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place.rs
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place.rs
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//! Computations on places -- field projections, going from mir::Place, and writing
//! into a place.
//! All high-level functions to write to memory work on places as destinations.
use std::convert::TryFrom;
use std::hash::Hash;
use rustc::mir;
use rustc::mir::interpret::truncate;
use rustc::ty::layout::{
self, Align, HasDataLayout, LayoutOf, PrimitiveExt, Size, TyLayout, VariantIdx,
};
use rustc::ty::{self, Ty};
use rustc_macros::HashStable;
use super::{
AllocId, AllocMap, Allocation, AllocationExtra, ImmTy, Immediate, InterpCx, InterpResult,
LocalValue, Machine, MemoryKind, OpTy, Operand, Pointer, PointerArithmetic, RawConst, Scalar,
ScalarMaybeUndef,
};
#[derive(Copy, Clone, Debug, Hash, PartialEq, Eq, HashStable)]
/// Information required for the sound usage of a `MemPlace`.
pub enum MemPlaceMeta<Tag = (), Id = AllocId> {
/// The unsized payload (e.g. length for slices or vtable pointer for trait objects).
Meta(Scalar<Tag, Id>),
/// `Sized` types or unsized `extern type`
None,
/// The address of this place may not be taken. This protects the `MemPlace` from coming from
/// a ZST Operand with a backing allocation and being converted to an integer address. This
/// should be impossible, because you can't take the address of an operand, but this is a second
/// protection layer ensuring that we don't mess up.
Poison,
}
impl<Tag, Id> MemPlaceMeta<Tag, Id> {
pub fn unwrap_meta(self) -> Scalar<Tag, Id> {
match self {
Self::Meta(s) => s,
Self::None | Self::Poison => {
bug!("expected wide pointer extra data (e.g. slice length or trait object vtable)")
}
}
}
fn has_meta(self) -> bool {
match self {
Self::Meta(_) => true,
Self::None | Self::Poison => false,
}
}
}
impl<Tag> MemPlaceMeta<Tag> {
pub fn erase_tag(self) -> MemPlaceMeta<()> {
match self {
Self::Meta(s) => MemPlaceMeta::Meta(s.erase_tag()),
Self::None => MemPlaceMeta::None,
Self::Poison => MemPlaceMeta::Poison,
}
}
}
#[derive(Copy, Clone, Debug, Hash, PartialEq, Eq, HashStable)]
pub struct MemPlace<Tag = (), Id = AllocId> {
/// A place may have an integral pointer for ZSTs, and since it might
/// be turned back into a reference before ever being dereferenced.
/// However, it may never be undef.
pub ptr: Scalar<Tag, Id>,
pub align: Align,
/// Metadata for unsized places. Interpretation is up to the type.
/// Must not be present for sized types, but can be missing for unsized types
/// (e.g., `extern type`).
pub meta: MemPlaceMeta<Tag, Id>,
}
#[derive(Copy, Clone, Debug, Hash, PartialEq, Eq, HashStable)]
pub enum Place<Tag = (), Id = AllocId> {
/// A place referring to a value allocated in the `Memory` system.
Ptr(MemPlace<Tag, Id>),
/// To support alloc-free locals, we are able to write directly to a local.
/// (Without that optimization, we'd just always be a `MemPlace`.)
Local { frame: usize, local: mir::Local },
}
#[derive(Copy, Clone, Debug)]
pub struct PlaceTy<'tcx, Tag = ()> {
place: Place<Tag>, // Keep this private; it helps enforce invariants.
pub layout: TyLayout<'tcx>,
}
impl<'tcx, Tag> ::std::ops::Deref for PlaceTy<'tcx, Tag> {
type Target = Place<Tag>;
#[inline(always)]
fn deref(&self) -> &Place<Tag> {
&self.place
}
}
/// A MemPlace with its layout. Constructing it is only possible in this module.
