// Part of the Carbon Language project, under the Apache License v2.0 with LLVM // Exceptions. See /LICENSE for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception #ifndef CARBON_TOOLCHAIN_CHECK_CONTEXT_H_ #define CARBON_TOOLCHAIN_CHECK_CONTEXT_H_ #include "common/map.h" #include "llvm/ADT/FoldingSet.h" #include "llvm/ADT/SmallVector.h" #include "toolchain/check/decl_introducer_state.h" #include "toolchain/check/decl_name_stack.h" #include "toolchain/check/diagnostic_helpers.h" #include "toolchain/check/full_pattern_stack.h" #include "toolchain/check/generic_region_stack.h" #include "toolchain/check/global_init.h" #include "toolchain/check/inst_block_stack.h" #include "toolchain/check/node_stack.h" #include "toolchain/check/param_and_arg_refs_stack.h" #include "toolchain/check/scope_index.h" #include "toolchain/check/scope_stack.h" #include "toolchain/parse/node_ids.h" #include "toolchain/parse/tree.h" #include "toolchain/parse/tree_and_subtrees.h" #include "toolchain/sem_ir/file.h" #include "toolchain/sem_ir/ids.h" #include "toolchain/sem_ir/import_ir.h" #include "toolchain/sem_ir/inst.h" #include "toolchain/sem_ir/name_scope.h" #include "toolchain/sem_ir/typed_insts.h" namespace Carbon::Check { // Information about a scope in which we can perform name lookup. struct LookupScope { // The name scope in which names are searched. SemIR::NameScopeId name_scope_id; // The specific for the name scope, or `None` if the name scope is not // defined by a generic or we should perform lookup into the generic itself. SemIR::SpecificId specific_id; }; // A result produced by name lookup. struct LookupResult { // The specific in which the lookup result was found. `None` if the result // was not found in a specific. SemIR::SpecificId specific_id; // The result from the lookup in the scope. SemIR::ScopeLookupResult scope_result; }; // Information about an access. struct AccessInfo { // The constant being accessed. SemIR::ConstantId constant_id; // The highest allowed access for a lookup. For example, `Protected` allows // access to `Public` and `Protected` names, but not `Private`. SemIR::AccessKind highest_allowed_access; }; // Context and shared functionality for semantics handlers. class Context { public: using DiagnosticEmitter = Carbon::DiagnosticEmitter; using DiagnosticBuilder = DiagnosticEmitter::DiagnosticBuilder; // A function that forms a diagnostic for some kind of problem. The // DiagnosticBuilder is returned rather than emitted so that the caller can // add contextual notes as appropriate. using BuildDiagnosticFn = llvm::function_refContext::DiagnosticBuilder>; // Stores references for work. explicit Context(DiagnosticEmitter* emitter, Parse::GetTreeAndSubtreesFn get_parse_tree_and_subtrees, SemIR::File* sem_ir, int imported_ir_count, int total_ir_count, llvm::raw_ostream* vlog_stream); // Marks an implementation TODO. Always returns false. auto TODO(SemIRLoc loc, std::string label) -> bool; // Runs verification that the processing cleanly finished. auto VerifyOnFinish() -> void; // Adds an instruction to the current block, returning the produced ID. auto AddInst(SemIR::LocIdAndInst loc_id_and_inst) -> SemIR::InstId { auto inst_id = AddInstInNoBlock(loc_id_and_inst); inst_block_stack_.AddInstId(inst_id); return inst_id; } // Convenience for AddInst with typed nodes. template auto AddInst(LocT loc, InstT inst) -> decltype(AddInst(SemIR::LocIdAndInst(loc, inst))) { return AddInst(SemIR::LocIdAndInst(loc, inst)); } // Returns a LocIdAndInst for an instruction with an imported location. Checks // that the imported location is compatible with the kind of instruction being // created. template requires SemIR::Internal::HasNodeId auto MakeImportedLocAndInst(SemIR::ImportIRInstId imported_loc_id, InstT inst) -> SemIR::LocIdAndInst { if constexpr (!SemIR::Internal::HasUntypedNodeId) { CheckCompatibleImportedNodeKind(imported_loc_id, InstT::Kind); } return SemIR::LocIdAndInst::UncheckedLoc(imported_loc_id, inst); } // Adds an instruction in no block, returning the produced ID. Should