//! Propagates assignment destinations backwards in the CFG to eliminate redundant assignments. //! //! # Motivation //! //! MIR building can insert a lot of redundant copies, and Rust code in general often tends to move //! values around a lot. The result is a lot of assignments of the form `dest = {move} src;` in MIR. //! MIR building for constants in particular tends to create additional locals that are only used //! inside a single block to shuffle a value around unnecessarily. //! //! LLVM by itself is not good enough at eliminating these redundant copies (eg. see //! ), so this leaves some performance on the table //! that we can regain by implementing an optimization for removing these assign statements in rustc //! itself. When this optimization runs fast enough, it can also speed up the constant evaluation //! and code generation phases of rustc due to the reduced number of statements and locals. //! //! # The Optimization //! //! Conceptually, this optimization is "destination propagation". It is similar to the Named Return //! Value Optimization, or NRVO, known from the C++ world, except that it isn't limited to return //! values or the return place `_0`. On a very high level, independent of the actual implementation //! details, it does the following: //! //! 1) Identify `dest = src;` statements that can be soundly eliminated. //! 2) Replace all mentions of `src` with `dest` ("unifying" them and propagating the destination //! backwards). //! 3) Delete the `dest = src;` statement (by making it a `nop`). //! //! Step 1) is by far the hardest, so it is explained in more detail below. //! //! ## Soundness //! //! Given an `Assign` statement `dest = src;`, where `dest` is a `Place` and `src` is an `Rvalue`, //! there are a few requirements that must hold for the optimization to be sound: //! //! * `dest` must not contain any *indirection* through a pointer. It must access part of the base //! local. Otherwise it might point to arbitrary memory that is hard to track. //! //! It must also not contain any indexing projections, since those take an arbitrary `Local` as //! the index, and that local might only be initialized shortly before `dest` is used. //! //! Subtle case: If `dest` is a, or projects through a union, then we have to make sure that there //! remains an assignment to it, since that sets the "active field" of the union. But if `src` is //! a ZST, it might not be initialized, so there might not be any use of it before the assignment, //! and performing the optimization would simply delete the assignment, leaving `dest` //! uninitialized. //! //! * `src` must be a bare `Local` without any indirections or field projections (FIXME: Is this a //! fundamental restriction or just current impl state?). It can be copied or moved by the //! assignment. //! //! * The `dest` and `src` locals must never be [*live*][liveness] at the same time. If they are, it //! means that they both hold a (potentially different) value that is needed by a future use of //! the locals. Unifying them would overwrite one of the values. //! //! Note that computing liveness of locals that have had their address taken is more difficult: //! Short of doing full escape analysis on the address/pointer/reference, the pass would need to //! assume that any operation that can potentially involve opaque user code (such as function //! calls, destructors, and inline assembly) may access any local that had its address taken //! before that point. //! //! Here, the first two conditions are simple structural requirements on the `Assign` statements //! that can be trivially checked. The liveness requirement however is more difficult and costly to //! check. //! //! ## Previous Work //! //! A [previous attempt] at implementing an optimization like this turned out to be a