//! # The MIR Visitor //! //! ## Overview //! //! There are two visitors, one for immutable and one for mutable references, //! but both are generated by the following macro. The code is written according //! to the following conventions: //! //! - introduce a `visit_foo` and a `super_foo` method for every MIR type //! - `visit_foo`, by default, calls `super_foo` //! - `super_foo`, by default, destructures the `foo` and calls `visit_foo` //! //! This allows you as a user to override `visit_foo` for types are //! interested in, and invoke (within that method) call //! `self.super_foo` to get the default behavior. Just as in an OO //! language, you should never call `super` methods ordinarily except //! in that circumstance. //! //! For the most part, we do not destructure things external to the //! MIR, e.g., types, spans, etc, but simply visit them and stop. This //! avoids duplication with other visitors like `TypeFoldable`. //! //! ## Updating //! //! The code is written in a very deliberate style intended to minimize //! the chance of things being overlooked. You'll notice that we always //! use pattern matching to reference fields and we ensure that all //! matches are exhaustive. //! //! For example, the `super_basic_block_data` method begins like this: //! //! ```rust //! fn super_basic_block_data(&mut self, //! block: BasicBlock, //! data: & $($mutability)? BasicBlockData<'tcx>) { //! let BasicBlockData { //! statements, //! terminator, //! is_cleanup: _ //! } = *data; //! //! for statement in statements { //! self.visit_statement(block, statement); //! } //! //! ... //! } //! ``` //! //! Here we used `let BasicBlockData { } = *data` deliberately, //! rather than writing `data.statements` in the body. This is because if one //! adds a new field to `BasicBlockData`, one will be forced to revise this code, //! and hence one will (hopefully) invoke the correct visit methods (if any). //! //! For this to work, ALL MATCHES MUST BE EXHAUSTIVE IN FIELDS AND VARIANTS. //! That means you never write `..` to skip over fields, nor do you write `_` //! to skip over variants in a `match`. //! //! The only place that `_` is acceptable is to match a field (or //! variant argument) that does not require visiting, as in //! `is_cleanup` above. use crate::mir::*; use crate::ty::subst::SubstsRef; use crate::ty::{CanonicalUserTypeAnnotation, Ty}; use rustc_span::Span; macro_rules! make_mir_visitor { ($visitor_trait_name:ident, $($mutability:ident)?) => { pub trait $visitor_trait_name<'tcx> { // Override these, and call `self.super_xxx` to revert back to the // default behavior. fn visit_body( &mut self, body: &$($mutability)? Body<'tcx>, ) { self.super_body(body); } fn visit_basic_block_data(&mut self, block: BasicBlock, data: & $($mutability)? BasicBlockData<'tcx>) { self.super_basic_block_data(block, data); } fn visit_source_scope_data(&mut self, scope_data: & $($mutability)? SourceScopeData<'tcx>) { self.super_source_scope_data(scope_data); } fn visit_statement(&mut self, statement: & $($mutability)? Statement<'tcx>, location: Location) { self.super_statement(statement, location); } fn visit_assign(&mut self, place: & $($mutability)? Place<'tcx>, rvalue: & $($mutability)? Rvalue<'tcx>, location: Location) { self.super_assign(place, rvalue, location); } fn visit_terminator(&mut self, terminator: & $($mutability)? Terminator<'tcx>, location: Location) { self.super_terminator(terminator, location); } fn visit_assert_message(&mut self, msg: & $($mutability)? AssertMessage<'tcx>, location: Location) { self.super_assert_message(msg, location); } fn visit_rvalue(&mut