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place.rs
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place.rs
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use super::operand::OperandValue;
use super::{FunctionCx, LocalRef};
use crate::common::IntPredicate;
use crate::glue;
use crate::traits::*;
use crate::MemFlags;
use rustc_middle::mir;
use rustc_middle::mir::tcx::PlaceTy;
use rustc_middle::ty::layout::{HasTyCtxt, TyAndLayout};
use rustc_middle::ty::{self, Ty};
use rustc_target::abi::{Abi, Align, FieldsShape, Int, TagEncoding};
use rustc_target::abi::{LayoutOf, VariantIdx, Variants};
#[derive(Copy, Clone, Debug)]
pub struct PlaceRef<'tcx, V> {
/// A pointer to the contents of the place.
pub llval: V,
/// This place's extra data if it is unsized, or `None` if null.
pub llextra: Option<V>,
/// The monomorphized type of this place, including variant information.
pub layout: TyAndLayout<'tcx>,
/// The alignment we know for this place.
pub align: Align,
}
impl<'a, 'tcx, V: CodegenObject> PlaceRef<'tcx, V> {
pub fn new_sized(llval: V, layout: TyAndLayout<'tcx>) -> PlaceRef<'tcx, V> {
assert!(!layout.is_unsized());
PlaceRef { llval, llextra: None, layout, align: layout.align.abi }
}
pub fn new_sized_aligned(
llval: V,
layout: TyAndLayout<'tcx>,
align: Align,
) -> PlaceRef<'tcx, V> {
assert!(!layout.is_unsized());
PlaceRef { llval, llextra: None, layout, align }
}
// FIXME(eddyb) pass something else for the name so no work is done
// unless LLVM IR names are turned on (e.g. for `--emit=llvm-ir`).
pub fn alloca<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
bx: &mut Bx,
layout: TyAndLayout<'tcx>,
) -> Self {
assert!(!layout.is_unsized(), "tried to statically allocate unsized place");
let tmp = bx.alloca(bx.cx().backend_type(layout), layout.align.abi);
Self::new_sized(tmp, layout)
}
/// Returns a place for an indirect reference to an unsized place.
// FIXME(eddyb) pass something else for the name so no work is done
// unless LLVM IR names are turned on (e.g. for `--emit=llvm-ir`).
pub fn alloca_unsized_indirect<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
bx: &mut Bx,
layout: TyAndLayout<'tcx>,
) -> Self {
assert!(layout.is_unsized(), "tried to allocate indirect place for sized values");
let ptr_ty = bx.cx().tcx().mk_mut_ptr(layout.ty);
let ptr_layout = bx.cx().layout_of(ptr_ty);
Self::alloca(bx, ptr_layout)
}
pub fn len<Cx: ConstMethods<'tcx, Value = V>>(&self, cx: &Cx) -> V {
if let FieldsShape::Array { count, .. } = self.layout.fields {
if self.layout.is_unsized() {
assert_eq!(count, 0);
self.llextra.unwrap()
} else {
cx.const_usize(count)
}
} else {
bug!("unexpected layout `{:#?}` in PlaceRef::len", self.layout)
}
}
}
impl<'a, 'tcx, V: CodegenObject> PlaceRef<'tcx, V> {
/// Access a field, at a point when the value's case is known.
pub fn project_field<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
bx: &mut Bx,
ix: usize,
) -> Self {
let field = self.layout.field(bx.cx(), ix);
let offset = self.layout.fields.offset(ix);
let effective_field_align = self.align.restrict_for_offset(offset);
let mut simple = || {
let llval = match self.layout.abi {
_ if offset.bytes() == 0 => {
// Unions and newtypes only use an offset of 0.
// Also handles the first field of Scalar, ScalarPair, and Vector layouts.
self.llval
}
Abi::ScalarPair(ref a, ref b)
if offset == a.value.size(bx.cx()).align_to(b.value.align(bx.cx()).abi) =>
{
// Offset matches second field.
bx.struct_gep(self.llval, 1)
}
Abi::Scalar(_) | Abi::ScalarPair(..) | Abi::Vector { .. } if field.is_zst() => {
// ZST fields are not included in Scalar, ScalarPair, and Vector layouts, so manually offset the pointer.
let byte_ptr = bx.pointercast(self.llval, bx.cx().type_i8p());
bx.gep(byte_ptr, &[bx.const_usize(offset.bytes())])
}
Abi::Scalar(_) | Abi::ScalarPair(..) => {
// All fields of Scalar and ScalarPair layouts must have been handled by this point.