significant //! regression in compiler performance. Fixing the regressions introduced a lot of undesirable //! complexity to the implementation. //! //! A [subsequent approach] tried to avoid the costly computation by limiting itself to acyclic //! CFGs, but still turned out to be far too costly to run due to suboptimal performance within //! individual basic blocks, requiring a walk across the entire block for every assignment found //! within the block. For the `tuple-stress` benchmark, which has 458745 statements in a single //! block, this proved to be far too costly. //! //! Since the first attempt at this, the compiler has improved dramatically, and new analysis //! frameworks have been added that should make this approach viable without requiring a limited //! approach that only works for some classes of CFGs: //! - rustc now has a powerful dataflow analysis framework that can handle forwards and backwards //! analyses efficiently. //! - Layout optimizations for generators have been added to improve code generation for //! async/await, which are very similar in spirit to what this optimization does. Both walk the //! MIR and record conflicting uses of locals in a `BitMatrix`. //! //! Also, rustc now has a simple NRVO pass (see `nrvo.rs`), which handles a subset of the cases that //! this destination propagation pass handles, proving that similar optimizations can be performed //! on MIR. //! //! ## Pre/Post Optimization //! //! It is recommended to run `SimplifyCfg` and then `SimplifyLocals` some time after this pass, as //! it replaces the eliminated assign statements with `nop`s and leaves unused locals behind. //! //! [liveness]: https://en.wikipedia.org/wiki/Live_variable_analysis //! [previous attempt]: https://github.com/rust-lang/rust/pull/47954 //! [subsequent approach]: https://github.com/rust-lang/rust/pull/71003 use crate::MirPass; use itertools::Itertools; use rustc_data_structures::unify::{InPlaceUnificationTable, UnifyKey}; use rustc_index::{ bit_set::{BitMatrix, BitSet}, vec::IndexVec, }; use rustc_middle::mir::tcx::PlaceTy; use rustc_middle::mir::visit::{MutVisitor, PlaceContext, Visitor}; use rustc_middle::mir::{dump_mir, PassWhere}; use rustc_middle::mir::{ traversal, Body, InlineAsmOperand, Local, LocalKind, Location, Operand, Place, PlaceElem, Rvalue, Statement, StatementKind, Terminator, TerminatorKind, }; use rustc_middle::ty::TyCtxt; use rustc_mir_dataflow::impls::{MaybeInitializedLocals, MaybeLiveLocals}; use rustc_mir_dataflow::Analysis; // Empirical measurements have resulted in some observations: // - Running on a body with a single block and 500 locals takes barely any time // - Running on a body with ~400 blocks and ~300 relevant locals takes "too long" // ...so we just limit both to somewhat reasonable-ish looking values. const MAX_LOCALS: usize = 500; const MAX_BLOCKS: usize = 250; pub struct DestinationPropagation; impl<'tcx> MirPass<'tcx> for DestinationPropagation { fn is_enabled(&self, sess: &rustc_session::Session) -> bool { // FIXME(#79191, #82678): This is unsound. // // Only run at mir-opt-level=3 or higher for now (we don't fix up debuginfo and remove // storage statements at the moment). sess.opts.debugging_opts.unsound_mir_opts && sess.mir_opt_level() >= 3 } fn run_pass(&self, tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) { let def_id = body.source.def_id(); let candidates = find_candidates(tcx, body); if candidates.is_empty() { debug!("{:?}: no dest prop candidates, done", def_id); return; } // Collect all locals we care about. We only compute conflicts for these to save time. let mut relevant_locals = BitSet::new_empty(body.local_decls.len()); for CandidateAssignment { dest, src, loc: _ } in &candidates { relevant_locals.insert(dest.local); relevant_locals.insert(*src); } // This pass unfortunately has `O(l² * s)` performance, where `l` is the number of locals // and `s` is the number of statements and terminators in the function. // To prevent blowing up compile times too much, we bail out when there are too many locals. let relevant = relevant_locals.count(); debug!