self, rvalue: & $($mutability)? Rvalue<'tcx>, location: Location) { self.super_rvalue(rvalue, location); } fn visit_operand(&mut self, operand: & $($mutability)? Operand<'tcx>, location: Location) { self.super_operand(operand, location); } fn visit_ascribe_user_ty(&mut self, place: & $($mutability)? Place<'tcx>, variance: & $($mutability)? ty::Variance, user_ty: & $($mutability)? UserTypeProjection, location: Location) { self.super_ascribe_user_ty(place, variance, user_ty, location); } fn visit_coverage(&mut self, coverage: & $($mutability)? Coverage, location: Location) { self.super_coverage(coverage, location); } fn visit_retag(&mut self, kind: & $($mutability)? RetagKind, place: & $($mutability)? Place<'tcx>, location: Location) { self.super_retag(kind, place, location); } fn visit_place(&mut self, place: & $($mutability)? Place<'tcx>, context: PlaceContext, location: Location) { self.super_place(place, context, location); } visit_place_fns!($($mutability)?); fn visit_constant(&mut self, constant: & $($mutability)? Constant<'tcx>, location: Location) { self.super_constant(constant, location); } fn visit_span(&mut self, span: & $($mutability)? Span) { self.super_span(span); } fn visit_source_info(&mut self, source_info: & $($mutability)? SourceInfo) { self.super_source_info(source_info); } fn visit_ty(&mut self, ty: $(& $mutability)? Ty<'tcx>, _: TyContext) { self.super_ty(ty); } fn visit_user_type_projection( &mut self, ty: & $($mutability)? UserTypeProjection, ) { self.super_user_type_projection(ty); } fn visit_user_type_annotation( &mut self, index: UserTypeAnnotationIndex, ty: & $($mutability)? CanonicalUserTypeAnnotation<'tcx>, ) { self.super_user_type_annotation(index, ty); } fn visit_region(&mut self, region: & $($mutability)? ty::Region<'tcx>, _: Location) { self.super_region(region); } fn visit_const(&mut self, constant: & $($mutability)? &'tcx ty::Const<'tcx>, _: Location) { self.super_const(constant); } fn visit_substs(&mut self, substs: & $($mutability)? SubstsRef<'tcx>, _: Location) { self.super_substs(substs); } fn visit_local_decl(&mut self, local: Local, local_decl: & $($mutability)? LocalDecl<'tcx>) { self.super_local_decl(local, local_decl); } fn visit_var_debug_info(&mut self, var_debug_info: & $($mutability)* VarDebugInfo<'tcx>) { self.super_var_debug_info(var_debug_info); } fn visit_local(&mut self, _local: & $($mutability)? Local, _context: PlaceContext, _location: Location) { } fn visit_source_scope(&mut self, scope: & $($mutability)? SourceScope) { self.super_source_scope(scope); } // The `super_xxx` methods comprise the default behavior and are // not meant to be overridden. fn super_body( &mut self, body: &$($mutability)? Body<'tcx>, ) { let span = body.span; if let Some(gen) = &$($mutability)? body.generator { if let Some(yield_ty) = &$($mutability)? gen.yield_ty { self.visit_ty( yield_ty, TyContext::YieldTy(SourceInfo::outermost(span)) ); } } // for best performance, we want to use an iterator rather // than a for-loop, to avoid calling `body::Body::invalidate` for // each basic block. macro_rules! basic_blocks { (mut) => (body.basic_blocks_mut().iter_enumerated_mut()); () => (body.basic_blocks().iter_enumerated()); } for (bb, data) in basic_blocks!($($mutability)?) { self.visit_basic_block_data(bb, data); } for scope in &$($mutability)? body.source_scopes { self.visit_source_scope_data(scope); } self.visit_ty( &$($mutability)? body.return_ty(), TyContext::ReturnTy(SourceInfo::outermost(body.span)) ); for local in body.local_decls.indices() { self.visit_local_decl(local, & $($mutability)? body.local_decls[local]); } macro_rules! type_annotations { (mut) => (body.user_type_annotations.iter_enumerated_mut()); () => (body.user_type_annotations.iter_enumerated()); } for (index, annotation) in type_annotations!