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layout.rs
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layout.rs
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use crate::ich::StableHashingContext;
use crate::middle::codegen_fn_attrs::CodegenFnAttrFlags;
use crate::mir::{GeneratorLayout, GeneratorSavedLocal};
use crate::ty::subst::Subst;
use crate::ty::{self, subst::SubstsRef, ReprOptions, Ty, TyCtxt, TypeFoldable};
use rustc_ast::{self as ast, IntTy, UintTy};
use rustc_attr as attr;
use rustc_data_structures::stable_hasher::{HashStable, StableHasher};
use rustc_hir as hir;
use rustc_hir::lang_items::LangItem;
use rustc_index::bit_set::BitSet;
use rustc_index::vec::{Idx, IndexVec};
use rustc_session::{DataTypeKind, FieldInfo, SizeKind, VariantInfo};
use rustc_span::symbol::{Ident, Symbol};
use rustc_span::DUMMY_SP;
use rustc_target::abi::call::{
ArgAbi, ArgAttribute, ArgAttributes, Conv, FnAbi, PassMode, Reg, RegKind,
};
use rustc_target::abi::*;
use rustc_target::spec::{abi::Abi as SpecAbi, HasTargetSpec, PanicStrategy};
use std::cmp;
use std::fmt;
use std::iter;
use std::mem;
use std::num::NonZeroUsize;
use std::ops::Bound;
pub trait IntegerExt {
fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>, signed: bool) -> Ty<'tcx>;
fn from_attr<C: HasDataLayout>(cx: &C, ity: attr::IntType) -> Integer;
fn repr_discr<'tcx>(
tcx: TyCtxt<'tcx>,
ty: Ty<'tcx>,
repr: &ReprOptions,
min: i128,
max: i128,
) -> (Integer, bool);
}
impl IntegerExt for Integer {
fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>, signed: bool) -> Ty<'tcx> {
match (*self, signed) {
(I8, false) => tcx.types.u8,
(I16, false) => tcx.types.u16,
(I32, false) => tcx.types.u32,
(I64, false) => tcx.types.u64,
(I128, false) => tcx.types.u128,
(I8, true) => tcx.types.i8,
(I16, true) => tcx.types.i16,
(I32, true) => tcx.types.i32,
(I64, true) => tcx.types.i64,
(I128, true) => tcx.types.i128,
}
}
/// Gets the Integer type from an attr::IntType.
fn from_attr<C: HasDataLayout>(cx: &C, ity: attr::IntType) -> Integer {
let dl = cx.data_layout();
match ity {
attr::SignedInt(IntTy::I8) | attr::UnsignedInt(UintTy::U8) => I8,
attr::SignedInt(IntTy::I16) | attr::UnsignedInt(UintTy::U16) => I16,
attr::SignedInt(IntTy::I32) | attr::UnsignedInt(UintTy::U32) => I32,
attr::SignedInt(IntTy::I64) | attr::UnsignedInt(UintTy::U64) => I64,
attr::SignedInt(IntTy::I128) | attr::UnsignedInt(UintTy::U128) => I128,
attr::SignedInt(IntTy::Isize) | attr::UnsignedInt(UintTy::Usize) => {
dl.ptr_sized_integer()
}
}
}
/// Finds the appropriate Integer type and signedness for the given
/// signed discriminant range and `#[repr]` attribute.
/// N.B.: `u128` values above `i128::MAX` will be treated as signed, but
/// that shouldn't affect anything, other than maybe debuginfo.
fn repr_discr<'tcx>(
tcx: TyCtxt<'tcx>,
ty: Ty<'tcx>,
repr: &ReprOptions,
min: i128,
max: i128,
) -> (Integer, bool) {
// Theoretically, negative values could be larger in unsigned representation
// than the unsigned representation of the signed minimum. However, if there
// are any negative values, the only valid unsigned representation is u128
// which can fit all i128 values, so the result remains unaffected.
let unsigned_fit = Integer::fit_unsigned(cmp::max(min as u128, max as u128));
let signed_fit = cmp::max(Integer::fit_signed(min), Integer::fit_signed(max));
let mut min_from_extern = None;
let min_default = I8;
if let Some(ity) = repr.int {
let discr = Integer::from_attr(&tcx, ity);
let fit = if ity.is_signed() { signed_fit } else { unsigned_fit };
if discr < fit {
bug!(
"Integer::repr_discr: `#[repr]` hint too small for \
discriminant range of enum `{}",
ty
)
}
return (discr, ity.is_signed());
}
if repr.c() {
match &tcx.sess.target.target.arch[..] {
// WARNING: the ARM EABI has two variants; the one corresponding
// to `at_least == I32` appears to be used on Linux and NetBSD,
// but some systems may use the variant corresponding to no
// lower bound. However, we don't run on those yet...?
