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|
//! Functions concerning immediate values and operands, and reading from operands.
//! All high-level functions to read from memory work on operands as sources.
use rustc_hir::def::Namespace;
use rustc_middle::ty::layout::{LayoutOf, PrimitiveExt, TyAndLayout};
use rustc_middle::ty::print::{FmtPrinter, PrettyPrinter};
use rustc_middle::ty::{ConstInt, DelaySpanBugEmitted, Ty};
use rustc_middle::{mir, ty};
use rustc_target::abi::{self, Abi, Align, HasDataLayout, Size, TagEncoding};
use rustc_target::abi::{VariantIdx, Variants};
use super::{
alloc_range, from_known_layout, mir_assign_valid_types, AllocId, ConstValue, Frame, GlobalId,
InterpCx, InterpResult, MPlaceTy, Machine, MemPlace, MemPlaceMeta, Place, PlaceTy, Pointer,
Provenance, Scalar,
};
/// An `Immediate` represents a single immediate self-contained Rust value.
///
/// For optimization of a few very common cases, there is also a representation for a pair of
/// primitive values (`ScalarPair`). It allows Miri to avoid making allocations for checked binary
/// operations and wide pointers. This idea was taken from rustc's codegen.
/// In particular, thanks to `ScalarPair`, arithmetic operations and casts can be entirely
/// defined on `Immediate`, and do not have to work with a `Place`.
#[derive(Copy, Clone, Debug)]
pub enum Immediate<Prov: Provenance = AllocId> {
/// A single scalar value (must have *initialized* `Scalar` ABI).
Scalar(Scalar<Prov>),
/// A pair of two scalar value (must have `ScalarPair` ABI where both fields are
/// `Scalar::Initialized`).
ScalarPair(Scalar<Prov>, Scalar<Prov>),
/// A value of fully uninitialized memory. Can have and size and layout.
Uninit,
}
impl<Prov: Provenance> From<Scalar<Prov>> for Immediate<Prov> {
#[inline(always)]
fn from(val: Scalar<Prov>) -> Self {
Immediate::Scalar(val.into())
}
}
impl<Prov: Provenance> Immediate<Prov> {
pub fn from_pointer(p: Pointer<Prov>, cx: &impl HasDataLayout) -> Self {
Immediate::Scalar(Scalar::from_pointer(p, cx))
}
pub fn from_maybe_pointer(p: Pointer<Option<Prov>>, cx: &impl HasDataLayout) -> Self {
Immediate::Scalar(Scalar::from_maybe_pointer(p, cx))
}
pub fn new_slice(val: Scalar<Prov>, len: u64, cx: &impl HasDataLayout) -> Self {
Immediate::ScalarPair(val.into(), Scalar::from_machine_usize(len, cx).into())
}
pub fn new_dyn_trait(
val: Scalar<Prov>,
vtable: Pointer<Option<Prov>>,
cx: &impl HasDataLayout,
) -> Self {
Immediate::ScalarPair(val.into(), Scalar::from_maybe_pointer(vtable, cx))
}
#[inline]
#[cfg_attr(debug_assertions, track_caller)] // only in debug builds due to perf (see #98980)
pub fn to_scalar(self) -> Scalar<Prov> {
match self {
Immediate::Scalar(val) => val,
Immediate::ScalarPair(..) => bug!("Got a scalar pair where a scalar was expected"),
Immediate::Uninit => bug!("Got uninit where a scalar was expected"),
}
}
#[inline]
#[cfg_attr(debug_assertions, track_caller)] // only in debug builds due to perf (see #98980)
pub fn to_scalar_pair(self) -> (Scalar<Prov>, Scalar<Prov>) {
match self {
Immediate::ScalarPair(val1, val2) => (val1, val2),
Immediate::Scalar(..) => bug!("Got a scalar where a scalar pair was expected"),
Immediate::Uninit => bug!("Got uninit where a scalar pair was expected"),
}
}
}
// ScalarPair needs a type to interpret, so we often have an immediate and a type together
// as input for binary and cast operations.
