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known_panics_lint.rs
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known_panics_lint.rs
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//! A lint that checks for known panics like
//! overflows, division by zero,
//! out-of-bound access etc.
//! Uses const propagation to determine the
//! values of operands during checks.
use std::fmt::Debug;
use rustc_const_eval::const_eval::DummyMachine;
use rustc_const_eval::interpret::{
format_interp_error, ImmTy, InterpCx, InterpResult, Projectable, Scalar,
};
use rustc_data_structures::fx::FxHashSet;
use rustc_hir::def::DefKind;
use rustc_hir::HirId;
use rustc_index::{bit_set::BitSet, IndexVec};
use rustc_middle::mir::visit::{MutatingUseContext, NonMutatingUseContext, PlaceContext, Visitor};
use rustc_middle::mir::*;
use rustc_middle::ty::layout::{LayoutError, LayoutOf, LayoutOfHelpers, TyAndLayout};
use rustc_middle::ty::{self, ConstInt, ParamEnv, ScalarInt, Ty, TyCtxt, TypeVisitableExt};
use rustc_span::Span;
use rustc_target::abi::{Abi, FieldIdx, HasDataLayout, Size, TargetDataLayout, VariantIdx};
use crate::errors::{AssertLint, AssertLintKind};
use crate::MirLint;
pub struct KnownPanicsLint;
impl<'tcx> MirLint<'tcx> for KnownPanicsLint {
fn run_lint(&self, tcx: TyCtxt<'tcx>, body: &Body<'tcx>) {
if body.tainted_by_errors.is_some() {
return;
}
let def_id = body.source.def_id().expect_local();
let def_kind = tcx.def_kind(def_id);
let is_fn_like = def_kind.is_fn_like();
let is_assoc_const = def_kind == DefKind::AssocConst;
// Only run const prop on functions, methods, closures and associated constants
if !is_fn_like && !is_assoc_const {
// skip anon_const/statics/consts because they'll be evaluated by miri anyway
trace!("KnownPanicsLint skipped for {:?}", def_id);
return;
}
// FIXME(welseywiser) const prop doesn't work on coroutines because of query cycles
// computing their layout.
if tcx.is_coroutine(def_id.to_def_id()) {
trace!("KnownPanicsLint skipped for coroutine {:?}", def_id);
return;
}
trace!("KnownPanicsLint starting for {:?}", def_id);
let mut linter = ConstPropagator::new(body, tcx);
linter.visit_body(body);
trace!("KnownPanicsLint done for {:?}", def_id);
}
}
/// Visits MIR nodes, performs const propagation
/// and runs lint checks as it goes
struct ConstPropagator<'mir, 'tcx> {
ecx: InterpCx<'mir, 'tcx, DummyMachine>,
tcx: TyCtxt<'tcx>,
param_env: ParamEnv<'tcx>,
worklist: Vec<BasicBlock>,
visited_blocks: BitSet<BasicBlock>,
locals: IndexVec<Local, Value<'tcx>>,
body: &'mir Body<'tcx>,
written_only_inside_own_block_locals: FxHashSet<Local>,
can_const_prop: IndexVec<Local, ConstPropMode>,
}
#[derive(Debug, Clone)]
enum Value<'tcx> {
Immediate(ImmTy<'tcx>),
Aggregate { variant: VariantIdx, fields: IndexVec<FieldIdx, Value<'tcx>> },
Uninit,
}
impl<'tcx> From<ImmTy<'tcx>> for Value<'tcx> {
fn from(v: ImmTy<'tcx>) -> Self {
Self::Immediate(v)
}
}
impl<'tcx> Value<'tcx> {
fn project(
&self,
proj: &[PlaceElem<'tcx>],
prop: &ConstPropagator<'_, 'tcx>,
) -> Option<&Value<'tcx>> {
let mut this = self;
for proj in proj {
this = match (*proj, this) {
(PlaceElem::Field(idx, _), Value::Aggregate { fields, .. }) => {
fields.get(idx).unwrap_or(&Value::Uninit)
}
(PlaceElem::Index(idx), Value::Aggregate { fields, .. }) => {
let idx = prop.get_const(idx.into())?.immediate()?;
let idx = prop.ecx.read_target_usize(idx).ok()?;
fields.get(FieldIdx::from_u32(idx.try_into().ok()?)).unwrap_or(&Value::Uninit)
}
(
PlaceElem::ConstantIndex { offset, min_length: _, from_end: false },
Value::Aggregate { fields, .. },
) => fields
.get(FieldIdx::from_u32(offset.try_into().ok()?))
