// 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 #include "toolchain/check/context.h" #include "toolchain/check/convert.h" #include "toolchain/check/facet_type.h" #include "toolchain/check/handle.h" #include "toolchain/check/inst.h" #include "toolchain/check/interface.h" #include "toolchain/check/name_lookup.h" #include "toolchain/check/pattern.h" #include "toolchain/check/return.h" #include "toolchain/check/type.h" #include "toolchain/check/type_completion.h" #include "toolchain/diagnostics/format_providers.h" #include "toolchain/parse/node_ids.h" #include "toolchain/sem_ir/ids.h" #include "toolchain/sem_ir/inst.h" #include "toolchain/sem_ir/pattern.h" #include "toolchain/sem_ir/typed_insts.h" namespace Carbon::Check { auto HandleParseNode(Context& context, Parse::UnderscoreNameId node_id) -> bool { context.node_stack().Push(node_id, SemIR::NameId::Underscore); return true; } // TODO: make this function shorter by factoring pieces out. static auto HandleAnyBindingPattern(Context& context, Parse::NodeId node_id, Parse::NodeKind node_kind) -> bool { // TODO: split this into smaller, more focused functions. auto [type_node, parsed_type_id] = context.node_stack().PopExprWithNodeId(); auto [cast_type_inst_id, cast_type_id] = ExprAsType(context, type_node, parsed_type_id); SemIR::ExprRegionId type_expr_region_id = EndSubpatternAsExpr(context, cast_type_inst_id); // The name in a generic binding may be wrapped in `template`. bool is_generic = node_kind == Parse::NodeKind::CompileTimeBindingPattern; bool is_template = context.node_stack() .PopAndDiscardSoloNodeIdIf(); // A non-generic template binding is diagnosed by the parser. is_template &= is_generic; // The name in a runtime binding may be wrapped in `ref`. bool is_ref = context.node_stack() .PopAndDiscardSoloNodeIdIf(); SemIR::InstKind pattern_inst_kind; switch (node_kind) { case Parse::NodeKind::CompileTimeBindingPattern: pattern_inst_kind = SemIR::InstKind::SymbolicBindingPattern; break; case Parse::NodeKind::LetBindingPattern: if (is_ref) { pattern_inst_kind = SemIR::InstKind::RefBindingPattern; } else { pattern_inst_kind = SemIR::InstKind::ValueBindingPattern; } break; case Parse::NodeKind::VarBindingPattern: pattern_inst_kind = SemIR::InstKind::RefBindingPattern; break; default: CARBON_FATAL("Unexpected node kind: {0}", node_kind); } auto [name_node, name_id] = context.node_stack().PopNameWithNodeId(); const DeclIntroducerState& introducer = context.decl_introducer_state_stack().innermost(); auto make_binding_pattern = [&]() -> SemIR::InstId { // TODO: Eventually the name will need to support associations with other // scopes, but right now we don't support qualified names here. auto binding = AddBindingPattern(context, name_node, name_id, cast_type_id, type_expr_region_id, pattern_inst_kind, is_template); // TODO: If `is_generic`, then `binding.bind_id is a SymbolicBinding. Subst // the `.Self` of type `type` in the `cast_type_id` type (a `FacetType`) // with the `binding.bind_id` itself, and build a new pattern with that. // This is kind of cyclical. So we need to reuse the EntityNameId, which // will also reuse the CompileTimeBinding for the new SymbolicBinding. if (name_id != SemIR::NameId::Underscore) { // Add name to lookup immediately, so it can be used in the rest of the // enclosing pattern. auto name_context = context.decl_name_stack().MakeUnqualifiedName(name_node, name_id); context.decl_name_stack().AddNameOrDiagnose( name_context, binding.bind_id, introducer.modifier_set.GetAccessKind()); context.full_pattern_stack().AddBindName(name_id); } return binding.pattern_id; }; // A `self` binding can only appear in an implicit parameter list. if (name_id == SemIR::NameId::SelfValue && !context.node_stack().PeekIs(Parse::NodeKind::ImplicitParamListStart)) { CARBON_DIAGNOSTIC( SelfOutsideImplicitParamList, Error, "`self` can only be declared in an implicit parameter list"); context.emitter().Emit(node_id, SelfOutsideImplicitParamList); } // Allocate an instruction of the appropriate kind, linked to the name for // error locations. switch (context.full_pattern_stack().CurrentKind()) { case FullPatternStack::Kind::ImplicitParamList: case FullPatternStack::Kind::ExplicitParamList: { // Parameters can have incomplete types in a function declaration, but not // in a function definition. We don't know which kind we have here. bool had_error = false; switch (introducer.kind) { case Lex::TokenKind::Fn: { if (context.full_pattern_stack().CurrentKind() == FullPatternStack::Kind::ImplicitParamList && !