#[derive(Clone, Debug)]
pub struct ImmTy<'tcx, Prov: Provenance = AllocId> {
imm: Immediate<Prov>,
pub layout: TyAndLayout<'tcx>,
}
impl<Prov: Provenance> std::fmt::Display for ImmTy<'_, Prov> {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
/// Helper function for printing a scalar to a FmtPrinter
fn p<'a, 'tcx, Prov: Provenance>(
cx: FmtPrinter<'a, 'tcx>,
s: Scalar<Prov>,
ty: Ty<'tcx>,
) -> Result<FmtPrinter<'a, 'tcx>, std::fmt::Error> {
match s {
Scalar::Int(int) => cx.pretty_print_const_scalar_int(int, ty, true),
Scalar::Ptr(ptr, _sz) => {
// Just print the ptr value. `pretty_print_const_scalar_ptr` would also try to
// print what is points to, which would fail since it has no access to the local
// memory.
cx.pretty_print_const_pointer(ptr, ty, true)
}
}
}
ty::tls::with(|tcx| {
match self.imm {
Immediate::Scalar(s) => {
if let Some(ty) = tcx.lift(self.layout.ty) {
let cx = FmtPrinter::new(tcx, Namespace::ValueNS);
f.write_str(&p(cx, s, ty)?.into_buffer())?;
return Ok(());
}
write!(f, "{:x}: {}", s, self.layout.ty)
}
Immediate::ScalarPair(a, b) => {
// FIXME(oli-obk): at least print tuples and slices nicely
write!(f, "({:x}, {:x}): {}", a, b, self.layout.ty)
}
Immediate::Uninit => {
write!(f, "uninit: {}", self.layout.ty)
}
}
})
}
}
impl<'tcx, Prov: Provenance> std::ops::Deref for ImmTy<'tcx, Prov> {
type Target = Immediate<Prov>;
#[inline(always)]
fn deref(&self) -> &Immediate<Prov> {
&self.imm
}
}
/// An `Operand` is the result of computing a `mir::Operand`. It can be immediate,
/// or still in memory. The latter is an optimization, to delay reading that chunk of
/// memory and to avoid having to store arbitrary-sized data here.
#[derive(Copy, Clone, Debug)]
pub enum Operand<Prov: Provenance = AllocId> {
Immediate(Immediate<Prov>),
Indirect(MemPlace<Prov>),
}
#[derive(Clone, Debug)]
pub struct OpTy<'tcx, Prov: Provenance = AllocId> {
op: Operand<Prov>, // Keep this private; it helps enforce invariants.
pub layout: TyAndLayout<'tcx>,
/// rustc does not have a proper way to represent the type of a field of a `repr(packed)` struct:
/// it needs to have a different alignment than the field type would usually have.
/// So we represent this here with a separate field that "overwrites" `layout.align`.
/// This means `layout.align` should never be used for an `OpTy`!
/// `None` means "alignment does not matter since this is a by-value operand"
/// (`Operand::Immediate`); this field is only relevant for `Operand::Indirect`.
/// Also CTFE ignores alignment anyway, so this is for Miri only.