.unwrap_or(&Value::Uninit),
_ => return None,
};
}
Some(this)
}
fn project_mut(&mut self, proj: &[PlaceElem<'_>]) -> Option<&mut Value<'tcx>> {
let mut this = self;
for proj in proj {
this = match (proj, this) {
(PlaceElem::Field(idx, _), Value::Aggregate { fields, .. }) => {
fields.ensure_contains_elem(*idx, || Value::Uninit)
}
(PlaceElem::Field(..), val @ Value::Uninit) => {
*val =
Value::Aggregate { variant: VariantIdx::ZERO, fields: Default::default() };
val.project_mut(&[*proj])?
}
_ => return None,
};
}
Some(this)
}
fn immediate(&self) -> Option<&ImmTy<'tcx>> {
match self {
Value::Immediate(op) => Some(op),
_ => None,
}
}
}
impl<'tcx> LayoutOfHelpers<'tcx> for ConstPropagator<'_, 'tcx> {
type LayoutOfResult = Result<TyAndLayout<'tcx>, LayoutError<'tcx>>;
#[inline]
fn handle_layout_err(&self, err: LayoutError<'tcx>, _: Span, _: Ty<'tcx>) -> LayoutError<'tcx> {
err
}
}
impl HasDataLayout for ConstPropagator<'_, '_> {
#[inline]
fn data_layout(&self) -> &TargetDataLayout {
&self.tcx.data_layout
}
}
impl<'tcx> ty::layout::HasTyCtxt<'tcx> for ConstPropagator<'_, 'tcx> {
#[inline]
fn tcx(&self) -> TyCtxt<'tcx> {
self.tcx
}
}
impl<'tcx> ty::layout::HasParamEnv<'tcx> for ConstPropagator<'_, 'tcx> {
#[inline]
fn param_env(&self) -> ty::ParamEnv<'tcx> {
self.param_env
}
}
impl<'mir, 'tcx> ConstPropagator<'mir, 'tcx> {
fn new(body: &'mir Body<'tcx>, tcx: TyCtxt<'tcx>) -> ConstPropagator<'mir, 'tcx> {
let def_id = body.source.def_id();
let param_env = tcx.param_env_reveal_all_normalized(def_id);
let can_const_prop = CanConstProp::check(tcx, param_env, body);
let ecx = InterpCx::new(tcx, tcx.def_span(def_id), param_env, DummyMachine);
ConstPropagator {
ecx,
tcx,
param_env,
worklist: vec![START_BLOCK],
visited_blocks: BitSet::new_empty(body.basic_blocks.len()),
locals: IndexVec::from_elem_n(Value::Uninit, body.local_decls.len()),
body,
can_const_prop,
written_only_inside_own_block_locals: Default::default(),
}
}
fn local_decls(&self) -> &'mir LocalDecls<'tcx> {
&self.body.local_decls
}
fn get_const(&self, place: Place<'tcx>) -> Option<&Value<'tcx>> {
self.locals[place.local].project(&place.projection, self)
}
/// Remove `local` from the pool of `Locals`. Allows writing to them,
/// but not reading from them anymore.
fn remove_const(&mut self, local: Local) {
self.locals[local] = Value::Uninit;
self.written_only_inside_own_block_locals.remove(&local);
}
fn access_mut(&mut self, place: &Place<'_>) -> Option<&mut Value<'tcx>> {
match self.can_const_prop[place.local] {
ConstPropMode::NoPropagation => return None,
ConstPropMode::OnlyInsideOwnBlock => {
self.written_only_inside_own_block_locals.insert(place.local);
}
ConstPropMode::FullConstProp => {}
}
self.locals[place.local].project_mut(place.projection)
}
fn lint_root(&self, source_info: SourceInfo) -> Option<HirId> {
source_info.scope.lint_root(&self.body.source_scopes)
}
fn use_ecx<F, T>(&mut self, f: F) -> Option<T>
where
F: FnOnce(&mut Self) -> InterpResult<'tcx, T>,
{
match f(self) {
Ok(val) => Some(val),
Err(error) => {
trace!("InterpCx operation failed: {:?}", error);
// Some errors shouldn't come up because creating them causes
// an allocation, which we should avoid. When that happens,
// dedicated error variants should be introduced instead.
assert!(
!error.kind().formatted_string(),
"known panics lint encountered formatting error: {}",
format_interp_error(self.ecx.tcx.dcx(), error),
);
None
}
}
}
/// Returns the value, if any, of evaluating `c`.
fn eval_constant(&mut self, c: &ConstOperand<'tcx>) -> Option<ImmTy<'tcx>> {
// FIXME we need to revisit this for #67176
if c.has_param() {
return None;
}
// Normalization needed b/c known panics lint runs 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.try_normalize_erasing_regions(self.param_env, c.const_).ok()?;
self.use_ecx(|this| this.ecx.eval_mir_constant(&val, c.span, None))?