// Vector layouts have additional fields for each element of the vector, so don't panic in that case.
bug!(
"offset of non-ZST field `{:?}` does not match layout `{:#?}`",
field,
self.layout
);
}
_ => bx.struct_gep(self.llval, bx.cx().backend_field_index(self.layout, ix)),
};
PlaceRef {
// HACK(eddyb): have to bitcast pointers until LLVM removes pointee types.
llval: bx.pointercast(llval, bx.cx().type_ptr_to(bx.cx().backend_type(field))),
llextra: if bx.cx().type_has_metadata(field.ty) { self.llextra } else { None },
layout: field,
align: effective_field_align,
}
};
// Simple cases, which don't need DST adjustment:
// * no metadata available - just log the case
// * known alignment - sized types, `[T]`, `str` or a foreign type
// * packed struct - there is no alignment padding
match field.ty.kind() {
_ if self.llextra.is_none() => {
debug!(
"unsized field `{}`, of `{:?}` has no metadata for adjustment",
ix, self.llval
);
return simple();
}
_ if !field.is_unsized() => return simple(),
ty::Slice(..) | ty::Str | ty::Foreign(..) => return simple(),
ty::Adt(def, _) => {
if def.repr.packed() {
// FIXME(eddyb) generalize the adjustment when we
// start supporting packing to larger alignments.
assert_eq!(self.layout.align.abi.bytes(), 1);
return simple();
}
}
_ => {}
}
// We need to get the pointer manually now.
// We do this by casting to a `*i8`, then offsetting it by the appropriate amount.
// We do this instead of, say, simply adjusting the pointer from the result of a GEP
// because the field may have an arbitrary alignment in the LLVM representation
// anyway.
//
// To demonstrate:
//
// struct Foo<T: ?Sized> {
// x: u16,
// y: T
// }
//
// The type `Foo<Foo<Trait>>` is represented in LLVM as `{ u16, { u16, u8 }}`, meaning that
// the `y` field has 16-bit alignment.
let meta = self.llextra;
let unaligned_offset = bx.cx().const_usize(offset.bytes());
// Get the alignment of the field
let (_, unsized_align) = glue::size_and_align_of_dst(bx, field.ty, meta);
// Bump the unaligned offset up to the appropriate alignment using the
// following expression:
//
// (unaligned offset + (align - 1)) & -align
// Calculate offset.
let align_sub_1 = bx.sub(unsized_align, bx.cx().const_usize(1u64));
let and_lhs = bx.add(unaligned_offset, align_sub_1);
let and_rhs = bx.neg(unsized_align);
let offset = bx.and(and_lhs, and_rhs);
debug!("struct_field_ptr: DST field offset: {:?}", offset);
// Cast and adjust pointer.
let byte_ptr = bx.pointercast(self.llval, bx.cx().type_i8p());
let byte_ptr = bx.gep(byte_ptr, &[offset]);
// Finally, cast back to the type expected.
let ll_fty = bx.cx().backend_type(field);
debug!("struct_field_ptr: Field type is {:?}", ll_fty);
PlaceRef {
llval: bx.pointercast(byte_ptr, bx.cx().type_ptr_to(ll_fty)),
llextra: self.llextra,
layout: field,
align: effective_field_align,
}
}
/// Obtain the actual discriminant of a value.
pub fn codegen_get_discr<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
bx: &mut Bx,
cast_to: Ty<'tcx>,
) -> V {
let cast_to = bx.cx().immediate_backend_type(bx.cx().layout_of(cast_to));
if self.layout.abi.is_uninhabited() {
return bx.cx().const_undef(cast_to);
}
let (tag_scalar, tag_encoding, tag_field) = match self.layout.variants {
Variants::Single { index } => {
let discr_val = self
.layout
.ty
.discriminant_for_variant(bx.cx().tcx(), index)
.map_or(index.as_u32() as u128, |discr| discr.val);
return bx.cx().const_uint_big(cast_to, discr_val);
}
Variants::Multiple { ref tag, ref tag_encoding, tag_field, .. } => {
(tag, tag_encoding, tag_field)
}
};
// Read the tag/niche-encoded discriminant from memory.
let tag = self.project_field(bx, tag_field);
let tag = bx.load_operand(tag);
// Decode the discriminant (specifically if it's niche-encoded).
match *tag_encoding {
TagEncoding::Direct => {
let signed = match tag_scalar.value {
// We use `i1` for bytes that are always `0` or `1`,
// e.g., `#[repr(i8)] enum E { A, B }`, but we can't
// let LLVM interpret the `i1` as signed, because
// then `i1 1` (i.e., `E::B`) is effectively `i8 -1`.
Int(_, signed) => !tag_scalar.is_bool() && signed,
_ => false,
};
bx.intcast(tag.immediate(), cast_to, signed)
}
TagEncoding::Niche { dataful_variant, ref niche_variants, niche_start } => {
// Rebase from niche values to discriminants, and check
// whether the result is in range for the niche variants.
let niche_llty = bx.cx().immediate_backend_type(tag.layout);
let tag = tag.immediate();
// We first compute the "relative discriminant" (wrt `niche_variants`),
// that is, if `n = niche_variants.end() - niche_variants.start()`,
// we remap `niche_start..=niche_start + n` (which may wrap around)
// to (non-wrap-around) `0..=n`, to be able to check whether the
// discriminant corresponds to a niche variant with one comparison.