be used // rarely. auto AddInstInNoBlock(SemIR::LocIdAndInst loc_id_and_inst) -> SemIR::InstId { auto inst_id = sem_ir().insts().AddInNoBlock(loc_id_and_inst); CARBON_VLOG("AddInst: {0}\n", loc_id_and_inst.inst); FinishInst(inst_id, loc_id_and_inst.inst); return inst_id; } // Convenience for AddInstInNoBlock with typed nodes. template auto AddInstInNoBlock(LocT loc, InstT inst) -> decltype(AddInstInNoBlock(SemIR::LocIdAndInst(loc, inst))) { return AddInstInNoBlock(SemIR::LocIdAndInst(loc, inst)); } // If the instruction has an implicit location and a constant value, returns // the constant value's instruction ID. Otherwise, same as AddInst. auto GetOrAddInst(SemIR::LocIdAndInst loc_id_and_inst) -> SemIR::InstId; // Convenience for GetOrAddInst with typed nodes. template auto GetOrAddInst(LocT loc, InstT inst) -> decltype(GetOrAddInst(SemIR::LocIdAndInst(loc, inst))) { return GetOrAddInst(SemIR::LocIdAndInst(loc, inst)); } // Adds an instruction to the current block, returning the produced ID. The // instruction is a placeholder that is expected to be replaced by // `ReplaceInstBeforeConstantUse`. auto AddPlaceholderInst(SemIR::LocIdAndInst loc_id_and_inst) -> SemIR::InstId; // Adds an instruction in no block, returning the produced ID. Should be used // rarely. The instruction is a placeholder that is expected to be replaced by // `ReplaceInstBeforeConstantUse`. auto AddPlaceholderInstInNoBlock(SemIR::LocIdAndInst loc_id_and_inst) -> SemIR::InstId; // Adds an instruction to the current pattern block, returning the produced // ID. // TODO: Is it possible to remove this and pattern_block_stack, now that // we have BeginSubpattern etc. instead? auto AddPatternInst(SemIR::LocIdAndInst loc_id_and_inst) -> SemIR::InstId { auto inst_id = AddInstInNoBlock(loc_id_and_inst); pattern_block_stack_.AddInstId(inst_id); return inst_id; } // Convenience for AddPatternInst with typed nodes. template requires(SemIR::Internal::HasNodeId) auto AddPatternInst(decltype(InstT::Kind)::TypedNodeId node_id, InstT inst) -> SemIR::InstId { return AddPatternInst(SemIR::LocIdAndInst(node_id, inst)); } // Pushes a parse tree node onto the stack, storing the SemIR::Inst as the // result. template requires(SemIR::Internal::HasNodeId) auto AddInstAndPush(decltype(InstT::Kind)::TypedNodeId node_id, InstT inst) -> void { node_stack_.Push(node_id, AddInst(node_id, inst)); } // Replaces the instruction at `inst_id` with `loc_id_and_inst`. The // instruction is required to not have been used in any constant evaluation, // either because it's newly created and entirely unused, or because it's only // used in a position that constant evaluation ignores, such as a return slot. auto ReplaceLocIdAndInstBeforeConstantUse(SemIR::InstId inst_id, SemIR::LocIdAndInst loc_id_and_inst) -> void; // Replaces the instruction at `inst_id` with `inst`, not affecting location. // The instruction is required to not have been used in any constant // evaluation, either because it's newly created and entirely unused, or // because it's only used in a position that constant evaluation ignores, such // as a return slot. auto ReplaceInstBeforeConstantUse(SemIR::InstId inst_id, SemIR::Inst inst) -> void; // Replaces the instruction at `inst_id` with `inst`, not affecting location. // The instruction is required to not change its constant value. auto ReplaceInstPreservingConstantValue(SemIR::InstId inst_id, SemIR::Inst inst) -> void; // Sets only the parse node of an instruction. This is only used when setting // the parse node of an imported namespace. Versus // ReplaceInstBeforeConstantUse, it is safe to use after the namespace is used // in constant evaluation. It's exposed this way mainly so that `insts()` can // remain const. auto SetNamespaceNodeId(SemIR::InstId inst_id, Parse::NodeId node_id) -> void { sem_ir().insts().SetLocId(inst_id, SemIR::LocId(node_id)); } // Adds a name to name lookup. Prints a diagnostic for name conflicts. If // specified, `scope_index` specifies which lexical scope the name is inserted // into, otherwise the