.as_mplace_or_imm()
.right()
}
/// Returns the value, if any, of evaluating `place`.
#[instrument(level = "trace", skip(self), ret)]
fn eval_place(&mut self, place: Place<'tcx>) -> Option<ImmTy<'tcx>> {
match self.get_const(place)? {
Value::Immediate(imm) => Some(imm.clone()),
Value::Aggregate { .. } => None,
Value::Uninit => None,
}
}
/// Returns the value, if any, of evaluating `op`. Calls upon `eval_constant`
/// or `eval_place`, depending on the variant of `Operand` used.
fn eval_operand(&mut self, op: &Operand<'tcx>) -> Option<ImmTy<'tcx>> {
match *op {
Operand::Constant(ref c) => self.eval_constant(c),
Operand::Move(place) | Operand::Copy(place) => self.eval_place(place),
}
}
fn report_assert_as_lint(
&self,
location: Location,
lint_kind: AssertLintKind,
assert_kind: AssertKind<impl Debug>,
) {
let source_info = self.body.source_info(location);
if let Some(lint_root) = self.lint_root(*source_info) {
let span = source_info.span;
self.tcx.emit_node_span_lint(
lint_kind.lint(),
lint_root,
span,
AssertLint { span, assert_kind, lint_kind },
);
}
}
fn check_unary_op(&mut self, op: UnOp, arg: &Operand<'tcx>, location: Location) -> Option<()> {
let arg = self.eval_operand(arg)?;
if let (val, true) = self.use_ecx(|this| {
let val = this.ecx.read_immediate(&arg)?;
let (_res, overflow) = this.ecx.overflowing_unary_op(op, &val)?;
Ok((val, overflow))
})? {
// `AssertKind` only has an `OverflowNeg` variant, so make sure that is
// appropriate to use.
assert_eq!(op, UnOp::Neg, "Neg is the only UnOp that can overflow");
self.report_assert_as_lint(
location,
AssertLintKind::ArithmeticOverflow,
AssertKind::OverflowNeg(val.to_const_int()),
);
return None;
}
Some(())
}
fn check_binary_op(
&mut self,
op: BinOp,
left: &Operand<'tcx>,
right: &Operand<'tcx>,
location: Location,
) -> Option<()> {
let r =
self.eval_operand(right).and_then(|r| self.use_ecx(|this| this.ecx.read_immediate(&r)));
let l =
self.eval_operand(left).and_then(|l| self.use_ecx(|this| this.ecx.read_immediate(&l)));
// Check for exceeding shifts *even if* we cannot evaluate the LHS.
if matches!(op, BinOp::Shr | BinOp::Shl) {
let r = r.clone()?;
// We need the type of the LHS. We cannot use `place_layout` as that is the type
// of the result, which for checked binops is not the same!
let left_ty = left.ty(self.local_decls(), self.tcx);
let left_size = self.ecx.layout_of(left_ty).ok()?.size;
let right_size = r.layout.size;
let r_bits = r.to_scalar().to_bits(right_size).ok();
if r_bits.is_some_and(|b| b >= left_size.bits() as u128) {
debug!("check_binary_op: reporting assert for {:?}", location);
let panic = AssertKind::Overflow(
op,
match l {
Some(l) => l.to_const_int(),
// Invent a dummy value, the diagnostic ignores it anyway
None => ConstInt::new(
ScalarInt::try_from_uint(1_u8, left_size).unwrap(),
left_ty.is_signed(),
left_ty.is_ptr_sized_integral(),
),
},
r.to_const_int(),
);
self.report_assert_as_lint(location, AssertLintKind::ArithmeticOverflow, panic);
return None;
}
}
if let (Some(l), Some(r)) = (l, r) {
// The remaining operators are handled through `overflowing_binary_op`.
if self.use_ecx(|this| {
let (_res, overflow) = this.ecx.overflowing_binary_op(op, &l, &r)?;
Ok(overflow)
})? {
self.report_assert_as_lint(
location,
AssertLintKind::ArithmeticOverflow,
AssertKind::Overflow(op, l.to_const_int(), r.to_const_int()),
);
return None;
}
}
Some(())
}
fn check_rvalue(&mut self, rvalue: &Rvalue<'tcx>, location: Location) -> Option<()> {
// Perform any special handling for specific Rvalue types.
