// 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/semantics/semantics_parse_tree_handler.h" #include #include #include "common/vlog.h" #include "llvm/Support/PrettyStackTrace.h" #include "toolchain/diagnostics/diagnostic_kind.h" #include "toolchain/lexer/token_kind.h" #include "toolchain/lexer/tokenized_buffer.h" #include "toolchain/parser/parse_node_kind.h" #include "toolchain/semantics/semantics_ir.h" #include "toolchain/semantics/semantics_node.h" #include "toolchain/semantics/semantics_node_block_stack.h" namespace Carbon { CARBON_DIAGNOSTIC(SemanticsTodo, Error, "Semantics TODO: {0}", std::string); class PrettyStackTraceFunction : public llvm::PrettyStackTraceEntry { public: explicit PrettyStackTraceFunction(std::function fn) : fn_(std::move(fn)) {} ~PrettyStackTraceFunction() override = default; auto print(llvm::raw_ostream& output) const -> void override { fn_(output); } private: const std::function fn_; }; auto SemanticsParseTreeHandler::Build() -> void { PrettyStackTraceFunction pretty_node_stack([&](llvm::raw_ostream& output) { node_stack_.PrintForStackDump(output); }); PrettyStackTraceFunction pretty_node_block_stack( [&](llvm::raw_ostream& output) { node_block_stack_.PrintForStackDump(output); }); // Add a block for the ParseTree. node_block_stack_.Push(); PushScope(); // Loops over all nodes in the tree. On some errors, this may return early, // for example if an unrecoverable state is encountered. for (auto parse_node : parse_tree_->postorder()) { switch (auto parse_kind = parse_tree_->node_kind(parse_node)) { #define CARBON_PARSE_NODE_KIND(Name) \ case ParseNodeKind::Name: { \ if (!Handle##Name(parse_node)) { \ return; \ } \ break; \ } #include "toolchain/parser/parse_node_kind.def" } } // Pop information for the file-level scope. semantics_->top_node_block_id_ = node_block_stack_.Pop(); PopScope(); // Information in all the various context objects should be cleaned up as // various pieces of context go out of scope. At this point, nothing should // remain. // node_stack_ will still contain top-level entities. CARBON_CHECK(name_lookup_.empty()) << name_lookup_.size(); CARBON_CHECK(scope_stack_.empty()) << scope_stack_.size(); CARBON_CHECK(node_block_stack_.empty()) << node_block_stack_.size(); CARBON_CHECK(params_or_args_stack_.empty()) << params_or_args_stack_.size(); } auto SemanticsParseTreeHandler::AddNode(SemanticsNode node) -> SemanticsNodeId { auto block = node_block_stack_.PeekForAdd(); CARBON_VLOG() << "AddNode " << block << ": " << node << "\n"; return semantics_->AddNode(block, node); } auto SemanticsParseTreeHandler::AddNodeAndPush(ParseTree::Node parse_node, SemanticsNode node) -> void { auto node_id = AddNode(node); node_stack_.Push(parse_node, node_id); } auto SemanticsParseTreeHandler::AddNameToLookup(ParseTree::Node name_node, SemanticsStringId name_id, SemanticsNodeId target_id) -> void { auto [it, inserted] = current_scope().names.insert(name_id); if (inserted) { name_lookup_[name_id].push_back(target_id); } else { CARBON_DIAGNOSTIC(NameRedefined, Error, "Redefining {0} in the same scope.", llvm::StringRef); CARBON_DIAGNOSTIC(PreviousDefinition, Note, "Previous definition is here."); auto prev_def_id = name_lookup_[name_id].back(); auto prev_def = semantics_->GetNode(prev_def_id); emitter_->Build(name_node, NameRedefined, semantics_->GetString(name_id)) .Note(prev_def.parse_node(), PreviousDefinition) .Emit(); } } auto