"arm" => min_from_extern = Some(I32),
_ => min_from_extern = Some(I32),
}
}
let at_least = min_from_extern.unwrap_or(min_default);
// If there are no negative values, we can use the unsigned fit.
if min >= 0 {
(cmp::max(unsigned_fit, at_least), false)
} else {
(cmp::max(signed_fit, at_least), true)
}
}
}
pub trait PrimitiveExt {
fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx>;
fn to_int_ty<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx>;
}
impl PrimitiveExt for Primitive {
fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx> {
match *self {
Int(i, signed) => i.to_ty(tcx, signed),
F32 => tcx.types.f32,
F64 => tcx.types.f64,
Pointer => tcx.mk_mut_ptr(tcx.mk_unit()),
}
}
/// Return an *integer* type matching this primitive.
/// Useful in particular when dealing with enum discriminants.
fn to_int_ty(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx> {
match *self {
Int(i, signed) => i.to_ty(tcx, signed),
Pointer => tcx.types.usize,
F32 | F64 => bug!("floats do not have an int type"),
}
}
}
/// The first half of a fat pointer.
///
/// - For a trait object, this is the address of the box.
/// - For a slice, this is the base address.
pub const FAT_PTR_ADDR: usize = 0;
/// The second half of a fat pointer.
///
/// - For a trait object, this is the address of the vtable.
/// - For a slice, this is the length.
pub const FAT_PTR_EXTRA: usize = 1;
#[derive(Copy, Clone, Debug, TyEncodable, TyDecodable)]
pub enum LayoutError<'tcx> {
Unknown(Ty<'tcx>),
SizeOverflow(Ty<'tcx>),
}
impl<'tcx> fmt::Display for LayoutError<'tcx> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match *self {
LayoutError::Unknown(ty) => write!(f, "the type `{}` has an unknown layout", ty),
LayoutError::SizeOverflow(ty) => {
write!(f, "the type `{}` is too big for the current architecture", ty)
}
}
}
}
fn layout_raw<'tcx>(
tcx: TyCtxt<'tcx>,
query: ty::ParamEnvAnd<'tcx, Ty<'tcx>>,
) -> Result<&'tcx Layout, LayoutError<'tcx>> {
ty::tls::with_related_context(tcx, move |icx| {
let (param_env, ty) = query.into_parts();
if !tcx.sess.recursion_limit().value_within_limit(icx.layout_depth) {
tcx.sess.fatal(&format!("overflow representing the type `{}`", ty));
}
// Update the ImplicitCtxt to increase the layout_depth
let icx = ty::tls::ImplicitCtxt { layout_depth: icx.layout_depth + 1, ..icx.clone() };
ty::tls::enter_context(&icx, |_| {
let cx = LayoutCx { tcx, param_env };
let layout = cx.layout_raw_uncached(ty);
// Type-level uninhabitedness should always imply ABI uninhabitedness.
if let Ok(layout) = layout {
if ty.conservative_is_privately_uninhabited(tcx) {
assert!(layout.abi.is_uninhabited());
}
}
layout
})
})
}
pub fn provide(providers: &mut ty::query::Providers) {
*providers = ty::query::Providers { layout_raw, ..*providers };
}
pub struct LayoutCx<'tcx, C> {
pub tcx: C,
pub param_env: ty::ParamEnv<'tcx>,
}
#[derive(Copy, Clone, Debug)]
enum StructKind {
/// A tuple, closure, or univariant which cannot be coerced to unsized.
AlwaysSized,
/// A univariant, the last field of which may be coerced to unsized.
MaybeUnsized,
/// A univariant, but with a prefix of an arbitrary size & alignment (e.g., enum tag).
