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fuchsia / third_party / rust / 0f9cb070bc312df3c9cadd358efaa1d1efe4a9d0 / . / compiler / rustc_mir_transform / src / lib.rs
blob: 62e73ba2c8e24dd55a2df143013f04500c4d3859 [file] [log] [blame]
// tidy-alphabetical-start
#![feature(assert_matches)]
#![feature(box_patterns)]
#![feature(const_type_name)]
#![feature(cow_is_borrowed)]
#![feature(if_let_guard)]
#![feature(impl_trait_in_assoc_type)]
#![feature(let_chains)]
#![feature(map_try_insert)]
#![feature(never_type)]
#![feature(round_char_boundary)]
#![feature(try_blocks)]
#![feature(yeet_expr)]
// tidy-alphabetical-end
use hir::ConstContext;
use required_consts::RequiredConstsVisitor;
use rustc_const_eval::check_consts::{self, ConstCx};
use rustc_const_eval::util;
use rustc_data_structures::fx::FxIndexSet;
use rustc_data_structures::steal::Steal;
use rustc_hir as hir;
use rustc_hir::def::DefKind;
use rustc_hir::def_id::LocalDefId;
use rustc_hir::intravisit::{self, Visitor};
use rustc_index::IndexVec;
use rustc_middle::mir::{
AnalysisPhase, Body, CallSource, ClearCrossCrate, ConstOperand, ConstQualifs, LocalDecl,
MirPhase, Operand, Place, ProjectionElem, Promoted, RuntimePhase, Rvalue, SourceInfo,
Statement, StatementKind, TerminatorKind, START_BLOCK,
};
use rustc_middle::ty::{self, TyCtxt, TypeVisitableExt};
use rustc_middle::util::Providers;
use rustc_middle::{bug, query, span_bug};
use rustc_span::source_map::Spanned;
use rustc_span::{sym, DUMMY_SP};
use rustc_trait_selection::traits;
use tracing::{debug, trace};
#[macro_use]
mod pass_manager;
use pass_manager::{self as pm, Lint, MirLint, MirPass, WithMinOptLevel};
mod abort_unwinding_calls;
mod add_call_guards;
mod add_moves_for_packed_drops;
mod add_retag;
mod add_subtyping_projections;
mod check_alignment;
mod check_const_item_mutation;
mod check_packed_ref;
// This pass is public to allow external drivers to perform MIR cleanup
pub mod cleanup_post_borrowck;
mod copy_prop;
mod coroutine;
mod cost_checker;
mod coverage;
mod cross_crate_inline;
mod ctfe_limit;
mod dataflow_const_prop;
mod dead_store_elimination;
mod deduce_param_attrs;
mod deduplicate_blocks;
mod deref_separator;
mod dest_prop;
pub mod dump_mir;
mod early_otherwise_branch;
mod elaborate_box_derefs;
mod elaborate_drops;
mod errors;
mod ffi_unwind_calls;
mod function_item_references;
mod gvn;
pub mod inline;
mod instsimplify;
mod jump_threading;
mod known_panics_lint;
mod large_enums;
mod lint;
mod lower_intrinsics;
mod lower_slice_len;
mod match_branches;
mod mentioned_items;
mod multiple_return_terminators;
mod nrvo;
mod prettify;
mod promote_consts;
mod ref_prop;
mod remove_noop_landing_pads;
mod remove_place_mention;
mod remove_storage_markers;
mod remove_uninit_drops;
mod remove_unneeded_drops;
mod remove_zsts;
mod required_consts;
mod reveal_all;
mod sanity_check;
mod shim;
mod ssa;
// This pass is public to allow external drivers to perform MIR cleanup
pub mod simplify;
mod simplify_branches;
mod simplify_comparison_integral;
mod single_use_consts;
mod sroa;
mod unreachable_enum_branching;
mod unreachable_prop;
mod validate;
rustc_fluent_macro::fluent_messages! { "../messages.ftl" }
pub fn provide(providers: &mut Providers) {
coverage::query::provide(providers);
ffi_unwind_calls::provide(providers);
