746,21 @@ static void ui_draw_track(UIState *s, bool is_mpc) { continue; } - if (!started) { - nvgMoveTo(s->vg, x, y); - track_end_y = vwp_h; - track_end_x = x; - started = true; - } else { - nvgLineTo(s->vg, x, y); - } + nvgLineTo(s->vg, x, y); } + nvgClosePath(s->vg); + NVGpaint track_bg; if (is_mpc) { - // green track + // Draw colored MPC track const uint8_t *clr = bg_colors[s->status]; - track_bg = nvgLinearGradient(s->vg, track_start_x, track_start_y, track_end_x, track_end_y, - nvgRGBA(clr[0], clr[1], clr[2], 255), nvgRGBA(clr[0], clr[1], clr[2], 150)); + track_bg = nvgLinearGradient(s->vg, vwp_w, vwp_h, vwp_w, vwp_h*.4, + nvgRGBA(clr[0], clr[1], clr[2], 255), nvgRGBA(clr[0], clr[1], clr[2], 255/2)); } else { - // white track - track_bg = nvgLinearGradient(s->vg, track_start_x, track_start_y, track_end_x, track_end_y, - nvgRGBA(255, 255, 255, 150), nvgRGBA(255, 255, 255, 75)); + // Draw white vision track + track_bg = nvgLinearGradient(s->vg, vwp_w, vwp_h, vwp_w, vwp_h*.4, + nvgRGBA(255, 255, 255, 255), nvgRGBA(255, 255, 255, 0)); } nvgFillPaint(s->vg, track_bg); @@ -822,7 +775,7 @@ static void draw_steering(UIState *s, float curvature) { points[i] = y_actual; } - ui_draw_lane_edge(s, points, 0.0, nvgRGBA(0, 0, 255, 128), 5); + // ui_draw_lane_edge(s, points, 0.0, nvgRGBA(0, 0, 255, 128), 5); } static void draw_frame(UIState *s) { @@ -879,178 +832,25 @@ static void draw_frame(UIState *s) { static void ui_draw_vision_lanes(UIState *s) { const UIScene *scene = &s->scene; - if ((nanos_since_boot() - scene->model_ts) < 1000000000ULL) { - // draw left lane edge - ui_draw_lane( - s, scene->model.left_lane, - nvgRGBAf(1.0, 1.0, 1.0, scene->model.left_lane.prob)); - - // draw right lane edge - ui_draw_lane( - s, scene->model.right_lane, - nvgRGBAf(1.0, 1.0, 1.0, scene->model.right_lane.prob)); - - // draw vision path - ui_draw_track(s, false); - - // draw MPC path when engaged - if (scene->engaged) { - ui_draw_track(s, true); - } + // Draw left lane edge + ui_draw_lane( + s, scene->model.left_lane, + nvgRGBAf(1.0, 1.0, 1.0, scene->model.left_lane.prob)); + + // Draw right lane edge + ui_draw_lane( + s, scene->model.right_lane, + nvgRGBAf(1.0, 1.0, 1.0, scene->model.right_lane.prob)); + + // Draw vision path + ui_draw_track(s, false); + + if (scene->engaged) { + // Draw MPC path when engaged + ui_draw_track(s, true); } } -static void ui_draw_vision_topbar(UIState *s) { - const UIScene *scene = &s->scene; - - const int bar_x = box_x; - const int bar_y = box_y; - const int bar_width = box_w; - const int bar_height = 250 - box_y; - - assert(s->status < ARRAYSIZE(bg_colors)); - const uint8_t *color = bg_colors[s->status]; - - nvgBeginPath(s->vg); - nvgRect(s->vg, bar_x, bar_y, bar_width, bar_height); - nvgFillColor(s->vg, nvgRGBA(color[0], color[1], color[2], color[3])); - nvgFill(s->vg); - - const int message_y = box_y; - const int message_height = bar_height; - const int message_width = 800; - const int message_x = box_x + box_w / 2 - message_width / 2; - - // message background - nvgBeginPath(s->vg); - NVGpaint bg = nvgLinearGradient(s->vg, message_x, message_y, message_x, message_y+message_height, - nvgRGBAf(0.0, 0.0, 0.0, 0.0), nvgRGBAf(0.0, 0.0, 0.0, 0.1)); - nvgFillPaint(s->vg, bg); - nvgRect(s->vg, message_x, message_y, message_width, message_height); - nvgFill(s->vg); - - nvgFillColor(s->vg, nvgRGBA(255, 255, 255, 255)); - - if (s->passive) { - if (s->scene.started_ts > 0) { - // draw drive time when passive - - uint64_t dt = nanos_since_boot() - s->scene.started_ts; - - nvgFontFace(s->vg, "sans-semibold"); - nvgFontSize(s->vg, 