( "{:?}: {} locals ({} relevant), {} blocks", def_id, body.local_decls.len(), relevant, body.basic_blocks().len() ); if relevant > MAX_LOCALS { warn!( "too many candidate locals in {:?} ({}, max is {}), not optimizing", def_id, relevant, MAX_LOCALS ); return; } if body.basic_blocks().len() > MAX_BLOCKS { warn!( "too many blocks in {:?} ({}, max is {}), not optimizing", def_id, body.basic_blocks().len(), MAX_BLOCKS ); return; } let mut conflicts = Conflicts::build(tcx, body, &relevant_locals); let mut replacements = Replacements::new(body.local_decls.len()); for candidate @ CandidateAssignment { dest, src, loc } in candidates { // Merge locals that don't conflict. if !conflicts.can_unify(dest.local, src) { debug!("at assignment {:?}, conflict {:?} vs. {:?}", loc, dest.local, src); continue; } if replacements.for_src(candidate.src).is_some() { debug!("src {:?} already has replacement", candidate.src); continue; } if !tcx.consider_optimizing(|| { format!("DestinationPropagation {:?} {:?}", def_id, candidate) }) { break; } replacements.push(candidate); conflicts.unify(candidate.src, candidate.dest.local); } replacements.flatten(tcx); debug!("replacements {:?}", replacements.map); Replacer { tcx, replacements, place_elem_cache: Vec::new() }.visit_body(body); // FIXME fix debug info } } #[derive(Debug, Eq, PartialEq, Copy, Clone)] struct UnifyLocal(Local); impl From for UnifyLocal { fn from(l: Local) -> Self { Self(l) } } impl UnifyKey for UnifyLocal { type Value = (); fn index(&self) -> u32 { self.0.as_u32() } fn from_index(u: u32) -> Self { Self(Local::from_u32(u)) } fn tag() -> &'static str { "UnifyLocal" } } struct Replacements<'tcx> { /// Maps locals to their replacement. map: IndexVec>>, /// Whose locals' live ranges to kill. kill: BitSet, } impl<'tcx> Replacements<'tcx> { fn new(locals: usize) -> Self { Self { map: IndexVec::from_elem_n(None, locals), kill: BitSet::new_empty(locals) } } fn push(&mut self, candidate: CandidateAssignment<'tcx>) { trace!("Replacements::push({:?})", candidate); let entry = &mut self.map[candidate.src]; assert!(entry.is_none()); *entry = Some(candidate.dest); self.kill.insert(candidate.src); self.kill.insert(candidate.dest.local); } /// Applies the stored replacements to all replacements, until no replacements would result in /// locals that need further replacements when applied. fn flatten(&mut self, tcx: TyCtxt<'tcx>) { // Note: This assumes that there are no cycles in the replacements, which is enforced via // `self.unified_locals`. Otherwise this can cause an infinite loop. for local in self.map.indices() { if let Some(replacement) = self.map[local] { // Substitute the base local of `replacement` until fixpoint. let mut base = replacement.local; let mut reversed_projection_slices = Vec::with_capacity(1); while let Some(replacement_for_replacement) = self.map[base] { base = replacement_for_replacement.local; reversed_projection_slices.push(replacement_for_replacement.projection); } let projection: Vec<_> = reversed_projection_slices .iter() .rev() .flat_map(|projs| projs.iter()) .chain(replacement.projection.iter()) .collect(); let projection = tcx.intern_place_elems(&projection); // Replace with the final `Place`. self.map[local] = Some(Place { local: base, projection }); } } } fn for_src(&self, src: Local) -> Option> { self.map[src] } } struct Replacer<'tcx> { tcx: TyCtxt<'tcx>, replacements: Replacements<'tcx>, place_elem_cache: Vec>, } impl<'tcx> MutVisitor<'tcx> for Replacer<'tcx> { fn tcx(&self) -> TyCtxt<'tcx> { self.tcx } fn visit_local(&mut self, local: &mut Local, context: PlaceContext, location: Location) { if context.is_use() && self.replacements.for_src(*local).is_some() { bug!