// Generally, checks here fall into one of two categories:
// 1. Additional checking to provide useful lints to the user
// - In this case, we will do some validation and then fall through to the
// end of the function which evals the assignment.
// 2. Working around bugs in other parts of the compiler
// - In this case, we'll return `None` from this function to stop evaluation.
match rvalue {
// Additional checking: give lints to the user if an overflow would occur.
// We do this here and not in the `Assert` terminator as that terminator is
// only sometimes emitted (overflow checks can be disabled), but we want to always
// lint.
Rvalue::UnaryOp(op, arg) => {
trace!("checking UnaryOp(op = {:?}, arg = {:?})", op, arg);
self.check_unary_op(*op, arg, location)?;
}
Rvalue::BinaryOp(op, box (left, right)) => {
trace!("checking BinaryOp(op = {:?}, left = {:?}, right = {:?})", op, left, right);
self.check_binary_op(*op, left, right, location)?;
}
Rvalue::CheckedBinaryOp(op, box (left, right)) => {
trace!(
"checking CheckedBinaryOp(op = {:?}, left = {:?}, right = {:?})",
op,
left,
right
);
self.check_binary_op(*op, left, right, location)?;
}
// Do not try creating references (#67862)
Rvalue::AddressOf(_, place) | Rvalue::Ref(_, _, place) => {
trace!("skipping AddressOf | Ref for {:?}", place);
// This may be creating mutable references or immutable references to cells.
// If that happens, the pointed to value could be mutated via that reference.
// Since we aren't tracking references, the const propagator loses track of what
// value the local has right now.
// Thus, all locals that have their reference taken
// must not take part in propagation.
self.remove_const(place.local);
return None;
}
Rvalue::ThreadLocalRef(def_id) => {
trace!("skipping ThreadLocalRef({:?})", def_id);
return None;
}
// There's no other checking to do at this time.
Rvalue::Aggregate(..)
| Rvalue::Use(..)
| Rvalue::CopyForDeref(..)
| Rvalue::Repeat(..)
| Rvalue::Len(..)
| Rvalue::Cast(..)
| Rvalue::ShallowInitBox(..)
| Rvalue::Discriminant(..)
| Rvalue::NullaryOp(..) => {}
}
// FIXME we need to revisit this for #67176
if rvalue.has_param() {
return None;
}
if !rvalue.ty(self.local_decls(), self.tcx).is_sized(self.tcx, self.param_env) {
// the interpreter doesn't support unsized locals (only unsized arguments),
// but rustc does (in a kinda broken way), so we have to skip them here
return None;
}
Some(())
}
fn check_assertion(
&mut self,
expected: bool,
msg: &AssertKind<Operand<'tcx>>,
cond: &Operand<'tcx>,
location: Location,
) -> Option<!> {
let value = &self.eval_operand(cond)?;
trace!("assertion on {:?} should be {:?}", value, expected);
let expected = Scalar::from_bool(expected);
let value_const = self.use_ecx(|this| this.ecx.read_scalar(value))?;
if expected != value_const {
// Poison all places this operand references so that further code
// doesn't use the invalid value
if let Some(place) = cond.place() {
self.remove_const(place.local);
}
enum DbgVal<T> {
Val(T),
Underscore,
}
impl<T: std::fmt::Debug> std::fmt::Debug for DbgVal<T> {
fn fmt(&self, fmt: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
Self::Val(val) => val.fmt(fmt),
Self::Underscore => fmt.write_str("_"),
}
}
}
let mut eval_to_int = |op| {
// This can be `None` if the lhs wasn't const propagated and we just
// triggered the assert on the value of the rhs.
self.eval_operand(op)
.and_then(|op| self.ecx.read_immediate(&op).ok())
.map_or(DbgVal::Underscore, |op| DbgVal::Val(op.to_const_int()))
};
let msg = match msg {
AssertKind::DivisionByZero(op) => AssertKind::DivisionByZero(eval_to_int(op)),
AssertKind::RemainderByZero(op) => AssertKind::RemainderByZero(eval_to_int(op)),
AssertKind::Overflow(bin_op @ (BinOp::Div | BinOp::Rem), op1, op2) => {
// Division overflow is *UB* in the MIR, and different than the
// other overflow checks.