shim::provide(providers);
cross_crate_inline::provide(providers);
providers.queries = query::Providers {
mir_keys,
mir_built,
mir_const_qualif,
mir_promoted,
mir_drops_elaborated_and_const_checked,
mir_for_ctfe,
mir_coroutine_witnesses: coroutine::mir_coroutine_witnesses,
optimized_mir,
is_mir_available,
is_ctfe_mir_available: is_mir_available,
mir_callgraph_reachable: inline::cycle::mir_callgraph_reachable,
mir_inliner_callees: inline::cycle::mir_inliner_callees,
promoted_mir,
deduced_param_attrs: deduce_param_attrs::deduced_param_attrs,
coroutine_by_move_body_def_id: coroutine::coroutine_by_move_body_def_id,
..providers.queries
};
}
fn remap_mir_for_const_eval_select<'tcx>(
tcx: TyCtxt<'tcx>,
mut body: Body<'tcx>,
context: hir::Constness,
) -> Body<'tcx> {
for bb in body.basic_blocks.as_mut().iter_mut() {
let terminator = bb.terminator.as_mut().expect("invalid terminator");
match terminator.kind {
TerminatorKind::Call {
func: Operand::Constant(box ConstOperand { ref const_, .. }),
ref mut args,
destination,
target,
unwind,
fn_span,
..
} if let ty::FnDef(def_id, _) = *const_.ty().kind()
&& tcx.is_intrinsic(def_id, sym::const_eval_select) =>
{
let Ok([tupled_args, called_in_const, called_at_rt]) = take_array(args) else {
unreachable!()
};
let ty = tupled_args.node.ty(&body.local_decls, tcx);
let fields = ty.tuple_fields();
let num_args = fields.len();
let func =
if context == hir::Constness::Const { called_in_const } else { called_at_rt };
let (method, place): (fn(Place<'tcx>) -> Operand<'tcx>, Place<'tcx>) =
match tupled_args.node {
Operand::Constant(_) => {
// there is no good way of extracting a tuple arg from a constant (const generic stuff)
// so we just create a temporary and deconstruct that.
let local = body.local_decls.push(LocalDecl::new(ty, fn_span));
bb.statements.push(Statement {
source_info: SourceInfo::outermost(fn_span),
kind: StatementKind::Assign(Box::new((
local.into(),
Rvalue::Use(tupled_args.node.clone()),
))),
});
(Operand::Move, local.into())
}
Operand::Move(place) => (Operand::Move, place),
Operand::Copy(place) => (Operand::Copy, place),
};
let place_elems = place.projection;
let arguments = (0..num_args)
.map(|x| {
let mut place_elems = place_elems.to_vec();
place_elems.push(ProjectionElem::Field(x.into(), fields[x]));
let projection = tcx.mk_place_elems(&place_elems);
let place = Place { local: place.local, projection };
Spanned { node: method(place), span: DUMMY_SP }
})
.collect();
terminator.kind = TerminatorKind::Call {
func: func.node,
args: arguments,
destination,
target,
unwind,
call_source: CallSource::Misc,
fn_span,
};
}
_ => {}
}
}
body
}
fn take_array<T, const N: usize>(b: &mut Box<[T]>) -> Result<[T; N], Box<[T]>> {
let b: Box<[T; N]> = std::mem::take(b).try_into()?;
Ok(*b)
}
fn is_mir_available(tcx: TyCtxt<'_>, def_id: LocalDefId) -> bool {
tcx.mir_keys(()).contains(&def_id)
}
/// Finds the full set of `DefId`s within the current crate that have
/// MIR associated with them.
fn mir_keys(tcx: TyCtxt<'_>, (): ()) -> FxIndexSet<LocalDefId> {
// All body-owners have MIR associated with them.
let mut set: FxIndexSet<_> = tcx.hir().body_owners().collect();
// Additionally, tuple struct/variant constructors have MIR, but
// they don't have a BodyId, so we need to build them separately.
