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operand.rs
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use std::fmt;
use arrayvec::ArrayVec;
use either::Either;
use rustc_abi as abi;
use rustc_abi::{
Align, BackendRepr, FIRST_VARIANT, Primitive, Size, TagEncoding, VariantIdx, Variants,
};
use rustc_middle::mir::interpret::{Pointer, Scalar, alloc_range};
use rustc_middle::mir::{self, ConstValue};
use rustc_middle::ty::Ty;
use rustc_middle::ty::layout::{LayoutOf, TyAndLayout};
use rustc_middle::{bug, span_bug};
use rustc_session::config::OptLevel;
use tracing::{debug, instrument};
use super::place::{PlaceRef, PlaceValue};
use super::{FunctionCx, LocalRef};
use crate::common::IntPredicate;
use crate::traits::*;
use crate::{MemFlags, size_of_val};
/// The representation of a Rust value. The enum variant is in fact
/// uniquely determined by the value's type, but is kept as a
/// safety check.
#[derive(Copy, Clone, Debug)]
pub enum OperandValue<V> {
/// A reference to the actual operand. The data is guaranteed
/// to be valid for the operand's lifetime.
/// The second value, if any, is the extra data (vtable or length)
/// which indicates that it refers to an unsized rvalue.
///
/// An `OperandValue` *must* be this variant for any type for which
/// [`LayoutTypeCodegenMethods::is_backend_ref`] returns `true`.
/// (That basically amounts to "isn't one of the other variants".)
///
/// This holds a [`PlaceValue`] (like a [`PlaceRef`] does) with a pointer
/// to the location holding the value. The type behind that pointer is the
/// one returned by [`LayoutTypeCodegenMethods::backend_type`].
Ref(PlaceValue<V>),
/// A single LLVM immediate value.
///
/// An `OperandValue` *must* be this variant for any type for which
/// [`LayoutTypeCodegenMethods::is_backend_immediate`] returns `true`.
/// The backend value in this variant must be the *immediate* backend type,
/// as returned by [`LayoutTypeCodegenMethods::immediate_backend_type`].
Immediate(V),
/// A pair of immediate LLVM values. Used by wide pointers too.
///
/// An `OperandValue` *must* be this variant for any type for which
/// [`LayoutTypeCodegenMethods::is_backend_scalar_pair`] returns `true`.
/// The backend values in this variant must be the *immediate* backend types,
/// as returned by [`LayoutTypeCodegenMethods::scalar_pair_element_backend_type`]
/// with `immediate: true`.
Pair(V, V),
/// A value taking no bytes, and which therefore needs no LLVM value at all.
///
/// If you ever need a `V` to pass to something, get a fresh poison value
/// from [`ConstCodegenMethods::const_poison`].
///
/// An `OperandValue` *must* be this variant for any type for which
/// `is_zst` on its `Layout` returns `true`. Note however that
/// these values can still require alignment.
ZeroSized,
}
impl<V: CodegenObject> OperandValue<V> {
/// If this is ZeroSized/Immediate/Pair, return an array of the 0/1/2 values.
/// If this is Ref, return the place.
#[inline]
pub(crate) fn immediates_or_place(self) -> Either<ArrayVec<V, 2>, PlaceValue<V>> {
match self {
OperandValue::ZeroSized => Either::Left(ArrayVec::new()),
OperandValue::Immediate(a) => Either::Left(ArrayVec::from_iter([a])),
OperandValue::Pair(a, b) => Either::Left([a, b].into()),
OperandValue::Ref(p) => Either::Right(p),
}
}
/// Given an array of 0/1/2 immediate values, return ZeroSized/Immediate/Pair.
#[inline]
pub(crate) fn from_immediates(immediates: ArrayVec<V, 2>) -> Self {
let mut it = immediates.into_iter();
let Some(a) = it.next() else {
return OperandValue::ZeroSized;
};
let Some(b) = it.next() else {
return OperandValue::Immediate(a);
};
OperandValue::Pair(a, b)
}
/// Treat this value as a pointer and return the data pointer and
/// optional metadata as backend values.
///
/// If you're making a place, use [`Self::deref`] instead.
pub(crate) fn pointer_parts(self) -> (V, Option<V>) {
match self {
OperandValue::Immediate(llptr) => (llptr, None),
OperandValue::Pair(llptr, llextra) => (llptr, Some(llextra)),
_ => bug!("OperandValue cannot be a pointer: {self:?}"),
}
}
/// Treat this value as a pointer and return the place to which it points.