AssertKind::Overflow(*bin_op, eval_to_int(op1), eval_to_int(op2))
}
AssertKind::BoundsCheck { ref len, ref index } => {
let len = eval_to_int(len);
let index = eval_to_int(index);
AssertKind::BoundsCheck { len, index }
}
// Remaining overflow errors are already covered by checks on the binary operators.
AssertKind::Overflow(..) | AssertKind::OverflowNeg(_) => return None,
// Need proper const propagator for these.
_ => return None,
};
self.report_assert_as_lint(location, AssertLintKind::UnconditionalPanic, msg);
}
None
}
fn ensure_not_propagated(&self, local: Local) {
if cfg!(debug_assertions) {
let val = self.get_const(local.into());
assert!(
matches!(val, Some(Value::Uninit))
|| self
.layout_of(self.local_decls()[local].ty)
.map_or(true, |layout| layout.is_zst()),
"failed to remove values for `{local:?}`, value={val:?}",
)
}
}
#[instrument(level = "trace", skip(self), ret)]
fn eval_rvalue(&mut self, rvalue: &Rvalue<'tcx>, dest: &Place<'tcx>) -> Option<()> {
if !dest.projection.is_empty() {
return None;
}
use rustc_middle::mir::Rvalue::*;
let layout = self.ecx.layout_of(dest.ty(self.body, self.tcx).ty).ok()?;
trace!(?layout);
let val: Value<'_> = match *rvalue {
ThreadLocalRef(_) => return None,
Use(ref operand) => self.eval_operand(operand)?.into(),
CopyForDeref(place) => self.eval_place(place)?.into(),
BinaryOp(bin_op, box (ref left, ref right)) => {
let left = self.eval_operand(left)?;
let left = self.use_ecx(|this| this.ecx.read_immediate(&left))?;
let right = self.eval_operand(right)?;
let right = self.use_ecx(|this| this.ecx.read_immediate(&right))?;
let val =
self.use_ecx(|this| this.ecx.wrapping_binary_op(bin_op, &left, &right))?;
val.into()
}
CheckedBinaryOp(bin_op, box (ref left, ref right)) => {
let left = self.eval_operand(left)?;
let left = self.use_ecx(|this| this.ecx.read_immediate(&left))?;
let right = self.eval_operand(right)?;
let right = self.use_ecx(|this| this.ecx.read_immediate(&right))?;
let (val, overflowed) =
self.use_ecx(|this| this.ecx.overflowing_binary_op(bin_op, &left, &right))?;
let overflowed = ImmTy::from_bool(overflowed, self.tcx);
Value::Aggregate {
variant: VariantIdx::ZERO,
fields: [Value::from(val), overflowed.into()].into_iter().collect(),
}
}
UnaryOp(un_op, ref operand) => {
let operand = self.eval_operand(operand)?;
let val = self.use_ecx(|this| this.ecx.read_immediate(&operand))?;
let val = self.use_ecx(|this| this.ecx.wrapping_unary_op(un_op, &val))?;
val.into()
}
Aggregate(ref kind, ref fields) => {
// Do not const prop union fields as they can be
// made to produce values that don't match their
// underlying layout's type (see ICE #121534).
