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Rollup merge of #131473 - workingjubilee:move-that-abi-up, r=saethlin

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compiler: `{TyAnd,}Layout` comes home

The `Layout` and `TyAndLayout` types are heavily abstract and have no particular target-specific qualities, though we do use them to answer questions particular to targets. We can keep it that way if we simply move them out of `rustc_target` and into `rustc_abi`. They bring a small entourage of connected types with them, but that's fine.

This will allow us to strengthen a few abstraction barriers over time and thus make the notoriously gnarly layout code easier to refactor. For now, we don't need to worry about that and deliberately use reexports to minimize this particular diff.
This commit is contained in:
Matthias Krüger 2024-10-14 06:04:28 +02:00 committed by GitHub
commit cb140dcb00
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32 changed files with 285 additions and 261 deletions
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254
compiler/rustc_abi/src/callconv.rs Normal file
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@ -0,0 +1,254 @@
mod abi {
pub(crate) use crate::Primitive::*;
pub(crate) use crate::Variants;
}
use rustc_macros::HashStable_Generic;
use crate::{Abi, Align, FieldsShape, HasDataLayout, Size, TyAbiInterface, TyAndLayout};
#[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable_Generic)]
pub enum RegKind {
Integer,
Float,
Vector,
}
#[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable_Generic)]
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() {
16 => dl.f16_align.abi,
32 => dl.f32_align.abi,
64 => dl.f64_align.abi,
128 => dl.f128_align.abi,
_ => panic!("unsupported float: {self:?}"),
},
RegKind::Vector => dl.vector_align(self.size).abi,
}
}
}
/// 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> {
/// Returns `true` if this is an aggregate type (including a ScalarPair!)
pub 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 1-ZST fields 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: TyAbiInterface<'a, C> + Copy,
{
match self.abi {
Abi::Uninhabited => Err(Heterogeneous),
// The primitive for this algorithm.
Abi::Scalar(scalar) => {
let kind = match scalar.primitive() {
abi::Int(..) | abi::Pointer(_) => RegKind::Integer,
abi::Float(_) => 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 { sized: true } => {
// 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() {
let field = layout.field(cx, i);
if field.is_1zst() {
// No data here and no impact on layout, can be ignored.
// (We might be able to also ignore all aligned ZST but that's less clear.)
continue;
}
if !is_union && total != layout.fields.offset(i) {
// This field isn't just after the previous one we considered, abort.
return Err(Heterogeneous);
}
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)
}
}
Abi::Aggregate { sized: false } => Err(Heterogeneous),
}
}
}

4
compiler/rustc_abi/src/layout.rs
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@ -11,6 +11,10 @@ use crate::{
Variants, WrappingRange,
};
mod ty;
pub use ty::{FIRST_VARIANT, FieldIdx, Layout, TyAbiInterface, TyAndLayout, VariantIdx};
// A variant is absent if it's uninhabited and only has ZST fields.
// Present uninhabited variants only require space for their fields,
// but *not* an encoding of the discriminant (e.g., a tag value).

12
compiler/rustc_target/src/abi/mod.rs → compiler/rustc_abi/src/layout/ty.rs
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@ -6,18 +6,8 @@ use Primitive::*;
use rustc_data_structures::intern::Interned;
use rustc_macros::HashStable_Generic;
use crate::json::{Json, ToJson};
pub mod call;
// Explicitly import `Float` to avoid ambiguity with `Primitive::Float`.
pub use rustc_abi::{Float, *};
impl ToJson for Endian {
fn to_json(&self) -> Json {
self.as_str().to_json()
}
}
use crate::{Float, *};
rustc_index::newtype_index! {
/// The *source-order* index of a field in a variant.