///
/// The pointer immediate doesn't inherently know its alignment,
/// so you need to pass it in. If you want to get it from a type's ABI
/// alignment, then maybe you want [`OperandRef::deref`] instead.
///
/// This is the inverse of [`PlaceValue::address`].
pub(crate) fn deref(self, align: Align) -> PlaceValue<V> {
let (llval, llextra) = self.pointer_parts();
PlaceValue { llval, llextra, align }
}
pub(crate) fn is_expected_variant_for_type<'tcx, Cx: LayoutTypeCodegenMethods<'tcx>>(
&self,
cx: &Cx,
ty: TyAndLayout<'tcx>,
) -> bool {
match self {
OperandValue::ZeroSized => ty.is_zst(),
OperandValue::Immediate(_) => cx.is_backend_immediate(ty),
OperandValue::Pair(_, _) => cx.is_backend_scalar_pair(ty),
OperandValue::Ref(_) => cx.is_backend_ref(ty),
}
}
}
/// An `OperandRef` is an "SSA" reference to a Rust value, along with
/// its type.
///
/// NOTE: unless you know a value's type exactly, you should not
/// generate LLVM opcodes acting on it and instead act via methods,
/// to avoid nasty edge cases. In particular, using `Builder::store`
/// directly is sure to cause problems -- use `OperandRef::store`
/// instead.
#[derive(Copy, Clone)]
pub struct OperandRef<'tcx, V> {
/// The value.
pub val: OperandValue<V>,
/// The layout of value, based on its Rust type.
pub layout: TyAndLayout<'tcx>,
}
impl<V: CodegenObject> fmt::Debug for OperandRef<'_, V> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "OperandRef({:?} @ {:?})", self.val, self.layout)
}
}
impl<'a, 'tcx, V: CodegenObject> OperandRef<'tcx, V> {
pub fn zero_sized(layout: TyAndLayout<'tcx>) -> OperandRef<'tcx, V> {
assert!(layout.is_zst());
OperandRef { val: OperandValue::ZeroSized, layout }
}
pub(crate) fn from_const<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
bx: &mut Bx,
val: mir::ConstValue<'tcx>,
ty: Ty<'tcx>,
) -> Self {
let layout = bx.layout_of(ty);
let val = match val {
ConstValue::Scalar(x) => {
let BackendRepr::Scalar(scalar) = layout.backend_repr else {
bug!("from_const: invalid ByVal layout: {:#?}", layout);
};
let llval = bx.scalar_to_backend(x, scalar, bx.immediate_backend_type(layout));
OperandValue::Immediate(llval)
}
ConstValue::ZeroSized => return OperandRef::zero_sized(layout),
ConstValue::Slice { data, meta } => {
let BackendRepr::ScalarPair(a_scalar, _) = layout.backend_repr else {
bug!("from_const: invalid ScalarPair layout: {:#?}", layout);
};
let a = Scalar::from_pointer(
Pointer::new(bx.tcx().reserve_and_set_memory_alloc(data).into(), Size::ZERO),
&bx.tcx(),
);
let a_llval = bx.scalar_to_backend(
a,
a_scalar,
bx.scalar_pair_element_backend_type(layout, 0, true),
);
let b_llval = bx.const_usize(meta);
OperandValue::Pair(a_llval, b_llval)
}
ConstValue::Indirect { alloc_id, offset } => {
let alloc = bx.tcx().global_alloc(alloc_id).unwrap_memory();
return Self::from_const_alloc(bx, layout, alloc, offset);
}
};
OperandRef { val, layout }
}
fn from_const_alloc<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
bx: &mut Bx,
layout: TyAndLayout<'tcx>,
alloc: rustc_middle::mir::interpret::ConstAllocation<'tcx>,
offset: Size,
) -> Self {
let alloc_align = alloc.inner().align;
assert!(alloc_align >= layout.align.abi);
let read_scalar = |start, size, s: abi::Scalar, ty| {
match alloc.0.read_scalar(
bx,
alloc_range(start, size),
/*read_provenance*/ matches!(s.primitive(), abi::Primitive::Pointer(_)),
) {
Ok(val) => bx.scalar_to_backend(val, s, ty),
Err(_) => bx.const_poison(ty),
}
};
// It may seem like all types with `Scalar` or `ScalarPair` ABI are fair game at this point.