pub align: Option<Align>,
}
impl<'tcx, Prov: Provenance> std::ops::Deref for OpTy<'tcx, Prov> {
type Target = Operand<Prov>;
#[inline(always)]
fn deref(&self) -> &Operand<Prov> {
&self.op
}
}
impl<'tcx, Prov: Provenance> From<MPlaceTy<'tcx, Prov>> for OpTy<'tcx, Prov> {
#[inline(always)]
fn from(mplace: MPlaceTy<'tcx, Prov>) -> Self {
OpTy { op: Operand::Indirect(*mplace), layout: mplace.layout, align: Some(mplace.align) }
}
}
impl<'tcx, Prov: Provenance> From<&'_ MPlaceTy<'tcx, Prov>> for OpTy<'tcx, Prov> {
#[inline(always)]
fn from(mplace: &MPlaceTy<'tcx, Prov>) -> Self {
OpTy { op: Operand::Indirect(**mplace), layout: mplace.layout, align: Some(mplace.align) }
}
}
impl<'tcx, Prov: Provenance> From<&'_ mut MPlaceTy<'tcx, Prov>> for OpTy<'tcx, Prov> {
#[inline(always)]
fn from(mplace: &mut MPlaceTy<'tcx, Prov>) -> Self {
OpTy { op: Operand::Indirect(**mplace), layout: mplace.layout, align: Some(mplace.align) }
}
}
impl<'tcx, Prov: Provenance> From<ImmTy<'tcx, Prov>> for OpTy<'tcx, Prov> {
#[inline(always)]
fn from(val: ImmTy<'tcx, Prov>) -> Self {
OpTy { op: Operand::Immediate(val.imm), layout: val.layout, align: None }
}
}
impl<'tcx, Prov: Provenance> ImmTy<'tcx, Prov> {
#[inline]
pub fn from_scalar(val: Scalar<Prov>, layout: TyAndLayout<'tcx>) -> Self {
ImmTy { imm: val.into(), layout }
}
#[inline]
pub fn from_immediate(imm: Immediate<Prov>, layout: TyAndLayout<'tcx>) -> Self {
ImmTy { imm, layout }
}
#[inline]
pub fn uninit(layout: TyAndLayout<'tcx>) -> Self {
ImmTy { imm: Immediate::Uninit, layout }
}
#[inline]
pub fn try_from_uint(i: impl Into<u128>, layout: TyAndLayout<'tcx>) -> Option<Self> {
Some(Self::from_scalar(Scalar::try_from_uint(i, layout.size)?, layout))
}
#[inline]
pub fn from_uint(i: impl Into<u128>, layout: TyAndLayout<'tcx>) -> Self {
Self::from_scalar(Scalar::from_uint(i, layout.size), layout)
}
#[inline]
pub fn try_from_int(i: impl Into<i128>, layout: TyAndLayout<'tcx>) -> Option<Self> {
Some(Self::from_scalar(Scalar::try_from_int(i, layout.size)?, layout))
}
#[inline]
pub fn from_int(i: impl Into<i128>, layout: TyAndLayout<'tcx>) -> Self {
Self::from_scalar(Scalar::from_int(i, layout.size), layout)
}
#[inline]
pub fn to_const_int(self) -> ConstInt {
assert!(self.layout.ty.is_integral());
let int = self.to_scalar().assert_int();
ConstInt::new(int, self.layout.ty.is_signed(), self.layout.ty.is_ptr_sized_integral())
}
}
impl<'tcx, Prov: Provenance> OpTy<'tcx, Prov> {
pub fn len(&self, cx: &impl HasDataLayout) -> InterpResult<'tcx, u64> {
if self.layout.is_unsized() {
// There are no unsized immediates.
self.assert_mem_place().len(cx)
} else {
match self.layout.fields {
abi::FieldsShape::Array { count, .. } => Ok(count),
_ => bug!("len not supported on sized type {:?}", self.layout.ty),
}
}
}
pub fn offset_with_meta(
&self,
offset: Size,
meta: MemPlaceMeta<Prov>,
layout: TyAndLayout<'tcx>,
cx: &impl HasDataLayout,
) -> InterpResult<'tcx, Self> {
match self.try_as_mplace() {
Ok(mplace) => Ok(mplace.offset_with_meta(offset, meta, layout, cx)?.into()),
Err(imm) => {
assert!(
matches!(*imm, Immediate::Uninit),
"Scalar/ScalarPair cannot be offset into"
);
assert!(!meta.has_meta()); // no place to store metadata here
// Every part of an uninit is uninit.
Ok(ImmTy::uninit(layout).into())
}
}
}
pub fn offset(
&self,
offset: Size,
layout: TyAndLayout<'tcx>,
cx: &impl HasDataLayout,
) -> InterpResult<'tcx, Self> {
assert!(!layout.is_unsized());
self.offset_with_meta(offset, MemPlaceMeta::None, layout, cx)
}
}
impl<'mir, 'tcx: 'mir, M: Machine<'mir, 'tcx>> InterpCx<'mir, 'tcx, M> {
/// Try reading an immediate in memory; this is interesting particularly for `ScalarPair`.
/// Returns `None` if the layout does not permit loading this as a value.
