//! We denote as "SSA" the set of locals that verify the following properties: //! 1/ They are only assigned-to once, either as a function parameter, or in an assign statement; //! 2/ This single assignment dominates all uses; //! //! As a consequence of rule 2, we consider that borrowed locals are not SSA, even if they are //! `Freeze`, as we do not track that the assignment dominates all uses of the borrow. use either::Either; use rustc_data_structures::graph::dominators::Dominators; use rustc_index::bit_set::BitSet; use rustc_index::{IndexSlice, IndexVec}; use rustc_middle::middle::resolve_bound_vars::Set1; use rustc_middle::mir::visit::*; use rustc_middle::mir::*; #[derive(Debug)] pub struct SsaLocals { /// Assignments to each local. This defines whether the local is SSA. assignments: IndexVec>, /// We visit the body in reverse postorder, to ensure each local is assigned before it is used. /// We remember the order in which we saw the assignments to compute the SSA values in a single /// pass. assignment_order: Vec, /// Copy equivalence classes between locals. See `copy_classes` for documentation. copy_classes: IndexVec, /// Number of "direct" uses of each local, ie. uses that are not dereferences. /// We ignore non-uses (Storage statements, debuginfo). direct_uses: IndexVec, } /// We often encounter MIR bodies with 1 or 2 basic blocks. In those cases, it's unnecessary to /// actually compute dominators, we can just compare block indices because bb0 is always the first /// block, and in any body all other blocks are always dominated by bb0. struct SmallDominators<'a> { inner: Option<&'a Dominators>, } impl SmallDominators<'_> { fn dominates(&self, first: Location, second: Location) -> bool { if first.block == second.block { first.statement_index <= second.statement_index } else if let Some(inner) = &self.inner { inner.dominates(first.block, second.block) } else { first.block < second.block } } fn check_dominates(&mut self, set: &mut Set1, loc: Location) { let assign_dominates = match *set { Set1::Empty | Set1::Many => false, Set1::One(LocationExtended::Arg) => true, Set1::One(LocationExtended::Plain(assign)) => { self.dominates(assign.successor_within_block(), loc) } }; // We are visiting a use that is not dominated by an assignment. // Either there is a cycle involved, or we are reading for uninitialized local. // Bail out. if !assign_dominates { *set = Set1::Many; } } } impl SsaLocals { pub fn new<'tcx>(body: &Body<'tcx>) -> SsaLocals { let assignment_order = Vec::with_capacity(body.local_decls.len()); let assignments = IndexVec::from_elem(Set1::Empty, &body.local_decls); let dominators = if body.basic_blocks.len() > 2 { Some(body.basic_blocks.dominators()) } else { None }; let dominators = SmallDominators { inner: dominators }; let direct_uses = IndexVec::from_elem(0, &body.local_decls); let mut visitor = SsaVisitor { assignments, assignment_order, dominators, direct_uses }; for local in body.args_iter() { visitor.assignments[local] = Set1::One(LocationExtended::Arg); } if body.basic_blocks.len() > 2 { for (bb, data) in traversal::reverse_postorder(body) { visitor.visit_basic_block_data(bb, data); } } else { for (bb, data) in body.basic_blocks.iter_enumerated() { visitor.visit_basic_block_data(bb, data); } } for var_debug_info in &body.var_debug_info { visitor.visit_var_debug_info(var_debug_info); } debug!(?visitor.assignments); debug!(?visitor.direct_uses); visitor .assignment_order .retain(|&local| matches!(visitor.assignments[local], Set1::One(_))); debug!(?visitor.assignment_order); let mut ssa = SsaLocals { assignments: visitor.assignments, assignment_order: visitor.assignment_order, direct_uses: visitor.direct_uses, // This is filled by `compute_copy_classes`. copy_classes: IndexVec::default(), }; compute_copy_classes(&mut ssa, body); ssa } pub fn num_locals(&self) -> usize { self.assignments.len() } pub fn locals(&self) -> impl Iterator { self.assignments.indices() } pub fn is_ssa(&self, local: Local) -> bool { matches!(self.assignments[local], Set1::One(_)) } /// Return the number of uses if a local that are not "Deref". pub fn num_direct_uses(&self, local: Local) -> u32 { self.direct_uses[local] } pub fn assignments<'a, 'tcx>( &'a self, body: &'a Body<'tcx>, ) -> impl Iterator, Location)> + 'a { self.assignment_order.iter().filter_map(|&local| { if let Set1::One(LocationExtended::Plain(loc)) = self.assignments[local] { // `loc` must point to a direct assignment to `local`. let Either::Left(stmt) = body.stmt_at(loc) else { bug!() }; let Some((target, rvalue)) = stmt.kind.as_assign() else { bug!() }; assert_eq!(target.as_local(), Some(local)); Some((local, rvalue, loc)) } else { None } }) } /// Compute the equivalence classes for locals, based on copy statements. /// /// The returned vector maps each local to the one it copies. In the following case: /// _a = &mut _0 /// _b = move? _a /// _c = move? _a /// _d = move? _c /// We return the mapping /// _a => _a // not a copy so, represented by itself /// _b => _a /// _c => _a /// _d => _a // transitively through _c /// /// Exception: we do not see through the return place, as it cannot be substituted. pub fn copy_classes(&self) -> &IndexSlice { &self.copy_classes } /// Make a property uniform on a copy equivalence class by removing elements. pub fn meet_copy_equivalence(&self, property: &mut BitSet) { // Consolidate to have a local iff all its copies are. // // `copy_classes` defines equivalence classes between locals. The `local`s that recursively // move/copy the same local all have the same `head`. for (local, &head) in self.copy_classes.iter_enumerated() { // If any copy does not have `property`, then the head is not. if !property.contains(local) { property.remove(head); } } for (local, &head) in self.copy_classes.iter_enumerated() { // If any copy does not have `property`, then the head doesn't either, // then no copy has `property`. if !property.contains(head) { property.remove(local); } } // Verify that we correctly computed equivalence classes. #[cfg(debug_assertions)] for (local, &head) in self.copy_classes.iter_enumerated() { assert_eq!