// However, `MaybeUninit<u64>` is considered a `Scalar` as far as its layout is concerned --
// and yet cannot be represented by an interpreter `Scalar`, since we have to handle the
// case where some of the bytes are initialized and others are not. So, we need an extra
// check that walks over the type of `mplace` to make sure it is truly correct to treat this
// like a `Scalar` (or `ScalarPair`).
match layout.backend_repr {
BackendRepr::Scalar(s @ abi::Scalar::Initialized { .. }) => {
let size = s.size(bx);
assert_eq!(size, layout.size, "abi::Scalar size does not match layout size");
let val = read_scalar(offset, size, s, bx.immediate_backend_type(layout));
OperandRef { val: OperandValue::Immediate(val), layout }
}
BackendRepr::ScalarPair(
a @ abi::Scalar::Initialized { .. },
b @ abi::Scalar::Initialized { .. },
) => {
let (a_size, b_size) = (a.size(bx), b.size(bx));
let b_offset = (offset + a_size).align_to(b.align(bx).abi);
assert!(b_offset.bytes() > 0);
let a_val = read_scalar(
offset,
a_size,
a,
bx.scalar_pair_element_backend_type(layout, 0, true),
);
let b_val = read_scalar(
b_offset,
b_size,
b,
bx.scalar_pair_element_backend_type(layout, 1, true),
);
OperandRef { val: OperandValue::Pair(a_val, b_val), layout }
}
_ if layout.is_zst() => OperandRef::zero_sized(layout),
_ => {
// Neither a scalar nor scalar pair. Load from a place
// FIXME: should we cache `const_data_from_alloc` to avoid repeating this for the
// same `ConstAllocation`?
let init = bx.const_data_from_alloc(alloc);
let base_addr = bx.static_addr_of(init, alloc_align, None);
let llval = bx.const_ptr_byte_offset(base_addr, offset);
bx.load_operand(PlaceRef::new_sized(llval, layout))
}
}
}
/// Asserts that this operand refers to a scalar and returns
/// a reference to its value.
pub fn immediate(self) -> V {
match self.val {
OperandValue::Immediate(s) => s,
_ => bug!("not immediate: {:?}", self),
}
}
/// Asserts that this operand is a pointer (or reference) and returns
/// the place to which it points. (This requires no code to be emitted
/// as we represent places using the pointer to the place.)
///
/// This uses [`Ty::builtin_deref`] to include the type of the place and
/// assumes the place is aligned to the pointee's usual ABI alignment.
///
/// If you don't need the type, see [`OperandValue::pointer_parts`]
/// or [`OperandValue::deref`].
pub fn deref<Cx: CodegenMethods<'tcx>>(self, cx: &Cx) -> PlaceRef<'tcx, V> {
if self.layout.ty.is_box() {
// Derefer should have removed all Box derefs
bug!("dereferencing {:?} in codegen", self.layout.ty);
}
let projected_ty = self
.layout
.ty
.builtin_deref(true)
.unwrap_or_else(|| bug!("deref of non-pointer {:?}", self));
let layout = cx.layout_of(projected_ty);
self.val.deref(layout.align.abi).with_type(layout)
}
/// If this operand is a `Pair`, we return an aggregate with the two values.
/// For other cases, see `immediate`.
pub fn immediate_or_packed_pair<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
bx: &mut Bx,
) -> V {
if let OperandValue::Pair(a, b) = self.val {
let llty = bx.cx().immediate_backend_type(self.layout);
debug!("Operand::immediate_or_packed_pair: packing {:?} into {:?}", self, llty);
// Reconstruct the immediate aggregate.
let mut llpair = bx.cx().const_poison(llty);
llpair = bx.insert_value(llpair, a, 0);
llpair = bx.insert_value(llpair, b, 1);
llpair
} else {
self.immediate()
}
}
/// If the type is a pair, we return a `Pair`, otherwise, an `Immediate`.
pub fn from_immediate_or_packed_pair<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
bx: &mut Bx,
llval: V,
layout: TyAndLayout<'tcx>,
) -> Self {
let val = if let BackendRepr::ScalarPair(..) = layout.backend_repr {
debug!("Operand::from_immediate_or_packed_pair: unpacking {:?} @ {:?}", llval, layout);
// Deconstruct the immediate aggregate.