#[derive(Copy, Clone, Debug, Hash, Eq, PartialEq)]
pub struct MPlaceTy<'tcx, Tag = ()> {
mplace: MemPlace<Tag>,
pub layout: TyLayout<'tcx>,
}
impl<'tcx, Tag> ::std::ops::Deref for MPlaceTy<'tcx, Tag> {
type Target = MemPlace<Tag>;
#[inline(always)]
fn deref(&self) -> &MemPlace<Tag> {
&self.mplace
}
}
impl<'tcx, Tag> From<MPlaceTy<'tcx, Tag>> for PlaceTy<'tcx, Tag> {
#[inline(always)]
fn from(mplace: MPlaceTy<'tcx, Tag>) -> Self {
PlaceTy { place: Place::Ptr(mplace.mplace), layout: mplace.layout }
}
}
impl<Tag> MemPlace<Tag> {
/// Replace ptr tag, maintain vtable tag (if any)
#[inline]
pub fn replace_tag(self, new_tag: Tag) -> Self {
MemPlace { ptr: self.ptr.erase_tag().with_tag(new_tag), align: self.align, meta: self.meta }
}
#[inline]
pub fn erase_tag(self) -> MemPlace {
MemPlace { ptr: self.ptr.erase_tag(), align: self.align, meta: self.meta.erase_tag() }
}
#[inline(always)]
fn from_scalar_ptr(ptr: Scalar<Tag>, align: Align) -> Self {
MemPlace { ptr, align, meta: MemPlaceMeta::None }
}
/// Produces a Place that will error if attempted to be read from or written to
#[inline(always)]
fn null(cx: &impl HasDataLayout) -> Self {
Self::from_scalar_ptr(Scalar::ptr_null(cx), Align::from_bytes(1).unwrap())
}
#[inline(always)]
pub fn from_ptr(ptr: Pointer<Tag>, align: Align) -> Self {
Self::from_scalar_ptr(ptr.into(), align)
}
/// Turn a mplace into a (thin or wide) pointer, as a reference, pointing to the same space.
/// This is the inverse of `ref_to_mplace`.
#[inline(always)]
pub fn to_ref(self) -> Immediate<Tag> {
match self.meta {
MemPlaceMeta::None => Immediate::Scalar(self.ptr.into()),
MemPlaceMeta::Meta(meta) => Immediate::ScalarPair(self.ptr.into(), meta.into()),
MemPlaceMeta::Poison => bug!(
"MPlaceTy::dangling may never be used to produce a \
place that will have the address of its pointee taken"
),
}
}
pub fn offset(
self,
offset: Size,
meta: MemPlaceMeta<Tag>,
cx: &impl HasDataLayout,
) -> InterpResult<'tcx, Self> {
Ok(MemPlace {
ptr: self.ptr.ptr_offset(offset, cx)?,
align: self.align.restrict_for_offset(offset),
meta,
})
}
}
impl<'tcx, Tag> MPlaceTy<'tcx, Tag> {
/// Produces a MemPlace that works for ZST but nothing else
#[inline]
pub fn dangling(layout: TyLayout<'tcx>, cx: &impl HasDataLayout) -> Self {
let align = layout.align.abi;
let ptr = Scalar::from_uint(align.bytes(), cx.pointer_size());
// `Poison` this to make sure that the pointer value `ptr` is never observable by the program.
MPlaceTy { mplace: MemPlace { ptr, align, meta: MemPlaceMeta::Poison }, layout }
}
/// Replace ptr tag, maintain vtable tag (if any)
#[inline]
pub fn replace_tag(self, new_tag: Tag) -> Self {
MPlaceTy { mplace: self.mplace.replace_tag(new_tag), layout: self.layout }
}
#[inline]
pub fn offset(
self,
offset: Size,
meta: MemPlaceMeta<Tag>,
layout: TyLayout<'tcx>,
cx: &impl HasDataLayout,
) -> InterpResult<'tcx, Self> {
Ok(MPlaceTy { mplace: self.mplace.offset(offset, meta, cx)?, layout })
}
#[inline]
fn from_aligned_ptr(ptr: Pointer<Tag>, layout: TyLayout<'tcx>) -> Self {
MPlaceTy { mplace: MemPlace::from_ptr(ptr, layout.align.abi), layout }
}
#[inline]
pub(super) fn len(self, cx: &impl HasDataLayout) -> InterpResult<'tcx, u64> {
if self.layout.is_unsized() {
// We need to consult `meta` metadata
match self.layout.ty.kind {
ty::Slice(..) | ty::Str => {
return self.mplace.meta.unwrap_meta().to_machine_usize(cx);
}
_ => bug!("len not supported on unsized type {:?}", self.layout.ty),
}
} else {
// Go through the layout. There are lots of types that support a length,
// e.g., SIMD types.
match self.layout.fields {
layout::FieldPlacement::Array { count, .. } => Ok(count),
_ => bug!("len not supported on sized type {:?}", self.layout.ty),
}
}
}
#[inline]
pub(super) fn vtable(self) -> Scalar<Tag> {
match self.layout.ty.kind {
ty::Dynamic(..) => self.mplace.meta.unwrap_meta(),
_ => bug!("vtable not supported on type {:?}", self.layout.ty),
}
}
}
// These are defined here because they produce a place.
impl<'tcx, Tag: ::std::fmt::Debug + Copy> OpTy<'tcx, Tag> {
#[inline(always)]
/// Note: do not call `as_ref` on the resulting place. This function should only be used to
/// read from the resulting mplace, not to get its address back.