8
compiler/rustc_abi/src/lib.rs
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@ -1,6 +1,7 @@
// tidy-alphabetical-start
#![cfg_attr(feature = "nightly", allow(internal_features))]
#![cfg_attr(feature = "nightly", doc(rust_logo))]
#![cfg_attr(feature = "nightly", feature(rustc_attrs))]
#![cfg_attr(feature = "nightly", feature(rustdoc_internals))]
#![cfg_attr(feature = "nightly", feature(step_trait))]
#![warn(unreachable_pub)]
@ -22,11 +23,16 @@ use rustc_macros::HashStable_Generic;
#[cfg(feature = "nightly")]
use rustc_macros::{Decodable_Generic, Encodable_Generic};
mod callconv;
mod layout;
#[cfg(test)]
mod tests;
pub use layout::{LayoutCalculator, LayoutCalculatorError};
pub use callconv::{Heterogeneous, HomogeneousAggregate, Reg, RegKind};
pub use layout::{
FIRST_VARIANT, FieldIdx, Layout, LayoutCalculator, LayoutCalculatorError, TyAbiInterface,
TyAndLayout, VariantIdx,
};
/// Requirements for a `StableHashingContext` to be used in this crate.
/// This is a hack to allow using the `HashStable_Generic` derive macro

2
compiler/rustc_middle/src/ty/context.rs
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@ -12,6 +12,7 @@ use std::marker::PhantomData;
use std::ops::{Bound, Deref};
use std::{fmt, iter, mem};
use rustc_abi::{FieldIdx, Layout, LayoutS, TargetDataLayout, VariantIdx};
use rustc_ast::{self as ast, attr};
use rustc_data_structures::defer;
use rustc_data_structures::fingerprint::Fingerprint;
@ -48,7 +49,6 @@ use rustc_session::{Limit, MetadataKind, Session};
use rustc_span::def_id::{CRATE_DEF_ID, DefPathHash, StableCrateId};
use rustc_span::symbol::{Ident, Symbol, kw, sym};
use rustc_span::{DUMMY_SP, Span};
use rustc_target::abi::{FieldIdx, Layout, LayoutS, TargetDataLayout, VariantIdx};
use rustc_target::spec::abi;
use rustc_type_ir::TyKind::*;
use rustc_type_ir::fold::TypeFoldable;

0
compiler/rustc_target/src/abi/call/aarch64.rs → compiler/rustc_target/src/callconv/aarch64.rs
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0
compiler/rustc_target/src/abi/call/amdgpu.rs → compiler/rustc_target/src/callconv/amdgpu.rs
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0
compiler/rustc_target/src/abi/call/arm.rs → compiler/rustc_target/src/callconv/arm.rs
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0
compiler/rustc_target/src/abi/call/avr.rs → compiler/rustc_target/src/callconv/avr.rs
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0
compiler/rustc_target/src/abi/call/bpf.rs → compiler/rustc_target/src/callconv/bpf.rs
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0
compiler/rustc_target/src/abi/call/csky.rs → compiler/rustc_target/src/callconv/csky.rs
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0
compiler/rustc_target/src/abi/call/hexagon.rs → compiler/rustc_target/src/callconv/hexagon.rs
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0
compiler/rustc_target/src/abi/call/loongarch.rs → compiler/rustc_target/src/callconv/loongarch.rs
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0
compiler/rustc_target/src/abi/call/m68k.rs → compiler/rustc_target/src/callconv/m68k.rs
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0
compiler/rustc_target/src/abi/call/mips.rs → compiler/rustc_target/src/callconv/mips.rs
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0
compiler/rustc_target/src/abi/call/mips64.rs → compiler/rustc_target/src/callconv/mips64.rs
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249
compiler/rustc_target/src/abi/call/mod.rs → compiler/rustc_target/src/callconv/mod.rs
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@ -1,10 +1,11 @@
use std::fmt;
use std::str::FromStr;
pub use rustc_abi::{Reg, RegKind};
use rustc_macros::HashStable_Generic;
use rustc_span::Symbol;
use crate::abi::{self, Abi, Align, FieldsShape, HasDataLayout, Size, TyAbiInterface, TyAndLayout};
use crate::abi::{self, Abi, Align, HasDataLayout, Size, TyAbiInterface, TyAndLayout};
use crate::spec::{self, HasTargetSpec, HasWasmCAbiOpt, WasmCAbi};
mod aarch64;
@ -192,63 +193,6 @@ impl ArgAttributes {
}
}
#[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable_Generic)]
pub enum RegKind {
Integer,
Float,
Vector,
}
#[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable_Generic)]
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() {
16 => dl.f16_align.abi,
32 => dl.f32_align.abi,
64 => dl.f64_align.abi,
128 => dl.f128_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, Hash, Debug, HashStable_Generic)]
@ -380,195 +324,6 @@ impl CastTarget {
}
}
/// 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> {
/// Returns `true` if this is an aggregate type (including a ScalarPair!)
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 1-ZST fields 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: TyAbiInterface<'a, C> + Copy,
{
match self.abi {
Abi::Uninhabited => Err(Heterogeneous),
// The primitive for this algorithm.
Abi::Scalar(scalar) => {
let kind = match scalar.primitive() {
abi::Int(..) | abi::Pointer(_) => RegKind::Integer,
abi::Float(_) => 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 { sized: true } => {
// 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() {
let field = layout.field(cx, i);
if field.is_1zst() {
// No data here and no impact on layout, can be ignored.
// (We might be able to also ignore all aligned ZST but that's less clear.)
continue;
}
if !is_union && total != layout.fields.offset(i) {
// This field isn't just after the previous one we considered, abort.
return Err(Heterogeneous);
}
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)
}
}
Abi::Aggregate { sized: false } => Err(Heterogeneous),
}
}
}
/// Information about how to pass an argument to,
/// or return a value from, a function, under some ABI.
#[derive(Clone, PartialEq, Eq, Hash, HashStable_Generic)]