(property.contains(local), property.contains(head)); } } } #[derive(Copy, Clone, Debug, PartialEq, Eq)] enum LocationExtended { Plain(Location), Arg, } struct SsaVisitor<'a> { dominators: SmallDominators<'a>, assignments: IndexVec>, assignment_order: Vec, direct_uses: IndexVec, } impl<'tcx> Visitor<'tcx> for SsaVisitor<'_> { fn visit_local(&mut self, local: Local, ctxt: PlaceContext, loc: Location) { match ctxt { PlaceContext::MutatingUse(MutatingUseContext::Projection) | PlaceContext::NonMutatingUse(NonMutatingUseContext::Projection) => bug!(), // Anything can happen with raw pointers, so remove them. // We do not verify that all uses of the borrow dominate the assignment to `local`, // so we have to remove them too. PlaceContext::NonMutatingUse( NonMutatingUseContext::SharedBorrow | NonMutatingUseContext::ShallowBorrow | NonMutatingUseContext::AddressOf, ) | PlaceContext::MutatingUse(_) => { self.assignments[local] = Set1::Many; } PlaceContext::NonMutatingUse(_) => { self.dominators.check_dominates(&mut self.assignments[local], loc); self.direct_uses[local] += 1; } PlaceContext::NonUse(_) => {} } } fn visit_place(&mut self, place: &Place<'tcx>, ctxt: PlaceContext, loc: Location) { if place.projection.first() == Some(&PlaceElem::Deref) { // Do not do anything for storage statements and debuginfo. if ctxt.is_use() { // Only change the context if it is a real use, not a "use" in debuginfo. let new_ctxt = PlaceContext::NonMutatingUse(NonMutatingUseContext::Copy); self.visit_projection(place.as_ref(), new_ctxt, loc); self.dominators.check_dominates(&mut self.assignments[place.local], loc); } return; } else { self.visit_projection(place.as_ref(), ctxt, loc); self.visit_local(place.local, ctxt, loc); } } fn visit_assign(&mut self, place: &Place<'tcx>, rvalue: &Rvalue<'tcx>, loc: Location) { if let Some(local) = place.as_local() { self.assignments[local].insert(LocationExtended::Plain(loc)); if let Set1::One(_) = self.assignments[local] { // Only record if SSA-like, to avoid growing the vector needlessly. self.assignment_order.push(local); } } else { self.visit_place(place, PlaceContext::MutatingUse(MutatingUseContext::Store), loc); } self.visit_rvalue(rvalue, loc); } } #[instrument(level = "trace", skip(ssa, body))] fn compute_copy_classes(ssa: &mut SsaLocals, body: &Body<'_>) { let mut direct_uses = std::mem::take(&mut ssa.direct_uses); let mut copies = IndexVec::from_fn_n(|l| l, body.local_decls.len()); for (local, rvalue, _) in ssa.assignments(body) { let (Rvalue::Use(Operand::Copy(place) | Operand::Move(place)) | Rvalue::CopyForDeref(place)) = rvalue else { continue }; let Some(rhs) = place.as_local() else { continue }; let local_ty = body.local_decls()[local].ty; let rhs_ty = body.local_decls()[rhs].ty; if local_ty != rhs_ty { // FIXME(#112651): This can be removed afterwards. trace!("skipped `{local:?} = {rhs:?}` due to subtyping: {local_ty} != {rhs_ty}"); continue; } if !ssa.is_ssa(rhs) { continue; } // We visit in `assignment_order`, ie. reverse post-order, so `rhs` has been // visited before `local`, and we just have to copy the representing local. let head = copies[rhs]; if local == RETURN_PLACE { // `_0` is special, we cannot rename it. Instead, rename the class of `rhs` to // `RETURN_PLACE`. This is only possible if the class head is a temporary, not an // argument. if body.local_kind(head) != LocalKind::Temp { continue; } for h in copies.iter_mut() { if *h == head { *h = RETURN_PLACE; } } } else { copies[local] = head; } direct_uses[rhs] -= 1; } debug!(?copies); debug!(?direct_uses); // Invariant: `copies` must point to the head of an equivalence class. #[cfg(debug_assertions)] for &head in copies.iter() { assert_eq!(copies[head], head); } debug_assert_eq!(copies[RETURN_PLACE], RETURN_PLACE); ssa.direct_uses = direct_uses; ssa.copy_classes = copies; } #[derive(Debug)] pub(crate) struct StorageLiveLocals { /// Set of "StorageLive" statements for each local. storage_live: IndexVec>, } impl StorageLiveLocals { pub(crate) fn new( body: &Body<'_>, always_storage_live_locals: &BitSet, ) -> StorageLiveLocals { let mut storage_live = IndexVec::from_elem(Set1::Empty, &body.local_decls); for local in always_storage_live_locals.iter() { storage_live[local] = Set1::One(LocationExtended::Arg); } for (block, bbdata) in body.basic_blocks.iter_enumerated() { for (statement_index, statement) in bbdata.statements.iter().enumerate() { if let StatementKind::StorageLive(local) = statement.kind { storage_live[local] .insert(LocationExtended::Plain(Location { block, statement_index })); } } } debug!(?storage_live); StorageLiveLocals { storage_live } } #[inline] pub(crate) fn has_single_storage(&self, local: Local) -> bool { matches!(self.storage_live[local], Set1::One(_)) } }