name is inserted into the current scope. auto AddNameToLookup(SemIR::NameId name_id, SemIR::InstId target_id, ScopeIndex scope_index = ScopeIndex::None) -> void; // Performs name lookup in a specified scope for a name appearing in a // declaration. If scope_id is `None`, performs lookup into the lexical scope // specified by scope_index instead. auto LookupNameInDecl(SemIR::LocId loc_id, SemIR::NameId name_id, SemIR::NameScopeId scope_id, ScopeIndex scope_index) -> SemIR::ScopeLookupResult; // Performs an unqualified name lookup, returning the referenced `InstId`. auto LookupUnqualifiedName(Parse::NodeId node_id, SemIR::NameId name_id, bool required = true) -> LookupResult; // Performs a name lookup in a specified scope, returning the referenced // `InstId`. Does not look into extended scopes. Returns `InstId::None` if the // name is not found. // // If `is_being_declared` is false, then this is a regular name lookup, and // the name will be poisoned if not found so that later lookups will fail; a // poisoned name will be treated as if it is not declared. Otherwise, this is // a lookup for a name being declared, so the name will not be poisoned, but // poison will be returned if it's already been looked up. auto LookupNameInExactScope(SemIR::LocId loc_id, SemIR::NameId name_id, SemIR::NameScopeId scope_id, SemIR::NameScope& scope, bool is_being_declared = false) -> SemIR::ScopeLookupResult; // Appends the lookup scopes corresponding to `base_const_id` to `*scopes`. // Returns `false` if not a scope. On invalid scopes, prints a diagnostic, but // still updates `*scopes` and returns `true`. auto AppendLookupScopesForConstant(SemIR::LocId loc_id, SemIR::ConstantId base_const_id, llvm::SmallVector* scopes) -> bool; // Performs a qualified name lookup in a specified scopes and in scopes that // they extend, returning the referenced `InstId`. auto LookupQualifiedName(SemIR::LocId loc_id, SemIR::NameId name_id, llvm::ArrayRef lookup_scopes, bool required = true, std::optional access_info = std::nullopt) -> LookupResult; // Returns the `InstId` corresponding to a name in the core package, or // BuiltinErrorInst if not found. auto LookupNameInCore(SemIR::LocId loc_id, llvm::StringRef name) -> SemIR::InstId; // Prints a diagnostic for a duplicate name. auto DiagnoseDuplicateName(SemIRLoc dup_def, SemIRLoc prev_def) -> void; // Prints a diagnostic for a poisoned name when it's later declared. auto DiagnosePoisonedName(SemIR::LocId poisoning_loc_id, SemIR::InstId decl_inst_id) -> void; // Prints a diagnostic for a missing name. auto DiagnoseNameNotFound(SemIRLoc loc, SemIR::NameId name_id) -> void; // Prints a diagnostic for a missing qualified name. auto DiagnoseMemberNameNotFound(SemIRLoc loc, SemIR::NameId name_id, llvm::ArrayRef lookup_scopes) -> void; // Adds a note to a diagnostic explaining that a class is incomplete. auto NoteIncompleteClass(SemIR::ClassId class_id, DiagnosticBuilder& builder) -> void; // Adds a note to a diagnostic explaining that a class is abstract. auto NoteAbstractClass(SemIR::ClassId class_id, DiagnosticBuilder& builder) -> void; // Adds a note to a diagnostic explaining that an interface is not defined. auto NoteUndefinedInterface(SemIR::InterfaceId interface_id, DiagnosticBuilder& builder) -> void; // Returns the current scope, if it is of the specified kind. Otherwise, // returns nullopt. template auto GetCurrentScopeAs() -> std::optional { return scope_stack().GetCurrentScopeAs(sem_ir()); } // Mark the start of a new single-entry region with the given entry block. auto PushRegion(SemIR::InstBlockId entry_block_id) -> void { region_stack_.PushArray(); region_stack_.AppendToTop(entry_block_id); } // Add `block_id` to the most recently pushed single-entry region. To preserve // the single-entry property, `block_id` must not be directly reachable from // any block outside the region. To ensure the region's blocks are in lexical // order, this should be called when the first parse node associated with this // block is handled, or as close as possible. auto