($($mutability)?) { self.visit_user_type_annotation( index, annotation ); } for var_debug_info in &$($mutability)? body.var_debug_info { self.visit_var_debug_info(var_debug_info); } self.visit_span(&$($mutability)? body.span); for const_ in &$($mutability)? body.required_consts { let location = START_BLOCK.start_location(); self.visit_constant(const_, location); } } fn super_basic_block_data(&mut self, block: BasicBlock, data: & $($mutability)? BasicBlockData<'tcx>) { let BasicBlockData { statements, terminator, is_cleanup: _ } = data; let mut index = 0; for statement in statements { let location = Location { block, statement_index: index }; self.visit_statement(statement, location); index += 1; } if let Some(terminator) = terminator { let location = Location { block, statement_index: index }; self.visit_terminator(terminator, location); } } fn super_source_scope_data( &mut self, scope_data: & $($mutability)? SourceScopeData<'tcx>, ) { let SourceScopeData { span, parent_scope, inlined, inlined_parent_scope, local_data: _, } = scope_data; self.visit_span(span); if let Some(parent_scope) = parent_scope { self.visit_source_scope(parent_scope); } if let Some((callee, callsite_span)) = inlined { let location = START_BLOCK.start_location(); self.visit_span(callsite_span); let ty::Instance { def: callee_def, substs: callee_substs } = callee; match callee_def { ty::InstanceDef::Item(_def_id) => {} ty::InstanceDef::Intrinsic(_def_id) | ty::InstanceDef::VtableShim(_def_id) | ty::InstanceDef::ReifyShim(_def_id) | ty::InstanceDef::Virtual(_def_id, _) | ty::InstanceDef::ClosureOnceShim { call_once: _def_id } | ty::InstanceDef::DropGlue(_def_id, None) => {} ty::InstanceDef::FnPtrShim(_def_id, ty) | ty::InstanceDef::DropGlue(_def_id, Some(ty)) | ty::InstanceDef::CloneShim(_def_id, ty) => { // FIXME(eddyb) use a better `TyContext` here. self.visit_ty(ty, TyContext::Location(location)); } } self.visit_substs(callee_substs, location); } if let Some(inlined_parent_scope) = inlined_parent_scope { self.visit_source_scope(inlined_parent_scope); } } fn super_statement(&mut self, statement: & $($mutability)? Statement<'tcx>, location: Location) { let Statement { source_info, kind, } = statement; self.visit_source_info(source_info); match kind { StatementKind::Assign( box(ref $($mutability)? place, ref $($mutability)? rvalue) ) => { self.visit_assign(place, rvalue, location); } StatementKind::FakeRead(_, place) => { self.visit_place( place, PlaceContext::NonMutatingUse(NonMutatingUseContext::Inspect), location ); } StatementKind::SetDiscriminant { place, .. } => { self.visit_place( place, PlaceContext::MutatingUse(MutatingUseContext::Store), location ); } StatementKind::StorageLive(local) => { self.visit_local( local, PlaceContext::NonUse(NonUseContext::StorageLive), location ); } StatementKind::StorageDead(local) => { self.visit_local( local, PlaceContext::NonUse(NonUseContext::StorageDead), location ); } StatementKind::LlvmInlineAsm(asm) => { for output in & $($mutability)? asm.outputs[..] { self.visit_place( output, PlaceContext::MutatingUse(MutatingUseContext::AsmOutput), location ); } for (span, input) in & $($mutability)? asm.inputs[..] { self.visit_span(span); self.visit_operand(input, location); } } StatementKind::Retag(kind, place) => { self.visit_retag(kind, place, location); } StatementKind::AscribeUserType( box(ref $($mutability)? place, ref $($mutability)? user_ty), variance ) => { self.visit_ascribe_user_ty(place, variance, user_ty, location); } StatementKind::Coverage(coverage) => { self.visit_coverage( coverage, location ) } StatementKind::CopyNonOverlapping(box crate::mir::CopyNonOverlapping{ ref $($mutability)? src, ref $($mutability)? dst, ref $($mutability)? count, }) => { self.visit_operand(src, location); self.visit_operand(dst, location); self.visit_operand(count, location) } StatementKind::Nop => {} } } fn super_assign(&mut self, place: &$($mutability)? Place<'tcx>, rvalue: &$($mutability)? Rvalue<'tcx>, location: Location) { self.visit_place( place, PlaceContext::MutatingUse(MutatingUseContext::Store), location ); self.visit_rvalue(rvalue, location); } fn super_terminator(&mut self, terminator: &$($mutability)? Terminator<'tcx>, location: Location) { let Terminator { source_info, kind } = terminator; self.visit_source_info(source_info); match kind { TerminatorKind::Goto { .. } | TerminatorKind::Resume | TerminatorKind::Abort | TerminatorKind::GeneratorDrop | TerminatorKind::Unreachable | TerminatorKind::FalseEdge { .. } | TerminatorKind::FalseUnwind { .. } => { } TerminatorKind::Return => { // `return` logically moves from the return place `_0`. Note that the place // cannot be changed by any visitor, though. let $($mutability)? local = RETURN_PLACE; self.visit_local( & $($mutability)? local, PlaceContext::NonMutatingUse(NonMutatingUseContext::Move), location, ); assert_eq!( local, RETURN_PLACE, "`MutVisitor` tried to mutate return place of `return` terminator" ); } TerminatorKind::SwitchInt { discr, switch_ty, targets: _ } => { self.visit_operand(discr, location); self.visit_ty(switch_ty, TyContext::Location(location)); } TerminatorKind::Drop { place, target: _, unwind: _, } => { self.visit_place( place, PlaceContext::MutatingUse(MutatingUseContext::Drop), location ); } TerminatorKind::DropAndReplace { place, value, target: _, unwind: _, } => { self.visit_place( place, PlaceContext::MutatingUse(MutatingUseContext::Drop), location ); self.visit_operand(value, location); } TerminatorKind::Call { func, args, destination, cleanup: _, from_hir_call: _, fn_span: _ } => { self.visit_operand(func, location); for arg in args { self.visit_operand(arg, location); } if let Some((destination, _)) = destination { self.visit_place( destination, PlaceContext::MutatingUse(MutatingUseContext::Call), location ); } } TerminatorKind::Assert { cond, expected: _, msg, target: _, cleanup: _, } => { self.visit_operand(cond, location); self.visit_assert_message(msg, location); } TerminatorKind::Yield { value, resume: _, resume_arg, drop: _, } => { self.visit_operand(value, location); self.visit_place( resume_arg, PlaceContext::MutatingUse(MutatingUseContext::Yield), location, ); } TerminatorKind::InlineAsm { template: _, operands, options: _, line_spans: _, destination: _, } => { for op in operands { match op { InlineAsmOperand::In { value, .. } | InlineAsmOperand::Const { value } => { self.visit_operand(value, location); } InlineAsmOperand::Out { place, .. } => { if let Some(place) = place { self.visit_place( place, PlaceContext::MutatingUse(MutatingUseContext::Store), location, ); } } InlineAsmOperand::InOut { in_value, out_place, .. } => { self.visit_operand(in_value, location); if let Some(out_place) = out_place { self.visit_place( out_place, PlaceContext::MutatingUse(MutatingUseContext::Store), location, ); } } InlineAsmOperand::SymFn { value } => { self.visit_constant(value, location); } InlineAsmOperand::SymStatic { def_id: _ } => {} } } } } } fn super_assert_message(&mut self, msg: & $($mutability)? AssertMessage<'tcx>, location: Location) { use