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codec.go
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codec.go
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package amino
import (
"bytes"
"crypto/sha256"
"fmt"
"io"
"reflect"
"strings"
"sync"
"unicode"
"github.com/pkg/errors"
)
//----------------------------------------
// PrefixBytes/DisambBytes/DisfixBytes types
// Lengths
const (
PrefixBytesLen = 4
DisambBytesLen = 3
DisfixBytesLen = PrefixBytesLen + DisambBytesLen
)
// Prefix types
type (
PrefixBytes [PrefixBytesLen]byte
DisambBytes [DisambBytesLen]byte
DisfixBytes [DisfixBytesLen]byte // Disamb+Prefix
)
// Copy into PrefixBytes
func NewPrefixBytes(prefixBytes []byte) PrefixBytes {
pb := PrefixBytes{}
copy(pb[:], prefixBytes)
return pb
}
func (pb PrefixBytes) Bytes() []byte { return pb[:] }
func (pb PrefixBytes) EqualBytes(bz []byte) bool { return bytes.Equal(pb[:], bz) }
func (db DisambBytes) Bytes() []byte { return db[:] }
func (db DisambBytes) EqualBytes(bz []byte) bool { return bytes.Equal(db[:], bz) }
func (df DisfixBytes) Bytes() []byte { return df[:] }
func (df DisfixBytes) EqualBytes(bz []byte) bool { return bytes.Equal(df[:], bz) }
// Return the DisambBytes and the PrefixBytes for a given name.
func NameToDisfix(name string) (db DisambBytes, pb PrefixBytes) {
return nameToDisfix(name)
}
//----------------------------------------
// Codec internals
type TypeInfo struct {
Type reflect.Type // Interface type.
PtrToType reflect.Type
ZeroValue reflect.Value
ZeroProto interface{}
InterfaceInfo
ConcreteInfo
StructInfo
}
type InterfaceInfo struct {
Priority []DisfixBytes // Disfix priority.
Implementers map[PrefixBytes][]*TypeInfo // Mutated over time.
InterfaceOptions
}
type InterfaceOptions struct {
Priority []string // Disamb priority.
AlwaysDisambiguate bool // If true, include disamb for all types.
}
type ConcreteInfo struct {
// These fields are only set when registered (as implementing an interface).
Registered bool // Registered with RegisterConcrete().
PointerPreferred bool // Deserialize to pointer type if possible.
// NilPreferred bool // Deserialize to nil for empty structs if PointerPreferred.
Name string // Registered name.
Disamb DisambBytes // Disambiguation bytes derived from name.
Prefix PrefixBytes // Prefix bytes derived from name.
ConcreteOptions // Registration options.
// These fields get set for all concrete types,
// even those not manually registered (e.g. are never interface values).
IsAminoMarshaler bool // Implements MarshalAmino() (<ReprObject>, error).
AminoMarshalReprType reflect.Type // <ReprType>
IsAminoUnmarshaler bool // Implements UnmarshalAmino(<ReprObject>) (error).
AminoUnmarshalReprType reflect.Type // <ReprType>
}
type StructInfo struct {
Fields []FieldInfo // If a struct.
}
func (cinfo ConcreteInfo) GetDisfix() DisfixBytes {
return toDisfix(cinfo.Disamb, cinfo.Prefix)
}
type ConcreteOptions struct {
}
type FieldInfo struct {
Name string // Struct field name
Type reflect.Type // Struct field type
Index int // Struct field index
ZeroValue reflect.Value // Could be nil pointer unlike TypeInfo.ZeroValue.
UnpackedList bool // True iff this field should be encoded as an unpacked list.
FieldOptions // Encoding options
}
type FieldOptions struct {
JSONName string // (JSON) field name
JSONOmitEmpty bool // (JSON) omitempty
BinFixed64 bool // (Binary) Encode as fixed64
BinFixed32 bool // (Binary) Encode as fixed32
BinFieldNum uint32 // (Binary) max 1<<29-1
Unsafe bool // e.g. if this field is a float.
