Avoid lowering code under dead SwitchInt targets
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a165f1f650
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@ -1237,6 +1237,16 @@ pub fn codegen_block(&mut self, mut bb: mir::BasicBlock) {
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}
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}
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pub fn codegen_block_as_unreachable(&mut self, bb: mir::BasicBlock) {
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let llbb = match self.try_llbb(bb) {
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Some(llbb) => llbb,
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None => return,
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};
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let bx = &mut Bx::build(self.cx, llbb);
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debug!("codegen_block_as_unreachable({:?})", bb);
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bx.unreachable();
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}
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fn codegen_terminator(
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&mut self,
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bx: &mut Bx,
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@ -256,13 +256,22 @@ pub fn codegen_mir<'a, 'tcx, Bx: BuilderMethods<'a, 'tcx>>(
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// Apply debuginfo to the newly allocated locals.
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fx.debug_introduce_locals(&mut start_bx);
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let reachable_blocks = mir.reachable_blocks_in_mono(cx.tcx(), instance);
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// The builders will be created separately for each basic block at `codegen_block`.
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// So drop the builder of `start_llbb` to avoid having two at the same time.
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drop(start_bx);
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// Codegen the body of each block using reverse postorder
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for (bb, _) in traversal::reverse_postorder(mir) {
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if reachable_blocks.contains(bb) {
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fx.codegen_block(bb);
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} else {
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// This may have references to things we didn't monomorphize, so we
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// don't actually codegen the body. We still create the block so
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// terminators in other blocks can reference it without worry.
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fx.codegen_block_as_unreachable(bb);
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}
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}
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}
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@ -10,7 +10,7 @@
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use crate::ty::print::{FmtPrinter, Printer};
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use crate::ty::visit::TypeVisitableExt;
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use crate::ty::{self, List, Ty, TyCtxt};
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use crate::ty::{AdtDef, InstanceDef, UserTypeAnnotationIndex};
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use crate::ty::{AdtDef, Instance, InstanceDef, UserTypeAnnotationIndex};
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use crate::ty::{GenericArg, GenericArgsRef};
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use rustc_data_structures::captures::Captures;
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@ -27,6 +27,8 @@
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use rustc_data_structures::fx::FxHashMap;
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use rustc_data_structures::fx::FxHashSet;
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use rustc_data_structures::graph::dominators::Dominators;
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use rustc_data_structures::stack::ensure_sufficient_stack;
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use rustc_index::bit_set::BitSet;
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use rustc_index::{Idx, IndexSlice, IndexVec};
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use rustc_serialize::{Decodable, Encodable};
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use rustc_span::symbol::Symbol;
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@ -640,6 +642,129 @@ pub fn is_custom_mir(&self) -> bool {
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self.injection_phase.is_some()
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}
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/// Finds which basic blocks are actually reachable for a specific
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/// monomorphization of this body.
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///
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/// This is allowed to have false positives; just because this says a block
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/// is reachable doesn't mean that's necessarily true. It's thus always
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/// legal for this to return a filled set.
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///
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/// Regardless, the [`BitSet::domain_size`] of the returned set will always
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/// exactly match the number of blocks in the body so that `contains`
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/// checks can be done without worrying about panicking.
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///
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/// This is mostly useful because it lets us skip lowering the `false` side
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/// of `if <T as Trait>::CONST`, as well as `intrinsics::debug_assertions`.
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pub fn reachable_blocks_in_mono(
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&self,
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tcx: TyCtxt<'tcx>,
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instance: Instance<'tcx>,
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) -> BitSet<BasicBlock> {
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let mut set = BitSet::new_empty(self.basic_blocks.len());
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self.reachable_blocks_in_mono_from(tcx, instance, &mut set, START_BLOCK);
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set
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}
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fn reachable_blocks_in_mono_from(
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&self,
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tcx: TyCtxt<'tcx>,
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instance: Instance<'tcx>,
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set: &mut BitSet<BasicBlock>,
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bb: BasicBlock,
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) {
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if !set.insert(bb) {
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return;
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}
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let data = &self.basic_blocks[bb];
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if let Some((bits, targets)) = Self::try_const_mono_switchint(tcx, instance, data) {
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let target = targets.target_for_value(bits);
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ensure_sufficient_stack(|| {
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self.reachable_blocks_in_mono_from(tcx, instance, set, target)
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});
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return;
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}
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for target in data.terminator().successors() {
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ensure_sufficient_stack(|| {
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self.reachable_blocks_in_mono_from(tcx, instance, set, target)
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});
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}
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}
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/// If this basic block ends with a [`TerminatorKind::SwitchInt`] for which we can evaluate the
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/// dimscriminant in monomorphization, we return the discriminant bits and the
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/// [`SwitchTargets`], just so the caller doesn't also have to match on the terminator.
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fn try_const_mono_switchint<'a>(
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tcx: TyCtxt<'tcx>,
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instance: Instance<'tcx>,
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block: &'a BasicBlockData<'tcx>,
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) -> Option<(u128, &'a SwitchTargets)> {
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// There are two places here we need to evaluate a constant.