pub fn try_as_mplace(
self,
cx: &impl HasDataLayout,
) -> Result<MPlaceTy<'tcx, Tag>, ImmTy<'tcx, Tag>> {
match *self {
Operand::Indirect(mplace) => Ok(MPlaceTy { mplace, layout: self.layout }),
Operand::Immediate(_) if self.layout.is_zst() => {
Ok(MPlaceTy::dangling(self.layout, cx))
}
Operand::Immediate(imm) => Err(ImmTy { imm, layout: self.layout }),
}
}
#[inline(always)]
/// Note: do not call `as_ref` on the resulting place. This function should only be used to
/// read from the resulting mplace, not to get its address back.
pub fn assert_mem_place(self, cx: &impl HasDataLayout) -> MPlaceTy<'tcx, Tag> {
self.try_as_mplace(cx).unwrap()
}
}
impl<Tag: ::std::fmt::Debug> Place<Tag> {
/// Produces a Place that will error if attempted to be read from or written to
#[inline(always)]
fn null(cx: &impl HasDataLayout) -> Self {
Place::Ptr(MemPlace::null(cx))
}
#[inline]
pub fn assert_mem_place(self) -> MemPlace<Tag> {
match self {
Place::Ptr(mplace) => mplace,
_ => bug!("assert_mem_place: expected Place::Ptr, got {:?}", self),
}
}
}
impl<'tcx, Tag: ::std::fmt::Debug> PlaceTy<'tcx, Tag> {
#[inline]
pub fn assert_mem_place(self) -> MPlaceTy<'tcx, Tag> {
MPlaceTy { mplace: self.place.assert_mem_place(), layout: self.layout }
}
}
// separating the pointer tag for `impl Trait`, see https://github.com/rust-lang/rust/issues/54385
impl<'mir, 'tcx, Tag, M> InterpCx<'mir, 'tcx, M>
where
// FIXME: Working around https://github.com/rust-lang/rust/issues/54385
Tag: ::std::fmt::Debug + Copy + Eq + Hash + 'static,
M: Machine<'mir, 'tcx, PointerTag = Tag>,
// FIXME: Working around https://github.com/rust-lang/rust/issues/24159
M::MemoryMap: AllocMap<AllocId, (MemoryKind<M::MemoryKinds>, Allocation<Tag, M::AllocExtra>)>,
M::AllocExtra: AllocationExtra<Tag>,
{
/// Take a value, which represents a (thin or wide) reference, and make it a place.
/// Alignment is just based on the type. This is the inverse of `MemPlace::to_ref()`.
///
/// Only call this if you are sure the place is "valid" (aligned and inbounds), or do not
/// want to ever use the place for memory access!
/// Generally prefer `deref_operand`.
pub fn ref_to_mplace(
&self,
val: ImmTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx, MPlaceTy<'tcx, M::PointerTag>> {
let pointee_type =
val.layout.ty.builtin_deref(true).expect("`ref_to_mplace` called on non-ptr type").ty;
let layout = self.layout_of(pointee_type)?;
let (ptr, meta) = match *val {
Immediate::Scalar(ptr) => (ptr.not_undef()?, MemPlaceMeta::None),
Immediate::ScalarPair(ptr, meta) => {
(ptr.not_undef()?, MemPlaceMeta::Meta(meta.not_undef()?))
}
};
let mplace = MemPlace {
ptr,
// We could use the run-time alignment here. For now, we do not, because
// the point of tracking the alignment here is to make sure that the *static*
// alignment information emitted with the loads is correct. The run-time
// alignment can only be more restrictive.
align: layout.align.abi,
meta,
};
Ok(MPlaceTy { mplace, layout })
}
/// Take an operand, representing a pointer, and dereference it to a place -- that
/// will always be a MemPlace. Lives in `place.rs` because it creates a place.
pub fn deref_operand(
&self,
src: OpTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx, MPlaceTy<'tcx, M::PointerTag>> {
let val = self.read_immediate(src)?;
trace!("deref to {} on {:?}", val.layout.ty, *val);
let place = self.ref_to_mplace(val)?;
self.mplace_access_checked(place)
}
/// Check if the given place is good for memory access with the given
/// size, falling back to the layout's size if `None` (in the latter case,
/// this must be a statically sized type).
///
/// On success, returns `None` for zero-sized accesses (where nothing else is
/// left to do) and a `Pointer` to use for the actual access otherwise.