struct GatherCtors<'a> {
set: &'a mut FxIndexSet<LocalDefId>,
}
impl<'tcx> Visitor<'tcx> for GatherCtors<'_> {
fn visit_variant_data(&mut self, v: &'tcx hir::VariantData<'tcx>) {
if let hir::VariantData::Tuple(_, _, def_id) = *v {
self.set.insert(def_id);
}
intravisit::walk_struct_def(self, v)
}
}
tcx.hir().visit_all_item_likes_in_crate(&mut GatherCtors { set: &mut set });
set
}
fn mir_const_qualif(tcx: TyCtxt<'_>, def: LocalDefId) -> ConstQualifs {
let const_kind = tcx.hir().body_const_context(def);
// No need to const-check a non-const `fn`.
match const_kind {
Some(ConstContext::Const { .. } | ConstContext::Static(_) | ConstContext::ConstFn) => {}
None => span_bug!(
tcx.def_span(def),
"`mir_const_qualif` should only be called on const fns and const items"
),
}
// N.B., this `borrow()` is guaranteed to be valid (i.e., the value
// cannot yet be stolen), because `mir_promoted()`, which steals
// from `mir_built()`, forces this query to execute before
// performing the steal.
let body = &tcx.mir_built(def).borrow();
if body.return_ty().references_error() {
// It's possible to reach here without an error being emitted (#121103).
tcx.dcx().span_delayed_bug(body.span, "mir_const_qualif: MIR had errors");
return Default::default();
}
let ccx = check_consts::ConstCx { body, tcx, const_kind, param_env: tcx.param_env(def) };
let mut validator = check_consts::check::Checker::new(&ccx);
validator.check_body();
// We return the qualifs in the return place for every MIR body, even though it is only used
// when deciding to promote a reference to a `const` for now.
validator.qualifs_in_return_place()
}
fn mir_built(tcx: TyCtxt<'_>, def: LocalDefId) -> &Steal<Body<'_>> {
let mut body = tcx.build_mir(def);
pass_manager::dump_mir_for_phase_change(tcx, &body);
pm::run_passes(
tcx,
&mut body,
&[
// MIR-level lints.
&Lint(check_packed_ref::CheckPackedRef),
&Lint(check_const_item_mutation::CheckConstItemMutation),
&Lint(function_item_references::FunctionItemReferences),
// What we need to do constant evaluation.
&simplify::SimplifyCfg::Initial,
&Lint(sanity_check::SanityCheck),
],
None,
);
tcx.alloc_steal_mir(body)
}
/// Compute the main MIR body and the list of MIR bodies of the promoteds.
fn mir_promoted(
tcx: TyCtxt<'_>,
def: LocalDefId,
) -> (&Steal<Body<'_>>, &Steal<IndexVec<Promoted, Body<'_>>>) {
// Ensure that we compute the `mir_const_qualif` for constants at
// this point, before we steal the mir-const result.
// Also this means promotion can rely on all const checks having been done.
let const_qualifs = match tcx.def_kind(def) {
DefKind::Fn | DefKind::AssocFn | DefKind::Closure
if tcx.constness(def) == hir::Constness::Const
|| tcx.is_const_default_method(def.to_def_id()) =>
{
tcx.mir_const_qualif(def)
}
DefKind::AssocConst
| DefKind::Const
| DefKind::Static { .. }
| DefKind::InlineConst
| DefKind::AnonConst => tcx.mir_const_qualif(def),
_ => ConstQualifs::default(),
};
// the `has_ffi_unwind_calls` query uses the raw mir, so make sure it is run.
tcx.ensure_with_value().has_ffi_unwind_calls(def);
// the `by_move_body` query uses the raw mir, so make sure it is run.
if tcx.needs_coroutine_by_move_body_def_id(def) {
tcx.ensure_with_value().coroutine_by_move_body_def_id(def);
}
let mut body = tcx.mir_built(def).steal();
if let Some(error_reported) = const_qualifs.tainted_by_errors {
body.tainted_by_errors = Some(error_reported);
}
// Collect `required_consts` *before* promotion, so if there are any consts being promoted
// we still add them to the list in the outer MIR body.