Prefixed(Size, Align),
}
// Invert a bijective mapping, i.e. `invert(map)[y] = x` if `map[x] = y`.
// This is used to go between `memory_index` (source field order to memory order)
// and `inverse_memory_index` (memory order to source field order).
// See also `FieldsShape::Arbitrary::memory_index` for more details.
// FIXME(eddyb) build a better abstraction for permutations, if possible.
fn invert_mapping(map: &[u32]) -> Vec<u32> {
let mut inverse = vec![0; map.len()];
for i in 0..map.len() {
inverse[map[i] as usize] = i as u32;
}
inverse
}
impl<'tcx> LayoutCx<'tcx, TyCtxt<'tcx>> {
fn scalar_pair(&self, a: Scalar, b: Scalar) -> Layout {
let dl = self.data_layout();
let b_align = b.value.align(dl);
let align = a.value.align(dl).max(b_align).max(dl.aggregate_align);
let b_offset = a.value.size(dl).align_to(b_align.abi);
let size = (b_offset + b.value.size(dl)).align_to(align.abi);
// HACK(nox): We iter on `b` and then `a` because `max_by_key`
// returns the last maximum.
let largest_niche = Niche::from_scalar(dl, b_offset, b.clone())
.into_iter()
.chain(Niche::from_scalar(dl, Size::ZERO, a.clone()))
.max_by_key(|niche| niche.available(dl));
Layout {
variants: Variants::Single { index: VariantIdx::new(0) },
fields: FieldsShape::Arbitrary {
offsets: vec![Size::ZERO, b_offset],
memory_index: vec![0, 1],
},
abi: Abi::ScalarPair(a, b),
largest_niche,
align,
size,
}
}
fn univariant_uninterned(
&self,
ty: Ty<'tcx>,
fields: &[TyAndLayout<'_>],
repr: &ReprOptions,
kind: StructKind,
) -> Result<Layout, LayoutError<'tcx>> {
let dl = self.data_layout();
let pack = repr.pack;
if pack.is_some() && repr.align.is_some() {
bug!("struct cannot be packed and aligned");
}
let mut align = if pack.is_some() { dl.i8_align } else { dl.aggregate_align };
let mut inverse_memory_index: Vec<u32> = (0..fields.len() as u32).collect();
let optimize = !repr.inhibit_struct_field_reordering_opt();
if optimize {
let end =
if let StructKind::MaybeUnsized = kind { fields.len() - 1 } else { fields.len() };
let optimizing = &mut inverse_memory_index[..end];
let field_align = |f: &TyAndLayout<'_>| {
if let Some(pack) = pack { f.align.abi.min(pack) } else { f.align.abi }
};
match kind {
StructKind::AlwaysSized | StructKind::MaybeUnsized => {
optimizing.sort_by_key(|&x| {
// Place ZSTs first to avoid "interesting offsets",
// especially with only one or two non-ZST fields.
let f = &fields[x as usize];
(!f.is_zst(), cmp::Reverse(field_align(f)))
});
}
StructKind::Prefixed(..) => {
// Sort in ascending alignment so that the layout stay optimal
// regardless of the prefix
optimizing.sort_by_key(|&x| field_align(&fields[x as usize]));
}
}
}
// inverse_memory_index holds field indices by increasing memory offset.
// That is, if field 5 has offset 0, the first element of inverse_memory_index is 5.
// We now write field offsets to the corresponding offset slot;
// field 5 with offset 0 puts 0 in offsets[5].
// At the bottom of this function, we invert `inverse_memory_index` to
// produce `memory_index` (see `invert_mapping`).