AddToRegion(SemIR::InstBlockId block_id, SemIR::LocId loc_id) -> void; // Complete creation of the most recently pushed single-entry region, and // return a list of its blocks. auto PopRegion() -> llvm::SmallVector { llvm::SmallVector result(region_stack_.PeekArray()); region_stack_.PopArray(); return result; } // Adds a `Branch` instruction branching to a new instruction block, and // returns the ID of the new block. All paths to the branch target must go // through the current block, though not necessarily through this branch. auto AddDominatedBlockAndBranch(Parse::NodeId node_id) -> SemIR::InstBlockId; // Adds a `Branch` instruction branching to a new instruction block with a // value, and returns the ID of the new block. All paths to the branch target // must go through the current block. auto AddDominatedBlockAndBranchWithArg(Parse::NodeId node_id, SemIR::InstId arg_id) -> SemIR::InstBlockId; // Adds a `BranchIf` instruction branching to a new instruction block, and // returns the ID of the new block. All paths to the branch target must go // through the current block. auto AddDominatedBlockAndBranchIf(Parse::NodeId node_id, SemIR::InstId cond_id) -> SemIR::InstBlockId; // Handles recovergence of control flow. Adds branches from the top // `num_blocks` on the instruction block stack to a new block, pops the // existing blocks, pushes the new block onto the instruction block stack, // and adds it to the most recently pushed region. auto AddConvergenceBlockAndPush(Parse::NodeId node_id, int num_blocks) -> void; // Handles recovergence of control flow with a result value. Adds branches // from the top few blocks on the instruction block stack to a new block, pops // the existing blocks, pushes the new block onto the instruction block // stack, and adds it to the most recently pushed region. The number of blocks // popped is the size of `block_args`, and the corresponding result values are // the elements of `block_args`. Returns an instruction referring to the // result value. auto AddConvergenceBlockWithArgAndPush( Parse::NodeId node_id, std::initializer_list block_args) -> SemIR::InstId; // Sets the constant value of a block argument created as the result of a // branch. `select_id` should be a `BlockArg` that selects between two // values. `cond_id` is the condition, `if_false` is the value to use if the // condition is false, and `if_true` is the value to use if the condition is // true. We don't track enough information in the `BlockArg` inst for // `TryEvalInst` to do this itself. auto SetBlockArgResultBeforeConstantUse(SemIR::InstId select_id, SemIR::InstId cond_id, SemIR::InstId if_true, SemIR::InstId if_false) -> void; // Returns whether the current position in the current block is reachable. auto is_current_position_reachable() -> bool; // Returns the type ID for a constant of type `type`. auto GetTypeIdForTypeConstant(SemIR::ConstantId constant_id) -> SemIR::TypeId; // Returns the type ID for an instruction whose constant value is of type // `type`. auto GetTypeIdForTypeInst(SemIR::InstId inst_id) -> SemIR::TypeId { return GetTypeIdForTypeConstant(constant_values().Get(inst_id)); } // Attempts to complete the type `type_id`. Returns `true` if the type is // complete, or `false` if it could not be completed. A complete type has // known object and value representations. Returns `true` if the type is // symbolic. // // Avoid calling this where possible, as it can lead to coherence issues. // However, it's important that we use it during monomorphization, where we // don't want to trigger a request for more monomorphization. // TODO: Remove the other call to this function. auto TryToCompleteType(SemIR::TypeId type_id, SemIRLoc loc, BuildDiagnosticFn diagnoser = nullptr) -> bool; // Completes the type `type_id`. CHECK-fails if it can't be completed. auto CompleteTypeOrCheckFail(SemIR::TypeId type_id) -> void; // Like `TryToCompleteType`, but for cases where it is an error for the type // to be incomplete. // // If the type is not complete, `diagnoser` is invoked to diagnose the