WriteEmpty bool // write empty structs and lists (default false except for pointers)
EmptyElements bool // Slice and Array elements are never nil, decode 0x00 as empty struct.
}
//----------------------------------------
// Codec
type Codec struct {
mtx sync.RWMutex
sealed bool
typeInfos map[reflect.Type]*TypeInfo
interfaceInfos []*TypeInfo
concreteInfos []*TypeInfo
disfixToTypeInfo map[DisfixBytes]*TypeInfo
nameToTypeInfo map[string]*TypeInfo
}
func NewCodec() *Codec {
cdc := &Codec{
sealed: false,
typeInfos: make(map[reflect.Type]*TypeInfo),
disfixToTypeInfo: make(map[DisfixBytes]*TypeInfo),
nameToTypeInfo: make(map[string]*TypeInfo),
}
return cdc
}
// This function should be used to register all interfaces that will be
// encoded/decoded by go-amino.
// Usage:
// `amino.RegisterInterface((*MyInterface1)(nil), nil)`
func (cdc *Codec) RegisterInterface(ptr interface{}, iopts *InterfaceOptions) {
cdc.assertNotSealed()
// Get reflect.Type from ptr.
rt := getTypeFromPointer(ptr)
if rt.Kind() != reflect.Interface {
panic(fmt.Sprintf("RegisterInterface expects an interface, got %v", rt))
}
// Construct InterfaceInfo
var info = cdc.newTypeInfoFromInterfaceType(rt, iopts)
// Finally, check conflicts and register.
func() {
cdc.mtx.Lock()
defer cdc.mtx.Unlock()
cdc.collectImplementersNolock(info)
err := cdc.checkConflictsInPrioNolock(info)
if err != nil {
panic(err)
}
cdc.setTypeInfoNolock(info)
}()
/*
NOTE: The above func block is a defensive pattern.
First of all, the defer call is necessary to recover from panics,
otherwise the Codec would become unusable after a single panic.
This “defer-panic-unlock” pattern requires a func block to denote the
boundary outside of which the defer call is guaranteed to have been
called. In other words, using any other form of curly braces (e.g. in
the form of a conditional or looping block) won't actually unlock when
it might appear to visually. Consider:
```
var info = ...
{
cdc.mtx.Lock()
defer cdc.mtx.Unlock()
...
}
// Here, cdc.mtx.Unlock() hasn't been called yet.
```
So, while the above code could be simplified, it's there for defense.
*/
}
// This function should be used to register concrete types that will appear in
// interface fields/elements to be encoded/decoded by go-amino.
// Usage:
// `amino.RegisterConcrete(MyStruct1{}, "com.tendermint/MyStruct1", nil)`
func (cdc *Codec) RegisterConcrete(o interface{}, name string, copts *ConcreteOptions) {
cdc.assertNotSealed()
var pointerPreferred bool
// Get reflect.Type.
rt := reflect.TypeOf(o)
if rt.Kind() == reflect.Interface {
panic(fmt.Sprintf("expected a non-interface: %v", rt))
}
if rt.Kind() == reflect.Ptr {
rt = rt.Elem()
if rt.Kind() == reflect.Ptr {
// We can encode/decode pointer-pointers, but not register them.
panic(fmt.Sprintf("registering pointer-pointers not yet supported: *%v", rt))
}
if rt.Kind() == reflect.Interface {
// MARKER: No interface-pointers
panic(fmt.Sprintf("registering interface-pointers not yet supported: *%v", rt))
}
pointerPreferred = true
}
// Construct ConcreteInfo.
var info = cdc.newTypeInfoFromRegisteredConcreteType(rt, pointerPreferred, name, copts)
// Finally, check conflicts and register.
func() {
cdc.mtx.Lock()
defer cdc.mtx.Unlock()
cdc.addCheckConflictsWithConcreteNolock(info)
cdc.setTypeInfoNolock(info)
}()
}
func (cdc *Codec) Seal() *Codec {
cdc.mtx.Lock()
defer cdc.mtx.Unlock()
cdc.sealed = true
return cdc
}
// PrintTypes writes all registered types in a markdown-style table.