RequiredConstsVisitor::compute_required_consts(&mut body);
// What we need to run borrowck etc.
let promote_pass = promote_consts::PromoteTemps::default();
pm::run_passes(
tcx,
&mut body,
&[&promote_pass, &simplify::SimplifyCfg::PromoteConsts, &coverage::InstrumentCoverage],
Some(MirPhase::Analysis(AnalysisPhase::Initial)),
);
let promoted = promote_pass.promoted_fragments.into_inner();
(tcx.alloc_steal_mir(body), tcx.alloc_steal_promoted(promoted))
}
/// Compute the MIR that is used during CTFE (and thus has no optimizations run on it)
fn mir_for_ctfe(tcx: TyCtxt<'_>, def_id: LocalDefId) -> &Body<'_> {
tcx.arena.alloc(inner_mir_for_ctfe(tcx, def_id))
}
fn inner_mir_for_ctfe(tcx: TyCtxt<'_>, def: LocalDefId) -> Body<'_> {
// FIXME: don't duplicate this between the optimized_mir/mir_for_ctfe queries
if tcx.is_constructor(def.to_def_id()) {
// There's no reason to run all of the MIR passes on constructors when
// we can just output the MIR we want directly. This also saves const
// qualification and borrow checking the trouble of special casing
// constructors.
return shim::build_adt_ctor(tcx, def.to_def_id());
}
let body = tcx.mir_drops_elaborated_and_const_checked(def);
let body = match tcx.hir().body_const_context(def) {
// consts and statics do not have `optimized_mir`, so we can steal the body instead of
// cloning it.
Some(hir::ConstContext::Const { .. } | hir::ConstContext::Static(_)) => body.steal(),
Some(hir::ConstContext::ConstFn) => body.borrow().clone(),
None => bug!("`mir_for_ctfe` called on non-const {def:?}"),
};
let mut body = remap_mir_for_const_eval_select(tcx, body, hir::Constness::Const);
pm::run_passes(tcx, &mut body, &[&ctfe_limit::CtfeLimit], None);
body
}
/// Obtain just the main MIR (no promoteds) and run some cleanups on it. This also runs
/// mir borrowck *before* doing so in order to ensure that borrowck can be run and doesn't
/// end up missing the source MIR due to stealing happening.
fn mir_drops_elaborated_and_const_checked(tcx: TyCtxt<'_>, def: LocalDefId) -> &Steal<Body<'_>> {
if tcx.is_coroutine(def.to_def_id()) {
tcx.ensure_with_value().mir_coroutine_witnesses(def);
}
// We only need to borrowck non-synthetic MIR.
let tainted_by_errors =
if !tcx.is_synthetic_mir(def) { tcx.mir_borrowck(def).tainted_by_errors } else { None };
let is_fn_like = tcx.def_kind(def).is_fn_like();
if is_fn_like {
// Do not compute the mir call graph without said call graph actually being used.
if pm::should_run_pass(tcx, &inline::Inline) {
tcx.ensure_with_value().mir_inliner_callees(ty::InstanceKind::Item(def.to_def_id()));
}
}
let (body, _) = tcx.mir_promoted(def);
let mut body = body.steal();
if let Some(error_reported) = tainted_by_errors {
body.tainted_by_errors = Some(error_reported);
}
// Check if it's even possible to satisfy the 'where' clauses
// for this item.
//
// This branch will never be taken for any normal function.
// However, it's possible to `#!feature(trivial_bounds)]` to write
// a function with impossible to satisfy clauses, e.g.:
// `fn foo() where String: Copy {}`
//
// We don't usually need to worry about this kind of case,
// since we would get a compilation error if the user tried
// to call it. However, since we optimize even without any
// calls to the function, we need to make sure that it even
// makes sense to try to evaluate the body.
//
// If there are unsatisfiable where clauses, then all bets are
// off, and we just give up.