///
/// This is an internal function; call `read_immediate` instead.
fn read_immediate_from_mplace_raw(
&self,
mplace: &MPlaceTy<'tcx, M::Provenance>,
) -> InterpResult<'tcx, Option<ImmTy<'tcx, M::Provenance>>> {
if mplace.layout.is_unsized() {
// Don't touch unsized
return Ok(None);
}
let Some(alloc) = self.get_place_alloc(mplace)? else {
// zero-sized type can be left uninit
return Ok(Some(ImmTy::uninit(mplace.layout)));
};
// 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`).
Ok(match mplace.layout.abi {
Abi::Scalar(abi::Scalar::Initialized { value: s, .. }) => {
let size = s.size(self);
assert_eq!(size, mplace.layout.size, "abi::Scalar size does not match layout size");
let scalar = alloc.read_scalar(
alloc_range(Size::ZERO, size),
/*read_provenance*/ s.is_ptr(),
)?;
Some(ImmTy { imm: scalar.into(), layout: mplace.layout })
}
Abi::ScalarPair(
abi::Scalar::Initialized { value: a, .. },
abi::Scalar::Initialized { value: b, .. },
) => {
// 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_size, b_size) = (a.size(self), b.size(self));
let b_offset = a_size.align_to(b.align(self).abi);
assert!(b_offset.bytes() > 0); // in `operand_field` we use the offset to tell apart the fields
let a_val = alloc.read_scalar(
alloc_range(Size::ZERO, a_size),
/*read_provenance*/ a.is_ptr(),
)?;
let b_val = alloc.read_scalar(
alloc_range(b_offset, b_size),
/*read_provenance*/ b.is_ptr(),
)?;
Some(ImmTy {
imm: Immediate::ScalarPair(a_val.into(), b_val.into()),
layout: mplace.layout,
})
}
_ => {
// Neither a scalar nor scalar pair.
None
}
})
}
/// Try returning an immediate for the operand. If the layout does not permit loading this as an
/// immediate, return where in memory we can find the data.
/// Note that for a given layout, this operation will either always fail or always
/// succeed! Whether it succeeds depends on whether the layout can be represented
/// in an `Immediate`, not on which data is stored there currently.
///
/// This is an internal function that should not usually be used; call `read_immediate` instead.
/// ConstProp needs it, though.
pub fn read_immediate_raw(
&self,
src: &OpTy<'tcx, M::Provenance>,
) -> InterpResult<'tcx, Result<ImmTy<'tcx, M::Provenance>, MPlaceTy<'tcx, M::Provenance>>> {
Ok(match src.try_as_mplace() {
Ok(ref mplace) => {
if let Some(val) = self.read_immediate_from_mplace_raw(mplace)? {
Ok(val)
} else {
Err(*mplace)
}
}
Err(val) => Ok(val),
})
}
/// Read an immediate from a place, asserting that that is possible with the given layout.
///
/// If this suceeds, the `ImmTy` is never `Uninit`.
#[inline(always)]
pub fn read_immediate(
&self,
op: &OpTy<'tcx, M::Provenance>,
) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
if !matches!(
op.layout.abi,
Abi::Scalar(abi::Scalar::Initialized { .. })
| Abi::ScalarPair(abi::Scalar::Initialized { .. }, abi::Scalar::Initialized { .. })
) {
span_bug!(self.cur_span(), "primitive read not possible for type: {:?}", op.layout.ty);
}
let imm = self.read_immediate_raw(op)?.unwrap();
if matches!(*imm, Immediate::Uninit) {
throw_ub!(InvalidUninitBytes(None));
}
Ok(imm)
}
/// Read a scalar from a place
pub fn read_scalar(
&self,
op: &OpTy<'tcx, M::Provenance>,
) -> InterpResult<'tcx, Scalar<M::Provenance>> {
Ok(self.read_immediate(op)?.to_scalar())
}
/// Read a pointer from a place.
pub fn read_pointer(
&self,
op: &OpTy<'tcx, M::Provenance>,
) -> InterpResult<'tcx, Pointer<Option<M::Provenance>>> {
self.read_scalar(op)?.to_pointer(self)
}
/// Turn the wide MPlace into a string (must already be dereferenced!)
pub fn read_str(&self, mplace: &MPlaceTy<'tcx, M::Provenance>) -> InterpResult<'tcx, &str> {
let len = mplace.len(self)?;
let bytes = self.read_bytes_ptr_strip_provenance(mplace.ptr, Size::from_bytes(len))?;
let str = std::str::from_utf8(bytes).map_err(|err| err_ub!(InvalidStr(err)))?;
Ok(str)
}
/// Converts a repr(simd) operand into an operand where `place_index` accesses the SIMD elements.