#[inline]
pub(super) fn check_mplace_access(
&self,
place: MPlaceTy<'tcx, M::PointerTag>,
size: Option<Size>,
) -> InterpResult<'tcx, Option<Pointer<M::PointerTag>>> {
let size = size.unwrap_or_else(|| {
assert!(!place.layout.is_unsized());
assert!(!place.meta.has_meta());
place.layout.size
});
self.memory.check_ptr_access(place.ptr, size, place.align)
}
/// Return the "access-checked" version of this `MPlace`, where for non-ZST
/// this is definitely a `Pointer`.
pub fn mplace_access_checked(
&self,
mut place: MPlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx, MPlaceTy<'tcx, M::PointerTag>> {
let (size, align) = self
.size_and_align_of_mplace(place)?
.unwrap_or((place.layout.size, place.layout.align.abi));
assert!(place.mplace.align <= align, "dynamic alignment less strict than static one?");
place.mplace.align = align; // maximally strict checking
// When dereferencing a pointer, it must be non-NULL, aligned, and live.
if let Some(ptr) = self.check_mplace_access(place, Some(size))? {
place.mplace.ptr = ptr.into();
}
Ok(place)
}
/// Force `place.ptr` to a `Pointer`.
/// Can be helpful to avoid lots of `force_ptr` calls later, if this place is used a lot.
pub(super) fn force_mplace_ptr(
&self,
mut place: MPlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx, MPlaceTy<'tcx, M::PointerTag>> {
place.mplace.ptr = self.force_ptr(place.mplace.ptr)?.into();
Ok(place)
}
/// Offset a pointer to project to a field. Unlike `place_field`, this is always
/// possible without allocating, so it can take `&self`. Also return the field's layout.
/// This supports both struct and array fields.
#[inline(always)]
pub fn mplace_field(
&self,
base: MPlaceTy<'tcx, M::PointerTag>,
field: u64,
) -> InterpResult<'tcx, MPlaceTy<'tcx, M::PointerTag>> {
// Not using the layout method because we want to compute on u64
let offset = match base.layout.fields {
layout::FieldPlacement::Arbitrary { ref offsets, .. } => {
offsets[usize::try_from(field).unwrap()]
}
layout::FieldPlacement::Array { stride, .. } => {
let len = base.len(self)?;
if field >= len {
// This can only be reached in ConstProp and non-rustc-MIR.
throw_ub!(BoundsCheckFailed { len, index: field });
}
stride * field
}
layout::FieldPlacement::Union(count) => {
// This is a narrow bug-fix for rust-lang/rust#69191: if we are
// trying to access absent field of uninhabited variant, then
// signal UB (but don't ICE the compiler).
// FIXME temporary hack to work around incoherence between
// layout computation and MIR building
if field >= count as u64 && base.layout.abi == layout::Abi::Uninhabited {
throw_ub!(Unreachable);
}
assert!(
field < count as u64,
"Tried to access field {} of union {:#?} with {} fields",
field,
base.layout,
count
);
// Offset is always 0
Size::from_bytes(0)
}
};
// the only way conversion can fail if is this is an array (otherwise we already panicked
// above). In that case, all fields are equal.
let field_layout = base.layout.field(self, usize::try_from(field).unwrap_or(0))?;
// Offset may need adjustment for unsized fields.
let (meta, offset) = if field_layout.is_unsized() {
// Re-use parent metadata to determine dynamic field layout.
// With custom DSTS, this *will* execute user-defined code, but the same
// happens at run-time so that's okay.
let align = match self.size_and_align_of(base.meta, field_layout)? {
Some((_, align)) => align,
None if offset == Size::ZERO => {
// An extern type at offset 0, we fall back to its static alignment.
// FIXME: Once we have made decisions for how to handle size and alignment
// of `extern type`, this should be adapted. It is just a temporary hack
// to get some code to work that probably ought to work.
field_layout.align.abi
}
None => bug!("Cannot compute offset for extern type field at non-0 offset"),
};
(base.meta, offset.align_to(align))
} else {
// base.meta could be present; we might be accessing a sized field of an unsized
// struct.
(MemPlaceMeta::None, offset)
};
// We do not look at `base.layout.align` nor `field_layout.align`, unlike
// codegen -- mostly to see if we can get away with that
base.offset(offset, meta, field_layout, self)
}
// Iterates over all fields of an array. Much more efficient than doing the
// same by repeatedly calling `mplace_array`.
pub(super) fn mplace_array_fields(
&self,
base: MPlaceTy<'tcx, Tag>,
) -> InterpResult<'tcx, impl Iterator<Item = InterpResult<'tcx, MPlaceTy<'tcx, Tag>>> + 'tcx>
{
let len = base.len(self)?; // also asserts that we have a type where this makes sense
let stride = match base.layout.fields {
layout::FieldPlacement::Array { stride, .. } => stride,
_ => bug!("mplace_array_fields: expected an array layout"),
};
let layout = base.layout.field(self, 0)?;
let dl = &self.tcx.data_layout;
Ok((0..len).map(move |i| base.offset(i * stride, MemPlaceMeta::None, layout, dl)))
}
fn mplace_subslice(
&self,
base: MPlaceTy<'tcx, M::PointerTag>,
from: u64,
to: u64,
from_end: bool,
) -> InterpResult<'tcx, MPlaceTy<'tcx, M::PointerTag>> {
let len = base.len(self)?; // also asserts that we have a type where this makes sense
let actual_to = if from_end {
if from + to > len {
// This can only be reached in ConstProp and non-rustc-MIR.