//
// We manually filter the predicates, skipping anything that's not
// "global". We are in a potentially generic context
// (e.g. we are evaluating a function without instantiating generic
// parameters, so this filtering serves two purposes:
//
// 1. We skip evaluating any predicates that we would
// never be able prove are unsatisfiable (e.g. `<T as Foo>`
// 2. We avoid trying to normalize predicates involving generic
// parameters (e.g. `<T as Foo>::MyItem`). This can confuse
// the normalization code (leading to cycle errors), since
// it's usually never invoked in this way.
let predicates = tcx
.predicates_of(body.source.def_id())
.predicates
.iter()
.filter_map(|(p, _)| if p.is_global() { Some(*p) } else { None });
if traits::impossible_predicates(tcx, traits::elaborate(tcx, predicates).collect()) {
trace!("found unsatisfiable predicates for {:?}", body.source);
// Clear the body to only contain a single `unreachable` statement.
let bbs = body.basic_blocks.as_mut();
bbs.raw.truncate(1);
bbs[START_BLOCK].statements.clear();
bbs[START_BLOCK].terminator_mut().kind = TerminatorKind::Unreachable;
body.var_debug_info.clear();
body.local_decls.raw.truncate(body.arg_count + 1);
}
run_analysis_to_runtime_passes(tcx, &mut body);
// Now that drop elaboration has been performed, we can check for
// unconditional drop recursion.
rustc_mir_build::lints::check_drop_recursion(tcx, &body);
tcx.alloc_steal_mir(body)
}
// Made public such that `mir_drops_elaborated_and_const_checked` can be overridden
// by custom rustc drivers, running all the steps by themselves.
pub fn run_analysis_to_runtime_passes<'tcx>(tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) {
assert!(body.phase == MirPhase::Analysis(AnalysisPhase::Initial));
let did = body.source.def_id();
debug!("analysis_mir_cleanup({:?})", did);
run_analysis_cleanup_passes(tcx, body);
assert!(body.phase == MirPhase::Analysis(AnalysisPhase::PostCleanup));
// Do a little drop elaboration before const-checking if `const_precise_live_drops` is enabled.
if check_consts::post_drop_elaboration::checking_enabled(&ConstCx::new(tcx, body)) {
pm::run_passes(
tcx,
body,
&[&remove_uninit_drops::RemoveUninitDrops, &simplify::SimplifyCfg::RemoveFalseEdges],
None,
);
check_consts::post_drop_elaboration::check_live_drops(tcx, body); // FIXME: make this a MIR lint
}
debug!("runtime_mir_lowering({:?})", did);
run_runtime_lowering_passes(tcx, body);
assert!(body.phase == MirPhase::Runtime(RuntimePhase::Initial));
debug!("runtime_mir_cleanup({:?})", did);
run_runtime_cleanup_passes(tcx, body);
assert!(body.phase == MirPhase::Runtime(RuntimePhase::PostCleanup));
}
// FIXME(JakobDegen): Can we make these lists of passes consts?
/// After this series of passes, no lifetime analysis based on borrowing can be done.
fn run_analysis_cleanup_passes<'tcx>(tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) {
let passes: &[&dyn MirPass<'tcx>] = &[
&cleanup_post_borrowck::CleanupPostBorrowck,
&remove_noop_landing_pads::RemoveNoopLandingPads,
&simplify::SimplifyCfg::PostAnalysis,
&deref_separator::Derefer,
];
pm::run_passes(tcx, body, passes, Some(MirPhase::Analysis(AnalysisPhase::PostCleanup)));
}
/// Returns the sequence of passes that lowers analysis to runtime MIR.
fn run_runtime_lowering_passes<'tcx>(tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) {
let passes: &[&dyn MirPass<'tcx>] = &[
// These next passes must be executed together
&add_call_guards::CriticalCallEdges,
&reveal_all::RevealAll, // has to be done before drop elaboration, since we need to drop opaque types, too.