/// Also returns the number of elements.
///
/// Can (but does not always) trigger UB if `op` is uninitialized.
pub fn operand_to_simd(
&self,
op: &OpTy<'tcx, M::Provenance>,
) -> InterpResult<'tcx, (MPlaceTy<'tcx, M::Provenance>, u64)> {
// Basically we just transmute this place into an array following simd_size_and_type.
// This only works in memory, but repr(simd) types should never be immediates anyway.
assert!(op.layout.ty.is_simd());
match op.try_as_mplace() {
Ok(mplace) => self.mplace_to_simd(&mplace),
Err(imm) => match *imm {
Immediate::Uninit => {
throw_ub!(InvalidUninitBytes(None))
}
Immediate::Scalar(..) | Immediate::ScalarPair(..) => {
bug!("arrays/slices can never have Scalar/ScalarPair layout")
}
},
}
}
/// Read from a local.
/// Will not access memory, instead an indirect `Operand` is returned.
///
/// This is public because it is used by [priroda](https://github.com/oli-obk/priroda) to get an
/// OpTy from a local.
pub fn local_to_op(
&self,
frame: &Frame<'mir, 'tcx, M::Provenance, M::FrameExtra>,
local: mir::Local,
layout: Option<TyAndLayout<'tcx>>,
) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> {
let layout = self.layout_of_local(frame, local, layout)?;
let op = *frame.locals[local].access()?;
Ok(OpTy { op, layout, align: Some(layout.align.abi) })
}
/// Every place can be read from, so we can turn them into an operand.
/// This will definitely return `Indirect` if the place is a `Ptr`, i.e., this
/// will never actually read from memory.
#[inline(always)]
pub fn place_to_op(
&self,
place: &PlaceTy<'tcx, M::Provenance>,
) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> {
let op = match **place {
Place::Ptr(mplace) => Operand::Indirect(mplace),
Place::Local { frame, local } => {
*self.local_to_op(&self.stack()[frame], local, None)?
}
};
Ok(OpTy { op, layout: place.layout, align: Some(place.align) })
}
/// Evaluate a place with the goal of reading from it. This lets us sometimes
/// avoid allocations.
pub fn eval_place_to_op(
&self,
mir_place: mir::Place<'tcx>,
layout: Option<TyAndLayout<'tcx>>,
) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> {
// Do not use the layout passed in as argument if the base we are looking at
// here is not the entire place.
let layout = if mir_place.projection.is_empty() { layout } else { None };
let mut op = self.local_to_op(self.frame(), mir_place.local, layout)?;
// Using `try_fold` turned out to be bad for performance, hence the loop.
for elem in mir_place.projection.iter() {
op = self.operand_projection(&op, elem)?
}
trace!("eval_place_to_op: got {:?}", *op);
// Sanity-check the type we ended up with.
debug_assert!(
mir_assign_valid_types(
*self.tcx,
self.param_env,
self.layout_of(self.subst_from_current_frame_and_normalize_erasing_regions(
mir_place.ty(&self.frame().body.local_decls, *self.tcx).ty
)?)?,
op.layout,
),
"eval_place of a MIR place with type {:?} produced an interpreter operand with type {:?}",
mir_place.ty(&self.frame().body.local_decls, *self.tcx).ty,
op.layout.ty,
);
Ok(op)
}
/// Evaluate the operand, returning a place where you can then find the data.
/// If you already know the layout, you can save two table lookups
/// by passing it in here.