(is_generic || name_id == SemIR::NameId::SelfValue)) { CARBON_DIAGNOSTIC( ImplictParamMustBeConstant, Error, "implicit parameters of functions must be constant or `self`"); context.emitter().Emit(node_id, ImplictParamMustBeConstant); had_error = true; } break; } case Lex::TokenKind::Choice: if (context.scope_stack().PeekInstId().has_value()) { // We are building a pattern for a choice alternative, not the // choice type itself. // Implicit param lists are prevented during parse. CARBON_CHECK(context.full_pattern_stack().CurrentKind() != FullPatternStack::Kind::ImplicitParamList, "choice alternative with implicit parameters"); // Don't fall through to the `Class` logic for choice alternatives. break; } [[fallthrough]]; case Lex::TokenKind::Class: case Lex::TokenKind::Impl: case Lex::TokenKind::Interface: { if (name_id == SemIR::NameId::SelfValue) { CARBON_DIAGNOSTIC(SelfParameterNotAllowed, Error, "`self` parameter only allowed on functions"); context.emitter().Emit(node_id, SelfParameterNotAllowed); had_error = true; } else if (!is_generic) { CARBON_DIAGNOSTIC(GenericParamMustBeConstant, Error, "parameters of generic types must be constant"); context.emitter().Emit(node_id, GenericParamMustBeConstant); had_error = true; } break; } default: break; } auto result_inst_id = SemIR::InstId::None; if (had_error) { if (name_id != SemIR::NameId::Underscore) { AddNameToLookup(context, name_id, SemIR::ErrorInst::InstId); } // Replace the parameter with `ErrorInst` so that we don't try // constructing a generic based on it. result_inst_id = SemIR::ErrorInst::InstId; } else { result_inst_id = make_binding_pattern(); // A binding pattern in a function signature is a `Call` parameter // unless it's nested inside a `var` pattern (because then the // enclosing `var` pattern is), or it's a compile-time binding pattern // (because then it's not passed to the `Call` inst). if (node_kind == Parse::NodeKind::LetBindingPattern) { if (is_ref) { result_inst_id = AddPatternInst( context, node_id, {.type_id = context.insts().Get(result_inst_id).type_id(), .subpattern_id = result_inst_id, .index = SemIR::CallParamIndex::None}); } else { result_inst_id = AddPatternInst( context, node_id, {.type_id = context.insts().Get(result_inst_id).type_id(), .subpattern_id = result_inst_id, .index = SemIR::CallParamIndex::None}); } } } context.node_stack().Push(node_id, result_inst_id); break; } case FullPatternStack::Kind::NameBindingDecl: { auto incomplete_diagnoser = [&] { CARBON_DIAGNOSTIC(IncompleteTypeInBindingDecl, Error, "binding pattern has incomplete type {0} in name " "binding declaration", InstIdAsType); return context.emitter().Build(type_node, IncompleteTypeInBindingDecl, cast_type_inst_id); }; if (node_kind == Parse::NodeKind::VarBindingPattern) { cast_type_id = AsConcreteType( context, cast_type_id, type_node, incomplete_diagnoser, [&] { CARBON_DIAGNOSTIC( AbstractTypeInVarPattern, Error, "binding pattern has abstract type {0} in `var` " "pattern", SemIR::TypeId); return context.emitter().Build( type_node, AbstractTypeInVarPattern, cast_type_id); }); } else { cast_type_id = AsCompleteType(context, cast_type_id, type_node, incomplete_diagnoser); } auto binding_pattern_id = make_binding_pattern(); if (node_kind == Parse::NodeKind::VarBindingPattern) { CARBON_CHECK(!is_generic); if (introducer.modifier_set.HasAnyOf(KeywordModifierSet::Returned)) { // TODO: Should we check this for the `var` as a whole, rather than // for the name binding? auto bind_id = context.bind_name_map() .Lookup(binding_pattern_id) .value() .bind_name_id; RegisterReturnedVar(context, introducer.modifier_node_id(ModifierOrder::Decl), type_node, cast_type_id, bind_id); } } context.node_stack().Push(node_id, binding_pattern_id); break; } } return true; } auto HandleParseNode(Context& context, Parse::LetBindingPatternId node_id) -> bool { return HandleAnyBindingPattern(context, node_id, Parse::NodeKind::LetBindingPattern); } auto HandleParseNode(Context& context, Parse::VarBindingPatternId node_id) -> bool { return HandleAnyBindingPattern(context, node_id, Parse::NodeKind::VarBindingPattern); } auto HandleParseNode(Context& context, Parse::CompileTimeBindingPatternStartId node_id) -> bool { // Make a scope to contain the `.Self` facet value for use in the type of the // compile time binding. This is popped when handling the // CompileTimeBindingPatternId. context.scope_stack().PushForSameRegion(); // The `.Self` must have a type of `FacetType`, so that it gets wrapped in // `FacetAccessType` when used in a type position, such as in `U:! I(.Self)`. // This allows substitution with other facet values without requiring an // additional `FacetAccessType` to be inserted. SemIR::FacetTypeId facet_type_id = context.facet_types().Add(SemIR::FacetTypeInfo{}); auto const_id = EvalOrAddInst( context, node_id, {.type_id = SemIR::TypeType::TypeId, .facet_type_id = facet_type_id}); auto type_id = context.types().GetTypeIdForTypeConstantId(const_id); MakePeriodSelfFacetValue(context, type_id); return true; } auto HandleParseNode(Context& context, Parse::CompileTimeBindingPatternId node_id) -> bool { // Pop the `.Self` facet value name introduced by the // CompileTimeBindingPatternStart. context.scope_stack().Pop(); auto node_kind = Parse::NodeKind::CompileTimeBindingPattern; const DeclIntroducerState& introducer = context.decl_introducer_state_stack().innermost(); if (introducer.kind == Lex::TokenKind::Let) { // Disallow `let` outside of function and interface definitions. // TODO: Find a less brittle way of doing this. A `scope_inst_id` of `None` // can represent a block scope, but is also used for other kinds of scopes // that aren't necessarily part of a function decl. // We don't need to check if the scope is an interface here as this is // already caught in the parse phase by the separated associated constant // logic. auto scope_inst_id = context.scope_stack().PeekInstId(); if (scope_inst_id.has_value()) { auto scope_inst = context.insts().Get(scope_inst_id); if (!scope_inst.Is()) { context.TODO( node_id, "`let` compile time binding outside function or interface"); node_kind = Parse::NodeKind::LetBindingPattern; } } } return HandleAnyBindingPattern(context, node_id, node_kind); } auto HandleParseNode(Context& context, Parse::AssociatedConstantNameAndTypeId node_id) -> bool { auto [type_node, parsed_type_id] = context.node_stack().PopExprWithNodeId(); auto [cast_type_inst_id, cast_type_id] = ExprAsType(context, type_node, parsed_type_id); EndSubpatternAsExpr(context, cast_type_inst_id); auto [name_node, name_id] = context.node_stack().PopNameWithNodeId(); if (name_id == SemIR::NameId::Underscore) { // The action item here may be to document this as not allowed, and // add a proper diagnostic. context.TODO(node_id, "_ used as associated constant name"); } cast_type_id = AsCompleteType(context, cast_type_id, type_node, [&] { CARBON_DIAGNOSTIC(IncompleteTypeInAssociatedConstantDecl, Error, "associated constant has incomplete type {0}", SemIR::TypeId); return context.emitter().Build( type_node, IncompleteTypeInAssociatedConstantDecl, cast_type_id); }); SemIR::AssociatedConstantDecl assoc_const_decl = { .type_id = cast_type_id, .assoc_const_id = SemIR::AssociatedConstantId::None, .decl_block_id = SemIR::InstBlockId::None}; auto decl_id = AddPlaceholderInstInNoBlock(context, node_id, assoc_const_decl); assoc_const_decl.assoc_const_id = context.associated_constants().Add( {.name_id = name_id, .parent_scope_id = context.scope_stack().PeekNameScopeId(), .decl_id = decl_id, .generic_id = SemIR::GenericId::None, .default_value_id = SemIR::InstId::None}); ReplaceInstBeforeConstantUse(context, decl_id, assoc_const_decl); context.node_stack().Push(node_id, decl_id); return true; } auto HandleParseNode(Context& context, Parse::FieldNameAndTypeId node_id) -> bool { auto [type_node, parsed_type_id] = context.node_stack().PopExprWithNodeId(); auto [cast_type_inst_id, cast_type_id] = ExprAsType(context, type_node, parsed_type_id); auto [name_node, name_id] = context.node_stack().PopNameWithNodeId(); auto parent_class_decl = context.scope_stack().GetCurrentScopeAs(); CARBON_CHECK(parent_class_decl); cast_type_id = AsConcreteType( context, cast_type_id, type_node, [&] { CARBON_DIAGNOSTIC(IncompleteTypeInFieldDecl, Error, "field has incomplete type {0}", SemIR::TypeId); return context.emitter().Build(type_node, IncompleteTypeInFieldDecl, cast_type_id); }, [&] { CARBON_DIAGNOSTIC(AbstractTypeInFieldDecl, Error, "field has abstract type {0}", SemIR::TypeId); return context.emitter().Build(type_node, AbstractTypeInFieldDecl, cast_type_id); }); if (cast_type_id == SemIR::ErrorInst::TypeId) { cast_type_inst_id = SemIR::ErrorInst::TypeInstId; } auto& class_info = context.classes().Get(parent_class_decl->class_id); auto field_type_id = GetUnboundElementType( context, context.types().GetInstId(class_info.self_type_id), cast_type_inst_id); auto field_id = AddInst(context, node_id, {.type_id = field_type_id, .name_id = name_id, .index = SemIR::ElementIndex::None}); context.field_decls_stack().AppendToTop(field_id); auto name_context = context.decl_name_stack().MakeUnqualifiedName(node_id, name_id); context.decl_name_stack().AddNameOrDiagnose( name_context, field_id, context.decl_introducer_state_stack() .innermost() .modifier_set.GetAccessKind()); return true; } auto HandleParseNode(Context& context, Parse::RefBindingNameId node_id) -> bool { context.node_stack().Push(node_id); return true; } auto HandleParseNode(Context& context, Parse::TemplateBindingNameId node_id) -> bool { context.node_stack().Push(node_id); return true; } } // namespace Carbon::Check