let mut sized = true;
let mut offsets = vec![Size::ZERO; fields.len()];
let mut offset = Size::ZERO;
let mut largest_niche = None;
let mut largest_niche_available = 0;
if let StructKind::Prefixed(prefix_size, prefix_align) = kind {
let prefix_align =
if let Some(pack) = pack { prefix_align.min(pack) } else { prefix_align };
align = align.max(AbiAndPrefAlign::new(prefix_align));
offset = prefix_size.align_to(prefix_align);
}
for &i in &inverse_memory_index {
let field = fields[i as usize];
if !sized {
bug!("univariant: field #{} of `{}` comes after unsized field", offsets.len(), ty);
}
if field.is_unsized() {
sized = false;
}
// Invariant: offset < dl.obj_size_bound() <= 1<<61
let field_align = if let Some(pack) = pack {
field.align.min(AbiAndPrefAlign::new(pack))
} else {
field.align
};
offset = offset.align_to(field_align.abi);
align = align.max(field_align);
debug!("univariant offset: {:?} field: {:#?}", offset, field);
offsets[i as usize] = offset;
if !repr.hide_niche() {
if let Some(mut niche) = field.largest_niche.clone() {
let available = niche.available(dl);
if available > largest_niche_available {
largest_niche_available = available;
niche.offset += offset;
largest_niche = Some(niche);
}
}
}
offset = offset.checked_add(field.size, dl).ok_or(LayoutError::SizeOverflow(ty))?;
}
if let Some(repr_align) = repr.align {
align = align.max(AbiAndPrefAlign::new(repr_align));
}
debug!("univariant min_size: {:?}", offset);
let min_size = offset;
// As stated above, inverse_memory_index holds field indices by increasing offset.
// This makes it an already-sorted view of the offsets vec.
// To invert it, consider:
// If field 5 has offset 0, offsets[0] is 5, and memory_index[5] should be 0.
// Field 5 would be the first element, so memory_index is i:
// Note: if we didn't optimize, it's already right.
let memory_index =
if optimize { invert_mapping(&inverse_memory_index) } else { inverse_memory_index };
let size = min_size.align_to(align.abi);
let mut abi = Abi::Aggregate { sized };
// Unpack newtype ABIs and find scalar pairs.
if sized && size.bytes() > 0 {
// All other fields must be ZSTs.
let mut non_zst_fields = fields.iter().enumerate().filter(|&(_, f)| !f.is_zst());
match (non_zst_fields.next(), non_zst_fields.next(), non_zst_fields.next()) {
// We have exactly one non-ZST field.
(Some((i, field)), None, None) => {
// Field fills the struct and it has a scalar or scalar pair ABI.
if offsets[i].bytes() == 0 && align.abi == field.align.abi && size == field.size
{
match field.abi {
// For plain scalars, or vectors of them, we can't unpack
// newtypes for `#[repr(C)]`, as that affects C ABIs.
Abi::Scalar(_) | Abi::Vector { .. } if optimize => {
abi = field.abi.clone();
}
// But scalar pairs are Rust-specific and get
// treated as aggregates by C ABIs anyway.
Abi::ScalarPair(..) => {
abi = field.abi.clone();
}
_ => {}
}
}
}
// Two non-ZST fields, and they're both scalars.
(
Some((i, &TyAndLayout { layout: &Layout { abi: Abi::Scalar(ref a), .. }, .. })),
Some((j, &TyAndLayout { layout: &Layout { abi: Abi::Scalar(ref b), .. }, .. })),
None,
) => {
// Order by the memory placement, not source order.
let ((i, a), (j, b)) =
if offsets[i] < offsets[j] { ((i, a), (j, b)) } else { ((j, b), (i, a)) };
let pair = self.scalar_pair(a.clone(), b.clone());
let pair_offsets = match pair.fields {
FieldsShape::Arbitrary { ref offsets, ref memory_index } => {
assert_eq!(memory_index, &[0, 1]);
offsets
}
_ => bug!(),
};
if offsets[i] == pair_offsets[0]
&& offsets[j] == pair_offsets[1]
&& align == pair.align
&& size == pair.size
{
// We can use `ScalarPair` only when it matches our
// already computed layout (including `#[repr(C)]`).
abi = pair.abi;
}
}
_ => {}
}
}
if sized && fields.iter().any(|f| f.abi.is_uninhabited()) {
abi = Abi::Uninhabited;
}
Ok(Layout {
variants: Variants::Single { index: VariantIdx::new(0) },
fields: FieldsShape::Arbitrary { offsets, memory_index },
abi,
largest_niche,
align,
size,
})
}
fn layout_raw_uncached(&self, ty: Ty<'tcx>) -> Result<&'tcx Layout, LayoutError<'tcx>> {
let tcx = self.tcx;
let param_env = self.param_env;
let dl = self.data_layout();
let scalar_unit = |value: Primitive| {
let bits = value.size(dl).bits();
assert!(bits <= 128);
Scalar { value, valid_range: 0..=(!0 >> (128 - bits)) }
};
let scalar = |value: Primitive| tcx.intern_layout(Layout::scalar(self, scalar_unit(value)));
let univariant = |fields: &[TyAndLayout<'_>], repr: &ReprOptions, kind| {
Ok(tcx.intern_layout(self.univariant_uninterned(ty, fields, repr, kind)?))
