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mod.rs
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use crate::abi::{self, Abi, Align, FieldsShape, Size};
use crate::abi::{HasDataLayout, LayoutOf, TyAndLayout, TyAndLayoutMethods};
use crate::spec::{self, HasTargetSpec};
mod aarch64;
mod amdgpu;
mod arm;
mod avr;
mod bpf;
mod hexagon;
mod mips;
mod mips64;
mod msp430;
mod nvptx;
mod nvptx64;
mod powerpc;
mod powerpc64;
mod riscv;
mod s390x;
mod sparc;
mod sparc64;
mod wasm;
mod x86;
mod x86_64;
mod x86_win64;
#[derive(Clone, Copy, PartialEq, Eq, Debug)]
pub enum PassMode {
/// Ignore the argument.
///
/// The argument is either uninhabited or a ZST.
Ignore,
/// Pass the argument directly.
///
/// The argument has a layout abi of `Scalar`, `Vector` or in rare cases `Aggregate`.
Direct(ArgAttributes),
/// Pass a pair's elements directly in two arguments.
///
/// The argument has a layout abi of `ScalarPair`.
Pair(ArgAttributes, ArgAttributes),
/// Pass the argument after casting it, to either
/// a single uniform or a pair of registers.
Cast(CastTarget),
/// Pass the argument indirectly via a hidden pointer.
/// The `extra_attrs` value, if any, is for the extra data (vtable or length)
/// which indicates that it refers to an unsized rvalue.
/// `on_stack` defines that the the value should be passed at a fixed
/// stack offset in accordance to the ABI rather than passed using a
/// pointer. This corresponds to the `byval` LLVM argument attribute.
Indirect { attrs: ArgAttributes, extra_attrs: Option<ArgAttributes>, on_stack: bool },
}
// Hack to disable non_upper_case_globals only for the bitflags! and not for the rest
// of this module
pub use attr_impl::ArgAttribute;
#[allow(non_upper_case_globals)]
#[allow(unused)]
mod attr_impl {
// The subset of llvm::Attribute needed for arguments, packed into a bitfield.
bitflags::bitflags! {
#[derive(Default)]
pub struct ArgAttribute: u16 {
const NoAlias = 1 << 1;
const NoCapture = 1 << 2;
const NonNull = 1 << 3;
const ReadOnly = 1 << 4;
const InReg = 1 << 5;
// NoAlias on &mut arguments can only be used with LLVM >= 12 due to miscompiles
// in earlier versions. FIXME: Remove this distinction once possible.
const NoAliasMutRef = 1 << 6;
}
}
}
/// Sometimes an ABI requires small integers to be extended to a full or partial register. This enum
/// defines if this extension should be zero-extension or sign-extension when necessary. When it is
/// not necessary to extend the argument, this enum is ignored.
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
pub enum ArgExtension {
None,
Zext,
Sext,
}
/// A compact representation of LLVM attributes (at least those relevant for this module)
/// that can be manipulated without interacting with LLVM's Attribute machinery.
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
pub struct ArgAttributes {
pub regular: ArgAttribute,
pub arg_ext: ArgExtension,
/// The minimum size of the pointee, guaranteed to be valid for the duration of the whole call
/// (corresponding to LLVM's dereferenceable and dereferenceable_or_null attributes).