#[inline]
pub fn eval_operand(
&self,
mir_op: &mir::Operand<'tcx>,
layout: Option<TyAndLayout<'tcx>>,
) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> {
use rustc_middle::mir::Operand::*;
let op = match *mir_op {
// FIXME: do some more logic on `move` to invalidate the old location
Copy(place) | Move(place) => self.eval_place_to_op(place, layout)?,
Constant(ref constant) => {
let val =
self.subst_from_current_frame_and_normalize_erasing_regions(constant.literal)?;
// This can still fail:
// * During ConstProp, with `TooGeneric` or since the `required_consts` were not all
// checked yet.
// * During CTFE, since promoteds in `const`/`static` initializer bodies can fail.
self.mir_const_to_op(&val, layout)?
}
};
trace!("{:?}: {:?}", mir_op, *op);
Ok(op)
}
/// Evaluate a bunch of operands at once
pub(super) fn eval_operands(
&self,
ops: &[mir::Operand<'tcx>],
) -> InterpResult<'tcx, Vec<OpTy<'tcx, M::Provenance>>> {
ops.iter().map(|op| self.eval_operand(op, None)).collect()
}
// Used when the miri-engine runs into a constant and for extracting information from constants
// in patterns via the `const_eval` module
/// The `val` and `layout` are assumed to already be in our interpreter
/// "universe" (param_env).
pub fn const_to_op(
&self,
c: ty::Const<'tcx>,
layout: Option<TyAndLayout<'tcx>>,
) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> {
match c.kind() {
ty::ConstKind::Param(_) | ty::ConstKind::Placeholder(..) => throw_inval!(TooGeneric),
ty::ConstKind::Error(DelaySpanBugEmitted { reported, .. }) => {
throw_inval!(AlreadyReported(reported))
}
ty::ConstKind::Unevaluated(uv) => {
// NOTE: We evaluate to a `ValTree` here as a check to ensure
// we're working with valid constants, even though we never need it.
let instance = self.resolve(uv.def, uv.substs)?;
let cid = GlobalId { instance, promoted: None };
let _valtree = self
.tcx
.eval_to_valtree(self.param_env.and(cid))?
.unwrap_or_else(|| bug!("unable to create ValTree for {:?}", uv));
Ok(self.eval_to_allocation(cid)?.into())
}
ty::ConstKind::Bound(..) | ty::ConstKind::Infer(..) => {
span_bug!(self.cur_span(), "const_to_op: Unexpected ConstKind {:?}", c)
}
ty::ConstKind::Value(valtree) => {
let ty = c.ty();
let const_val = self.tcx.valtree_to_const_val((ty, valtree));
self.const_val_to_op(const_val, ty, layout)
}
}
}
pub fn mir_const_to_op(
&self,
val: &mir::ConstantKind<'tcx>,
layout: Option<TyAndLayout<'tcx>>,
) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> {
// FIXME(const_prop): normalization needed b/c const prop lint in
// `mir_drops_elaborated_and_const_checked`, which happens before
// optimized MIR. Only after optimizing the MIR can we guarantee
// that the `RevealAll` pass has happened and that the body's consts
// are normalized, so any call to resolve before that needs to be
// manually normalized.
let val = self.tcx.normalize_erasing_regions(self.param_env, *val);
match val {
mir::ConstantKind::Ty(ct) => self.const_to_op(ct, layout),
mir::ConstantKind::Val(val, ty) => self.const_val_to_op(val, ty, layout),
mir::ConstantKind::Unevaluated(uv, _) => {
let instance = self.resolve(uv.def, uv.substs)?;
Ok(self.eval_to_allocation(GlobalId { instance, promoted: uv.promoted })?.into())
}
}
}
pub(crate) fn const_val_to_op(
&self,
val_val: ConstValue<'tcx>,
ty: Ty<'tcx>,
layout: Option<TyAndLayout<'tcx>>,
) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> {
// Other cases need layout.
let adjust_scalar = |scalar| -> InterpResult<'tcx, _> {
Ok(match scalar {
Scalar::Ptr(ptr, size) => Scalar::Ptr(self.global_base_pointer(ptr)?, size),
Scalar::Int(int) => Scalar::Int(int),
})
};
let layout = from_known_layout(self.tcx, self.param_env, layout, || self.layout_of(ty))?;
let op = match val_val {
ConstValue::ByRef { alloc, offset } => {
let id = self.tcx.create_memory_alloc(alloc);
// We rely on mutability being set correctly in that allocation to prevent writes
// where none should happen.