};
debug_assert!(!ty.has_infer_types_or_consts());
Ok(match *ty.kind() {
// Basic scalars.
ty::Bool => tcx.intern_layout(Layout::scalar(
self,
Scalar { value: Int(I8, false), valid_range: 0..=1 },
)),
ty::Char => tcx.intern_layout(Layout::scalar(
self,
Scalar { value: Int(I32, false), valid_range: 0..=0x10FFFF },
)),
ty::Int(ity) => scalar(Int(Integer::from_attr(dl, attr::SignedInt(ity)), true)),
ty::Uint(ity) => scalar(Int(Integer::from_attr(dl, attr::UnsignedInt(ity)), false)),
ty::Float(fty) => scalar(match fty {
ast::FloatTy::F32 => F32,
ast::FloatTy::F64 => F64,
}),
ty::FnPtr(_) => {
let mut ptr = scalar_unit(Pointer);
ptr.valid_range = 1..=*ptr.valid_range.end();
tcx.intern_layout(Layout::scalar(self, ptr))
}
// The never type.
ty::Never => tcx.intern_layout(Layout {
variants: Variants::Single { index: VariantIdx::new(0) },
fields: FieldsShape::Primitive,
abi: Abi::Uninhabited,
largest_niche: None,
align: dl.i8_align,
size: Size::ZERO,
}),
// Potentially-wide pointers.
ty::Ref(_, pointee, _) | ty::RawPtr(ty::TypeAndMut { ty: pointee, .. }) => {
let mut data_ptr = scalar_unit(Pointer);
if !ty.is_unsafe_ptr() {
data_ptr.valid_range = 1..=*data_ptr.valid_range.end();
}
let pointee = tcx.normalize_erasing_regions(param_env, pointee);
if pointee.is_sized(tcx.at(DUMMY_SP), param_env) {
return Ok(tcx.intern_layout(Layout::scalar(self, data_ptr)));
}
let unsized_part = tcx.struct_tail_erasing_lifetimes(pointee, param_env);
let metadata = match unsized_part.kind() {
ty::Foreign(..) => {
return Ok(tcx.intern_layout(Layout::scalar(self, data_ptr)));
}
ty::Slice(_) | ty::Str => scalar_unit(Int(dl.ptr_sized_integer(), false)),
ty::Dynamic(..) => {
let mut vtable = scalar_unit(Pointer);
vtable.valid_range = 1..=*vtable.valid_range.end();
vtable
}
_ => return Err(LayoutError::Unknown(unsized_part)),
};
// Effectively a (ptr, meta) tuple.
tcx.intern_layout(self.scalar_pair(data_ptr, metadata))
}
// Arrays and slices.
ty::Array(element, mut count) => {
if count.has_projections() {
count = tcx.normalize_erasing_regions(param_env, count);
if count.has_projections() {
return Err(LayoutError::Unknown(ty));
}
}
let count = count.try_eval_usize(tcx, param_env).ok_or(LayoutError::Unknown(ty))?;
let element = self.layout_of(element)?;
let size =
element.size.checked_mul(count, dl).ok_or(LayoutError::SizeOverflow(ty))?;
let abi = if count != 0 && ty.conservative_is_privately_uninhabited(tcx) {
Abi::Uninhabited
} else {
Abi::Aggregate { sized: true }
};
let largest_niche = if count != 0 { element.largest_niche.clone() } else { None };
tcx.intern_layout(Layout {
variants: Variants::Single { index: VariantIdx::new(0) },
fields: FieldsShape::Array { stride: element.size, count },
abi,
largest_niche,
align: element.align,
size,
})
}
ty::Slice(element) => {
let element = self.layout_of(element)?;
tcx.intern_layout(Layout {
variants: Variants::Single { index: VariantIdx::new(0) },
fields: FieldsShape::Array { stride: element.size, count: 0 },
abi: Abi::Aggregate { sized: false },
largest_niche: None,
align: element.align,
size: Size::ZERO,
})
}
ty::Str => tcx.intern_layout(Layout {
variants: Variants::Single { index: VariantIdx::new(0) },
fields: FieldsShape::Array { stride: Size::from_bytes(1), count: 0 },
abi: Abi::Aggregate { sized: false },
largest_niche: None,
align: dl.i8_align,
size: Size::ZERO,
}),
// Odd unit types.