// The table's header is:
//
// | Type | Name | Prefix | Notes |
//
// Where Type is the golang type name and Name is the name the type was registered with.
func (cdc *Codec) PrintTypes(out io.Writer) error {
cdc.mtx.RLock()
defer cdc.mtx.RUnlock()
// print header
if _, err := io.WriteString(out, "| Type | Name | Prefix | Length | Notes |\n"); err != nil {
return err
}
if _, err := io.WriteString(out, "| ---- | ---- | ------ | ----- | ------ |\n"); err != nil {
return err
}
// only print concrete types for now (if we want everything, we can iterate over the typeInfos map instead)
for _, i := range cdc.concreteInfos {
if _, err := io.WriteString(out, "| "); err != nil {
return err
}
// TODO(ismail): optionally create a link to code on github:
if _, err := io.WriteString(out, i.Type.Name()); err != nil {
return err
}
if _, err := io.WriteString(out, " | "); err != nil {
return err
}
if _, err := io.WriteString(out, i.Name); err != nil {
return err
}
if _, err := io.WriteString(out, " | "); err != nil {
return err
}
if _, err := io.WriteString(out, fmt.Sprintf("0x%X", i.Prefix)); err != nil {
return err
}
if _, err := io.WriteString(out, " | "); err != nil {
return err
}
if _, err := io.WriteString(out, getLengthStr(i)); err != nil {
return err
}
if _, err := io.WriteString(out, " | "); err != nil {
return err
}
// empty notes table data by default // TODO(ismail): make this configurable
if _, err := io.WriteString(out, " |\n"); err != nil {
return err
}
}
// finish table
return nil
}
// A heuristic to guess the size of a registered type and return it as a string.
// If the size is not fixed it returns "variable".
func getLengthStr(info *TypeInfo) string {
switch info.Type.Kind() {
case reflect.Array,
reflect.Int8,
reflect.Int16, reflect.Int32, reflect.Int64,
reflect.Float32, reflect.Float64,
reflect.Complex64, reflect.Complex128:
s := info.Type.Size()
return fmt.Sprintf("0x%X", s)
default:
return "variable"
}
}
//----------------------------------------
func (cdc *Codec) assertNotSealed() {
cdc.mtx.Lock()
defer cdc.mtx.Unlock()
if cdc.sealed {
panic("codec sealed")
}
}
func (cdc *Codec) setTypeInfoNolock(info *TypeInfo) {
if info.Type.Kind() == reflect.Ptr {
panic(fmt.Sprintf("unexpected pointer type"))
}
if _, ok := cdc.typeInfos[info.Type]; ok {
panic(fmt.Sprintf("TypeInfo already exists for %v", info.Type))
}
cdc.typeInfos[info.Type] = info
if info.Type.Kind() == reflect.Interface {
cdc.interfaceInfos = append(cdc.interfaceInfos, info)
} else if info.Registered {
cdc.concreteInfos = append(cdc.concreteInfos, info)
disfix := info.GetDisfix()
if existing, ok := cdc.disfixToTypeInfo[disfix]; ok {
panic(fmt.Sprintf("disfix <%X> already registered for %v", disfix, existing.Type))
}
if existing, ok := cdc.nameToTypeInfo[info.Name]; ok {
panic(fmt.Sprintf("name <%s> already registered for %v", info.Name, existing.Type))
}
cdc.disfixToTypeInfo[disfix] = info
cdc.nameToTypeInfo[info.Name] = info
//cdc.prefixToTypeInfos[prefix] =
// append(cdc.prefixToTypeInfos[prefix], info)
}
}
func (cdc *Codec) getTypeInfoWlock(rt reflect.Type) (info *TypeInfo, err error) {
// We do not use defer cdc.mtx.Unlock() here due to performance overhead of
// defer in go1.11 (and prior versions). Ensure new code paths unlock the
// mutex.
cdc.mtx.Lock() // requires wlock because we might set.