throw_ub!(BoundsCheckFailed { len: len as u64, index: from as u64 + to as u64 });
}
len - to
} else {
to
};
// Not using layout method because that works with usize, and does not work with slices
// (that have count 0 in their layout).
let from_offset = match base.layout.fields {
layout::FieldPlacement::Array { stride, .. } => stride * from,
_ => bug!("Unexpected layout of index access: {:#?}", base.layout),
};
// Compute meta and new layout
let inner_len = actual_to - from;
let (meta, ty) = match base.layout.ty.kind {
// It is not nice to match on the type, but that seems to be the only way to
// implement this.
ty::Array(inner, _) => (MemPlaceMeta::None, self.tcx.mk_array(inner, inner_len)),
ty::Slice(..) => {
let len = Scalar::from_uint(inner_len, self.pointer_size());
(MemPlaceMeta::Meta(len), base.layout.ty)
}
_ => bug!("cannot subslice non-array type: `{:?}`", base.layout.ty),
};
let layout = self.layout_of(ty)?;
base.offset(from_offset, meta, layout, self)
}
pub(super) fn mplace_downcast(
&self,
base: MPlaceTy<'tcx, M::PointerTag>,
variant: VariantIdx,
) -> InterpResult<'tcx, MPlaceTy<'tcx, M::PointerTag>> {
// Downcasts only change the layout
assert!(!base.meta.has_meta());
Ok(MPlaceTy { layout: base.layout.for_variant(self, variant), ..base })
}
/// Project into an mplace
pub(super) fn mplace_projection(
&self,
base: MPlaceTy<'tcx, M::PointerTag>,
proj_elem: &mir::PlaceElem<'tcx>,
) -> InterpResult<'tcx, MPlaceTy<'tcx, M::PointerTag>> {
use rustc::mir::ProjectionElem::*;
Ok(match *proj_elem {
Field(field, _) => self.mplace_field(base, field.index() as u64)?,
Downcast(_, variant) => self.mplace_downcast(base, variant)?,
Deref => self.deref_operand(base.into())?,
Index(local) => {
let layout = self.layout_of(self.tcx.types.usize)?;
let n = self.access_local(self.frame(), local, Some(layout))?;
let n = self.read_scalar(n)?;
let n = self.force_bits(n.not_undef()?, self.tcx.data_layout.pointer_size)?;
self.mplace_field(base, u64::try_from(n).unwrap())?
}
ConstantIndex { offset, min_length, from_end } => {
let n = base.len(self)?;
if n < min_length as u64 {
// This can only be reached in ConstProp and non-rustc-MIR.
throw_ub!(BoundsCheckFailed { len: min_length as u64, index: n as u64 });
}
let index = if from_end {
assert!(0 < offset && offset - 1 < min_length);
n - u64::from(offset)
} else {
assert!(offset < min_length);
u64::from(offset)
};
self.mplace_field(base, index)?
}
Subslice { from, to, from_end } => {
self.mplace_subslice(base, u64::from(from), u64::from(to), from_end)?
}
})
}
/// Gets the place of a field inside the place, and also the field's type.
/// Just a convenience function, but used quite a bit.
/// This is the only projection that might have a side-effect: We cannot project
/// into the field of a local `ScalarPair`, we have to first allocate it.
pub fn place_field(
&mut self,
base: PlaceTy<'tcx, M::PointerTag>,
field: u64,
) -> InterpResult<'tcx, PlaceTy<'tcx, M::PointerTag>> {
// FIXME: We could try to be smarter and avoid allocation for fields that span the
// entire place.
let mplace = self.force_allocation(base)?;
Ok(self.mplace_field(mplace, field)?.into())
}
pub fn place_downcast(
&self,
base: PlaceTy<'tcx, M::PointerTag>,
variant: VariantIdx,
) -> InterpResult<'tcx, PlaceTy<'tcx, M::PointerTag>> {
// Downcast just changes the layout
Ok(match base.place {
Place::Ptr(mplace) => {
self.mplace_downcast(MPlaceTy { mplace, layout: base.layout }, variant)?.into()
}
Place::Local { .. } => {
let layout = base.layout.for_variant(self, variant);
PlaceTy { layout, ..base }
}
})
}
/// Projects into a place.
pub fn place_projection(
&mut self,
base: PlaceTy<'tcx, M::PointerTag>,
proj_elem: &mir::ProjectionElem<mir::Local, Ty<'tcx>>,
) -> InterpResult<'tcx, PlaceTy<'tcx, M::PointerTag>> {
use rustc::mir::ProjectionElem::*;
Ok(match *proj_elem {
Field(field, _) => self.place_field(base, field.index() as u64)?,
Downcast(_, variant) => self.place_downcast(base, variant)?,
Deref => self.deref_operand(self.place_to_op(base)?)?.into(),
// For the other variants, we have to force an allocation.