let a_llval = bx.extract_value(llval, 0);
let b_llval = bx.extract_value(llval, 1);
OperandValue::Pair(a_llval, b_llval)
} else {
OperandValue::Immediate(llval)
};
OperandRef { val, layout }
}
pub(crate) fn extract_field<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
&self,
fx: &mut FunctionCx<'a, 'tcx, Bx>,
bx: &mut Bx,
i: usize,
) -> Self {
let field = self.layout.field(bx.cx(), i);
let offset = self.layout.fields.offset(i);
if !bx.is_backend_ref(self.layout) && bx.is_backend_ref(field) {
if let BackendRepr::SimdVector { count, .. } = self.layout.backend_repr
&& let BackendRepr::Memory { sized: true } = field.backend_repr
&& count.is_power_of_two()
{
assert_eq!(field.size, self.layout.size);
// This is being deprecated, but for now stdarch still needs it for
// Newtype vector of array, e.g. #[repr(simd)] struct S([i32; 4]);
let place = PlaceRef::alloca(bx, field);
self.val.store(bx, place.val.with_type(self.layout));
return bx.load_operand(place);
} else {
// Part of https://github.com/rust-lang/compiler-team/issues/838
bug!("Non-ref type {self:?} cannot project to ref field type {field:?}");
}
}
let val = if field.is_zst() {
OperandValue::ZeroSized
} else if field.size == self.layout.size {
assert_eq!(offset.bytes(), 0);
fx.codegen_transmute_operand(bx, *self, field).unwrap_or_else(|| {
bug!(
"Expected `codegen_transmute_operand` to handle equal-size \
field {i:?} projection from {self:?} to {field:?}"
)
})
} else {
let (in_scalar, imm) = match (self.val, self.layout.backend_repr) {
// Extract a scalar component from a pair.
(OperandValue::Pair(a_llval, b_llval), BackendRepr::ScalarPair(a, b)) => {
if offset.bytes() == 0 {
assert_eq!(field.size, a.size(bx.cx()));
(Some(a), a_llval)
} else {
assert_eq!(offset, a.size(bx.cx()).align_to(b.align(bx.cx()).abi));
assert_eq!(field.size, b.size(bx.cx()));
(Some(b), b_llval)
}
}
_ => {
span_bug!(fx.mir.span, "OperandRef::extract_field({:?}): not applicable", self)
}
};
OperandValue::Immediate(match field.backend_repr {
BackendRepr::SimdVector { .. } => imm,
BackendRepr::Scalar(out_scalar) => {
let Some(in_scalar) = in_scalar else {
span_bug!(
fx.mir.span,
"OperandRef::extract_field({:?}): missing input scalar for output scalar",
self
)
};
if in_scalar != out_scalar {
// If the backend and backend_immediate types might differ,
// flip back to the backend type then to the new immediate.
// This avoids nop truncations, but still handles things like
// Bools in union fields needs to be truncated.
let backend = bx.from_immediate(imm);
bx.to_immediate_scalar(backend, out_scalar)
} else {
imm
}
}
BackendRepr::ScalarPair(_, _) | BackendRepr::Memory { .. } => bug!(),
})
};
OperandRef { val, layout: field }
}
/// Obtain the actual discriminant of a value.
#[instrument(level = "trace", skip(fx, bx))]
pub fn codegen_get_discr<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
fx: &mut FunctionCx<'a, 'tcx, Bx>,
bx: &mut Bx,
cast_to: Ty<'tcx>,
) -> V {
let dl = &bx.tcx().data_layout;
let cast_to_layout = bx.cx().layout_of(cast_to);
let cast_to = bx.cx().immediate_backend_type(cast_to_layout);
// We check uninhabitedness separately because a type like
// `enum Foo { Bar(i32, !) }` is still reported as `Variants::Single`,
// *not* as `Variants::Empty`.
if self.layout.is_uninhabited() {
return bx.cx().const_poison(cast_to);
}
let (tag_scalar, tag_encoding, tag_field) = match self.layout.variants {
Variants::Empty => unreachable!("we already handled uninhabited types"),
Variants::Single { index } => {
let discr_val =
if let Some(discr) = self.layout.ty.discriminant_for_variant(bx.tcx(), index) {
discr.val
} else {
// This arm is for types which are neither enums nor coroutines,
// and thus for which the only possible "variant" should be the first one.
assert_eq!(index, FIRST_VARIANT);
// There's thus no actual discriminant to return, so we return
// what it would have been if this was a single-variant enum.
0
};
return bx.cx().const_uint_big(cast_to, discr_val);
}
Variants::Multiple { tag, ref tag_encoding, tag_field, .. } => {
(tag, tag_encoding, tag_field)
}
};
// Read the tag/niche-encoded discriminant from memory.
let tag_op = match self.val {
OperandValue::ZeroSized => bug!(),
OperandValue::Immediate(_) | OperandValue::Pair(_, _) => {
self.extract_field(fx, bx, tag_field)
}
OperandValue::Ref(place) => {
let tag = place.with_type(self.layout).project_field(bx, tag_field);
bx.load_operand(tag)
}
};
let tag_imm = tag_op.immediate();
// Decode the discriminant (specifically if it's niche-encoded).
match *tag_encoding {
TagEncoding::Direct => {
let signed = match tag_scalar.primitive() {
// 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`.