let ptr = self.global_base_pointer(Pointer::new(id, offset))?;
Operand::Indirect(MemPlace::from_ptr(ptr.into()))
}
ConstValue::Scalar(x) => Operand::Immediate(adjust_scalar(x)?.into()),
ConstValue::ZeroSized => Operand::Immediate(Immediate::Uninit),
ConstValue::Slice { data, start, end } => {
// We rely on mutability being set correctly in `data` to prevent writes
// where none should happen.
let ptr = Pointer::new(
self.tcx.create_memory_alloc(data),
Size::from_bytes(start), // offset: `start`
);
Operand::Immediate(Immediate::new_slice(
Scalar::from_pointer(self.global_base_pointer(ptr)?, &*self.tcx),
u64::try_from(end.checked_sub(start).unwrap()).unwrap(), // len: `end - start`
self,
))
}
};
Ok(OpTy { op, layout, align: Some(layout.align.abi) })
}
/// Read discriminant, return the runtime value as well as the variant index.
/// Can also legally be called on non-enums (e.g. through the discriminant_value intrinsic)!
pub fn read_discriminant(
&self,
op: &OpTy<'tcx, M::Provenance>,
) -> InterpResult<'tcx, (Scalar<M::Provenance>, VariantIdx)> {
trace!("read_discriminant_value {:#?}", op.layout);
// Get type and layout of the discriminant.
let discr_layout = self.layout_of(op.layout.ty.discriminant_ty(*self.tcx))?;
trace!("discriminant type: {:?}", discr_layout.ty);
// We use "discriminant" to refer to the value associated with a particular enum variant.
// This is not to be confused with its "variant index", which is just determining its position in the
// declared list of variants -- they can differ with explicitly assigned discriminants.
// We use "tag" to refer to how the discriminant is encoded in memory, which can be either
// straight-forward (`TagEncoding::Direct`) or with a niche (`TagEncoding::Niche`).
let (tag_scalar_layout, tag_encoding, tag_field) = match op.layout.variants {
Variants::Single { index } => {
let discr = match op.layout.ty.discriminant_for_variant(*self.tcx, index) {
Some(discr) => {
// This type actually has discriminants.
assert_eq!(discr.ty, discr_layout.ty);
Scalar::from_uint(discr.val, discr_layout.size)
}
None => {
// On a type without actual discriminants, variant is 0.
assert_eq!(index.as_u32(), 0);
Scalar::from_uint(index.as_u32(), discr_layout.size)
}
};
return Ok((discr, index));
}
Variants::Multiple { tag, ref tag_encoding, tag_field, .. } => {
(tag, tag_encoding, tag_field)
}
};
// There are *three* layouts that come into play here:
// - The discriminant has a type for typechecking. This is `discr_layout`, and is used for
// the `Scalar` we return.
// - The tag (encoded discriminant) has layout `tag_layout`. This is always an integer type,
// and used to interpret the value we read from the tag field.
// For the return value, a cast to `discr_layout` is performed.
// - The field storing the tag has a layout, which is very similar to `tag_layout` but
// may be a pointer. This is `tag_val.layout`; we just use it for sanity checks.
// Get layout for tag.
let tag_layout = self.layout_of(tag_scalar_layout.primitive().to_int_ty(*self.tcx))?;
// Read tag and sanity-check `tag_layout`.
let tag_val = self.read_immediate(&self.operand_field(op, tag_field)?)?;
assert_eq!(tag_layout.size, tag_val.layout.size);
assert_eq!(tag_layout.abi.is_signed(), tag_val.layout.abi.is_signed());
trace!("tag value: {}", tag_val);
// Figure out which discriminant and variant this corresponds to.
Ok(match *tag_encoding {
TagEncoding::Direct => {
let scalar = tag_val.to_scalar();
// Generate a specific error if `tag_val` is not an integer.