0
compiler/rustc_target/src/abi/call/msp430.rs → compiler/rustc_target/src/callconv/msp430.rs
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0
compiler/rustc_target/src/abi/call/nvptx64.rs → compiler/rustc_target/src/callconv/nvptx64.rs
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0
compiler/rustc_target/src/abi/call/powerpc.rs → compiler/rustc_target/src/callconv/powerpc.rs
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0
compiler/rustc_target/src/abi/call/powerpc64.rs → compiler/rustc_target/src/callconv/powerpc64.rs
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0
compiler/rustc_target/src/abi/call/riscv.rs → compiler/rustc_target/src/callconv/riscv.rs
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0
compiler/rustc_target/src/abi/call/s390x.rs → compiler/rustc_target/src/callconv/s390x.rs
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0
compiler/rustc_target/src/abi/call/sparc.rs → compiler/rustc_target/src/callconv/sparc.rs
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0
compiler/rustc_target/src/abi/call/sparc64.rs → compiler/rustc_target/src/callconv/sparc64.rs
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0
compiler/rustc_target/src/abi/call/wasm.rs → compiler/rustc_target/src/callconv/wasm.rs
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0
compiler/rustc_target/src/abi/call/x86.rs → compiler/rustc_target/src/callconv/x86.rs
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0
compiler/rustc_target/src/abi/call/x86_64.rs → compiler/rustc_target/src/callconv/x86_64.rs
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0
compiler/rustc_target/src/abi/call/x86_win64.rs → compiler/rustc_target/src/callconv/x86_win64.rs
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0
compiler/rustc_target/src/abi/call/xtensa.rs → compiler/rustc_target/src/callconv/xtensa.rs
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6
compiler/rustc_target/src/json.rs
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@ -134,3 +134,9 @@ impl ToJson for TargetMetadata {
})
}
}
impl ToJson for rustc_abi::Endian {
fn to_json(&self) -> Json {
self.as_str().to_json()
}
}

11
compiler/rustc_target/src/lib.rs
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@ -21,8 +21,8 @@
use std::path::{Path, PathBuf};
pub mod abi;
pub mod asm;
pub mod callconv;
pub mod json;
pub mod spec;
pub mod target_features;
@ -30,6 +30,15 @@ pub mod target_features;
#[cfg(test)]
mod tests;
pub mod abi {
pub(crate) use Float::*;
pub(crate) use Primitive::*;
// Explicitly import `Float` to avoid ambiguity with `Primitive::Float`.
pub use rustc_abi::{Float, *};
pub use crate::callconv as call;
}
pub use rustc_abi::HashStableContext;
/// The name of rustc's own place to organize libraries.