Primitive::Int(_, signed) => !tag_scalar.is_bool() && signed,
_ => false,
};
bx.intcast(tag_imm, cast_to, signed)
}
TagEncoding::Niche { untagged_variant, ref niche_variants, niche_start } => {
// Cast to an integer so we don't have to treat a pointer as a
// special case.
let (tag, tag_llty) = match tag_scalar.primitive() {
// FIXME(erikdesjardins): handle non-default addrspace ptr sizes
Primitive::Pointer(_) => {
let t = bx.type_from_integer(dl.ptr_sized_integer());
let tag = bx.ptrtoint(tag_imm, t);
(tag, t)
}
_ => (tag_imm, bx.cx().immediate_backend_type(tag_op.layout)),
};
// Layout ensures that we only get here for cases where the discriminant
// value and the variant index match, since that's all `Niche` can encode.
// But for emphasis and debugging, let's double-check one anyway.
debug_assert_eq!(
self.layout
.ty
.discriminant_for_variant(bx.tcx(), untagged_variant)
.unwrap()
.val,
u128::from(untagged_variant.as_u32()),
);
let relative_max = niche_variants.end().as_u32() - niche_variants.start().as_u32();
let tag_range = tag_scalar.valid_range(&dl);
let tag_size = tag_scalar.size(&dl);
// We have a subrange `niche_start..=niche_end` inside `range`.
// If the value of the tag is inside this subrange, it's a
// "niche value", an increment of the discriminant. Otherwise it
// indicates the untagged variant.
// A general algorithm to extract the discriminant from the tag
// is:
// relative_tag = tag - niche_start
// is_niche = relative_tag <= (ule) relative_max
// discr = if is_niche {
// cast(relative_tag) + niche_variants.start()
// } else {
// untagged_variant
// }
// However, we will likely be able to emit simpler code.
// First, the incredibly-common case of a two-variant enum (like
// `Option` or `Result`) where we only need one check.
if relative_max == 0 {
let niche_start = bx.cx().const_uint_big(tag_llty, niche_start);
let is_natural = bx.icmp(IntPredicate::IntNE, tag, niche_start);
return if untagged_variant == VariantIdx::from_u32(1)
&& *niche_variants.start() == VariantIdx::from_u32(0)
{
// The polarity of the comparison above is picked so we can
// just extend for `Option<T>`, which has these variants.
bx.zext(is_natural, cast_to)
} else {
let tagged_discr =
bx.cx().const_uint(cast_to, u64::from(niche_variants.start().as_u32()));
let untagged_discr =
bx.cx().const_uint(cast_to, u64::from(untagged_variant.as_u32()));
bx.select(is_natural, untagged_discr, tagged_discr)
};
}
let niche_end =
tag_size.truncate(u128::from(relative_max).wrapping_add(niche_start));
// Next, the layout algorithm prefers to put the niches at one end,
// so look for cases where we don't need to calculate a relative_tag
// at all and can just look at the original tag value directly.
// This also lets us move any possibly-wrapping addition to the end
// where it's easiest to get rid of in the normal uses: it's easy
// to optimize `COMPLICATED + 2 == 7` to `COMPLICATED == (7 - 2)`.
{
// Work in whichever size is wider, because it's possible for
// the untagged variant to be further away from the niches than
// is possible to represent in the smaller type.