issue, // if a `diagnoser` is provided. The builder it returns will be annotated to // describe the reason why the type is not complete. // // `diagnoser` should build an error diagnostic. If `type_id` is dependent, // the completeness of the type will be enforced during monomorphization, and // `loc_id` is used as the location for a diagnostic produced at that time. auto RequireCompleteType(SemIR::TypeId type_id, SemIR::LocId loc_id, BuildDiagnosticFn diagnoser) -> bool; // Like `RequireCompleteType`, but also require the type to not be an abstract // class type. If it is, `abstract_diagnoser` is used to diagnose the problem, // and this function returns false. auto RequireConcreteType(SemIR::TypeId type_id, SemIR::LocId loc_id, BuildDiagnosticFn diagnoser, BuildDiagnosticFn abstract_diagnoser) -> bool; // Like `RequireCompleteType`, but also require the type to be defined. A // defined type has known members. If the type is not defined, `diagnoser` is // used to diagnose the problem, and this function returns false. // // This is the same as `RequireCompleteType` except for facet types, which are // complete before they are fully defined. auto RequireDefinedType(SemIR::TypeId type_id, SemIR::LocId loc_id, BuildDiagnosticFn diagnoser) -> bool; // Returns the type `type_id` if it is a complete type, or produces an // incomplete type error and returns an error type. This is a convenience // wrapper around `RequireCompleteType`. auto AsCompleteType(SemIR::TypeId type_id, SemIR::LocId loc_id, BuildDiagnosticFn diagnoser) -> SemIR::TypeId { return RequireCompleteType(type_id, loc_id, diagnoser) ? type_id : SemIR::ErrorInst::SingletonTypeId; } // Returns the type `type_id` if it is a concrete type, or produces an // incomplete or abstract type error and returns an error type. This is a // convenience wrapper around `RequireConcreteType`. auto AsConcreteType(SemIR::TypeId type_id, SemIR::LocId loc_id, BuildDiagnosticFn diagnoser, BuildDiagnosticFn abstract_diagnoser) -> SemIR::TypeId { return RequireConcreteType(type_id, loc_id, diagnoser, abstract_diagnoser) ? type_id : SemIR::ErrorInst::SingletonTypeId; } // Returns whether `type_id` represents a facet type. auto IsFacetType(SemIR::TypeId type_id) -> bool { return type_id == SemIR::TypeType::SingletonTypeId || types().Is(type_id); } // Create a FacetType typed instruction object consisting of a single // interface. auto FacetTypeFromInterface(SemIR::InterfaceId interface_id, SemIR::SpecificId specific_id) -> SemIR::FacetType; // TODO: Consider moving these `Get*Type` functions to a separate class. // Gets the type to use for an unbound associated entity declared in this // interface. For example, this is the type of `I.T` after // `interface I { let T:! type; }`. // The name of the interface is used for diagnostics. // TODO: Should we use a different type for each such entity, or the same type // for all associated entities? auto GetAssociatedEntityType(SemIR::TypeId interface_type_id) -> SemIR::TypeId; // Gets a singleton type. The returned type will be complete. Requires that // `singleton_id` is already validated to be a singleton. auto GetSingletonType(SemIR::InstId singleton_id) -> SemIR::TypeId; // Gets a class type. auto GetClassType(SemIR::ClassId class_id, SemIR::SpecificId specific_id) -> SemIR::TypeId; // Gets a function type. The returned type will be complete. auto GetFunctionType(SemIR::FunctionId fn_id, SemIR::SpecificId specific_id) -> SemIR::TypeId; // Gets the type of an associated function with the `Self` parameter bound to // a particular value. The returned type will be complete. auto GetFunctionTypeWithSelfType(SemIR::InstId interface_function_type_id, SemIR::InstId self_id) -> SemIR::TypeId; // Gets a generic class type, which is the type of a name of a generic class, // such as the type of `Vector` given `class Vector(T:! type)`. The returned // type will be complete. auto GetGenericClassType(SemIR::ClassId class_id, SemIR::SpecificId enclosing_specific_id) -> SemIR::TypeId; // Gets a generic interface