// If the last element of the `Adt` tuple
// is `Some` it indicates the ADT is a union
if let AggregateKind::Adt(_, _, _, _, Some(_)) = **kind {
return None;
};
Value::Aggregate {
fields: fields
.iter()
.map(|field| {
self.eval_operand(field).map_or(Value::Uninit, Value::Immediate)
})
.collect(),
variant: match **kind {
AggregateKind::Adt(_, variant, _, _, _) => variant,
AggregateKind::Array(_)
| AggregateKind::Tuple
| AggregateKind::RawPtr(_, _)
| AggregateKind::Closure(_, _)
| AggregateKind::Coroutine(_, _)
| AggregateKind::CoroutineClosure(_, _) => VariantIdx::ZERO,
},
}
}
Repeat(ref op, n) => {
trace!(?op, ?n);
return None;
}
Len(place) => {
let len = match self.get_const(place)? {
Value::Immediate(src) => src.len(&self.ecx).ok()?,
Value::Aggregate { fields, .. } => fields.len() as u64,
Value::Uninit => match place.ty(self.local_decls(), self.tcx).ty.kind() {
ty::Array(_, n) => n.try_eval_target_usize(self.tcx, self.param_env)?,
_ => return None,
},
};
ImmTy::from_scalar(Scalar::from_target_usize(len, self), layout).into()
}
Ref(..) | AddressOf(..) => return None,
NullaryOp(ref null_op, ty) => {
let op_layout = self.use_ecx(|this| this.ecx.layout_of(ty))?;
let val = match null_op {
NullOp::SizeOf => op_layout.size.bytes(),
NullOp::AlignOf => op_layout.align.abi.bytes(),
NullOp::OffsetOf(fields) => {
op_layout.offset_of_subfield(self, fields.iter()).bytes()
}
NullOp::UbChecks => return None,
};
ImmTy::from_scalar(Scalar::from_target_usize(val, self), layout).into()
}
ShallowInitBox(..) => return None,
Cast(ref kind, ref value, to) => match kind {
CastKind::IntToInt | CastKind::IntToFloat => {
let value = self.eval_operand(value)?;
let value = self.ecx.read_immediate(&value).ok()?;
let to = self.ecx.layout_of(to).ok()?;
let res = self.ecx.int_to_int_or_float(&value, to).ok()?;
res.into()
}
CastKind::FloatToFloat | CastKind::FloatToInt => {
let value = self.eval_operand(value)?;
let value = self.ecx.read_immediate(&value).ok()?;
let to = self.ecx.layout_of(to).ok()?;
let res = self.ecx.float_to_float_or_int(&value, to).ok()?;
res.into()
}
CastKind::Transmute => {
let value = self.eval_operand(value)?;
let to = self.ecx.layout_of(to).ok()?;
// `offset` for immediates only supports scalar/scalar-pair ABIs,
// so bail out if the target is not one.
match (value.layout.abi, to.abi) {
(Abi::Scalar(..), Abi::Scalar(..)) => {}
(Abi::ScalarPair(..), Abi::ScalarPair(..)) => {}
_ => return None,
}
value.offset(Size::ZERO, to, &self.ecx).ok()?.into()
}
_ => return None,
},
Discriminant(place) => {
let variant = match self.get_const(place)? {
Value::Immediate(op) => {
let op = op.clone();
self.use_ecx(|this| this.ecx.read_discriminant(&op))?
}
Value::Aggregate { variant, .. } => *variant,
Value::Uninit => return None,
};
let imm = self.use_ecx(|this| {
this.ecx.discriminant_for_variant(
place.ty(this.local_decls(), this.tcx).ty,
variant,
)
})?;
imm.into()
}
};
trace!(?val);
*self.access_mut(dest)? = val;
Some(())
}
}
impl<'tcx> Visitor<'tcx> for ConstPropagator<'_, 'tcx> {
fn visit_body(&mut self, body: &Body<'tcx>) {
while let Some(bb) = self.worklist.pop() {
if !self.visited_blocks.insert(bb) {
continue;
}
let data = &body.basic_blocks[bb];
self.visit_basic_block_data(bb, data);
}
}
fn visit_operand(&mut self, operand: &Operand<'tcx>, location: Location) {
self.super_operand(operand, location);
}
fn visit_constant(&mut self, constant: &ConstOperand<'tcx>, location: Location) {
trace!("visit_constant: {:?}", constant);
self.super_constant(constant, location);
self.eval_constant(constant);
}
fn visit_assign(&mut self, place: &Place<'tcx>, rvalue: &Rvalue<'tcx>, location: Location) {
self.super_assign(place, rvalue, location);
let Some(()) = self.check_rvalue(rvalue, location) else { return };
match self.can_const_prop[place.local] {
// Do nothing if the place is indirect.
_ if place.is_indirect() => {}
ConstPropMode::NoPropagation => self.ensure_not_propagated(place.local),
ConstPropMode::OnlyInsideOwnBlock | ConstPropMode::FullConstProp => {
if self.eval_rvalue(rvalue, place).is_none() {
// Const prop failed, so erase the destination, ensuring that whatever happens
// from here on, does not know about the previous value.
// This is important in case we have
// ```rust
// let mut x = 42;
// x = SOME_MUTABLE_STATIC;
// // x must now be uninit
// ```
// FIXME: we overzealously erase the entire local, because that's easier to
// implement.
trace!(
"propagation into {:?} failed.
Nuking the entire site from orbit, it's the only way to be sure",
place,
);
self.remove_const(place.local);
}
}
}
}
fn visit_statement(&mut self, statement: &Statement<'tcx>, location: Location) {
trace!("visit_statement: {:?}", statement);
// We want to evaluate operands before any change to the assigned-to value,
// so we recurse first.
self.super_statement(statement, location);
match statement.kind {
StatementKind::SetDiscriminant { ref place, variant_index } => {
match self.can_const_prop[place.local] {
// Do nothing if the place is indirect.