crate::mir::AssertKind::*; match msg { BoundsCheck { len, index } => { self.visit_operand(len, location); self.visit_operand(index, location); } Overflow(_, l, r) => { self.visit_operand(l, location); self.visit_operand(r, location); } OverflowNeg(op) | DivisionByZero(op) | RemainderByZero(op) => { self.visit_operand(op, location); } ResumedAfterReturn(_) | ResumedAfterPanic(_) => { // Nothing to visit } } } fn super_rvalue(&mut self, rvalue: & $($mutability)? Rvalue<'tcx>, location: Location) { match rvalue { Rvalue::Use(operand) => { self.visit_operand(operand, location); } Rvalue::Repeat(value, _) => { self.visit_operand(value, location); } Rvalue::ThreadLocalRef(_) => {} Rvalue::Ref(r, bk, path) => { self.visit_region(r, location); let ctx = match bk { BorrowKind::Shared => PlaceContext::NonMutatingUse( NonMutatingUseContext::SharedBorrow ), BorrowKind::Shallow => PlaceContext::NonMutatingUse( NonMutatingUseContext::ShallowBorrow ), BorrowKind::Unique => PlaceContext::NonMutatingUse( NonMutatingUseContext::UniqueBorrow ), BorrowKind::Mut { .. } => PlaceContext::MutatingUse(MutatingUseContext::Borrow), }; self.visit_place(path, ctx, location); } Rvalue::AddressOf(m, path) => { let ctx = match m { Mutability::Mut => PlaceContext::MutatingUse( MutatingUseContext::AddressOf ), Mutability::Not => PlaceContext::NonMutatingUse( NonMutatingUseContext::AddressOf ), }; self.visit_place(path, ctx, location); } Rvalue::Len(path) => { self.visit_place( path, PlaceContext::NonMutatingUse(NonMutatingUseContext::Inspect), location ); } Rvalue::Cast(_cast_kind, operand, ty) => { self.visit_operand(operand, location); self.visit_ty(ty, TyContext::Location(location)); } Rvalue::BinaryOp(_bin_op, box(lhs, rhs)) | Rvalue::CheckedBinaryOp(_bin_op, box(lhs, rhs)) => { self.visit_operand(lhs, location); self.visit_operand(rhs, location); } Rvalue::UnaryOp(_un_op, op) => { self.visit_operand(op, location); } Rvalue::Discriminant(place) => { self.visit_place( place, PlaceContext::NonMutatingUse(NonMutatingUseContext::Inspect), location ); } Rvalue::NullaryOp(_op, ty) => { self.visit_ty(ty, TyContext::Location(location)); } Rvalue::Aggregate(kind, operands) => { let kind = &$($mutability)? **kind; match kind { AggregateKind::Array(ty) => { self.visit_ty(ty, TyContext::Location(location)); } AggregateKind::Tuple => { } AggregateKind::Adt( _adt_def, _variant_index, substs, _user_substs, _active_field_index ) => { self.visit_substs(substs, location); } AggregateKind::Closure( _, closure_substs ) => { self.visit_substs(closure_substs, location); } AggregateKind::Generator( _, generator_substs, _movability, ) => { self.visit_substs(generator_substs, location); } } for operand in operands { self.visit_operand(operand, location); } } } } fn super_operand(&mut self, operand: & $($mutability)? Operand<'tcx>, location: Location) { match operand { Operand::Copy(place) => { self.visit_place( place, PlaceContext::NonMutatingUse(NonMutatingUseContext::Copy), location ); } Operand::Move(place) => { self.visit_place( place, PlaceContext::NonMutatingUse(NonMutatingUseContext::Move), location ); } Operand::Constant(constant) => { self.visit_constant(constant, location); } } } fn super_ascribe_user_ty(&mut self, place: & $($mutability)? Place<'tcx>, _variance: & $($mutability)? ty::Variance, user_ty: & $($mutability)? UserTypeProjection, location: Location) { self.visit_place( place, PlaceContext::NonUse(NonUseContext::AscribeUserTy), location ); self.visit_user_type_projection(user_ty); } fn super_coverage(&mut self, _coverage: & $($mutability)? Coverage, _location: Location) { } fn super_retag(&mut