ty::FnDef(..) => univariant(&[], &ReprOptions::default(), StructKind::AlwaysSized)?,
ty::Dynamic(..) | ty::Foreign(..) => {
let mut unit = self.univariant_uninterned(
ty,
&[],
&ReprOptions::default(),
StructKind::AlwaysSized,
)?;
match unit.abi {
Abi::Aggregate { ref mut sized } => *sized = false,
_ => bug!(),
}
tcx.intern_layout(unit)
}
ty::Generator(def_id, substs, _) => self.generator_layout(ty, def_id, substs)?,
ty::Closure(_, ref substs) => {
let tys = substs.as_closure().upvar_tys();
univariant(
&tys.map(|ty| self.layout_of(ty)).collect::<Result<Vec<_>, _>>()?,
&ReprOptions::default(),
StructKind::AlwaysSized,
)?
}
ty::Tuple(tys) => {
let kind =
if tys.len() == 0 { StructKind::AlwaysSized } else { StructKind::MaybeUnsized };
univariant(
&tys.iter()
.map(|k| self.layout_of(k.expect_ty()))
.collect::<Result<Vec<_>, _>>()?,
&ReprOptions::default(),
kind,
)?
}
// SIMD vector types.
ty::Adt(def, ..) if def.repr.simd() => {
let element = self.layout_of(ty.simd_type(tcx))?;
let count = ty.simd_size(tcx);
assert!(count > 0);
let scalar = match element.abi {
Abi::Scalar(ref scalar) => scalar.clone(),
_ => {
tcx.sess.fatal(&format!(
"monomorphising SIMD type `{}` with \
a non-machine element type `{}`",
ty, element.ty
));
}
};
let size =
element.size.checked_mul(count, dl).ok_or(LayoutError::SizeOverflow(ty))?;
let align = dl.vector_align(size);
let size = size.align_to(align.abi);
tcx.intern_layout(Layout {
variants: Variants::Single { index: VariantIdx::new(0) },
fields: FieldsShape::Array { stride: element.size, count },
abi: Abi::Vector { element: scalar, count },
largest_niche: element.largest_niche.clone(),
size,
align,
})
}
// ADTs.
ty::Adt(def, substs) => {
// Cache the field layouts.
let variants = def
.variants
.iter()
.map(|v| {
v.fields
.iter()
.map(|field| self.layout_of(field.ty(tcx, substs)))
.collect::<Result<Vec<_>, _>>()
})
.collect::<Result<IndexVec<VariantIdx, _>, _>>()?;
if def.is_union() {
if def.repr.pack.is_some() && def.repr.align.is_some() {
bug!("union cannot be packed and aligned");
}
let mut align =
if def.repr.pack.is_some() { dl.i8_align } else { dl.aggregate_align };
if let Some(repr_align) = def.repr.align {
align = align.max(AbiAndPrefAlign::new(repr_align));
}
let optimize = !def.repr.inhibit_union_abi_opt();
let mut size = Size::ZERO;
let mut abi = Abi::Aggregate { sized: true };
let index = VariantIdx::new(0);
for field in &variants[index] {
assert!(!field.is_unsized());
align = align.max(field.align);
// If all non-ZST fields have the same ABI, forward this ABI
if optimize && !field.is_zst() {
// Normalize scalar_unit to the maximal valid range
let field_abi = match &field.abi {
Abi::Scalar(x) => Abi::Scalar(scalar_unit(x.value)),
Abi::ScalarPair(x, y) => {
Abi::ScalarPair(scalar_unit(x.value), scalar_unit(y.value))
}
Abi::Vector { element: x, count } => {
Abi::Vector { element: scalar_unit(x.value), count: *count }
}
Abi::Uninhabited | Abi::Aggregate { .. } => {
Abi::Aggregate { sized: true }
}
};
if size == Size::ZERO {
// first non ZST: initialize 'abi'
abi = field_abi;
} else if abi != field_abi {
// different fields have different ABI: reset to Aggregate
abi = Abi::Aggregate { sized: true };
}
}
size = cmp::max(size, field.size);
}
if let Some(pack) = def.repr.pack {
align = align.min(AbiAndPrefAlign::new(pack));
}
return Ok(tcx.intern_layout(Layout {
variants: Variants::Single { index },
fields: FieldsShape::Union(
NonZeroUsize::new(variants[index].len())
.ok_or(LayoutError::Unknown(ty))?,
),
abi,
largest_niche: None,
align,
size: size.align_to(align.abi),
}));
}
// 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).