let (wide_size, wide_ibty) = if cast_to_layout.size > tag_size {
(cast_to_layout.size, cast_to)
} else {
(tag_size, tag_llty)
};
struct NoWrapData<V> {
wide_tag: V,
is_niche: V,
needs_assume: bool,
wide_niche_to_variant: u128,
wide_niche_untagged: u128,
}
let first_variant = u128::from(niche_variants.start().as_u32());
let untagged_variant = u128::from(untagged_variant.as_u32());
let opt_data = if tag_range.no_unsigned_wraparound(tag_size) == Ok(true) {
let wide_tag = bx.zext(tag, wide_ibty);
let extend = |x| x;
let wide_niche_start = extend(niche_start);
let wide_niche_end = extend(niche_end);
debug_assert!(wide_niche_start <= wide_niche_end);
let wide_first_variant = extend(first_variant);
let wide_untagged_variant = extend(untagged_variant);
let wide_niche_to_variant =
wide_first_variant.wrapping_sub(wide_niche_start);
let wide_niche_untagged = wide_size
.truncate(wide_untagged_variant.wrapping_sub(wide_niche_to_variant));
let (is_niche, needs_assume) = if tag_range.start == niche_start {
let end = bx.cx().const_uint_big(tag_llty, niche_end);
(
bx.icmp(IntPredicate::IntULE, tag, end),
wide_niche_untagged <= wide_niche_end,
)
} else if tag_range.end == niche_end {
let start = bx.cx().const_uint_big(tag_llty, niche_start);
(
bx.icmp(IntPredicate::IntUGE, tag, start),
wide_niche_untagged >= wide_niche_start,
)
} else {
bug!()
};
Some(NoWrapData {
wide_tag,
is_niche,
needs_assume,
wide_niche_to_variant,
wide_niche_untagged,
})
} else if tag_range.no_signed_wraparound(tag_size) == Ok(true) {
let wide_tag = bx.sext(tag, wide_ibty);
let extend = |x| tag_size.sign_extend(x);
let wide_niche_start = extend(niche_start);
let wide_niche_end = extend(niche_end);
debug_assert!(wide_niche_start <= wide_niche_end);
let wide_first_variant = extend(first_variant);
let wide_untagged_variant = extend(untagged_variant);
let wide_niche_to_variant =
wide_first_variant.wrapping_sub(wide_niche_start);
let wide_niche_untagged = wide_size.sign_extend(
wide_untagged_variant
.wrapping_sub(wide_niche_to_variant)
.cast_unsigned(),
);
let (is_niche, needs_assume) = if tag_range.start == niche_start {
let end = bx.cx().const_uint_big(tag_llty, niche_end);
(
bx.icmp(IntPredicate::IntSLE, tag, end),
wide_niche_untagged <= wide_niche_end,
)
} else if tag_range.end == niche_end {
let start = bx.cx().const_uint_big(tag_llty, niche_start);
(
bx.icmp(IntPredicate::IntSGE, tag, start),
wide_niche_untagged >= wide_niche_start,
)
} else {
bug!()
};
Some(NoWrapData {
wide_tag,
is_niche,
needs_assume,
wide_niche_to_variant: wide_niche_to_variant.cast_unsigned(),
wide_niche_untagged: wide_niche_untagged.cast_unsigned(),
})
} else {
None
};
if let Some(NoWrapData {
wide_tag,
is_niche,
needs_assume,
wide_niche_to_variant,
wide_niche_untagged,
}) = opt_data
{
let wide_niche_untagged =
bx.cx().const_uint_big(wide_ibty, wide_niche_untagged);
if needs_assume && bx.cx().sess().opts.optimize != OptLevel::No {
let not_untagged =
bx.icmp(IntPredicate::IntNE, wide_tag, wide_niche_untagged);
bx.assume(not_untagged);
}
let wide_niche = bx.select(is_niche, wide_tag, wide_niche_untagged);
let cast_niche = bx.trunc(wide_niche, cast_to);
let discr = if wide_niche_to_variant == 0 {
cast_niche
} else {
let niche_to_variant =
bx.cx().const_uint_big(cast_to, wide_niche_to_variant);
bx.add(cast_niche, niche_to_variant)
};
return discr;
}
}
// Otherwise the special cases don't apply,
// so we'll have to go with the general algorithm.
let relative_tag = bx.sub(tag, bx.cx().const_uint_big(tag_llty, niche_start));
let relative_discr = bx.intcast(relative_tag, cast_to, false);
let is_niche = bx.icmp(
IntPredicate::IntULE,
relative_tag,
bx.cx().const_uint(tag_llty, u64::from(relative_max)),
);
// Thanks to parameter attributes and load metadata, LLVM already knows
// the general valid range of the tag. It's possible, though, for there
// to be an impossible value *in the middle*, which those ranges don't
// communicate, so it's worth an `assume` to let the optimizer know.
if niche_variants.contains(&untagged_variant)
&& bx.cx().sess().opts.optimize != OptLevel::No
{
let impossible =
u64::from(untagged_variant.as_u32() - niche_variants.start().as_u32());
let impossible = bx.cx().const_uint(tag_llty, impossible);
let ne = bx.icmp(IntPredicate::IntNE, relative_tag, impossible);
bx.assume(ne);
}
let delta = niche_variants.start().as_u32();
let tagged_discr = if delta == 0 {
relative_discr
} else {
bx.add(relative_discr, bx.cx().const_uint(cast_to, u64::from(delta)))
};
let discr = bx.select(
is_niche,
tagged_discr,
bx.cx().const_uint(cast_to, untagged_variant.as_u32() as u64),
);
// In principle we could insert assumes on the possible range of `discr`, but
// currently in LLVM this isn't worth it because the original `tag` will
// have either a `range` parameter attribute or `!range` metadata,
// or come from a `transmute` that already `assume`d it.
discr
}
}
}
}
impl<'a, 'tcx, V: CodegenObject> OperandValue<V> {
/// Returns an `OperandValue` that's generally UB to use in any way.