( "use of local {:?} should have been replaced by visit_place; context={:?}, loc={:?}", local, context, location, ); } } fn visit_place(&mut self, place: &mut Place<'tcx>, context: PlaceContext, location: Location) { if let Some(replacement) = self.replacements.for_src(place.local) { // Rebase `place`s projections onto `replacement`'s. self.place_elem_cache.clear(); self.place_elem_cache.extend(replacement.projection.iter().chain(place.projection)); let projection = self.tcx.intern_place_elems(&self.place_elem_cache); let new_place = Place { local: replacement.local, projection }; debug!("Replacer: {:?} -> {:?}", place, new_place); *place = new_place; } self.super_place(place, context, location); } fn visit_statement(&mut self, statement: &mut Statement<'tcx>, location: Location) { self.super_statement(statement, location); match &statement.kind { // FIXME: Don't delete storage statements, merge the live ranges instead StatementKind::StorageDead(local) | StatementKind::StorageLive(local) if self.replacements.kill.contains(*local) => { statement.make_nop() } StatementKind::Assign(box (dest, rvalue)) => { match rvalue { Rvalue::Use(Operand::Copy(place) | Operand::Move(place)) => { // These might've been turned into self-assignments by the replacement // (this includes the original statement we wanted to eliminate). if dest == place { debug!("{:?} turned into self-assignment, deleting", location); statement.make_nop(); } } _ => {} } } _ => {} } } } struct Conflicts<'a> { relevant_locals: &'a BitSet, /// The conflict matrix. It is always symmetric and the adjacency matrix of the corresponding /// conflict graph. matrix: BitMatrix, /// Preallocated `BitSet` used by `unify`. unify_cache: BitSet, /// Tracks locals that have been merged together to prevent cycles and propagate conflicts. unified_locals: InPlaceUnificationTable, } impl<'a> Conflicts<'a> { fn build<'tcx>( tcx: TyCtxt<'tcx>, body: &'_ Body<'tcx>, relevant_locals: &'a BitSet, ) -> Self { // We don't have to look out for locals that have their address taken, since // `find_candidates` already takes care of that. let conflicts = BitMatrix::from_row_n( &BitSet::new_empty(body.local_decls.len()), body.local_decls.len(), ); let mut init = MaybeInitializedLocals .into_engine(tcx, body) .iterate_to_fixpoint() .into_results_cursor(body); let mut live = MaybeLiveLocals.into_engine(tcx, body).iterate_to_fixpoint().into_results_cursor(body); let mut reachable = None; dump_mir(tcx, None, "DestinationPropagation-dataflow", &"", body, |pass_where, w| { let reachable = reachable.get_or_insert_with(|| traversal::reachable_as_bitset(body)); match pass_where { PassWhere::BeforeLocation(loc) if reachable.contains(loc.block) => { init.seek_before_primary_effect(loc); live.seek_after_primary_effect(loc); writeln!(w, " // init: {:?}", init.get())?; writeln!(w, " // live: {:?}", live.get())?; } PassWhere::AfterTerminator(bb) if reachable.contains(bb) => { let loc = body.terminator_loc(bb); init.seek_after_primary_effect(loc); live.seek_before_primary_effect(loc); writeln!(w, " // init: {:?}", init.get())?; writeln!(w, " // live: {:?}", live.get())?; } PassWhere::BeforeBlock(bb) if reachable.contains(bb) => { init.seek_to_block_start(bb); live.seek_to_block_start(bb); writeln!(w, " // init: {:?}", init.get())?; writeln!(w, " // live: {:?}", live.get())?; } PassWhere::BeforeCFG | PassWhere::AfterCFG | PassWhere::AfterLocation(_) => {} PassWhere::BeforeLocation(_) | PassWhere::AfterTerminator(_) => { writeln!(w, " // init: ")?; writeln!(w, " // live: ")?; } PassWhere::BeforeBlock(_) => { writeln!(w, " // init: ")?; writeln!