&add_subtyping_projections::Subtyper, // calling this after reveal_all ensures that we don't deal with opaque types
&elaborate_drops::ElaborateDrops,
// This will remove extraneous landing pads which are no longer
// necessary as well as forcing any call in a non-unwinding
// function calling a possibly-unwinding function to abort the process.
&abort_unwinding_calls::AbortUnwindingCalls,
// AddMovesForPackedDrops needs to run after drop
// elaboration.
&add_moves_for_packed_drops::AddMovesForPackedDrops,
// `AddRetag` needs to run after `ElaborateDrops` but before `ElaborateBoxDerefs`. Otherwise it should run fairly late,
// but before optimizations begin.
&add_retag::AddRetag,
&elaborate_box_derefs::ElaborateBoxDerefs,
&coroutine::StateTransform,
&Lint(known_panics_lint::KnownPanicsLint),
];
pm::run_passes_no_validate(tcx, body, passes, Some(MirPhase::Runtime(RuntimePhase::Initial)));
}
/// Returns the sequence of passes that do the initial cleanup of runtime MIR.
fn run_runtime_cleanup_passes<'tcx>(tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) {
let passes: &[&dyn MirPass<'tcx>] = &[
&lower_intrinsics::LowerIntrinsics,
&remove_place_mention::RemovePlaceMention,
&simplify::SimplifyCfg::PreOptimizations,
];
pm::run_passes(tcx, body, passes, Some(MirPhase::Runtime(RuntimePhase::PostCleanup)));
// Clear this by anticipation. Optimizations and runtime MIR have no reason to look
// into this information, which is meant for borrowck diagnostics.
for decl in &mut body.local_decls {
decl.local_info = ClearCrossCrate::Clear;
}
}
fn run_optimization_passes<'tcx>(tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) {
fn o1<T>(x: T) -> WithMinOptLevel<T> {
WithMinOptLevel(1, x)
}
// The main optimizations that we do on MIR.
pm::run_passes(
tcx,
body,
&[
// Add some UB checks before any UB gets optimized away.
&check_alignment::CheckAlignment,
// Before inlining: trim down MIR with passes to reduce inlining work.
// Has to be done before inlining, otherwise actual call will be almost always inlined.
// Also simple, so can just do first
&lower_slice_len::LowerSliceLenCalls,
// Perform instsimplify before inline to eliminate some trivial calls (like clone shims).
&instsimplify::InstSimplify::BeforeInline,
// Perform inlining, which may add a lot of code.
&inline::Inline,
// Code from other crates may have storage markers, so this needs to happen after inlining.
&remove_storage_markers::RemoveStorageMarkers,
// Inlining and instantiation may introduce ZST and useless drops.
&remove_zsts::RemoveZsts,
&remove_unneeded_drops::RemoveUnneededDrops,
// Type instantiation may create uninhabited enums.
// Also eliminates some unreachable branches based on variants of enums.
&unreachable_enum_branching::UnreachableEnumBranching,
&unreachable_prop::UnreachablePropagation,
&o1(simplify::SimplifyCfg::AfterUnreachableEnumBranching),
// Inlining may have introduced a lot of redundant code and a large move pattern.
// Now, we need to shrink the generated MIR.
&ref_prop::ReferencePropagation,
&sroa::ScalarReplacementOfAggregates,
&match_branches::MatchBranchSimplification,
// inst combine is after MatchBranchSimplification to clean up Ne(_1, false)
&multiple_return_terminators::MultipleReturnTerminators,
// After simplifycfg, it allows us to discover new opportunities for peephole optimizations.