_ if place.is_indirect() => {}
ConstPropMode::NoPropagation => self.ensure_not_propagated(place.local),
ConstPropMode::FullConstProp | ConstPropMode::OnlyInsideOwnBlock => {
match self.access_mut(place) {
Some(Value::Aggregate { variant, .. }) => *variant = variant_index,
_ => self.remove_const(place.local),
}
}
}
}
StatementKind::StorageLive(local) => {
self.remove_const(local);
}
StatementKind::StorageDead(local) => {
self.remove_const(local);
}
_ => {}
}
}
fn visit_terminator(&mut self, terminator: &Terminator<'tcx>, location: Location) {
self.super_terminator(terminator, location);
match &terminator.kind {
TerminatorKind::Assert { expected, ref msg, ref cond, .. } => {
self.check_assertion(*expected, msg, cond, location);
}
TerminatorKind::SwitchInt { ref discr, ref targets } => {
if let Some(ref value) = self.eval_operand(discr)
&& let Some(value_const) = self.use_ecx(|this| this.ecx.read_scalar(value))
&& let Ok(constant) = value_const.try_to_int()
&& let Ok(constant) = constant.try_to_bits(constant.size())
{
// We managed to evaluate the discriminant, so we know we only need to visit
// one target.
let target = targets.target_for_value(constant);
self.worklist.push(target);
return;
}
// We failed to evaluate the discriminant, fallback to visiting all successors.
}
// None of these have Operands to const-propagate.
TerminatorKind::Goto { .. }
| TerminatorKind::UnwindResume
| TerminatorKind::UnwindTerminate(_)
| TerminatorKind::Return
| TerminatorKind::Unreachable
| TerminatorKind::Drop { .. }
| TerminatorKind::Yield { .. }
| TerminatorKind::CoroutineDrop
| TerminatorKind::FalseEdge { .. }
| TerminatorKind::FalseUnwind { .. }
| TerminatorKind::Call { .. }
| TerminatorKind::InlineAsm { .. } => {}
}
self.worklist.extend(terminator.successors());
}
fn visit_basic_block_data(&mut self, block: BasicBlock, data: &BasicBlockData<'tcx>) {
self.super_basic_block_data(block, data);
// We remove all Locals which are restricted in propagation to their containing blocks and
// which were modified in the current block.
// Take it out of the ecx so we can get a mutable reference to the ecx for `remove_const`.
let mut written_only_inside_own_block_locals =
std::mem::take(&mut self.written_only_inside_own_block_locals);
// This loop can get very hot for some bodies: it check each local in each bb.
// To avoid this quadratic behaviour, we only clear the locals that were modified inside
// the current block.
// The order in which we remove consts does not matter.
#[allow(rustc::potential_query_instability)]
for local in written_only_inside_own_block_locals.drain() {
debug_assert_eq!(self.can_const_prop[local], ConstPropMode::OnlyInsideOwnBlock);
self.remove_const(local);
}
self.written_only_inside_own_block_locals = written_only_inside_own_block_locals;
if cfg!(debug_assertions) {
for (local, &mode) in self.can_const_prop.iter_enumerated() {
match mode {
ConstPropMode::FullConstProp => {}
ConstPropMode::NoPropagation | ConstPropMode::OnlyInsideOwnBlock => {
self.ensure_not_propagated(local);
}
}
}
}
}
}
/// The maximum number of bytes that we'll allocate space for a local or the return value.
/// Needed for #66397, because otherwise we eval into large places and that can cause OOM or just
/// Severely regress performance.
const MAX_ALLOC_LIMIT: u64 = 1024;
/// The mode that `ConstProp` is allowed to run in for a given `Local`.
#[derive(Clone, Copy, Debug, PartialEq)]
pub enum ConstPropMode {
/// The `Local` can be propagated into and reads of this `Local` can also be propagated.
FullConstProp,
/// The `Local` can only be propagated into and from its own block.
OnlyInsideOwnBlock,
/// The `Local` cannot be part of propagation at all. Any statement
/// referencing it either for reading or writing will not get propagated.