(w, " // live: ")?; } } Ok(()) }); let mut this = Self { relevant_locals, matrix: conflicts, unify_cache: BitSet::new_empty(body.local_decls.len()), unified_locals: { let mut table = InPlaceUnificationTable::new(); // Pre-fill table with all locals (this creates N nodes / "connected" components, // "graph"-ically speaking). for local in 0..body.local_decls.len() { assert_eq!(table.new_key(()), UnifyLocal(Local::from_usize(local))); } table }, }; let mut live_and_init_locals = Vec::new(); // Visit only reachable basic blocks. The exact order is not important. for (block, data) in traversal::preorder(body) { // We need to observe the dataflow state *before* all possible locations (statement or // terminator) in each basic block, and then observe the state *after* the terminator // effect is applied. As long as neither `init` nor `borrowed` has a "before" effect, // we will observe all possible dataflow states. // Since liveness is a backwards analysis, we need to walk the results backwards. To do // that, we first collect in the `MaybeInitializedLocals` results in a forwards // traversal. live_and_init_locals.resize_with(data.statements.len() + 1, || { BitSet::new_empty(body.local_decls.len()) }); // First, go forwards for `MaybeInitializedLocals` and apply intra-statement/terminator // conflicts. for (i, statement) in data.statements.iter().enumerate() { this.record_statement_conflicts(statement); let loc = Location { block, statement_index: i }; init.seek_before_primary_effect(loc); live_and_init_locals[i].clone_from(init.get()); } this.record_terminator_conflicts(data.terminator()); let term_loc = Location { block, statement_index: data.statements.len() }; init.seek_before_primary_effect(term_loc); live_and_init_locals[term_loc.statement_index].clone_from(init.get()); // Now, go backwards and union with the liveness results. for statement_index in (0..=data.statements.len()).rev() { let loc = Location { block, statement_index }; live.seek_after_primary_effect(loc); live_and_init_locals[statement_index].intersect(live.get()); trace!("record conflicts at {:?}", loc); this.record_dataflow_conflicts(&mut live_and_init_locals[statement_index]); } init.seek_to_block_end(block); live.seek_to_block_end(block); let mut conflicts = init.get().clone(); conflicts.intersect(live.get()); trace!("record conflicts at end of {:?}", block); this.record_dataflow_conflicts(&mut conflicts); } this } fn record_dataflow_conflicts(&mut self, new_conflicts: &mut BitSet) { // Remove all locals that are not candidates. new_conflicts.intersect(self.relevant_locals); for local in new_conflicts.iter() { self.matrix.union_row_with(&new_conflicts, local); } } fn record_local_conflict(&mut self, a: Local, b: Local, why: &str) { trace!("conflict {:?} <-> {:?} due to {}", a, b, why); self.matrix.insert(a, b); self.matrix.insert(b, a); } /// Records locals that must not overlap during the evaluation of `stmt`. These locals conflict /// and must not be merged. fn record_statement_conflicts(&mut self, stmt: &Statement<'_>) { match &stmt.kind { // While the left and right sides of an assignment must not overlap, we do not mark // conflicts here as that would make this optimization useless. When we optimize, we // eliminate the resulting self-assignments automatically. StatementKind::Assign(_) => {} StatementKind::SetDiscriminant { .. } | StatementKind::StorageLive(..) | StatementKind::StorageDead(..) | StatementKind::Retag(..) | StatementKind::FakeRead(..) | StatementKind::AscribeUserType(..) | StatementKind::Coverage(..) | StatementKind::CopyNonOverlapping(..) | StatementKind::Nop => {} } } fn record_terminator_conflicts(&mut self, term: &Terminator<'_>) { match &term.kind { TerminatorKind::DropAndReplace { place: dropped_place, value, target: _, unwind: _, } => { if let Some(place) = value.place() { if !place.is_indirect() && !dropped_place.is_indirect() { self.record_local_conflict( place.local, dropped_place.local, "DropAndReplace operand overlap", ); } } } TerminatorKind::Yield { value, resume: _, resume_arg, drop: _ } => { if let Some(place) = value.place() { if !place.is_indirect() && !resume_arg.is_indirect() { self.record_local_conflict( place.local, resume_arg.local, "Yield operand overlap", ); } } } TerminatorKind::Call { func, args, destination: Some((dest_place, _)), cleanup: _, from_hir_call: _, fn_span: _, } => { // No arguments may overlap with the destination. for arg in args.iter().chain(Some(func)) { if let Some(place) = arg.place() { if !place.is_indirect() && !dest_place.is_indirect() { self.record_local_conflict( dest_place.local, place.local, "call dest/arg overlap", ); } } } } TerminatorKind::InlineAsm { template: _, operands, options: _, line_spans: _, destination: _, cleanup: _, } => { // The intended semantics here aren't documented, we just assume that nothing that // could be written to by the assembly may overlap with any other operands. for op in operands { match op { InlineAsmOperand::Out { reg: _, late: _, place: Some(dest_place) } | InlineAsmOperand::InOut { reg: _, late: _, in_value: _, out_place: Some(dest_place), } => { // For output place `place`, add all places accessed by the inline asm. for op in operands { match op { InlineAsmOperand::In { reg: _, value } => { if let Some(p) = value.place() { if !p.is_indirect() && !dest_place.is_indirect() { self.record_local_conflict( p.local, dest_place.local, "asm! operand overlap", ); } } } InlineAsmOperand::Out { reg: _, late: _, place: Some(place), } => { if !place.is_indirect() && !dest_place.is_indirect() { self.record_local_conflict( place.local, dest_place.local, "asm! operand overlap", ); } } InlineAsmOperand::InOut { reg: _, late: _, in_value, out_place, } => { if let Some(place) = in_value.place() { if !place.is_indirect() && !dest_place.is_indirect() { self.record_local_conflict( place.local, dest_place.local, "asm! operand overlap", ); } } if let Some(place) = out_place { if !place.is_indirect() && !dest_place.is_indirect() { self.record_local_conflict( place.local, dest_place.local, "asm! operand overlap", ); } } } InlineAsmOperand::Out { reg: _, late: _, place: None } | InlineAsmOperand::Const { value: _ } | InlineAsmOperand::SymFn { value: _ } | InlineAsmOperand::SymStatic { def_id: _ } => {} } } } InlineAsmOperand::InOut { reg: _, late: _, in_value: _, out_place: None, } | InlineAsmOperand::In { reg: _, value: _ } | InlineAsmOperand::Out { reg: _, late: _, place: None } | InlineAsmOperand::Const { value: _ } | InlineAsmOperand::SymFn { value: _ } | InlineAsmOperand::SymStatic { def_id: _ } => {} } } } TerminatorKind::Goto { .. } | TerminatorKind::Call { destination: None, .. } | TerminatorKind::SwitchInt { .. } | TerminatorKind::Resume | TerminatorKind::Abort | TerminatorKind::Return | TerminatorKind::Unreachable | TerminatorKind::Drop { .. } | TerminatorKind::Assert { .. } | TerminatorKind::GeneratorDrop | TerminatorKind::FalseEdge { .. } | TerminatorKind::FalseUnwind { .. } => {} } } /// Checks whether `a` and `b` may be merged. Returns `false` if there's a conflict. fn can_unify(&mut self, a: Local, b: Local) -> bool { // After some locals have been unified, their conflicts are only tracked in the root key, // so look that up. let a = self.unified_locals.find(a).0; let b = self.unified_locals.find(b).0; if a == b { // Already merged (part of the same connected component). return false; } if self.matrix.contains(a, b) { // Conflict (derived via dataflow, intra-statement conflicts, or inherited from another // local during unification). return false; } true } /// Merges the conflicts of `a` and `b`, so that each one inherits all conflicts of the