type, which is the type of a name of a generic // interface, such as the type of `AddWith` given // `interface AddWith(T:! type)`. The returned type will be complete. auto GetGenericInterfaceType(SemIR::InterfaceId interface_id, SemIR::SpecificId enclosing_specific_id) -> SemIR::TypeId; // Gets the facet type corresponding to a particular interface. auto GetInterfaceType(SemIR::InterfaceId interface_id, SemIR::SpecificId specific_id) -> SemIR::TypeId; // Returns a pointer type whose pointee type is `pointee_type_id`. auto GetPointerType(SemIR::TypeId pointee_type_id) -> SemIR::TypeId; // Returns a struct type with the given fields. auto GetStructType(SemIR::StructTypeFieldsId fields_id) -> SemIR::TypeId; // Returns a tuple type with the given element types. auto GetTupleType(llvm::ArrayRef type_ids) -> SemIR::TypeId; // Returns an unbound element type. auto GetUnboundElementType(SemIR::TypeId class_type_id, SemIR::TypeId element_type_id) -> SemIR::TypeId; // Adds an exported name. auto AddExport(SemIR::InstId inst_id) -> void { exports_.push_back(inst_id); } auto Finalize() -> void; // Returns the imported IR ID for an IR, or `None` if not imported. auto GetImportIRId(const SemIR::File& sem_ir) -> SemIR::ImportIRId& { return check_ir_map_[sem_ir.check_ir_id().index]; } // True if the current file is an impl file. auto IsImplFile() -> bool { return sem_ir_->import_irs().Get(SemIR::ImportIRId::ApiForImpl).sem_ir != nullptr; } // Prints information for a stack dump. auto PrintForStackDump(llvm::raw_ostream& output) const -> void; // Prints the the formatted sem_ir to stderr. LLVM_DUMP_METHOD auto DumpFormattedFile() const -> void; // Get the Lex::TokenKind of a node for diagnostics. auto token_kind(Parse::NodeId node_id) -> Lex::TokenKind { return tokens().GetKind(parse_tree().node_token(node_id)); } auto emitter() -> DiagnosticEmitter& { return *emitter_; } auto parse_tree_and_subtrees() -> const Parse::TreeAndSubtrees& { return get_parse_tree_and_subtrees_(); } auto sem_ir() -> SemIR::File& { return *sem_ir_; } auto sem_ir() const -> const SemIR::File& { return *sem_ir_; } auto parse_tree() const -> const Parse::Tree& { return sem_ir_->parse_tree(); } auto tokens() const -> const Lex::TokenizedBuffer& { return parse_tree().tokens(); } auto node_stack() -> NodeStack& { return node_stack_; } auto inst_block_stack() -> InstBlockStack& { return inst_block_stack_; } auto pattern_block_stack() -> InstBlockStack& { return pattern_block_stack_; } auto param_and_arg_refs_stack() -> ParamAndArgRefsStack& { return param_and_arg_refs_stack_; } auto args_type_info_stack() -> InstBlockStack& { return args_type_info_stack_; } auto struct_type_fields_stack() -> ArrayStack& { return struct_type_fields_stack_; } auto field_decls_stack() -> ArrayStack& { return field_decls_stack_; } auto decl_name_stack() -> DeclNameStack& { return decl_name_stack_; } auto decl_introducer_state_stack() -> DeclIntroducerStateStack& { return decl_introducer_state_stack_; } auto scope_stack() -> ScopeStack& { return scope_stack_; } auto return_scope_stack() -> llvm::SmallVector& { return scope_stack().return_scope_stack(); } auto break_continue_stack() -> llvm::SmallVector& { return scope_stack().break_continue_stack(); } auto generic_region_stack() -> GenericRegionStack& { return generic_region_stack_; } auto vtable_stack() -> InstBlockStack& { return vtable_stack_; } auto import_ir_constant_values() -> llvm::SmallVector& { return import_ir_constant_values_; } // Directly expose SemIR::File data accessors for brevity in calls. auto identifiers() -> SharedValueStores::IdentifierStore& { return sem_ir().identifiers(); } auto ints() -> SharedValueStores::IntStore& { return sem_ir().ints(); } auto reals() -> SharedValueStores::RealStore& { return sem_ir().reals(); } auto floats() -> SharedValueStores::FloatStore& { return sem_ir().floats(); } auto string_literal_values() -> SharedValueStores::StringLiteralStore& { return sem_ir().string_literal_values(); } auto entity_names() -> SemIR::EntityNameStore& { return sem_ir().entity_names(); } auto