// This matches `operand_projection`.
Subslice { .. } | ConstantIndex { .. } | Index(_) => {
let mplace = self.force_allocation(base)?;
self.mplace_projection(mplace, proj_elem)?.into()
}
})
}
/// Computes a place. You should only use this if you intend to write into this
/// place; for reading, a more efficient alternative is `eval_place_for_read`.
pub fn eval_place(
&mut self,
place: &mir::Place<'tcx>,
) -> InterpResult<'tcx, PlaceTy<'tcx, M::PointerTag>> {
let mut place_ty = match place.local {
mir::RETURN_PLACE => {
// `return_place` has the *caller* layout, but we want to use our
// `layout to verify our assumption. The caller will validate
// their layout on return.
PlaceTy {
place: match self.frame().return_place {
Some(p) => *p,
// Even if we don't have a return place, we sometimes need to
// create this place, but any attempt to read from / write to it
// (even a ZST read/write) needs to error, so let us make this
// a NULL place.
//
// FIXME: Ideally we'd make sure that the place projections also
// bail out.
None => Place::null(&*self),
},
layout: self.layout_of(self.subst_from_frame_and_normalize_erasing_regions(
self.frame().body.return_ty(),
))?,
}
}
local => PlaceTy {
// This works even for dead/uninitialized locals; we check further when writing
place: Place::Local { frame: self.cur_frame(), local },
layout: self.layout_of_local(self.frame(), local, None)?,
},
};
for elem in place.projection.iter() {
place_ty = self.place_projection(place_ty, elem)?
}
self.dump_place(place_ty.place);
Ok(place_ty)
}
/// Write a scalar to a place
#[inline(always)]
pub fn write_scalar(
&mut self,
val: impl Into<ScalarMaybeUndef<M::PointerTag>>,
dest: PlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx> {
self.write_immediate(Immediate::Scalar(val.into()), dest)
}
/// Write an immediate to a place
#[inline(always)]
pub fn write_immediate(
&mut self,
src: Immediate<M::PointerTag>,
dest: PlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx> {
self.write_immediate_no_validate(src, dest)?;
if M::enforce_validity(self) {
// Data got changed, better make sure it matches the type!
self.validate_operand(self.place_to_op(dest)?)?;
}
Ok(())
}
/// Write an `Immediate` to memory.
#[inline(always)]
pub fn write_immediate_to_mplace(
&mut self,
src: Immediate<M::PointerTag>,
dest: MPlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx> {
self.write_immediate_to_mplace_no_validate(src, dest)?;
if M::enforce_validity(self) {
// Data got changed, better make sure it matches the type!
self.validate_operand(dest.into())?;
}
Ok(())
}
/// Write an immediate to a place.
/// If you use this you are responsible for validating that things got copied at the
/// right type.
fn write_immediate_no_validate(
&mut self,
src: Immediate<M::PointerTag>,
dest: PlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx> {
if cfg!(debug_assertions) {
// This is a very common path, avoid some checks in release mode
assert!(!dest.layout.is_unsized(), "Cannot write unsized data");
match src {
Immediate::Scalar(ScalarMaybeUndef::Scalar(Scalar::Ptr(_))) => assert_eq!(
self.pointer_size(),
dest.layout.size,
"Size mismatch when writing pointer"
),
Immediate::Scalar(ScalarMaybeUndef::Scalar(Scalar::Raw { size, .. })) => {
assert_eq!(
Size::from_bytes(size.into()),
dest.layout.size,
"Size mismatch when writing bits"
)
}
Immediate::Scalar(ScalarMaybeUndef::Undef) => {} // undef can have any size
Immediate::ScalarPair(_, _) => {
// FIXME: Can we check anything here?
}
}
}
trace!("write_immediate: {:?} <- {:?}: {}", *dest, src, dest.layout.ty);
// See if we can avoid an allocation. This is the counterpart to `try_read_immediate`,
// but not factored as a separate function.
let mplace = match dest.place {
Place::Local { frame, local } => {
match self.stack[frame].locals[local].access_mut()? {
Ok(local) => {
// Local can be updated in-place.