///
/// Depending on the `layout`, returns `ZeroSized` for ZSTs, an `Immediate` or
/// `Pair` containing poison value(s), or a `Ref` containing a poison pointer.
///
/// Supports sized types only.
pub fn poison<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
bx: &mut Bx,
layout: TyAndLayout<'tcx>,
) -> OperandValue<V> {
assert!(layout.is_sized());
if layout.is_zst() {
OperandValue::ZeroSized
} else if bx.cx().is_backend_immediate(layout) {
let ibty = bx.cx().immediate_backend_type(layout);
OperandValue::Immediate(bx.const_poison(ibty))
} else if bx.cx().is_backend_scalar_pair(layout) {
let ibty0 = bx.cx().scalar_pair_element_backend_type(layout, 0, true);
let ibty1 = bx.cx().scalar_pair_element_backend_type(layout, 1, true);
OperandValue::Pair(bx.const_poison(ibty0), bx.const_poison(ibty1))
} else {
let ptr = bx.cx().type_ptr();
OperandValue::Ref(PlaceValue::new_sized(bx.const_poison(ptr), layout.align.abi))
}
}
pub fn store<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
bx: &mut Bx,
dest: PlaceRef<'tcx, V>,
) {
self.store_with_flags(bx, dest, MemFlags::empty());
}
pub fn volatile_store<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
bx: &mut Bx,
dest: PlaceRef<'tcx, V>,
) {
self.store_with_flags(bx, dest, MemFlags::VOLATILE);
}
pub fn unaligned_volatile_store<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
bx: &mut Bx,
dest: PlaceRef<'tcx, V>,
) {
self.store_with_flags(bx, dest, MemFlags::VOLATILE | MemFlags::UNALIGNED);
}
pub fn nontemporal_store<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
bx: &mut Bx,
dest: PlaceRef<'tcx, V>,
) {
self.store_with_flags(bx, dest, MemFlags::NONTEMPORAL);
}
pub(crate) fn store_with_flags<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
bx: &mut Bx,
dest: PlaceRef<'tcx, V>,
flags: MemFlags,
) {
debug!("OperandRef::store: operand={:?}, dest={:?}", self, dest);
match self {
OperandValue::ZeroSized => {
// Avoid generating stores of zero-sized values, because the only way to have a
// zero-sized value is through `undef`/`poison`, and the store itself is useless.
}
OperandValue::Ref(val) => {
assert!(dest.layout.is_sized(), "cannot directly store unsized values");
if val.llextra.is_some() {
bug!("cannot directly store unsized values");
}
bx.typed_place_copy_with_flags(dest.val, val, dest.layout, flags);
}
OperandValue::Immediate(s) => {
let val = bx.from_immediate(s);
bx.store_with_flags(val, dest.val.llval, dest.val.align, flags);
}
OperandValue::Pair(a, b) => {
let BackendRepr::ScalarPair(a_scalar, b_scalar) = dest.layout.backend_repr else {
bug!("store_with_flags: invalid ScalarPair layout: {:#?}", dest.layout);
};
let b_offset = a_scalar.size(bx).align_to(b_scalar.align(bx).abi);
let val = bx.from_immediate(a);
let align = dest.val.align;
bx.store_with_flags(val, dest.val.llval, align, flags);
let llptr = bx.inbounds_ptradd(dest.val.llval, bx.const_usize(b_offset.bytes()));
let val = bx.from_immediate(b);
let align = dest.val.align.restrict_for_offset(b_offset);
bx.store_with_flags(val, llptr, align, flags);
}
}
}
pub fn store_unsized<Bx: BuilderMethods<'a, 'tcx, Value = V>>(
self,
bx: &mut Bx,
indirect_dest: PlaceRef<'tcx, V>,
) {
debug!("OperandRef::store_unsized: operand={:?}, indirect_dest={:?}", self, indirect_dest);
// `indirect_dest` must have `*mut T` type. We extract `T` out of it.
let unsized_ty = indirect_dest
.layout
.ty
.builtin_deref(true)
.unwrap_or_else(|| bug!("indirect_dest has non-pointer type: {:?}", indirect_dest));
let OperandValue::Ref(PlaceValue { llval: llptr, llextra: Some(llextra), .. }) = self
else {
bug!("store_unsized called with a sized value (or with an extern type)")
};
// Allocate an appropriate region on the stack, and copy the value into it. Since alloca
// doesn't support dynamic alignment, we allocate an extra align - 1 bytes, and align the
// pointer manually.