// Dereference pointer type.
for rt.Kind() == reflect.Ptr {
rt = rt.Elem()
}
info, ok := cdc.typeInfos[rt]
if !ok {
if rt.Kind() == reflect.Interface {
err = fmt.Errorf("unregistered interface %v", rt)
cdc.mtx.Unlock()
return
}
info = cdc.newTypeInfoUnregistered(rt)
cdc.setTypeInfoNolock(info)
}
cdc.mtx.Unlock()
return info, nil
}
// iinfo: TypeInfo for the interface for which we must decode a
// concrete type with prefix bytes pb.
func (cdc *Codec) getTypeInfoFromPrefixRlock(iinfo *TypeInfo, pb PrefixBytes) (info *TypeInfo, err error) {
// We do not use defer cdc.mtx.Unlock() here due to performance overhead of
// defer in go1.11 (and prior versions). Ensure new code paths unlock the
// mutex.
cdc.mtx.RLock()
infos, ok := iinfo.Implementers[pb]
if !ok {
err = fmt.Errorf("unrecognized prefix bytes %X", pb)
cdc.mtx.RUnlock()
return
}
if len(infos) > 1 {
err = fmt.Errorf("conflicting concrete types registered for %X: e.g. %v and %v", pb, infos[0].Type, infos[1].Type)
cdc.mtx.RUnlock()
return
}
info = infos[0]
cdc.mtx.RUnlock()
return
}
func (cdc *Codec) getTypeInfoFromDisfixRlock(df DisfixBytes) (info *TypeInfo, err error) {
// We do not use defer cdc.mtx.Unlock() here due to performance overhead of
// defer in go1.11 (and prior versions). Ensure new code paths unlock the
// mutex.
cdc.mtx.RLock()
info, ok := cdc.disfixToTypeInfo[df]
if !ok {
err = fmt.Errorf("unrecognized disambiguation+prefix bytes %X", df)
cdc.mtx.RUnlock()
return
}
cdc.mtx.RUnlock()
return
}
func (cdc *Codec) getTypeInfoFromNameRlock(name string) (info *TypeInfo, err error) {
// We do not use defer cdc.mtx.Unlock() here due to performance overhead of
// defer in go1.11 (and prior versions). Ensure new code paths unlock the
// mutex.
cdc.mtx.RLock()
info, ok := cdc.nameToTypeInfo[name]
if !ok {
err = fmt.Errorf("unrecognized concrete type name %s", name)
cdc.mtx.RUnlock()
return
}
cdc.mtx.RUnlock()
return
}
func (cdc *Codec) parseStructInfo(rt reflect.Type) (sinfo StructInfo) {
if rt.Kind() != reflect.Struct {
panic("should not happen")
}
var infos = make([]FieldInfo, 0, rt.NumField())
for i := 0; i < rt.NumField(); i++ {
var field = rt.Field(i)
var ftype = field.Type
var unpackedList = false
if !isExported(field) {
continue // field is unexported
}
skip, fopts := cdc.parseFieldOptions(field)
if skip {
continue // e.g. json:"-"
}
if ftype.Kind() == reflect.Array || ftype.Kind() == reflect.Slice {
if ftype.Elem().Kind() == reflect.Uint8 {
// These get handled by our optimized methods,
// encodeReflectBinaryByte[Slice/Array].
unpackedList = false
} else {
etype := ftype.Elem()
for etype.Kind() == reflect.Ptr {
etype = etype.Elem()
}
typ3 := typeToTyp3(etype, fopts)
if typ3 == Typ3ByteLength {
unpackedList = true
}
}
}
// NOTE: This is going to change a bit.
// NOTE: BinFieldNum starts with 1.
fopts.BinFieldNum = uint32(len(infos) + 1)
fieldInfo := FieldInfo{
Name: field.Name, // Mostly for debugging.