pub pointee_size: Size,
pub pointee_align: Option<Align>,
}
impl ArgAttributes {
pub fn new() -> Self {
ArgAttributes {
regular: ArgAttribute::default(),
arg_ext: ArgExtension::None,
pointee_size: Size::ZERO,
pointee_align: None,
}
}
pub fn ext(&mut self, ext: ArgExtension) -> &mut Self {
assert!(
self.arg_ext == ArgExtension::None || self.arg_ext == ext,
"cannot set {:?} when {:?} is already set",
ext,
self.arg_ext
);
self.arg_ext = ext;
self
}
pub fn set(&mut self, attr: ArgAttribute) -> &mut Self {
self.regular |= attr;
self
}
pub fn contains(&self, attr: ArgAttribute) -> bool {
self.regular.contains(attr)
}
}
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
pub enum RegKind {
Integer,
Float,
Vector,
}
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
pub struct Reg {
pub kind: RegKind,
pub size: Size,
}
macro_rules! reg_ctor {
($name:ident, $kind:ident, $bits:expr) => {
pub fn $name() -> Reg {
Reg { kind: RegKind::$kind, size: Size::from_bits($bits) }
}
};
}
impl Reg {
reg_ctor!(i8, Integer, 8);
reg_ctor!(i16, Integer, 16);
reg_ctor!(i32, Integer, 32);
reg_ctor!(i64, Integer, 64);
reg_ctor!(i128, Integer, 128);
reg_ctor!(f32, Float, 32);
reg_ctor!(f64, Float, 64);
}
impl Reg {
pub fn align<C: HasDataLayout>(&self, cx: &C) -> Align {
let dl = cx.data_layout();
match self.kind {
RegKind::Integer => match self.size.bits() {
1 => dl.i1_align.abi,
2..=8 => dl.i8_align.abi,
9..=16 => dl.i16_align.abi,
17..=32 => dl.i32_align.abi,
33..=64 => dl.i64_align.abi,
65..=128 => dl.i128_align.abi,
_ => panic!("unsupported integer: {:?}", self),
},
RegKind::Float => match self.size.bits() {
32 => dl.f32_align.abi,
64 => dl.f64_align.abi,
_ => panic!("unsupported float: {:?}", self),
},
RegKind::Vector => dl.vector_align(self.size).abi,
}
}
}
/// An argument passed entirely registers with the
/// same kind (e.g., HFA / HVA on PPC64 and AArch64).
#[derive(Clone, Copy, PartialEq, Eq, Debug)]
pub struct Uniform {
pub unit: Reg,
/// The total size of the argument, which can be:
/// * equal to `unit.size` (one scalar/vector),
/// * a multiple of `unit.size` (an array of scalar/vectors),
/// * if `unit.kind` is `Integer`, the last element
/// can be shorter, i.e., `{ i64, i64, i32 }` for
/// 64-bit integers with a total size of 20 bytes.
pub total: Size,
}
impl From<Reg> for Uniform {
fn from(unit: Reg) -> Uniform {
Uniform { unit, total: unit.size }
}
}
impl Uniform {
pub fn align<C: HasDataLayout>(&self, cx: &C) -> Align {
self.unit.align(cx)
}
}
#[derive(Clone, Copy, PartialEq, Eq, Debug)]
pub struct CastTarget {
pub prefix: [Option<RegKind>; 8],
pub prefix_chunk_size: Size,
pub rest: Uniform,
}
impl From<Reg> for CastTarget {
fn from(unit: Reg) -> CastTarget {
CastTarget::from(Uniform::from(unit))
}
}
impl From<Uniform> for CastTarget {
fn from(uniform: Uniform) -> CastTarget {
CastTarget { prefix: [None; 8], prefix_chunk_size: Size::ZERO, rest: uniform }
}
}
impl CastTarget {
pub fn pair(a: Reg, b: Reg) -> CastTarget {
CastTarget {
prefix: [Some(a.kind), None, None, None, None, None, None, None],
prefix_chunk_size: a.size,
rest: Uniform::from(b),
}
}
pub fn size<C: HasDataLayout>(&self, cx: &C) -> Size {
(self.prefix_chunk_size * self.prefix.iter().filter(|x| x.is_some()).count() as u64)
.align_to(self.rest.align(cx))
+ self.rest.total
}
pub fn align<C: HasDataLayout>(&self, cx: &C) -> Align {
self.prefix
.iter()
.filter_map(|x| x.map(|kind| Reg { kind, size: self.prefix_chunk_size }.align(cx)))
.fold(cx.data_layout().aggregate_align.abi.max(self.rest.align(cx)), |acc, align| {
acc.max(align)
})
}
}
/// Return value from the `homogeneous_aggregate` test function.
#[derive(Copy, Clone, Debug)]
pub enum HomogeneousAggregate {
/// Yes, all the "leaf fields" of this struct are passed in the
/// same way (specified in the `Reg` value).
Homogeneous(Reg),
/// There are no leaf fields at all.
NoData,
}
/// Error from the `homogeneous_aggregate` test function, indicating
/// there are distinct leaf fields passed in different ways,
/// or this is uninhabited.