*local = LocalValue::Live(Operand::Immediate(src));
return Ok(());
}
Err(mplace) => {
// The local is in memory, go on below.
mplace
}
}
}
Place::Ptr(mplace) => mplace, // already referring to memory
};
let dest = MPlaceTy { mplace, layout: dest.layout };
// This is already in memory, write there.
self.write_immediate_to_mplace_no_validate(src, dest)
}
/// Write an immediate to memory.
/// If you use this you are responsible for validating that things got copied at the
/// right type.
fn write_immediate_to_mplace_no_validate(
&mut self,
value: Immediate<M::PointerTag>,
dest: MPlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx> {
// Note that it is really important that the type here is the right one, and matches the
// type things are read at. In case `src_val` is a `ScalarPair`, we don't do any magic here
// to handle padding properly, which is only correct if we never look at this data with the
// wrong type.
// Invalid places are a thing: the return place of a diverging function
let ptr = match self.check_mplace_access(dest, None)? {
Some(ptr) => ptr,
None => return Ok(()), // zero-sized access
};
let tcx = &*self.tcx;
// FIXME: We should check that there are dest.layout.size many bytes available in
// memory. The code below is not sufficient, with enough padding it might not
// cover all the bytes!
match value {
Immediate::Scalar(scalar) => {
match dest.layout.abi {
layout::Abi::Scalar(_) => {} // fine
_ => {
bug!("write_immediate_to_mplace: invalid Scalar layout: {:#?}", dest.layout)
}
}
self.memory.get_raw_mut(ptr.alloc_id)?.write_scalar(
tcx,
ptr,
scalar,
dest.layout.size,
)
}
Immediate::ScalarPair(a_val, b_val) => {
// We checked `ptr_align` above, so all fields will have the alignment they need.
// We would anyway check against `ptr_align.restrict_for_offset(b_offset)`,
// which `ptr.offset(b_offset)` cannot possibly fail to satisfy.
let (a, b) = match dest.layout.abi {
layout::Abi::ScalarPair(ref a, ref b) => (&a.value, &b.value),
_ => bug!(
"write_immediate_to_mplace: invalid ScalarPair layout: {:#?}",
dest.layout
),
};
let (a_size, b_size) = (a.size(self), b.size(self));
let b_offset = a_size.align_to(b.align(self).abi);
let b_ptr = ptr.offset(b_offset, self)?;
// It is tempting to verify `b_offset` against `layout.fields.offset(1)`,
// but that does not work: We could be a newtype around a pair, then the
// fields do not match the `ScalarPair` components.
self.memory.get_raw_mut(ptr.alloc_id)?.write_scalar(tcx, ptr, a_val, a_size)?;
self.memory.get_raw_mut(b_ptr.alloc_id)?.write_scalar(tcx, b_ptr, b_val, b_size)
}
}
}
/// Copies the data from an operand to a place. This does not support transmuting!
/// Use `copy_op_transmute` if the layouts could disagree.
#[inline(always)]
pub fn copy_op(
&mut self,
src: OpTy<'tcx, M::PointerTag>,
dest: PlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx> {
self.copy_op_no_validate(src, dest)?;
if M::enforce_validity(self) {
// Data got changed, better make sure it matches the type!
self.validate_operand(self.place_to_op(dest)?)?;
}
Ok(())
}
/// Copies the data from an operand to a place. This does not support transmuting!
/// Use `copy_op_transmute` if the layouts could disagree.
/// Also, if you use this you are responsible for validating that things get copied at the
/// right type.
fn copy_op_no_validate(
&mut self,
src: OpTy<'tcx, M::PointerTag>,
dest: PlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx> {
// We do NOT compare the types for equality, because well-typed code can
// actually "transmute" `&mut T` to `&T` in an assignment without a cast.
assert!(
src.layout.details == dest.layout.details,
"Layout mismatch when copying!\nsrc: {:#?}\ndest: {:#?}",
src,
dest
);
// Let us see if the layout is simple so we take a shortcut, avoid force_allocation.
let src = match self.try_read_immediate(src)? {
Ok(src_val) => {
assert!(!src.layout.is_unsized(), "cannot have unsized immediates");
// Yay, we got a value that we can write directly.