functions() -> ValueStore& { return sem_ir().functions(); } auto classes() -> ValueStore& { return sem_ir().classes(); } auto interfaces() -> ValueStore& { return sem_ir().interfaces(); } auto associated_constants() -> ValueStore& { return sem_ir().associated_constants(); } auto facet_types() -> CanonicalValueStore& { return sem_ir().facet_types(); } auto impls() -> SemIR::ImplStore& { return sem_ir().impls(); } auto generics() -> SemIR::GenericStore& { return sem_ir().generics(); } auto specifics() -> SemIR::SpecificStore& { return sem_ir().specifics(); } auto import_irs() -> ValueStore& { return sem_ir().import_irs(); } auto import_ir_insts() -> ValueStore& { return sem_ir().import_ir_insts(); } auto names() -> SemIR::NameStoreWrapper { return sem_ir().names(); } auto name_scopes() -> SemIR::NameScopeStore& { return sem_ir().name_scopes(); } auto struct_type_fields() -> SemIR::StructTypeFieldsStore& { return sem_ir().struct_type_fields(); } auto types() -> SemIR::TypeStore& { return sem_ir().types(); } auto type_blocks() -> SemIR::BlockValueStore& { return sem_ir().type_blocks(); } // Instructions should be added with `AddInst` or `AddInstInNoBlock`. This is // `const` to prevent accidental misuse. auto insts() -> const SemIR::InstStore& { return sem_ir().insts(); } auto constant_values() -> SemIR::ConstantValueStore& { return sem_ir().constant_values(); } auto inst_blocks() -> SemIR::InstBlockStore& { return sem_ir().inst_blocks(); } auto constants() -> SemIR::ConstantStore& { return sem_ir().constants(); } auto definitions_required() -> llvm::SmallVector& { return definitions_required_; } auto global_init() -> GlobalInit& { return global_init_; } // Marks the start of a region of insts in a pattern context that might // represent an expression or a pattern. Typically this is called when // handling a parse node that can immediately precede a subpattern (such // as `let` or a `,` in a pattern list), and the handler for the subpattern // node makes the matching `EndSubpatternAs*` call. auto BeginSubpattern() -> void; // Ends a region started by BeginSubpattern (in stack order), treating it as // an expression with the given result, and returns the ID of the region. The // region will not yet have any control-flow edges into or out of it. auto EndSubpatternAsExpr(SemIR::InstId result_id) -> SemIR::ExprRegionId; // Ends a region started by BeginSubpattern (in stack order), asserting that // it was empty. auto EndSubpatternAsEmpty() -> void; // TODO: Add EndSubpatternAsPattern, when needed. // Inserts the given region into the current code block. If the region // consists of a single block, this will be implemented as a `splice_block` // inst. Otherwise, this will end the current block with a branch to the entry // block of the region, and add future insts to a new block which is the // immediate successor of the region's exit block. As a result, this cannot be // called more than once for the same region. auto InsertHere(SemIR::ExprRegionId region_id) -> SemIR::InstId; auto import_ref_ids() -> llvm::SmallVector& { return import_ref_ids_; } // Map from an AnyBindingPattern inst to precomputed parts of the // pattern-match SemIR for it. // // TODO: Consider putting this behind a narrower API to guard against emitting // multiple times. struct BindingPatternInfo { // The corresponding AnyBindName inst. SemIR::InstId bind_name_id; // The region of insts that computes the type of the binding. SemIR::ExprRegionId type_expr_region_id; }; auto bind_name_map() -> Map& { return bind_name_map_; } auto var_storage_map() -> Map& { return var_storage_map_; } auto full_pattern_stack() -> FullPatternStack& { return scope_stack_.full_pattern_stack(); } private: // A FoldingSet node for a type. class TypeNode : public llvm::FastFoldingSetNode { public: explicit TypeNode(const llvm::FoldingSetNodeID& node_id, SemIR::TypeId type_id) : llvm::FastFoldingSetNode(node_id), type_id_(type_id) {} auto type_id() -> SemIR::TypeId { return type_id_; } private: SemIR::TypeId type_id_; }; // Checks