&instsimplify::InstSimplify::AfterSimplifyCfg,
&simplify::SimplifyLocals::BeforeConstProp,
&dead_store_elimination::DeadStoreElimination::Initial,
&gvn::GVN,
&simplify::SimplifyLocals::AfterGVN,
&dataflow_const_prop::DataflowConstProp,
&single_use_consts::SingleUseConsts,
&o1(simplify_branches::SimplifyConstCondition::AfterConstProp),
&jump_threading::JumpThreading,
&early_otherwise_branch::EarlyOtherwiseBranch,
&simplify_comparison_integral::SimplifyComparisonIntegral,
&dest_prop::DestinationPropagation,
&o1(simplify_branches::SimplifyConstCondition::Final),
&o1(remove_noop_landing_pads::RemoveNoopLandingPads),
&o1(simplify::SimplifyCfg::Final),
&copy_prop::CopyProp,
&dead_store_elimination::DeadStoreElimination::Final,
&nrvo::RenameReturnPlace,
&simplify::SimplifyLocals::Final,
&multiple_return_terminators::MultipleReturnTerminators,
&deduplicate_blocks::DeduplicateBlocks,
&large_enums::EnumSizeOpt { discrepancy: 128 },
// Some cleanup necessary at least for LLVM and potentially other codegen backends.
&add_call_guards::CriticalCallEdges,
// Cleanup for human readability, off by default.
&prettify::ReorderBasicBlocks,
&prettify::ReorderLocals,
// Dump the end result for testing and debugging purposes.
&dump_mir::Marker("PreCodegen"),
],
Some(MirPhase::Runtime(RuntimePhase::Optimized)),
);
}
/// Optimize the MIR and prepare it for codegen.
fn optimized_mir(tcx: TyCtxt<'_>, did: LocalDefId) -> &Body<'_> {
tcx.arena.alloc(inner_optimized_mir(tcx, did))
}
fn inner_optimized_mir(tcx: TyCtxt<'_>, did: LocalDefId) -> Body<'_> {
if tcx.is_constructor(did.to_def_id()) {
// There's no reason to run all of the MIR passes on constructors when
// we can just output the MIR we want directly. This also saves const
// qualification and borrow checking the trouble of special casing
// constructors.
return shim::build_adt_ctor(tcx, did.to_def_id());
}
match tcx.hir().body_const_context(did) {
// Run the `mir_for_ctfe` query, which depends on `mir_drops_elaborated_and_const_checked`
// which we are going to steal below. Thus we need to run `mir_for_ctfe` first, so it
// computes and caches its result.
Some(hir::ConstContext::ConstFn) => tcx.ensure_with_value().mir_for_ctfe(did),
None => {}
Some(other) => panic!("do not use `optimized_mir` for constants: {other:?}"),
}
debug!("about to call mir_drops_elaborated...");
let body = tcx.mir_drops_elaborated_and_const_checked(did).steal();
let mut body = remap_mir_for_const_eval_select(tcx, body, hir::Constness::NotConst);
if body.tainted_by_errors.is_some() {
return body;
}
// Before doing anything, remember which items are being mentioned so that the set of items
// visited does not depend on the optimization level.
// We do not use `run_passes` for this as that might skip the pass if `injection_phase` is set.
mentioned_items::MentionedItems.run_pass(tcx, &mut body);
// If `mir_drops_elaborated_and_const_checked` found that the current body has unsatisfiable
// predicates, it will shrink the MIR to a single `unreachable` terminator.
// More generally, if MIR is a lone `unreachable`, there is nothing to optimize.
if let TerminatorKind::Unreachable = body.basic_blocks[START_BLOCK].terminator().kind
&& body.basic_blocks[START_BLOCK].statements.is_empty()
{
return body;
}
run_optimization_passes(tcx, &mut body);
body
}
/// Fetch all the promoteds of an item and prepare their MIR bodies to be ready for
/// constant evaluation once all generic parameters become known.
fn promoted_mir(tcx: TyCtxt<'_>, def: LocalDefId) -> &IndexVec<Promoted, Body<'_>> {
if tcx.is_constructor(def.to_def_id()) {
return tcx.arena.alloc(IndexVec::new());
}
if !tcx.is_synthetic_mir(def) {
tcx.ensure_with_value().mir_borrowck(def);
}
let mut promoted = tcx.mir_promoted(def).1.steal();
for body in &mut promoted {
run_analysis_to_runtime_passes(tcx, body);
}
tcx.arena.alloc(promoted)
}