// (`tag_bits` itself is only used for error messages below.)
let tag_bits = scalar
.try_to_int()
.map_err(|dbg_val| err_ub!(InvalidTag(dbg_val)))?
.assert_bits(tag_layout.size);
// Cast bits from tag layout to discriminant layout.
// After the checks we did above, this cannot fail, as
// discriminants are int-like.
let discr_val =
self.cast_from_int_like(scalar, tag_val.layout, discr_layout.ty).unwrap();
let discr_bits = discr_val.assert_bits(discr_layout.size);
// Convert discriminant to variant index, and catch invalid discriminants.
let index = match *op.layout.ty.kind() {
ty::Adt(adt, _) => {
adt.discriminants(*self.tcx).find(|(_, var)| var.val == discr_bits)
}
ty::Generator(def_id, substs, _) => {
let substs = substs.as_generator();
substs
.discriminants(def_id, *self.tcx)
.find(|(_, var)| var.val == discr_bits)
}
_ => span_bug!(self.cur_span(), "tagged layout for non-adt non-generator"),
}
.ok_or_else(|| err_ub!(InvalidTag(Scalar::from_uint(tag_bits, tag_layout.size))))?;
// Return the cast value, and the index.
(discr_val, index.0)
}
TagEncoding::Niche { untagged_variant, ref niche_variants, niche_start } => {
let tag_val = tag_val.to_scalar();
// Compute the variant this niche value/"tag" corresponds to. With niche layout,
// discriminant (encoded in niche/tag) and variant index are the same.
let variants_start = niche_variants.start().as_u32();
let variants_end = niche_variants.end().as_u32();
let variant = match tag_val.try_to_int() {
Err(dbg_val) => {
// So this is a pointer then, and casting to an int failed.
// Can only happen during CTFE.
// The niche must be just 0, and the ptr not null, then we know this is
// okay. Everything else, we conservatively reject.
let ptr_valid = niche_start == 0
&& variants_start == variants_end
&& !self.scalar_may_be_null(tag_val)?;
if !ptr_valid {
throw_ub!(InvalidTag(dbg_val))
}
untagged_variant
}
Ok(tag_bits) => {
let tag_bits = tag_bits.assert_bits(tag_layout.size);
// We need to use machine arithmetic to get the relative variant idx:
// variant_index_relative = tag_val - niche_start_val
let tag_val = ImmTy::from_uint(tag_bits, tag_layout);
let niche_start_val = ImmTy::from_uint(niche_start, tag_layout);
let variant_index_relative_val =
self.binary_op(mir::BinOp::Sub, &tag_val, &niche_start_val)?;
let variant_index_relative =
variant_index_relative_val.to_scalar().assert_bits(tag_val.layout.size);
// Check if this is in the range that indicates an actual discriminant.
if variant_index_relative <= u128::from(variants_end - variants_start) {
let variant_index_relative = u32::try_from(variant_index_relative)
.expect("we checked that this fits into a u32");
// Then computing the absolute variant idx should not overflow any more.
let variant_index = variants_start
.checked_add(variant_index_relative)
.expect("overflow computing absolute variant idx");
let variants_len = op
.layout
.ty
.ty_adt_def()
.expect("tagged layout for non adt")
.variants()
.len();
assert!(usize::try_from(variant_index).unwrap() < variants_len);
VariantIdx::from_u32(variant_index)
} else {
untagged_variant
}
}
};
// Compute the size of the scalar we need to return.
// No need to cast, because the variant index directly serves as discriminant and is
// encoded in the tag.
(Scalar::from_uint(variant.as_u32(), discr_layout.size), variant)
}
})
}
}
// Some nodes are used a lot. Make sure they don't unintentionally get bigger.
#[cfg(all(target_arch = "x86_64", target_pointer_width = "64", not(bootstrap)))]
mod size_asserts {
use super::*;
use rustc_data_structures::static_assert_size;
// These are in alphabetical order, which is easy to maintain.
static_assert_size!(Immediate, 48);
static_assert_size!(ImmTy<'_>, 64);
static_assert_size!(Operand, 56);
static_assert_size!(OpTy<'_>, 80);
}
|