40*2.5); - nvgTextAlign(s->vg, NVG_ALIGN_CENTER | NVG_ALIGN_BASELINE); - - char time_str[64]; - if (dt > 60*60*1000000000ULL) { - // hours - snprintf(time_str, sizeof(time_str), "Drive time: %d:%02d:%02d", - (int)(dt/(60*60*1000000000ULL)), - (int)((dt%(60*60*1000000000ULL))/(60*1000000000ULL)), - (int)(dt%(60*1000000000ULL)/1000000000ULL)); - } else { - snprintf(time_str, sizeof(time_str), "Drive time: %d:%02d", - (int)(dt/(60*1000000000ULL)), - (int)(dt%(60*1000000000ULL)/1000000000ULL)); - } - nvgText(s->vg, message_x+message_width/2, message_y+message_height/2+15, time_str, NULL); - } - } else { - // status text - nvgFontFace(s->vg, "sans-semibold"); - nvgFontSize(s->vg, 48*2.5); - nvgTextAlign(s->vg, NVG_ALIGN_CENTER | NVG_ALIGN_BASELINE); - if (s->scene.alert_size == cereal_Live100Data_AlertSize_small) { - nvgFontSize(s->vg, 40*2.5); - nvgText(s->vg, message_x+message_width/2, 115, s->scene.alert_text1, NULL); - nvgFontSize(s->vg, 26*2.5); - nvgText(s->vg, message_x+message_width/2, 185, s->scene.alert_text2, NULL); - } else if (s->status == STATUS_DISENGAGED) { - nvgText(s->vg, message_x+message_width/2, message_y+message_height/2+15, "DISENGAGED", NULL); - } else if (s->status == STATUS_ENGAGED) { - nvgText(s->vg, message_x+message_width/2, message_y+message_height/2+15, "ENGAGED", NULL); - } - } - - // set speed - const int left_x = bar_x; - const int left_y = bar_y; - const int left_width = (bar_width - message_width) / 2; - const int left_height = bar_height; - - nvgFontFace(s->vg, "sans-semibold"); - nvgFontSize(s->vg, 40*2.5); - nvgTextAlign(s->vg, NVG_ALIGN_CENTER | NVG_ALIGN_BASELINE); - - if (scene->v_cruise != 255 && scene->v_cruise != 0) { - char speed_str[16]; - if (s->is_metric) { - snprintf(speed_str, sizeof(speed_str), "%3d kph", - (int)(scene->v_cruise + 0.5)); - } else { - /* Convert KPH to MPH. Using an approximated mph to kph - conversion factor of 1.60642 because this is what the Honda - hud seems to be using */ - snprintf(speed_str, sizeof(speed_str), "%3d mph", - (int)(scene->v_cruise * 0.6225 + 0.5)); - } - nvgText(s->vg, left_x+left_width/2, 115, speed_str, NULL); - } else { - nvgText(s->vg, left_x+left_width/2, 115, "N/A", NULL); - } - - nvgFontFace(s->vg, "sans-regular"); - nvgFontSize(s->vg, 26*2.5); - nvgText(s->vg, left_x+left_width/2, 185, "SET SPEED", NULL); - - // lead car - const int right_y = bar_y; - const int right_width = (bar_width - message_width) / 2; - const int right_x = bar_x+bar_width-right_width; - const int right_height = bar_height; - - nvgFontFace(s->vg, "sans-semibold"); - nvgFontSize(s->vg, 40*2.5); - nvgTextAlign(s->vg, NVG_ALIGN_CENTER | NVG_ALIGN_BASELINE); - - if (scene->lead_status) { - char radar_str[16]; - // lead car is always in meters - if (s->is_metric || true) { - snprintf(radar_str, sizeof(radar_str), "%d m", (int)scene->lead_d_rel); - } else { - snprintf(radar_str, sizeof(radar_str), "%d ft", (int)(scene->lead_d_rel * 3.28084)); - } - nvgText(s->vg, right_x+right_width/2, 115, radar_str, NULL); - } else { - nvgText(s->vg, right_x+right_width/2, 115, "N/A", NULL); - } - - nvgFontFace(s->vg, "sans-regular"); - nvgFontSize(s->vg, 26*2.5); - nvgText(s->vg, right_x+right_width/2, 185, "LEAD CAR", NULL); -} - -static void ui_draw_gpsplanner_status(UIState *s) { - const UIScene *scene = &s->scene; - - int rec_width = 1120; - int x_pos = 500; - nvgBeginPath(s->vg); - nvgStrokeWidth(s->vg, 14); - nvgRoundedRect(s->vg, (1920-rec_width)/2, 920, rec_width, 225, 20); - nvgStroke(s->vg); - nvgFillColor(s->vg, nvgRGBA(0,0,0,180)); - nvgFill(s->vg); - - nvgFontSize(s->vg, 