// We also can't go directly to the (variant index) discriminant
// and check that it is in the range `niche_variants`, because
// that might not fit in the same type, on top of needing an extra
// comparison (see also the comment on `let niche_discr`).
let relative_discr = if niche_start == 0 {
// Avoid subtracting `0`, which wouldn't work for pointers.
// FIXME(eddyb) check the actual primitive type here.
tag
} else {
bx.sub(tag, bx.cx().const_uint_big(niche_llty, niche_start))
};
let relative_max = niche_variants.end().as_u32() - niche_variants.start().as_u32();
let is_niche = if relative_max == 0 {
// Avoid calling `const_uint`, which wouldn't work for pointers.
// Also use canonical == 0 instead of non-canonical u<= 0.
// FIXME(eddyb) check the actual primitive type here.
bx.icmp(IntPredicate::IntEQ, relative_discr, bx.cx().const_null(niche_llty))
} else {
let relative_max = bx.cx().const_uint(niche_llty, relative_max as u64);
bx.icmp(IntPredicate::IntULE, relative_discr, relative_max)
};
// NOTE(eddyb) this addition needs to be performed on the final
// type, in case the niche itself can't represent all variant
// indices (e.g. `u8` niche with more than `256` variants,
// but enough uninhabited variants so that the remaining variants
// fit in the niche).
// In other words, `niche_variants.end - niche_variants.start`
// is representable in the niche, but `niche_variants.end`
// might not be, in extreme cases.
let niche_discr = {
let relative_discr = if relative_max == 0 {
// HACK(eddyb) since we have only one niche, we know which
// one it is, and we can avoid having a dynamic value here.
bx.cx().const_uint(cast_to, 0)
} else {
bx.intcast(relative_discr, cast_to, false)
};
bx.add(
relative_discr,
bx.cx().const_uint(cast_to, niche_variants.start().as_u32() as u64),
)
};
bx.select(
is_niche,
niche_discr,
bx.cx().const_uint(cast_to, dataful_variant.as_u32() as u64),
)
}
}
}
/// Sets the discriminant for a new value of the given case of the given
/// representation.
pub fn codegen_set_discr<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
&self,
bx: &mut Bx,
variant_index: VariantIdx,
) {
if self.layout.for_variant(bx.cx(), variant_index).abi.is_uninhabited() {
// We play it safe by using a well-defined `abort`, but we could go for immediate UB
// if that turns out to be helpful.
bx.abort();
return;
}
match self.layout.variants {
Variants::Single { index } => {
assert_eq!(index, variant_index);
}
Variants::Multiple { tag_encoding: TagEncoding::Direct, tag_field, .. } => {
let ptr = self.project_field(bx, tag_field);
let to =
self.layout.ty.discriminant_for_variant(bx.tcx(), variant_index).unwrap().val;
bx.store(
bx.cx().const_uint_big(bx.cx().backend_type(ptr.layout), to),
ptr.llval,
ptr.align,
);
}
Variants::Multiple {
tag_encoding:
TagEncoding::Niche { dataful_variant, ref niche_variants, niche_start },
tag_field,
..
} => {
if variant_index != dataful_variant {
if bx.cx().sess().target.arch == "arm"
|| bx.cx().sess().target.arch == "aarch64"
{
// FIXME(#34427): as workaround for LLVM bug on ARM,
// use memset of 0 before assigning niche value.
let fill_byte = bx.cx().const_u8(0);
let size = bx.cx().const_usize(self.layout.size.bytes());
bx.memset(self.llval, fill_byte, size, self.align, MemFlags::empty());
}
let niche = self.project_field(bx, tag_field);
let niche_llty = bx.cx().immediate_backend_type(niche.layout);
let niche_value = variant_index.as_u32() - niche_variants.start().as_u32();
let niche_value = (niche_value as u128).wrapping_add(niche_start);
// FIXME(eddyb): check the actual primitive type here.
let niche_llval = if niche_value == 0 {
// HACK(eddyb): using `c_null` as it works on all types.
bx.cx().const_null(niche_llty)
} else {
bx.cx().const_uint_big(niche_llty, niche_value)
};
OperandValue::Immediate(niche_llval).store(bx, niche);
}
}
}
}
pub fn project_index<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
&self,
bx: &mut Bx,
llindex: V,
) -> Self {
// Statically compute the offset if we can, otherwise just use the element size,
// as this will yield the lowest alignment.