// See issue #49298 for more details on the need to leave space
// for non-ZST uninhabited data (mostly partial initialization).
let absent = |fields: &[TyAndLayout<'_>]| {
let uninhabited = fields.iter().any(|f| f.abi.is_uninhabited());
let is_zst = fields.iter().all(|f| f.is_zst());
uninhabited && is_zst
};
let (present_first, present_second) = {
let mut present_variants = variants
.iter_enumerated()
.filter_map(|(i, v)| if absent(v) { None } else { Some(i) });
(present_variants.next(), present_variants.next())
};
let present_first = match present_first {
Some(present_first) => present_first,
// Uninhabited because it has no variants, or only absent ones.
None if def.is_enum() => return tcx.layout_raw(param_env.and(tcx.types.never)),
// If it's a struct, still compute a layout so that we can still compute the
// field offsets.
None => VariantIdx::new(0),
};
let is_struct = !def.is_enum() ||
// Only one variant is present.
(present_second.is_none() &&
// Representation optimizations are allowed.
!def.repr.inhibit_enum_layout_opt());
if is_struct {
// Struct, or univariant enum equivalent to a struct.
// (Typechecking will reject discriminant-sizing attrs.)
let v = present_first;
let kind = if def.is_enum() || variants[v].is_empty() {
StructKind::AlwaysSized
} else {
let param_env = tcx.param_env(def.did);
let last_field = def.variants[v].fields.last().unwrap();
let always_sized =
tcx.type_of(last_field.did).is_sized(tcx.at(DUMMY_SP), param_env);
if !always_sized {
StructKind::MaybeUnsized
} else {
StructKind::AlwaysSized
}
};
let mut st = self.univariant_uninterned(ty, &variants[v], &def.repr, kind)?;
st.variants = Variants::Single { index: v };
let (start, end) = self.tcx.layout_scalar_valid_range(def.did);
match st.abi {
Abi::Scalar(ref mut scalar) | Abi::ScalarPair(ref mut scalar, _) => {
// the asserts ensure that we are not using the
// `#[rustc_layout_scalar_valid_range(n)]`
// attribute to widen the range of anything as that would probably
// result in UB somewhere
// FIXME(eddyb) the asserts are probably not needed,
// as larger validity ranges would result in missed
// optimizations, *not* wrongly assuming the inner
// value is valid. e.g. unions enlarge validity ranges,
// because the values may be uninitialized.
if let Bound::Included(start) = start {
// FIXME(eddyb) this might be incorrect - it doesn't
// account for wrap-around (end < start) ranges.
assert!(*scalar.valid_range.start() <= start);
scalar.valid_range = start..=*scalar.valid_range.end();
}
if let Bound::Included(end) = end {
// FIXME(eddyb) this might be incorrect - it doesn't
// account for wrap-around (end < start) ranges.
assert!(*scalar.valid_range.end() >= end);
scalar.valid_range = *scalar.valid_range.start()..=end;
}
// Update `largest_niche` if we have introduced a larger niche.
let niche = if def.repr.hide_niche() {
None
} else {
Niche::from_scalar(dl, Size::ZERO, scalar.clone())
};
if let Some(niche) = niche {
match &st.largest_niche {
Some(largest_niche) => {
// Replace the existing niche even if they're equal,
// because this one is at a lower offset.
if largest_niche.available(dl) <= niche.available(dl) {
st.largest_niche = Some(niche);
}
}
None => st.largest_niche = Some(niche),
}
}
}
_ => assert!(
start == Bound::Unbounded && end == Bound::Unbounded,
"nonscalar layout for layout_scalar_valid_range type {:?}: {:#?}",
def,
st,
),
}
return Ok(tcx.intern_layout(st));
}
// At this point, we have handled all unions and
// structs. (We have also handled univariant enums
// that allow representation optimization.)