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let eval_mono_const = |constant: &ConstOperand<'tcx>| {
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let env = ty::ParamEnv::reveal_all();
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let mono_literal = instance.instantiate_mir_and_normalize_erasing_regions(
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tcx,
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env,
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crate::ty::EarlyBinder::bind(constant.const_),
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);
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let Some(bits) = mono_literal.try_eval_bits(tcx, env) else {
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bug!("Couldn't evaluate constant {:?} in mono {:?}", constant, instance);
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};
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bits
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};
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let TerminatorKind::SwitchInt { discr, targets } = &block.terminator().kind else {
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return None;
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};
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// If this is a SwitchInt(const _), then we can just evaluate the constant and return.
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let discr = match discr {
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Operand::Constant(constant) => {
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let bits = eval_mono_const(constant);
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return Some((bits, targets));
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}
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Operand::Move(place) | Operand::Copy(place) => place,
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};
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// MIR for `if false` actually looks like this:
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// _1 = const _
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// SwitchInt(_1)
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//
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// And MIR for if intrinsics::debug_assertions() looks like this:
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// _1 = cfg!(debug_assertions)
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// SwitchInt(_1)
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//
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// So we're going to try to recognize this pattern.
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//
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// If we have a SwitchInt on a non-const place, we find the most recent statement that
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// isn't a storage marker. If that statement is an assignment of a const to our
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// discriminant place, we evaluate and return the const, as if we've const-propagated it
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// into the SwitchInt.
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let last_stmt = block.statements.iter().rev().find(|stmt| {
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!matches!(stmt.kind, StatementKind::StorageDead(_) | StatementKind::StorageLive(_))
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})?;
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let (place, rvalue) = last_stmt.kind.as_assign()?;
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if discr != place {
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return None;
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}
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match rvalue {
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Rvalue::NullaryOp(NullOp::UbCheck(_), _) => {
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Some((tcx.sess.opts.debug_assertions as u128, targets))
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}
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Rvalue::Use(Operand::Constant(constant)) => {
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let bits = eval_mono_const(constant);
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Some((bits, targets))
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}
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_ => None,
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}
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}
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/// For a `Location` in this scope, determine what the "caller location" at that point is. This
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/// is interesting because of inlining: the `#[track_caller]` attribute of inlined functions
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/// must be honored. Falls back to the `tracked_caller` value for `#[track_caller]` functions,
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@ -1,5 +1,3 @@
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use rustc_index::bit_set::BitSet;
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use super::*;
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/// Preorder traversal of a graph.
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27
tests/codegen/precondition-checks.rs
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27
tests/codegen/precondition-checks.rs
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@ -0,0 +1,27 @@
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//@ compile-flags: -Cno-prepopulate-passes -Copt-level=0 -Cdebug-assertions=no
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// This test ensures that in a debug build which turns off debug assertions, we do not monomorphize
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// any of the standard library's unsafe precondition checks.
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// The naive codegen of those checks contains the actual check underneath an `if false`, which
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// could be optimized out if optimizations are enabled. But if we rely on optimizations to remove
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// panic branches, then we can't link compiler_builtins without optimizing it, which means that
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// -Zbuild-std doesn't work with -Copt-level=0.
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//
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// In other words, this tests for a mandatory optimization.
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#![crate_type = "lib"]
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use std::ptr::NonNull;
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// CHECK-LABEL: ; core::ptr::non_null::NonNull<T>::new_unchecked
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// CHECK-NOT: call
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// CHECK: }
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// CHECK-LABEL: @nonnull_new
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#[no_mangle]
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pub unsafe fn nonnull_new(ptr: *mut u8) -> NonNull<u8> {
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// CHECK: ; call core::ptr::non_null::NonNull<T>::new_unchecked
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unsafe {
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NonNull::new_unchecked(ptr)
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}
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}
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tests/codegen/skip-mono-inside-if-false.rs
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41
tests/codegen/skip-mono-inside-if-false.rs
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@ -0,0 +1,41 @@
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//@ compile-flags: -Cno-prepopulate-passes -Copt-level=0
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#![crate_type = "lib"]
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#[no_mangle]
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pub fn demo_for_i32() {
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generic_impl::<i32>();
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}
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// Two important things here:
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// - We replace the "then" block with `unreachable` to avoid linking problems
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// - We neither declare nor define the `big_impl` that said block "calls".
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// CHECK-LABEL: ; skip_mono_inside_if_false::generic_impl
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// CHECK: start:
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// CHECK-NEXT: br label %[[ELSE_BRANCH:bb[0-9]+]]
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// CHECK: [[ELSE_BRANCH]]:
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// CHECK-NEXT: call skip_mono_inside_if_false::small_impl
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// CHECK: bb{{[0-9]+}}:
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// CHECK-NEXT: ret void
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// CHECK: bb{{[0-9+]}}:
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// CHECK-NEXT: unreachable
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fn generic_impl<T>() {
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trait MagicTrait {
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const IS_BIG: bool;
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}
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impl<T> MagicTrait for T {
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const IS_BIG: bool = std::mem::size_of::<T>() > 10;
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}
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if T::IS_BIG {
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big_impl::<T>();
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} else {
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small_impl::<T>();
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}
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}
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#[inline(never)]
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fn small_impl<T>() {}
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#[inline(never)]
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fn big_impl<T>() {}
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