#[derive(Copy, Clone, Debug)]
pub struct Heterogeneous;
impl HomogeneousAggregate {
/// If this is a homogeneous aggregate, returns the homogeneous
/// unit, else `None`.
pub fn unit(self) -> Option<Reg> {
match self {
HomogeneousAggregate::Homogeneous(reg) => Some(reg),
HomogeneousAggregate::NoData => None,
}
}
/// Try to combine two `HomogeneousAggregate`s, e.g. from two fields in
/// the same `struct`. Only succeeds if only one of them has any data,
/// or both units are identical.
fn merge(self, other: HomogeneousAggregate) -> Result<HomogeneousAggregate, Heterogeneous> {
match (self, other) {
(x, HomogeneousAggregate::NoData) | (HomogeneousAggregate::NoData, x) => Ok(x),
(HomogeneousAggregate::Homogeneous(a), HomogeneousAggregate::Homogeneous(b)) => {
if a != b {
return Err(Heterogeneous);
}
Ok(self)
}
}
}
}
impl<'a, Ty> TyAndLayout<'a, Ty> {
fn is_aggregate(&self) -> bool {
match self.abi {
Abi::Uninhabited | Abi::Scalar(_) | Abi::Vector { .. } => false,
Abi::ScalarPair(..) | Abi::Aggregate { .. } => true,
}
}
/// Returns `Homogeneous` if this layout is an aggregate containing fields of
/// only a single type (e.g., `(u32, u32)`). Such aggregates are often
/// special-cased in ABIs.
///
/// Note: We generally ignore fields of zero-sized type when computing
/// this value (see #56877).
///
/// This is public so that it can be used in unit tests, but
/// should generally only be relevant to the ABI details of
/// specific targets.
pub fn homogeneous_aggregate<C>(&self, cx: &C) -> Result<HomogeneousAggregate, Heterogeneous>
where
Ty: TyAndLayoutMethods<'a, C> + Copy,
C: LayoutOf<Ty = Ty, TyAndLayout = Self>,
{
match self.abi {
Abi::Uninhabited => Err(Heterogeneous),
// The primitive for this algorithm.
Abi::Scalar(ref scalar) => {
let kind = match scalar.value {
abi::Int(..) | abi::Pointer => RegKind::Integer,
abi::F32 | abi::F64 => RegKind::Float,
};
Ok(HomogeneousAggregate::Homogeneous(Reg { kind, size: self.size }))
}
Abi::Vector { .. } => {
assert!(!self.is_zst());
Ok(HomogeneousAggregate::Homogeneous(Reg {
kind: RegKind::Vector,
size: self.size,
}))
}
Abi::ScalarPair(..) | Abi::Aggregate { .. } => {
// Helper for computing `homogeneous_aggregate`, allowing a custom
// starting offset (used below for handling variants).
let from_fields_at =
|layout: Self,
start: Size|
-> Result<(HomogeneousAggregate, Size), Heterogeneous> {
let is_union = match layout.fields {
FieldsShape::Primitive => {
unreachable!("aggregates can't have `FieldsShape::Primitive`")
}
FieldsShape::Array { count, .. } => {
assert_eq!(start, Size::ZERO);
let result = if count > 0 {
layout.field(cx, 0).homogeneous_aggregate(cx)?
} else {
HomogeneousAggregate::NoData
};
return Ok((result, layout.size));
}
FieldsShape::Union(_) => true,
FieldsShape::Arbitrary { .. } => false,
};
let mut result = HomogeneousAggregate::NoData;
let mut total = start;
for i in 0..layout.fields.count() {
if !is_union && total != layout.fields.offset(i) {
return Err(Heterogeneous);
}
let field = layout.field(cx, i);
result = result.merge(field.homogeneous_aggregate(cx)?)?;
// Keep track of the offset (without padding).
let size = field.size;
if is_union {
total = total.max(size);
} else {
total += size;
}
}
Ok((result, total))
};
let (mut result, mut total) = from_fields_at(*self, Size::ZERO)?;
match &self.variants {
abi::Variants::Single { .. } => {}
abi::Variants::Multiple { variants, .. } => {
// Treat enum variants like union members.
// HACK(eddyb) pretend the `enum` field (discriminant)
// is at the start of every variant (otherwise the gap
// at the start of all variants would disqualify them).