let layout = self.layout.field(bx, 0);
let offset = if let Some(llindex) = bx.const_to_opt_uint(llindex) {
layout.size.checked_mul(llindex, bx).unwrap_or(layout.size)
} else {
layout.size
};
PlaceRef {
llval: bx.inbounds_gep(self.llval, &[bx.cx().const_usize(0), llindex]),
llextra: None,
layout,
align: self.align.restrict_for_offset(offset),
}
}
pub fn project_downcast<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
&self,
bx: &mut Bx,
variant_index: VariantIdx,
) -> Self {
let mut downcast = *self;
downcast.layout = self.layout.for_variant(bx.cx(), variant_index);
// Cast to the appropriate variant struct type.
let variant_ty = bx.cx().backend_type(downcast.layout);
downcast.llval = bx.pointercast(downcast.llval, bx.cx().type_ptr_to(variant_ty));
downcast
}
pub fn storage_live<Bx: BuilderMethods<'a, 'tcx, Value = V>>(&self, bx: &mut Bx) {
bx.lifetime_start(self.llval, self.layout.size);
}
pub fn storage_dead<Bx: BuilderMethods<'a, 'tcx, Value = V>>(&self, bx: &mut Bx) {
bx.lifetime_end(self.llval, self.layout.size);
}
}
impl<'a, 'tcx, Bx: BuilderMethods<'a, 'tcx>> FunctionCx<'a, 'tcx, Bx> {
pub fn codegen_place(
&mut self,
bx: &mut Bx,
place_ref: mir::PlaceRef<'tcx>,
) -> PlaceRef<'tcx, Bx::Value> {
debug!("codegen_place(place_ref={:?})", place_ref);
let cx = self.cx;
let tcx = self.cx.tcx();
let result = match place_ref {
mir::PlaceRef { local, projection: [] } => match self.locals[local] {
LocalRef::Place(place) => {
return place;
}
LocalRef::UnsizedPlace(place) => {
return bx.load_operand(place).deref(cx);
}
LocalRef::Operand(..) => {
bug!("using operand local {:?} as place", place_ref);
}
},
mir::PlaceRef { local, projection: [proj_base @ .., mir::ProjectionElem::Deref] } => {
// Load the pointer from its location.
self.codegen_consume(bx, mir::PlaceRef { local, projection: proj_base })
.deref(bx.cx())
}
mir::PlaceRef { local, projection: &[ref proj_base @ .., elem] } => {
// FIXME turn this recursion into iteration
let cg_base =
self.codegen_place(bx, mir::PlaceRef { local, projection: proj_base });
match elem {
mir::ProjectionElem::Deref => bug!(),
mir::ProjectionElem::Field(ref field, _) => {
cg_base.project_field(bx, field.index())
}
mir::ProjectionElem::Index(index) => {
let index = &mir::Operand::Copy(mir::Place::from(index));
let index = self.codegen_operand(bx, index);
let llindex = index.immediate();
cg_base.project_index(bx, llindex)
}
mir::ProjectionElem::ConstantIndex {
offset,
from_end: false,
min_length: _,
} => {
let lloffset = bx.cx().const_usize(offset as u64);
cg_base.project_index(bx, lloffset)
}
mir::ProjectionElem::ConstantIndex {
offset,
from_end: true,
min_length: _,
} => {
let lloffset = bx.cx().const_usize(offset as u64);
let lllen = cg_base.len(bx.cx());
let llindex = bx.sub(lllen, lloffset);
cg_base.project_index(bx, llindex)
}
mir::ProjectionElem::Subslice { from, to, from_end } => {
let mut subslice =
cg_base.project_index(bx, bx.cx().const_usize(from as u64));
let projected_ty =
PlaceTy::from_ty(cg_base.layout.ty).projection_ty(tcx, elem).ty;
subslice.layout = bx.cx().layout_of(self.monomorphize(&projected_ty));
if subslice.layout.is_unsized() {
assert!(from_end, "slice subslices should be `from_end`");
subslice.llextra = Some(bx.sub(
cg_base.llextra.unwrap(),
bx.cx().const_usize((from as u64) + (to as u64)),
));
}
// Cast the place pointer type to the new
// array or slice type (`*[%_; new_len]`).
subslice.llval = bx.pointercast(
subslice.llval,
bx.cx().type_ptr_to(bx.cx().backend_type(subslice.layout)),
);
subslice
}
mir::ProjectionElem::Downcast(_, v) => cg_base.project_downcast(bx, v),
}
}
};
debug!("codegen_place(place={:?}) => {:?}", place_ref, result);
result
}
pub fn monomorphized_place_ty(&self, place_ref: mir::PlaceRef<'tcx>) -> Ty<'tcx> {
let tcx = self.cx.tcx();
let place_ty = mir::Place::ty_from(place_ref.local, place_ref.projection, self.mir, tcx);
self.monomorphize(&place_ty.ty)
}
}