// FIXME: Add a check to make sure that if `src` is indirect,
// it does not overlap with `dest`.
return self.write_immediate_no_validate(*src_val, dest);
}
Err(mplace) => mplace,
};
// Slow path, this does not fit into an immediate. Just memcpy.
trace!("copy_op: {:?} <- {:?}: {}", *dest, src, dest.layout.ty);
// This interprets `src.meta` with the `dest` local's layout, if an unsized local
// is being initialized!
let (dest, size) = self.force_allocation_maybe_sized(dest, src.meta)?;
let size = size.unwrap_or_else(|| {
assert!(
!dest.layout.is_unsized(),
"Cannot copy into already initialized unsized place"
);
dest.layout.size
});
assert_eq!(src.meta, dest.meta, "Can only copy between equally-sized instances");
let src = self
.check_mplace_access(src, Some(size))
.expect("places should be checked on creation");
let dest = self
.check_mplace_access(dest, Some(size))
.expect("places should be checked on creation");
let (src_ptr, dest_ptr) = match (src, dest) {
(Some(src_ptr), Some(dest_ptr)) => (src_ptr, dest_ptr),
(None, None) => return Ok(()), // zero-sized copy
_ => bug!("The pointers should both be Some or both None"),
};
self.memory.copy(src_ptr, dest_ptr, size, /*nonoverlapping*/ true)
}
/// Copies the data from an operand to a place. The layouts may disagree, but they must
/// have the same size.
pub fn copy_op_transmute(
&mut self,
src: OpTy<'tcx, M::PointerTag>,
dest: PlaceTy<'tcx, M::PointerTag>,
) -> InterpResult<'tcx> {
if src.layout.details == dest.layout.details {
// Fast path: Just use normal `copy_op`
return self.copy_op(src, dest);
}
// We still require the sizes to match.
if src.layout.size != dest.layout.size {
// FIXME: This should be an assert instead of an error, but if we transmute within an
// array length computation, `typeck` may not have yet been run and errored out. In fact
// most likey we *are* running `typeck` right now. Investigate whether we can bail out
// on `typeck_tables().has_errors` at all const eval entry points.
debug!("Size mismatch when transmuting!\nsrc: {:#?}\ndest: {:#?}", src, dest);
throw_unsup!(TransmuteSizeDiff(src.layout.ty, dest.layout.ty));
}
// Unsized copies rely on interpreting `src.meta` with `dest.layout`, we want
// to avoid that here.
assert!(
!src.layout.is_unsized() && !dest.layout.is_unsized(),
"Cannot transmute unsized data"
);
// The hard case is `ScalarPair`. `src` is already read from memory in this case,
// using `src.layout` to figure out which bytes to use for the 1st and 2nd field.
// We have to write them to `dest` at the offsets they were *read at*, which is
// not necessarily the same as the offsets in `dest.layout`!
// Hence we do the copy with the source layout on both sides. We also make sure to write
// into memory, because if `dest` is a local we would not even have a way to write
// at the `src` offsets; the fact that we came from a different layout would
// just be lost.
let dest = self.force_allocation(dest)?;
self.copy_op_no_validate(
src,
PlaceTy::from(MPlaceTy { mplace: *dest, layout: src.layout }),
)?;
if M::enforce_validity(self) {
// Data got changed, better make sure it matches the type!
self.validate_operand(dest.into())?;
}
Ok(())
}
/// Ensures that a place is in memory, and returns where it is.
/// If the place currently refers to a local that doesn't yet have a matching allocation,
/// create such an allocation.
/// This is essentially `force_to_memplace`.
///
/// This supports unsized types and returns the computed size to avoid some
/// redundant computation when copying; use `force_allocation` for a simpler, sized-only
/// version.
pub fn force_allocation_maybe_sized(
&mut self,
place: PlaceTy<'tcx, M::PointerTag>,
meta: MemPlaceMeta<M::PointerTag>,
) -> InterpResult<'tcx, (MPlaceTy<'tcx, M::PointerTag>, Option<Size>)> {
let (mplace, size) = match place.place {
Place::Local { frame, local } => {
match self.stack[frame].locals[local].access_mut()? {
Ok(&mut local_val) => {
// We need to make an allocation.
// We need the layout of the local. We can NOT use the layout we got,
// that might e.g., be an inner field of a struct with `Scalar` layout,
// that has different alignment than the outer field.
let local_layout = self.layout_of_local(&self.stack[frame], local, None)?;
// We also need to support unsized types, and hence cannot use `allocate`.
let (size, align) = self
.size_and_align_of(meta, local_layout)?
.expect("Cannot allocate for non-dyn-sized type");
let ptr = self.memory.allocate(size, align, MemoryKind::Stack);
let mplace = MemPlace { ptr: ptr.into(), align, meta };
if let LocalValue::Live(Operand::Immediate(value)) = local_val {
// Preserve old value.
// We don't have to validate as we can assume the local
// was already valid for its type.
let mplace = MPlaceTy { mplace, layout: local_layout };
self.write_immediate_to_mplace_no_validate(value, mplace)?;
}
// Now we can call `access_mut` again, asserting it goes well,
// and actually overwrite things.
*self.stack[frame].locals[local].access_mut().unwrap().unwrap() =
LocalValue::Live(Operand::Indirect(mplace));
(mplace, Some(size))