self, _kind: & $($mutability)? RetagKind, place: & $($mutability)? Place<'tcx>, location: Location) { self.visit_place( place, PlaceContext::MutatingUse(MutatingUseContext::Retag), location, ); } fn super_local_decl(&mut self, local: Local, local_decl: & $($mutability)? LocalDecl<'tcx>) { let LocalDecl { mutability: _, ty, user_ty, source_info, internal: _, local_info: _, is_block_tail: _, } = local_decl; self.visit_ty(ty, TyContext::LocalDecl { local, source_info: *source_info, }); if let Some(user_ty) = user_ty { for (user_ty, _) in & $($mutability)? user_ty.contents { self.visit_user_type_projection(user_ty); } } self.visit_source_info(source_info); } fn super_var_debug_info(&mut self, var_debug_info: & $($mutability)? VarDebugInfo<'tcx>) { let VarDebugInfo { name: _, source_info, value, } = var_debug_info; self.visit_source_info(source_info); let location = START_BLOCK.start_location(); match value { VarDebugInfoContents::Const(c) => self.visit_constant(c, location), VarDebugInfoContents::Place(place) => self.visit_place( place, PlaceContext::NonUse(NonUseContext::VarDebugInfo), location ), } } fn super_source_scope(&mut self, _scope: & $($mutability)? SourceScope) { } fn super_constant(&mut self, constant: & $($mutability)? Constant<'tcx>, location: Location) { let Constant { span, user_ty, literal, } = constant; self.visit_span(span); drop(user_ty); // no visit method for this self.visit_const(literal, location); } fn super_span(&mut self, _span: & $($mutability)? Span) { } fn super_source_info(&mut self, source_info: & $($mutability)? SourceInfo) { let SourceInfo { span, scope, } = source_info; self.visit_span(span); self.visit_source_scope(scope); } fn super_user_type_projection( &mut self, _ty: & $($mutability)? UserTypeProjection, ) { } fn super_user_type_annotation( &mut self, _index: UserTypeAnnotationIndex, ty: & $($mutability)? CanonicalUserTypeAnnotation<'tcx>, ) { self.visit_span(& $($mutability)? ty.span); self.visit_ty(& $($mutability)? ty.inferred_ty, TyContext::UserTy(ty.span)); } fn super_ty(&mut self, _ty: $(& $mutability)? Ty<'tcx>) { } fn super_region(&mut self, _region: & $($mutability)? ty::Region<'tcx>) { } fn super_const(&mut self, _const: & $($mutability)? &'tcx ty::Const<'tcx>) { } fn super_substs(&mut self, _substs: & $($mutability)? SubstsRef<'tcx>) { } // Convenience methods fn visit_location( &mut self, body: &$($mutability)? Body<'tcx>, location: Location ) { macro_rules! basic_blocks { (mut) => (body.basic_blocks_mut()); () => (body.basic_blocks()); } let basic_block = & $($mutability)? basic_blocks!($($mutability)?)[location.block]; if basic_block.statements.len() == location.statement_index { if let Some(ref $($mutability)? terminator) = basic_block.terminator { self.visit_terminator(terminator, location) } } else { let statement = & $($mutability)? basic_block.statements[location.statement_index]; self.visit_statement(statement, location) } } } } } macro_rules! visit_place_fns { (mut) => { fn tcx<'a>(&'a self) -> TyCtxt<'tcx>; fn super_place( &mut self, place: &mut Place<'tcx>, context: PlaceContext, location: Location, ) { self.visit_local(&mut place.local, context, location); if let Some(new_projection) = self.process_projection(&place.projection, location) { place.projection = self.tcx().intern_place_elems(&new_projection); } } fn process_projection( &mut self, projection: &'a [PlaceElem<'tcx>], location: Location, ) -> Option>> { let mut projection = Cow::Borrowed(projection); for i in 0..projection.len() { if let Some(&elem) = projection.get(i) { if let Some(elem) = self.process_projection_elem(elem, location) { // This