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compiler: Wire TyAndLayout into rustc_abi
This type can finally land where it has always belonged.
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mod abi { | ||
pub(crate) use crate::Primitive::*; | ||
pub(crate) use crate::Variants; | ||
} | ||
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use rustc_macros::HashStable_Generic; | ||
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use crate::{Abi, Align, FieldsShape, HasDataLayout, Size, TyAbiInterface, TyAndLayout}; | ||
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#[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable_Generic)] | ||
pub enum RegKind { | ||
Integer, | ||
Float, | ||
Vector, | ||
} | ||
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#[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable_Generic)] | ||
pub struct Reg { | ||
pub kind: RegKind, | ||
pub size: Size, | ||
} | ||
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macro_rules! reg_ctor { | ||
($name:ident, $kind:ident, $bits:expr) => { | ||
pub fn $name() -> Reg { | ||
Reg { kind: RegKind::$kind, size: Size::from_bits($bits) } | ||
} | ||
}; | ||
} | ||
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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); | ||
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reg_ctor!(f32, Float, 32); | ||
reg_ctor!(f64, Float, 64); | ||
} | ||
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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, | ||
} | ||
} | ||
} | ||
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/// 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), | ||
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/// There are no leaf fields at all. | ||
NoData, | ||
} | ||
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/// 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; | ||
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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, | ||
} | ||
} | ||
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/// 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), | ||
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(HomogeneousAggregate::Homogeneous(a), HomogeneousAggregate::Homogeneous(b)) => { | ||
if a != b { | ||
return Err(Heterogeneous); | ||
} | ||
Ok(self) | ||
} | ||
} | ||
} | ||
} | ||
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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, | ||
} | ||
} | ||
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/// 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), | ||
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// 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 })) | ||
} | ||
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Abi::Vector { .. } => { | ||
assert!(!self.is_zst()); | ||
Ok(HomogeneousAggregate::Homogeneous(Reg { | ||
kind: RegKind::Vector, | ||
size: self.size, | ||
})) | ||
} | ||
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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); | ||
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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, | ||
}; | ||
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let mut result = HomogeneousAggregate::NoData; | ||
let mut total = start; | ||
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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; | ||
} | ||
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if !is_union && total != layout.fields.offset(i) { | ||
// This field isn't just after the previous one we considered, abort. | ||
return Err(Heterogeneous); | ||
} | ||
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result = result.merge(field.homogeneous_aggregate(cx)?)?; | ||
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// Keep track of the offset (without padding). | ||
let size = field.size; | ||
if is_union { | ||
total = total.max(size); | ||
} else { | ||
total += size; | ||
} | ||
} | ||
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Ok((result, total)) | ||
}; | ||
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let (mut result, mut total) = from_fields_at(*self, Size::ZERO)?; | ||
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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)?; | ||
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result = result.merge(variant_result)?; | ||
total = total.max(variant_total); | ||
} | ||
} | ||
} | ||
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// 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), | ||
} | ||
} | ||
} |
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