Index: i,
Type: ftype,
ZeroValue: reflect.Zero(ftype),
UnpackedList: unpackedList,
FieldOptions: fopts,
}
checkUnsafe(fieldInfo)
infos = append(infos, fieldInfo)
}
sinfo = StructInfo{infos}
return sinfo
}
func (cdc *Codec) parseFieldOptions(field reflect.StructField) (skip bool, fopts FieldOptions) {
binTag := field.Tag.Get("binary")
aminoTag := field.Tag.Get("amino")
jsonTag := field.Tag.Get("json")
// If `json:"-"`, don't encode.
// NOTE: This skips binary as well.
if jsonTag == "-" {
skip = true
return
}
// Get JSON field name.
jsonTagParts := strings.Split(jsonTag, ",")
if jsonTagParts[0] == "" {
fopts.JSONName = field.Name
} else {
fopts.JSONName = jsonTagParts[0]
}
// Get JSON omitempty.
if len(jsonTagParts) > 1 {
if jsonTagParts[1] == "omitempty" {
fopts.JSONOmitEmpty = true
}
}
// Parse binary tags.
if binTag == "fixed64" { // TODO: extend
fopts.BinFixed64 = true
} else if binTag == "fixed32" {
fopts.BinFixed32 = true
}
// Parse amino tags.
aminoTags := strings.Split(aminoTag, ",")
for _, aminoTag := range aminoTags {
if aminoTag == "unsafe" {
fopts.Unsafe = true
}
if aminoTag == "write_empty" {
fopts.WriteEmpty = true
}
if aminoTag == "empty_elements" {
fopts.EmptyElements = true
}
}
return skip, fopts
}
// Constructs a *TypeInfo automatically, not from registration.
func (cdc *Codec) newTypeInfoUnregistered(rt reflect.Type) *TypeInfo {
if rt.Kind() == reflect.Ptr {
panic("unexpected pointer type") // should not happen.
}
if rt.Kind() == reflect.Interface {
panic("unexpected interface type") // should not happen.
}
var info = new(TypeInfo)
info.Type = rt
info.PtrToType = reflect.PtrTo(rt)
info.ZeroValue = reflect.Zero(rt)
info.ZeroProto = reflect.Zero(rt).Interface()
if rt.Kind() == reflect.Struct {
info.StructInfo = cdc.parseStructInfo(rt)
}
if rm, ok := rt.MethodByName("MarshalAmino"); ok {
info.ConcreteInfo.IsAminoMarshaler = true
info.ConcreteInfo.AminoMarshalReprType = marshalAminoReprType(rm)
}
if rm, ok := reflect.PtrTo(rt).MethodByName("UnmarshalAmino"); ok {
info.ConcreteInfo.IsAminoUnmarshaler = true
info.ConcreteInfo.AminoUnmarshalReprType = unmarshalAminoReprType(rm)
}
return info
}
func (cdc *Codec) newTypeInfoFromInterfaceType(rt reflect.Type, iopts *InterfaceOptions) *TypeInfo {
if rt.Kind() != reflect.Interface {
panic(fmt.Sprintf("expected interface type, got %v", rt))
}
var info = new(TypeInfo)
info.Type = rt
info.PtrToType = reflect.PtrTo(rt)
info.ZeroValue = reflect.Zero(rt)
info.ZeroProto = reflect.Zero(rt).Interface()
info.InterfaceInfo.Implementers = make(map[PrefixBytes][]*TypeInfo)
if iopts != nil {
info.InterfaceInfo.InterfaceOptions = *iopts
info.InterfaceInfo.Priority = make([]DisfixBytes, len(iopts.Priority))
// Construct Priority []DisfixBytes
for i, name := range iopts.Priority {
disamb, prefix := nameToDisfix(name)
disfix := toDisfix(disamb, prefix)
info.InterfaceInfo.Priority[i] = disfix
}
}
return info
}
func (cdc *Codec) newTypeInfoFromRegisteredConcreteType(rt reflect.Type, pointerPreferred bool,
name string, copts *ConcreteOptions) *TypeInfo {
if rt.Kind() == reflect.Interface ||
rt.Kind() == reflect.Ptr {
panic(fmt.Sprintf("expected non-interface non-pointer concrete type, got %v", rt))
}
var info = cdc.newTypeInfoUnregistered(rt)
info.ConcreteInfo.Registered = true
info.ConcreteInfo.PointerPreferred = pointerPreferred
info.ConcreteInfo.Name = name
info.ConcreteInfo.Disamb = nameToDisamb(name)
info.ConcreteInfo.Prefix = nameToPrefix(name)
if copts != nil {
info.ConcreteOptions = *copts
}
return info
}
// Find all conflicting prefixes for concrete types
// that "implement" the interface. "Implement" in quotes because
// we only consider the pointer, for extra safety.