//
// NB: for all tagged `enum`s (which include all non-C-like
// `enum`s with defined FFI representation), this will
// match the homogeneous computation on the equivalent
// `struct { tag; union { variant1; ... } }` and/or
// `union { struct { tag; variant1; } ... }`
// (the offsets of variant fields should be identical
// between the two for either to be a homogeneous aggregate).
let variant_start = total;
for variant_idx in variants.indices() {
let (variant_result, variant_total) =
from_fields_at(self.for_variant(cx, variant_idx), variant_start)?;
result = result.merge(variant_result)?;
total = total.max(variant_total);
}
}
}
// There needs to be no padding.
if total != self.size {
Err(Heterogeneous)
} else {
match result {
HomogeneousAggregate::Homogeneous(_) => {
assert_ne!(total, Size::ZERO);
}
HomogeneousAggregate::NoData => {
assert_eq!(total, Size::ZERO);
}
}
Ok(result)
}
}
}
}
}
/// Information about how to pass an argument to,
/// or return a value from, a function, under some ABI.
#[derive(Debug)]
pub struct ArgAbi<'a, Ty> {
pub layout: TyAndLayout<'a, Ty>,
/// Dummy argument, which is emitted before the real argument.
pub pad: Option<Reg>,
pub mode: PassMode,
}
impl<'a, Ty> ArgAbi<'a, Ty> {
pub fn new(
cx: &impl HasDataLayout,
layout: TyAndLayout<'a, Ty>,
scalar_attrs: impl Fn(&TyAndLayout<'a, Ty>, &abi::Scalar, Size) -> ArgAttributes,
) -> Self {
let mode = match &layout.abi {
Abi::Uninhabited => PassMode::Ignore,
Abi::Scalar(scalar) => PassMode::Direct(scalar_attrs(&layout, scalar, Size::ZERO)),
Abi::ScalarPair(a, b) => PassMode::Pair(
scalar_attrs(&layout, a, Size::ZERO),
scalar_attrs(&layout, b, a.value.size(cx).align_to(b.value.align(cx).abi)),
),
Abi::Vector { .. } => PassMode::Direct(ArgAttributes::new()),
Abi::Aggregate { .. } => PassMode::Direct(ArgAttributes::new()),
};
ArgAbi { layout, pad: None, mode }
}
fn indirect_pass_mode(layout: &TyAndLayout<'a, Ty>) -> PassMode {
let mut attrs = ArgAttributes::new();
// For non-immediate arguments the callee gets its own copy of
// the value on the stack, so there are no aliases. It's also
// program-invisible so can't possibly capture
attrs.set(ArgAttribute::NoAlias).set(ArgAttribute::NoCapture).set(ArgAttribute::NonNull);
attrs.pointee_size = layout.size;
// FIXME(eddyb) We should be doing this, but at least on
// i686-pc-windows-msvc, it results in wrong stack offsets.
// attrs.pointee_align = Some(layout.align.abi);
let extra_attrs = layout.is_unsized().then_some(ArgAttributes::new());
PassMode::Indirect { attrs, extra_attrs, on_stack: false }
}
pub fn make_indirect(&mut self) {
match self.mode {
PassMode::Direct(_) | PassMode::Pair(_, _) => {}
PassMode::Indirect { attrs: _, extra_attrs: None, on_stack: false } => return,
_ => panic!("Tried to make {:?} indirect", self.mode),
}
self.mode = Self::indirect_pass_mode(&self.layout);
}
pub fn make_indirect_byval(&mut self) {
self.make_indirect();
match self.mode {
PassMode::Indirect { attrs: _, extra_attrs: _, ref mut on_stack } => {
*on_stack = true;
}
_ => unreachable!(),
}
}
pub fn extend_integer_width_to(&mut self, bits: u64) {
// Only integers have signedness
if let Abi::Scalar(ref scalar) = self.layout.abi {
if let abi::Int(i, signed) = scalar.value {
if i.size().bits() < bits {
if let PassMode::Direct(ref mut attrs) = self.mode {
if signed {
attrs.ext(ArgExtension::Sext)
} else {
attrs.ext(ArgExtension::Zext)
};
}
}
}
}
}
pub fn cast_to<T: Into<CastTarget>>(&mut self, target: T) {
self.mode = PassMode::Cast(target.into());
}
pub fn pad_with(&mut self, reg: Reg) {
self.pad = Some(reg);
}
pub fn is_indirect(&self) -> bool {
matches!(self.mode, PassMode::Indirect { .. })
}
pub fn is_sized_indirect(&self) -> bool {
matches!(self.mode, PassMode::Indirect { attrs: _, extra_attrs: None, on_stack: _ })
}
pub fn is_unsized_indirect(&self) -> bool {
matches!(self.mode, PassMode::Indirect { attrs: _, extra_attrs: Some(_), on_stack: _ })
}
pub fn is_ignore(&self) -> bool {
matches!(self.mode, PassMode::Ignore)
}
}
#[derive(Copy, Clone, PartialEq, Debug)]
pub enum Conv {
// General language calling conventions, for which every target
// should have its own backend (e.g. LLVM) support.