other. /// /// `can_unify` must have returned `true` for the same locals, or this may panic or lead to /// miscompiles. /// /// This is called when the pass makes the decision to unify `a` and `b` (or parts of `a` and /// `b`) and is needed to ensure that future unification decisions take potentially newly /// introduced conflicts into account. /// /// For an example, assume we have locals `_0`, `_1`, `_2`, and `_3`. There are these conflicts: /// /// * `_0` <-> `_1` /// * `_1` <-> `_2` /// * `_3` <-> `_0` /// /// We then decide to merge `_2` with `_3` since they don't conflict. Then we decide to merge /// `_2` with `_0`, which also doesn't have a conflict in the above list. However `_2` is now /// `_3`, which does conflict with `_0`. fn unify(&mut self, a: Local, b: Local) { trace!("unify({:?}, {:?})", a, b); // Get the root local of the connected components. The root local stores the conflicts of // all locals in the connected component (and *is stored* as the conflicting local of other // locals). let a = self.unified_locals.find(a).0; let b = self.unified_locals.find(b).0; assert_ne!(a, b); trace!("roots: a={:?}, b={:?}", a, b); trace!("{:?} conflicts: {:?}", a, self.matrix.iter(a).format(", ")); trace!("{:?} conflicts: {:?}", b, self.matrix.iter(b).format(", ")); self.unified_locals.union(a, b); let root = self.unified_locals.find(a).0; assert!(root == a || root == b); // Make all locals that conflict with `a` also conflict with `b`, and vice versa. self.unify_cache.clear(); for conflicts_with_a in self.matrix.iter(a) { self.unify_cache.insert(conflicts_with_a); } for conflicts_with_b in self.matrix.iter(b) { self.unify_cache.insert(conflicts_with_b); } for conflicts_with_a_or_b in self.unify_cache.iter() { // Set both `a` and `b` for this local's row. self.matrix.insert(conflicts_with_a_or_b, a); self.matrix.insert(conflicts_with_a_or_b, b); } // Write the locals `a` conflicts with to `b`'s row. self.matrix.union_rows(a, b); // Write the locals `b` conflicts with to `a`'s row. self.matrix.union_rows(b, a); } } /// A `dest = {move} src;` statement at `loc`. /// /// We want to consider merging `dest` and `src` due to this assignment. #[derive(Debug, Copy, Clone)] struct CandidateAssignment<'tcx> { /// Does not contain indirection or indexing (so the only local it contains is the place base). dest: Place<'tcx>, src: Local, loc: Location, } /// Scans the MIR for assignments between locals that we might want to consider merging. /// /// This will filter out assignments that do not match the right form (as described in the top-level /// comment) and also throw out assignments that involve a local that has its address taken or is /// otherwise ineligible (eg. locals used as array indices are ignored because we cannot propagate /// arbitrary places into array indices). fn find_candidates<'tcx>(tcx: TyCtxt<'tcx>, body: &Body<'tcx>) -> Vec> { let mut visitor = FindAssignments { tcx, body, candidates: Vec::new(), ever_borrowed_locals: ever_borrowed_locals(body), locals_used_as_array_index: locals_used_as_array_index(body), }; visitor.visit_body(body); visitor.candidates } struct FindAssignments<'a, 'tcx> { tcx: TyCtxt<'tcx>, body: &'a Body<'tcx>, candidates: Vec>, ever_borrowed_locals: BitSet, locals_used_as_array_index: BitSet, } impl<'tcx> Visitor<'tcx> for FindAssignments<'_, 'tcx> { fn visit_statement(&mut self, statement: &Statement<'tcx>, location: Location) { if let StatementKind::Assign(box ( dest, Rvalue::Use(Operand::Copy(src) | Operand::Move(src)), )) = &statement.kind { // `dest` must not have pointer indirection. if dest.is_indirect() { return; } // `src` must be a plain local. if !src.projection.is_empty() { return; } // Since we want to replace `src` with `dest`, `src` must not be required. if is_local_required(src.local, self.body) { return; } // Can't optimize if both locals ever have their address taken (can introduce // aliasing). // FIXME: This can be smarter and take `StorageDead` into account (which // invalidates borrows). if self.ever_borrowed_locals.contains(dest.local) || self.ever_borrowed_locals.contains(src.local) { return; } assert_ne!