func (cdc *Codec) collectImplementersNolock(info *TypeInfo) {
for _, cinfo := range cdc.concreteInfos {
if cinfo.PtrToType.Implements(info.Type) {
info.Implementers[cinfo.Prefix] = append(
info.Implementers[cinfo.Prefix], cinfo)
}
}
}
// Ensure that prefix-conflicting implementing concrete types
// are all registered in the priority list.
// Returns an error if a disamb conflict is found.
func (cdc *Codec) checkConflictsInPrioNolock(iinfo *TypeInfo) error {
for _, cinfos := range iinfo.Implementers {
if len(cinfos) < 2 {
continue
}
for _, cinfo := range cinfos {
var inPrio = false
for _, disfix := range iinfo.InterfaceInfo.Priority {
if cinfo.GetDisfix() == disfix {
inPrio = true
}
}
if !inPrio {
return errors.Errorf("%v conflicts with %v other(s). Add it to the priority list for %v.",
cinfo.Type, len(cinfos), iinfo.Type)
}
}
}
return nil
}
func (cdc *Codec) addCheckConflictsWithConcreteNolock(cinfo *TypeInfo) {
// Iterate over registered interfaces that this "implements".
// "Implement" in quotes because we only consider the pointer, for extra
// safety.
for _, iinfo := range cdc.interfaceInfos {
if !cinfo.PtrToType.Implements(iinfo.Type) {
continue
}
// Add cinfo to iinfo.Implementers.
var origImpls = iinfo.Implementers[cinfo.Prefix]
iinfo.Implementers[cinfo.Prefix] = append(origImpls, cinfo)
// Finally, check that all conflicts are in `.Priority`.
// NOTE: This could be optimized, but it's non-trivial.
err := cdc.checkConflictsInPrioNolock(iinfo)
if err != nil {
// Return to previous state.
iinfo.Implementers[cinfo.Prefix] = origImpls
panic(err)
}
}
}
//----------------------------------------
// .String()
func (ti TypeInfo) String() string {
buf := new(bytes.Buffer)
buf.Write([]byte("TypeInfo{"))
buf.Write([]byte(fmt.Sprintf("Type:%v,", ti.Type)))
if ti.Type.Kind() == reflect.Interface {
buf.Write([]byte(fmt.Sprintf("Priority:%v,", ti.Priority)))
buf.Write([]byte("Implementers:{"))
for pb, cinfos := range ti.Implementers {
buf.Write([]byte(fmt.Sprintf("\"%X\":", pb)))
buf.Write([]byte(fmt.Sprintf("%v,", cinfos)))
}
buf.Write([]byte("}"))
buf.Write([]byte(fmt.Sprintf("Priority:%v,", ti.InterfaceOptions.Priority)))
buf.Write([]byte(fmt.Sprintf("AlwaysDisambiguate:%v,", ti.InterfaceOptions.AlwaysDisambiguate)))
}
if ti.Type.Kind() != reflect.Interface {
if ti.ConcreteInfo.Registered {
buf.Write([]byte("Registered:true,"))
buf.Write([]byte(fmt.Sprintf("PointerPreferred:%v,", ti.PointerPreferred)))
buf.Write([]byte(fmt.Sprintf("Name:\"%v\",", ti.Name)))
buf.Write([]byte(fmt.Sprintf("Disamb:\"%X\",", ti.Disamb)))
buf.Write([]byte(fmt.Sprintf("Prefix:\"%X\",", ti.Prefix)))
} else {
buf.Write([]byte("Registered:false,"))
}
buf.Write([]byte(fmt.Sprintf("AminoMarshalReprType:\"%v\",", ti.AminoMarshalReprType)))
buf.Write([]byte(fmt.Sprintf("AminoUnmarshalReprType:\"%v\",", ti.AminoUnmarshalReprType)))
if ti.Type.Kind() == reflect.Struct {
buf.Write([]byte(fmt.Sprintf("Fields:%v,", ti.Fields)))
}
}
buf.Write([]byte("}"))
return buf.String()
}
//----------------------------------------
// Misc.