NoPropagation,
}
/// A visitor that determines locals in a MIR body
/// that can be const propagated
pub struct CanConstProp {
can_const_prop: IndexVec<Local, ConstPropMode>,
// False at the beginning. Once set, no more assignments are allowed to that local.
found_assignment: BitSet<Local>,
}
impl CanConstProp {
/// Returns true if `local` can be propagated
pub fn check<'tcx>(
tcx: TyCtxt<'tcx>,
param_env: ParamEnv<'tcx>,
body: &Body<'tcx>,
) -> IndexVec<Local, ConstPropMode> {
let mut cpv = CanConstProp {
can_const_prop: IndexVec::from_elem(ConstPropMode::FullConstProp, &body.local_decls),
found_assignment: BitSet::new_empty(body.local_decls.len()),
};
for (local, val) in cpv.can_const_prop.iter_enumerated_mut() {
let ty = body.local_decls[local].ty;
if ty.is_union() {
// Do not const prop unions as they can
// ICE during layout calc
*val = ConstPropMode::NoPropagation;
} else {
match tcx.layout_of(param_env.and(ty)) {
Ok(layout) if layout.size < Size::from_bytes(MAX_ALLOC_LIMIT) => {}
// Either the layout fails to compute, then we can't use this local anyway
// or the local is too large, then we don't want to.
_ => {
*val = ConstPropMode::NoPropagation;
continue;
}
}
}
}
// Consider that arguments are assigned on entry.
for arg in body.args_iter() {
cpv.found_assignment.insert(arg);
}
cpv.visit_body(body);
cpv.can_const_prop
}
}
impl<'tcx> Visitor<'tcx> for CanConstProp {
fn visit_place(&mut self, place: &Place<'tcx>, mut context: PlaceContext, loc: Location) {
use rustc_middle::mir::visit::PlaceContext::*;
// Dereferencing just read the addess of `place.local`.
if place.projection.first() == Some(&PlaceElem::Deref) {
context = NonMutatingUse(NonMutatingUseContext::Copy);
}
self.visit_local(place.local, context, loc);
self.visit_projection(place.as_ref(), context, loc);
}
fn visit_local(&mut self, local: Local, context: PlaceContext, _: Location) {
use rustc_middle::mir::visit::PlaceContext::*;
match context {
// These are just stores, where the storing is not propagatable, but there may be later
// mutations of the same local via `Store`
| MutatingUse(MutatingUseContext::Call)
| MutatingUse(MutatingUseContext::AsmOutput)
| MutatingUse(MutatingUseContext::Deinit)
// Actual store that can possibly even propagate a value
| MutatingUse(MutatingUseContext::Store)
| MutatingUse(MutatingUseContext::SetDiscriminant) => {
if !self.found_assignment.insert(local) {
match &mut self.can_const_prop[local] {
// If the local can only get propagated in its own block, then we don't have
// to worry about multiple assignments, as we'll nuke the const state at the
// end of the block anyway, and inside the block we overwrite previous
// states as applicable.
ConstPropMode::OnlyInsideOwnBlock => {}
ConstPropMode::NoPropagation => {}
other @ ConstPropMode::FullConstProp => {
trace!(
"local {:?} can't be propagated because of multiple assignments. Previous state: {:?}",
local, other,
);
*other = ConstPropMode::OnlyInsideOwnBlock;
}
}
}
}
// Reading constants is allowed an arbitrary number of times
NonMutatingUse(NonMutatingUseContext::Copy)
| NonMutatingUse(NonMutatingUseContext::Move)
| NonMutatingUse(NonMutatingUseContext::Inspect)
| NonMutatingUse(NonMutatingUseContext::PlaceMention)
| NonUse(_) => {}
// These could be propagated with a smarter analysis or just some careful thinking about
// whether they'd be fine right now.
MutatingUse(MutatingUseContext::Yield)
| MutatingUse(MutatingUseContext::Drop)
| MutatingUse(MutatingUseContext::Retag)
// These can't ever be propagated under any scheme, as we can't reason about indirect
// mutation.
| NonMutatingUse(NonMutatingUseContext::SharedBorrow)
| NonMutatingUse(NonMutatingUseContext::FakeBorrow)
| NonMutatingUse(NonMutatingUseContext::AddressOf)
| MutatingUse(MutatingUseContext::Borrow)
| MutatingUse(MutatingUseContext::AddressOf) => {
trace!("local {:?} can't be propagated because it's used: {:?}", local, context);
self.can_const_prop[local] = ConstPropMode::NoPropagation;
}
MutatingUse(MutatingUseContext::Projection)
| NonMutatingUse(NonMutatingUseContext::Projection) => bug!("visit_place should not pass {context:?} for {local:?}"),
}
}
}