(dest.local, src.local, "self-assignments are UB"); // We can't replace locals occurring in `PlaceElem::Index` for now. if self.locals_used_as_array_index.contains(src.local) { return; } // Handle the "subtle case" described above by rejecting any `dest` that is or // projects through a union. let mut place_ty = PlaceTy::from_ty(self.body.local_decls[dest.local].ty); if place_ty.ty.is_union() { return; } for elem in dest.projection { if let PlaceElem::Index(_) = elem { // `dest` contains an indexing projection. return; } place_ty = place_ty.projection_ty(self.tcx, elem); if place_ty.ty.is_union() { return; } } self.candidates.push(CandidateAssignment { dest: *dest, src: src.local, loc: location, }); } } } /// Some locals are part of the function's interface and can not be removed. /// /// Note that these locals *can* still be merged with non-required locals by removing that other /// local. fn is_local_required(local: Local, body: &Body<'_>) -> bool { match body.local_kind(local) { LocalKind::Arg | LocalKind::ReturnPointer => true, LocalKind::Var | LocalKind::Temp => false, } } /// Walks MIR to find all locals that have their address taken anywhere. fn ever_borrowed_locals(body: &Body<'_>) -> BitSet { let mut visitor = BorrowCollector { locals: BitSet::new_empty(body.local_decls.len()) }; visitor.visit_body(body); visitor.locals } struct BorrowCollector { locals: BitSet, } impl<'tcx> Visitor<'tcx> for BorrowCollector { fn visit_rvalue(&mut self, rvalue: &Rvalue<'tcx>, location: Location) { self.super_rvalue(rvalue, location); match rvalue { Rvalue::AddressOf(_, borrowed_place) | Rvalue::Ref(_, _, borrowed_place) => { if !borrowed_place.is_indirect() { self.locals.insert(borrowed_place.local); } } Rvalue::Cast(..) | Rvalue::ShallowInitBox(..) | Rvalue::Use(..) | Rvalue::Repeat(..) | Rvalue::Len(..) | Rvalue::BinaryOp(..) | Rvalue::CheckedBinaryOp(..) | Rvalue::NullaryOp(..) | Rvalue::UnaryOp(..) | Rvalue::Discriminant(..) | Rvalue::Aggregate(..) | Rvalue::ThreadLocalRef(..) => {} } } fn visit_terminator(&mut self, terminator: &Terminator<'tcx>, location: Location) { self.super_terminator(terminator, location); match terminator.kind { TerminatorKind::Drop { place: dropped_place, .. } | TerminatorKind::DropAndReplace { place: dropped_place, .. } => { self.locals.insert(dropped_place.local); } TerminatorKind::Abort | TerminatorKind::Assert { .. } | TerminatorKind::Call { .. } | TerminatorKind::FalseEdge { .. } | TerminatorKind::FalseUnwind { .. } | TerminatorKind::GeneratorDrop | TerminatorKind::Goto { .. } | TerminatorKind::Resume | TerminatorKind::Return | TerminatorKind::SwitchInt { .. } | TerminatorKind::Unreachable | TerminatorKind::Yield { .. } | TerminatorKind::InlineAsm { .. } => {} } } } /// `PlaceElem::Index` only stores a `Local`, so we can't replace that with a full `Place`. /// /// Collect locals used as indices so we don't generate candidates that are impossible to apply /// later. fn locals_used_as_array_index(body: &Body<'_>) -> BitSet { let mut visitor = IndexCollector { locals: BitSet::new_empty(body.local_decls.len()) }; visitor.visit_body(body); visitor.locals } struct IndexCollector { locals: BitSet, } impl<'tcx> Visitor<'tcx> for IndexCollector { fn visit_projection_elem( &mut self, local: Local, proj_base: &[PlaceElem<'tcx>], elem: PlaceElem<'tcx>, context: PlaceContext, location: Location, ) { if let PlaceElem::Index(i) = elem { self.locals.insert(i); } self.super_projection_elem(local, proj_base, elem, context, location); } }