converts the borrowed projection into `Cow::Owned(_)` and returns a // clone of the projection so we can mutate and reintern later. let vec = projection.to_mut(); vec[i] = elem; } } } match projection { Cow::Borrowed(_) => None, Cow::Owned(vec) => Some(vec), } } fn process_projection_elem( &mut self, elem: PlaceElem<'tcx>, location: Location, ) -> Option> { match elem { PlaceElem::Index(local) => { let mut new_local = local; self.visit_local( &mut new_local, PlaceContext::NonMutatingUse(NonMutatingUseContext::Copy), location, ); if new_local == local { None } else { Some(PlaceElem::Index(new_local)) } } PlaceElem::Deref | PlaceElem::Field(..) | PlaceElem::ConstantIndex { .. } | PlaceElem::Subslice { .. } | PlaceElem::Downcast(..) => None, } } }; () => { fn visit_projection( &mut self, place_ref: PlaceRef<'tcx>, context: PlaceContext, location: Location, ) { self.super_projection(place_ref, context, location); } fn visit_projection_elem( &mut self, local: Local, proj_base: &[PlaceElem<'tcx>], elem: PlaceElem<'tcx>, context: PlaceContext, location: Location, ) { self.super_projection_elem(local, proj_base, elem, context, location); } fn super_place(&mut self, place: &Place<'tcx>, context: PlaceContext, location: Location) { let mut context = context; if !place.projection.is_empty() { if context.is_use() { // ^ Only change the context if it is a real use, not a "use" in debuginfo. context = if context.is_mutating_use() { PlaceContext::MutatingUse(MutatingUseContext::Projection) } else { PlaceContext::NonMutatingUse(NonMutatingUseContext::Projection) }; } } self.visit_local(&place.local, context, location); self.visit_projection(place.as_ref(), context, location); } fn super_projection( &mut self, place_ref: PlaceRef<'tcx>, context: PlaceContext, location: Location, ) { // FIXME: Use PlaceRef::iter_projections, once that exists. let mut cursor = place_ref.projection; while let &[ref proj_base @ .., elem] = cursor { cursor = proj_base; self.visit_projection_elem(place_ref.local, cursor, elem, context, location); } } fn super_projection_elem( &mut self, _local: Local, _proj_base: &[PlaceElem<'tcx>], elem: PlaceElem<'tcx>, _context: PlaceContext, location: Location, ) { match elem { ProjectionElem::Field(_field, ty) => { self.visit_ty(ty, TyContext::Location(location)); } ProjectionElem::Index(local) => { self.visit_local( &local, PlaceContext::NonMutatingUse(NonMutatingUseContext::Copy), location, ); } ProjectionElem::Deref | ProjectionElem::Subslice { from: _, to: _, from_end: _ } | ProjectionElem::ConstantIndex { offset: _, min_length: _, from_end: _ } | ProjectionElem::Downcast(_, _) => {} } } }; } make_mir_visitor!(Visitor,); make_mir_visitor!(MutVisitor, mut); pub trait MirVisitable<'tcx> { fn apply(&self, location: Location, visitor: &mut dyn Visitor<'tcx>); } impl<'tcx> MirVisitable<'tcx> for Statement<'tcx> { fn apply(&self, location: Location, visitor: &mut dyn Visitor<'tcx>) { visitor.visit_statement(self, location) } } impl<'tcx> MirVisitable<'tcx> for Terminator<'tcx> { fn apply(&self, location: Location, visitor: &mut dyn Visitor<'tcx>) { visitor.visit_terminator(self, location) } } impl<'tcx> MirVisitable<'tcx> for Option> { fn apply(&self, location: Location, visitor: &mut dyn Visitor<'tcx>) { visitor.visit_terminator(self.as_ref().unwrap(), location) } } /// Extra information passed to `visit_ty` and friends to give context /// about where the type etc appears. #[derive(Debug)] pub enum TyContext { LocalDecl { /// The index of the local variable we are visiting. local: Local, /// The source location where this local variable was declared. source_info: SourceInfo, }, /// The inferred type of a user type annotation. UserTy(Span), /// The return type of the function. ReturnTy(SourceInfo), YieldTy(SourceInfo), /// A type found at some location. Location(Location), } #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub enum NonMutatingUseContext { /// Being inspected in some way, like loading a len. Inspect, /// Consumed as part of an operand. Copy, /// Consumed as part of an operand. Move, /// Shared borrow. SharedBorrow, /// Shallow borrow. ShallowBorrow, /// Unique borrow. UniqueBorrow, /// AddressOf for *const pointer. AddressOf, /// Used as base for another place, e.g., `x` in `x.y`. Will not mutate the place. /// For example, the projection `x.y` is not marked as a mutation in these cases: /// /// z = x.y; /// f(&x.y); /// Projection, } #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub enum MutatingUseContext { /// Appears as LHS of an assignment. Store, /// Can often be treated as a `Store`, but needs to be separate because /// ASM is allowed to read outputs as well, so a `Store`-`AsmOutput` sequence /// cannot be simplified the way a `Store`-`Store` can be. AsmOutput, /// Destination of a call. Call, /// Destination of a yield. Yield, /// Being dropped. Drop, /// Mutable borrow. Borrow, /// AddressOf for *mut pointer. AddressOf, /// Used as base for another place, e.g., `x` in `x.y`. Could potentially mutate the place. /// For example, the projection `x.y` is marked as a mutation in these cases: /// /// x.y = ...; /// f(&mut x.y); /// Projection, /// Retagging, a "Stacked Borrows" shadow state operation Retag, } #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub enum NonUseContext { /// Starting a storage live range. StorageLive, /// Ending a storage live range. StorageDead, /// User type annotation assertions for NLL. AscribeUserTy, /// The data of an user variable, for debug info. VarDebugInfo, } #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub enum PlaceContext { NonMutatingUse(NonMutatingUseContext), MutatingUse(MutatingUseContext), NonUse(NonUseContext), } impl PlaceContext { /// Returns `true` if this place context represents a drop. #[inline] pub fn is_drop(&self) -> bool { matches!(self, PlaceContext::MutatingUse(MutatingUseContext::Drop)) } /// Returns `true` if this place context represents a borrow. pub fn is_borrow(&self) -> bool { matches!( self, PlaceContext::NonMutatingUse( NonMutatingUseContext::SharedBorrow | NonMutatingUseContext::ShallowBorrow | NonMutatingUseContext::UniqueBorrow ) | PlaceContext::MutatingUse(MutatingUseContext::Borrow) ) } /// Returns `true` if this place context represents a storage live or storage dead marker. #[inline] pub fn is_storage_marker(&self) -> bool { matches!( self, PlaceContext::NonUse(NonUseContext::StorageLive | NonUseContext::StorageDead) ) } /// Returns `true` if this place context represents a use that potentially changes the value. #[inline] pub fn is_mutating_use(&self) -> bool { matches!(self, PlaceContext::MutatingUse(..)) } /// Returns `true` if this place context represents a use that does not change the value. #[inline] pub fn is_nonmutating_use(&self) -> bool { matches!(self, PlaceContext::NonMutatingUse(..)) } /// Returns `true` if this place context represents a use. #[inline] pub fn is_use(&self) -> bool { !matches!(self, PlaceContext::NonUse(..)) } /// Returns `true` if this place context represents an assignment statement. pub fn is_place_assignment(&self) -> bool { matches!( self, PlaceContext::MutatingUse( MutatingUseContext::Store | MutatingUseContext::Call | MutatingUseContext::AsmOutput, ) ) } }