assert!(def.is_enum());
// The current code for niche-filling relies on variant indices
// instead of actual discriminants, so dataful enums with
// explicit discriminants (RFC #2363) would misbehave.
let no_explicit_discriminants = def
.variants
.iter_enumerated()
.all(|(i, v)| v.discr == ty::VariantDiscr::Relative(i.as_u32()));
let mut niche_filling_layout = None;
// Niche-filling enum optimization.
if !def.repr.inhibit_enum_layout_opt() && no_explicit_discriminants {
let mut dataful_variant = None;
let mut niche_variants = VariantIdx::MAX..=VariantIdx::new(0);
// Find one non-ZST variant.
'variants: for (v, fields) in variants.iter_enumerated() {
if absent(fields) {
continue 'variants;
}
for f in fields {
if !f.is_zst() {
if dataful_variant.is_none() {
dataful_variant = Some(v);
continue 'variants;
} else {
dataful_variant = None;
break 'variants;
}
}
}
niche_variants = *niche_variants.start().min(&v)..=v;
}
if niche_variants.start() > niche_variants.end() {
dataful_variant = None;
}
if let Some(i) = dataful_variant {
let count = (niche_variants.end().as_u32()
- niche_variants.start().as_u32()
+ 1) as u128;
// Find the field with the largest niche
let niche_candidate = variants[i]
.iter()
.enumerate()
.filter_map(|(j, &field)| Some((j, field.largest_niche.as_ref()?)))
.max_by_key(|(_, niche)| niche.available(dl));
if let Some((field_index, niche, (niche_start, niche_scalar))) =
niche_candidate.and_then(|(field_index, niche)| {
Some((field_index, niche, niche.reserve(self, count)?))
})
{
let mut align = dl.aggregate_align;
let st = variants
.iter_enumerated()
.map(|(j, v)| {
let mut st = self.univariant_uninterned(
ty,
v,
&def.repr,
StructKind::AlwaysSized,
)?;
st.variants = Variants::Single { index: j };
align = align.max(st.align);
Ok(st)
})
.collect::<Result<IndexVec<VariantIdx, _>, _>>()?;
let offset = st[i].fields.offset(field_index) + niche.offset;
let size = st[i].size;
let abi = if st.iter().all(|v| v.abi.is_uninhabited()) {
Abi::Uninhabited
} else {
match st[i].abi {
Abi::Scalar(_) => Abi::Scalar(niche_scalar.clone()),
Abi::ScalarPair(ref first, ref second) => {
// We need to use scalar_unit to reset the
// valid range to the maximal one for that
// primitive, because only the niche is
// guaranteed to be initialised, not the
// other primitive.
if offset.bytes() == 0 {
Abi::ScalarPair(
niche_scalar.clone(),
scalar_unit(second.value),
)
} else {
Abi::ScalarPair(
scalar_unit(first.value),
niche_scalar.clone(),
)
}
}
_ => Abi::Aggregate { sized: true },
}
};
let largest_niche =
Niche::from_scalar(dl, offset, niche_scalar.clone());
niche_filling_layout = Some(Layout {
variants: Variants::Multiple {
tag: niche_scalar,
tag_encoding: TagEncoding::Niche {
dataful_variant: i,
niche_variants,
niche_start,
},
tag_field: 0,
variants: st,
},
fields: FieldsShape::Arbitrary {
offsets: vec![offset],
memory_index: vec![0],
},
abi,
largest_niche,
size,
align,
});
}
}
}
let (mut min, mut max) = (i128::MAX, i128::MIN);
let discr_type = def.repr.discr_type();
let bits = Integer::from_attr(self, discr_type).size().bits();
for (i, discr) in def.discriminants(tcx) {
if variants[i].iter().any(|f| f.abi.is_uninhabited()) {
continue;
}
let mut x = discr.val as i128;
if discr_type.is_signed() {
// sign extend the raw representation to be an i128
x = (x << (128 - bits)) >> (128 - bits);
}
if x < min {
min = x;
}
if x > max {
max = x;
}