C,
Rust,
// Target-specific calling conventions.
ArmAapcs,
CCmseNonSecureCall,
Msp430Intr,
PtxKernel,
X86Fastcall,
X86Intr,
X86Stdcall,
X86ThisCall,
X86VectorCall,
X86_64SysV,
X86_64Win64,
AmdGpuKernel,
AvrInterrupt,
AvrNonBlockingInterrupt,
}
/// Metadata describing how the arguments to a native function
/// should be passed in order to respect the native ABI.
///
/// I will do my best to describe this structure, but these
/// comments are reverse-engineered and may be inaccurate. -NDM
#[derive(Debug)]
pub struct FnAbi<'a, Ty> {
/// The LLVM types of each argument.
pub args: Vec<ArgAbi<'a, Ty>>,
/// LLVM return type.
pub ret: ArgAbi<'a, Ty>,
pub c_variadic: bool,
/// The count of non-variadic arguments.
///
/// Should only be different from args.len() when c_variadic is true.
/// This can be used to know whether an argument is variadic or not.
pub fixed_count: usize,
pub conv: Conv,
pub can_unwind: bool,
}
impl<'a, Ty> FnAbi<'a, Ty> {
pub fn adjust_for_cabi<C>(&mut self, cx: &C, abi: spec::abi::Abi) -> Result<(), String>
where
Ty: TyAndLayoutMethods<'a, C> + Copy,
C: LayoutOf<Ty = Ty, TyAndLayout = TyAndLayout<'a, Ty>> + HasDataLayout + HasTargetSpec,
{
if abi == spec::abi::Abi::X86Interrupt {
if let Some(arg) = self.args.first_mut() {
arg.make_indirect_byval();
}
return Ok(());
}
match &cx.target_spec().arch[..] {
"x86" => {
let flavor = if abi == spec::abi::Abi::Fastcall {
x86::Flavor::Fastcall
} else {
x86::Flavor::General
};
x86::compute_abi_info(cx, self, flavor);
}
"x86_64" => {
if abi == spec::abi::Abi::SysV64 {
x86_64::compute_abi_info(cx, self);
} else if abi == spec::abi::Abi::Win64 || cx.target_spec().is_like_windows {
x86_win64::compute_abi_info(self);
} else {
x86_64::compute_abi_info(cx, self);
}
}
"aarch64" => aarch64::compute_abi_info(cx, self),
"amdgpu" => amdgpu::compute_abi_info(cx, self),
"arm" => arm::compute_abi_info(cx, self),
"avr" => avr::compute_abi_info(self),
"mips" => mips::compute_abi_info(cx, self),
"mips64" => mips64::compute_abi_info(cx, self),
"powerpc" => powerpc::compute_abi_info(self),
"powerpc64" => powerpc64::compute_abi_info(cx, self),
"s390x" => s390x::compute_abi_info(cx, self),
"msp430" => msp430::compute_abi_info(self),
"sparc" => sparc::compute_abi_info(cx, self),
"sparc64" => sparc64::compute_abi_info(cx, self),
"nvptx" => nvptx::compute_abi_info(self),
"nvptx64" => nvptx64::compute_abi_info(self),
"hexagon" => hexagon::compute_abi_info(self),
"riscv32" | "riscv64" => riscv::compute_abi_info(cx, self),
"wasm32" | "wasm64" => {
if cx.target_spec().adjust_abi(abi) == spec::abi::Abi::Wasm {
wasm::compute_wasm_abi_info(self)
} else {
wasm::compute_c_abi_info(cx, self)
}
}
"asmjs" => wasm::compute_c_abi_info(cx, self),
"bpf" => bpf::compute_abi_info(self),
a => return Err(format!("unrecognized arch \"{}\" in target specification", a)),
}
Ok(())
}
}