let (size, align) = size_of_val::size_and_align_of_dst(bx, unsized_ty, Some(llextra));
let one = bx.const_usize(1);
let align_minus_1 = bx.sub(align, one);
let size_extra = bx.add(size, align_minus_1);
let min_align = Align::ONE;
let alloca = bx.dynamic_alloca(size_extra, min_align);
let address = bx.ptrtoint(alloca, bx.type_isize());
let neg_address = bx.neg(address);
let offset = bx.and(neg_address, align_minus_1);
let dst = bx.inbounds_ptradd(alloca, offset);
bx.memcpy(dst, min_align, llptr, min_align, size, MemFlags::empty());
// Store the allocated region and the extra to the indirect place.
let indirect_operand = OperandValue::Pair(dst, llextra);
indirect_operand.store(bx, indirect_dest);
}
}
impl<'a, 'tcx, Bx: BuilderMethods<'a, 'tcx>> FunctionCx<'a, 'tcx, Bx> {
fn maybe_codegen_consume_direct(
&mut self,
bx: &mut Bx,
place_ref: mir::PlaceRef<'tcx>,
) -> Option<OperandRef<'tcx, Bx::Value>> {
debug!("maybe_codegen_consume_direct(place_ref={:?})", place_ref);
match self.locals[place_ref.local] {
LocalRef::Operand(mut o) => {
// Moves out of scalar and scalar pair fields are trivial.
for elem in place_ref.projection.iter() {
match elem {
mir::ProjectionElem::Field(f, _) => {
assert!(
!o.layout.ty.is_any_ptr(),
"Bad PlaceRef: destructing pointers should use cast/PtrMetadata, \
but tried to access field {f:?} of pointer {o:?}",
);
o = o.extract_field(self, bx, f.index());
}
mir::ProjectionElem::Index(_)
| mir::ProjectionElem::ConstantIndex { .. } => {
// ZSTs don't require any actual memory access.
// FIXME(eddyb) deduplicate this with the identical
// checks in `codegen_consume` and `extract_field`.
let elem = o.layout.field(bx.cx(), 0);
if elem.is_zst() {
o = OperandRef::zero_sized(elem);
} else {
return None;
}
}
_ => return None,
}
}
Some(o)
}
LocalRef::PendingOperand => {
bug!("use of {:?} before def", place_ref);
}
LocalRef::Place(..) | LocalRef::UnsizedPlace(..) => {
// watch out for locals that do not have an
// alloca; they are handled somewhat differently
None
}
}
}
pub fn codegen_consume(
&mut self,
bx: &mut Bx,
place_ref: mir::PlaceRef<'tcx>,
) -> OperandRef<'tcx, Bx::Value> {
debug!("codegen_consume(place_ref={:?})", place_ref);
let ty = self.monomorphized_place_ty(place_ref);
let layout = bx.cx().layout_of(ty);
// ZSTs don't require any actual memory access.
if layout.is_zst() {
return OperandRef::zero_sized(layout);
}
if let Some(o) = self.maybe_codegen_consume_direct(bx, place_ref) {
return o;
}
// for most places, to consume them we just load them
// out from their home
let place = self.codegen_place(bx, place_ref);
bx.load_operand(place)
}
pub fn codegen_operand(
&mut self,
bx: &mut Bx,
operand: &mir::Operand<'tcx>,
) -> OperandRef<'tcx, Bx::Value> {
debug!("codegen_operand(operand={:?})", operand);
match *operand {
mir::Operand::Copy(ref place) | mir::Operand::Move(ref place) => {
self.codegen_consume(bx, place.as_ref())
}
mir::Operand::Constant(ref constant) => {
let constant_ty = self.monomorphize(constant.ty());
// Most SIMD vector constants should be passed as immediates.
// (In particular, some intrinsics really rely on this.)
if constant_ty.is_simd() {
// However, some SIMD types do not actually use the vector ABI
// (in particular, packed SIMD types do not). Ensure we exclude those.
let layout = bx.layout_of(constant_ty);
if let BackendRepr::SimdVector { .. } = layout.backend_repr {
let (llval, ty) = self.immediate_const_vector(bx, constant);
return OperandRef {
val: OperandValue::Immediate(llval),
layout: bx.layout_of(ty),
};
}
}
self.eval_mir_constant_to_operand(bx, constant)
}
}
}
}