func isExported(field reflect.StructField) bool {
// Test 1:
if field.PkgPath != "" {
return false
}
// Test 2:
var first rune
for _, c := range field.Name {
first = c
break
}
// TODO: JAE: I'm not sure that the unicode spec
// is the correct spec to use, so this might be wrong.
return unicode.IsUpper(first)
}
func nameToDisamb(name string) (db DisambBytes) {
db, _ = nameToDisfix(name)
return
}
func nameToPrefix(name string) (pb PrefixBytes) {
_, pb = nameToDisfix(name)
return
}
func nameToDisfix(name string) (db DisambBytes, pb PrefixBytes) {
hasher := sha256.New()
if _, err := hasher.Write([]byte(name)); err != nil {
return
}
bz := hasher.Sum(nil)
for bz[0] == 0x00 {
bz = bz[1:]
}
copy(db[:], bz[0:3])
bz = bz[3:]
for bz[0] == 0x00 {
bz = bz[1:]
}
copy(pb[:], bz[0:4])
return
}
func toDisfix(db DisambBytes, pb PrefixBytes) (df DisfixBytes) {
copy(df[0:3], db[0:3])
copy(df[3:7], pb[0:4])
return
}
func marshalAminoReprType(rm reflect.Method) (rrt reflect.Type) {
// Verify form of this method.
if rm.Type.NumIn() != 1 {
panic(fmt.Sprintf("MarshalAmino should have 1 input parameters (including receiver); got %v", rm.Type))
}
if rm.Type.NumOut() != 2 {
panic(fmt.Sprintf("MarshalAmino should have 2 output parameters; got %v", rm.Type))
}
if out := rm.Type.Out(1); out != errorType {
panic(fmt.Sprintf("MarshalAmino should have second output parameter of error type, got %v", out))
}
rrt = rm.Type.Out(0)
if rrt.Kind() == reflect.Ptr {
panic(fmt.Sprintf("Representative objects cannot be pointers; got %v", rrt))
}
return
}
func unmarshalAminoReprType(rm reflect.Method) (rrt reflect.Type) {
// Verify form of this method.
if rm.Type.NumIn() != 2 {
panic(fmt.Sprintf("UnmarshalAmino should have 2 input parameters (including receiver); got %v", rm.Type))
}
if in1 := rm.Type.In(0); in1.Kind() != reflect.Ptr {
panic(fmt.Sprintf("UnmarshalAmino first input parameter should be pointer type but got %v", in1))
}
if rm.Type.NumOut() != 1 {
panic(fmt.Sprintf("UnmarshalAmino should have 1 output parameters; got %v", rm.Type))
}
if out := rm.Type.Out(0); out != errorType {
panic(fmt.Sprintf("UnmarshalAmino should have first output parameter of error type, got %v", out))
}
rrt = rm.Type.In(1)
if rrt.Kind() == reflect.Ptr {
panic(fmt.Sprintf("Representative objects cannot be pointers; got %v", rrt))
}
return
}