40*2.5); - nvgTextAlign(s->vg, NVG_ALIGN_LEFT | NVG_ALIGN_BASELINE); - nvgFontFace(s->vg, "sans-semibold"); - nvgFillColor(s->vg, nvgRGBA(255, 255, 255, 220)); - nvgText(s->vg, x_pos, 1010, "GPS planner active", NULL); -} - - // Draw all world space objects. static void ui_draw_world(UIState *s) { const UIScene *scene = &s->scene; @@ -1058,9 +858,26 @@ static void ui_draw_world(UIState *s) { return; } - //draw_steering(s, scene->curvature); - ui_draw_vision_lanes(s); + if ((nanos_since_boot() - scene->model_ts) < 1000000000ULL) { + // Draw lane edges and vision/mpc tracks + ui_draw_vision_lanes(s); + } + if (scene->lead_status) { + // Draw lead car indicator + float fillAlpha = 0; + float speedBuff = 10.; + float leadBuff = 40.; + if (scene->lead_d_rel < leadBuff) { + fillAlpha = 255*(1.0-(scene->lead_d_rel/leadBuff)); + if (scene->lead_v_rel < 0) { + fillAlpha += 255*(-1*(scene->lead_v_rel/speedBuff)); + } + fillAlpha = (int)(min(fillAlpha, 255)); + } + draw_chevron(s, scene->lead_d_rel+2.7, scene->lead_y_rel, 25, + nvgRGBA(201, 34, 49, fillAlpha), nvgRGBA(218, 202, 37, 255)); + } } static void ui_draw_vision_maxspeed(UIState *s) { @@ -1288,14 +1105,8 @@ static void ui_draw_vision(UIState *s) { nvgScissor(s->vg, ui_viz_rx, box_y, ui_viz_rw, box_h); nvgTranslate(s->vg, ui_viz_rx+ui_viz_ro, box_y + (box_h-inner_height)/2.0); nvgScale(s->vg, (float)viz_w / s->fb_w, (float)inner_height / s->fb_h); - if (!scene->frontview) { ui_draw_world(s); - - if (scene->lead_status) { - draw_chevron(s, scene->lead_d_rel+2.7, scene->lead_y_rel, 30, - nvgRGBA(201, 34, 49, 255), nvgRGBA(218, 202, 37, 255)); - } } nvgRestore(s->vg); @@ -1307,11 +1118,9 @@ static void ui_draw_vision(UIState *s) { // Controls Alerts ui_draw_vision_alert(s, s->scene.alert_size, s->status, s->scene.alert_text1, s->scene.alert_text2); - } else { + } else if (scene->cal_status == CALIBRATION_UNCALIBRATED) { // Calibration Status - if (scene->cal_status == CALIBRATION_UNCALIBRATED) { - ui_draw_calibration_status(s); - } + ui_draw_calibration_status(s); } nvgEndFrame(s->vg); @@ -1323,42 +1132,6 @@ static void ui_draw_blank(UIState *s) { glClear(GL_STENCIL_BUFFER_BIT | GL_COLOR_BUFFER_BIT); } -static void ui_draw_aside(UIState *s) { - char speed_str[32]; - float speed; - - bool is_cruise_set = (s->scene.v_cruise != 0 && s->scene.v_cruise != 255); - unsigned long last_cruise_update_dt = (nanos_since_boot() - s->scene.v_cruise_update_ts); - bool should_draw_cruise_speed = is_cruise_set && last_cruise_update_dt < 2000000000ULL; - if (should_draw_cruise_speed) { - speed = s->scene.v_cruise / 3.6; - nvgFillColor(s->vg, nvgRGBA(0xFF, 0xD8, 0xAC, 0xFF)); - } else { - speed = s->scene.v_ego; - nvgFillColor(s->vg, nvgRGBA(255, 255, 255, 255)); - } - - nvgTextAlign(s->vg, NVG_ALIGN_CENTER | NVG_ALIGN_BASELINE); - - nvgFontFace(s->vg, "sans-semibold"); - nvgFontSize(s->vg, 110); - if (s->is_metric) { - snprintf(speed_str, sizeof(speed_str), "%d", (int)(speed * 3.6 + 0.5)); - } else { - snprintf(speed_str, sizeof(speed_str), "%d", (int)(speed * 2.2374144 + 0.5)); - } - nvgText(s->vg, 150, 762, speed_str, NULL); - - nvgFontFace(s->vg, "sans-regular"); - nvgFontSize(s->vg, 70); - - if (s->is_metric) { - nvgText(s->vg, 150, 817, "kph", NULL); - } else { - nvgText(s->vg, 150, 817, "mph", NULL); - } -} - static void ui_draw(UIState *s) { if (s->vision_connected && s->plus_state == 0) { ui_draw_vision(s); diff --git a/selfdrive/visiond/visiond b/selfdrive/visiond/visiond index 6f19199a8279cf..65bf902d0b5195 100755 Binary files a/selfdrive/visiond/visiond and b/selfdrive/visiond/visiond differ