that the provided imported location has a node kind that is // compatible with that of the given instruction. auto CheckCompatibleImportedNodeKind(SemIR::ImportIRInstId imported_loc_id, SemIR::InstKind kind) -> void; // Finish producing an instruction. Set its constant value, and register it in // any applicable instruction lists. auto FinishInst(SemIR::InstId inst_id, SemIR::Inst inst) -> void; // Handles diagnostics. DiagnosticEmitter* emitter_; // Returns a lazily constructed TreeAndSubtrees. Parse::GetTreeAndSubtreesFn get_parse_tree_and_subtrees_; // The SemIR::File being added to. SemIR::File* sem_ir_; // Whether to print verbose output. llvm::raw_ostream* vlog_stream_; // The stack during Build. Will contain file-level parse nodes on return. NodeStack node_stack_; // The stack of instruction blocks being used for general IR generation. InstBlockStack inst_block_stack_; // The stack of instruction blocks that contain pattern instructions. InstBlockStack pattern_block_stack_; // The stack of instruction blocks being used for param and arg ref blocks. ParamAndArgRefsStack param_and_arg_refs_stack_; // The stack of instruction blocks being used for type information while // processing arguments. This is used in parallel with // param_and_arg_refs_stack_. It's currently only used for struct literals, // where we need to track names for a type separate from the literal // arguments. InstBlockStack args_type_info_stack_; // The stack of StructTypeFields for in-progress StructTypeLiterals. ArrayStack struct_type_fields_stack_; // The stack of FieldDecls for in-progress Class definitions. ArrayStack field_decls_stack_; // The stack used for qualified declaration name construction. DeclNameStack decl_name_stack_; // The stack of declarations that could have modifiers. DeclIntroducerStateStack decl_introducer_state_stack_; // The stack of scopes we are currently within. ScopeStack scope_stack_; // The stack of generic regions we are currently within. GenericRegionStack generic_region_stack_; // Contains a vtable block for each `class` scope which is currently being // defined, regardless of whether the class can have virtual functions. InstBlockStack vtable_stack_; // Cache of reverse mapping from type constants to types. // // TODO: Instead of mapping to a dense `TypeId` space, we could make `TypeId` // be a thin wrapper around `ConstantId` and only perform the lookup only when // we want to access the completeness and value representation of a type. It's // not clear whether that would result in more or fewer lookups. // // TODO: Should this be part of the `TypeStore`? Map type_ids_for_type_constants_; // The list which will form NodeBlockId::Exports. llvm::SmallVector exports_; // Maps CheckIRId to ImportIRId. llvm::SmallVector check_ir_map_; // Per-import constant values. These refer to the main IR and mainly serve as // a lookup table for quick access. // // Inline 0 elements because it's expected to require heap allocation. llvm::SmallVector import_ir_constant_values_; // Declaration instructions of entities that should have definitions by the // end of the current source file. llvm::SmallVector definitions_required_; // State for global initialization. GlobalInit global_init_; // A list of import refs which can't be inserted into their current context. // They're typically added during name lookup or import ref resolution, where // the current block on inst_block_stack_ is unrelated. // // These are instead added here because they're referenced by other // instructions and needs to be visible in textual IR. // FinalizeImportRefBlock() will produce an inst block for them. llvm::SmallVector import_ref_ids_; Map bind_name_map_; // Map from VarPattern insts to the corresponding VarStorage insts. The // VarStorage insts are allocated, emitted, and stored in the map after // processing the enclosing full-pattern. Map var_storage_map_; // Stack of single-entry regions being built. ArrayStack region_stack_; }; } // namespace Carbon::Check #endif // CARBON_TOOLCHAIN_CHECK_CONTEXT_H_