SemanticsParseTreeHandler::BindName(ParseTree::Node name_node, SemanticsNodeId type_id, SemanticsNodeId target_id) -> SemanticsStringId { CARBON_CHECK(parse_tree_->node_kind(name_node) == ParseNodeKind::DeclaredName) << parse_tree_->node_kind(name_node); auto name_str = parse_tree_->GetNodeText(name_node); auto name_id = semantics_->AddString(name_str); AddNode(SemanticsNode::MakeBindName(name_node, type_id, name_id, target_id)); AddNameToLookup(name_node, name_id, target_id); return name_id; } auto SemanticsParseTreeHandler::PushScope() -> void { scope_stack_.push_back({}); } auto SemanticsParseTreeHandler::PopScope() -> void { auto scope = scope_stack_.pop_back_val(); for (const auto& str_id : scope.names) { auto it = name_lookup_.find(str_id); if (it->second.size() == 1) { // Erase names that no longer resolve. name_lookup_.erase(it); } else { it->second.pop_back(); } } } auto SemanticsParseTreeHandler::CanTypeConvert(SemanticsNodeId from_type, SemanticsNodeId to_type) -> SemanticsNodeId { // TODO: This should attempt implicit conversions, but there's not enough // implemented to do that right now. if (from_type == SemanticsNodeId::BuiltinInvalidType || to_type == SemanticsNodeId::BuiltinInvalidType) { return SemanticsNodeId::BuiltinInvalidType; } if (from_type == to_type) { return from_type; } return SemanticsNodeId::Invalid; } auto SemanticsParseTreeHandler::TryTypeConversion(ParseTree::Node parse_node, SemanticsNodeId lhs_id, SemanticsNodeId rhs_id, bool /*can_convert_lhs*/) -> SemanticsNodeId { auto lhs_type = semantics_->GetType(lhs_id); auto rhs_type = semantics_->GetType(rhs_id); // TODO: CanTypeConvert can be assumed to handle rhs conversions, and we'll // either want to call it twice or refactor it to be aware of lhs conversions. auto type = CanTypeConvert(rhs_type, lhs_type); if (type.is_valid()) { return type; } // TODO: This should use type names instead of nodes. CARBON_DIAGNOSTIC(TypeMismatch, Error, "Type mismatch: lhs is {0}, rhs is {1}", std::string, std::string); emitter_->Emit(parse_node, TypeMismatch, semantics_->StringifyNode(lhs_type), semantics_->StringifyNode(rhs_type)); return SemanticsNodeId::BuiltinInvalidType; } auto SemanticsParseTreeHandler::TryTypeConversionOnArgs( ParseTree::Node arg_parse_node, SemanticsNodeBlockId /*arg_ir_id*/, SemanticsNodeBlockId arg_refs_id, ParseTree::Node param_parse_node, SemanticsNodeBlockId param_refs_id) -> bool { CARBON_DIAGNOSTIC(NoMatchingCall, Error, "No matching callable was found."); // If both arguments and parameters are empty, return quickly. Otherwise, // we'll fetch both so that errors are consistent. if (arg_refs_id == SemanticsNodeBlockId::Empty && param_refs_id == SemanticsNodeBlockId::Empty) { return true; } auto arg_refs = semantics_->GetNodeBlock(arg_refs_id); auto param_refs = semantics_->GetNodeBlock(param_refs_id); // If sizes mismatch, fail early. if (arg_refs.size() != param_refs.size()) { CARBON_DIAGNOSTIC(CallArgCountMismatch, Note, "Received {0} argument(s), but require {1} argument(s).", int, int); emitter_->Build(arg_parse_node, NoMatchingCall) .Note(param_parse_node, CallArgCountMismatch, arg_refs.size(), param_refs.size()) .Emit(); return false; } // Check type conversions per-element. // TODO: arg_ir_id is passed so that implicit conversions can be inserted. // It's currently not supported, but will be needed. for (size_t i = 0; i < arg_refs.size(); ++i) { const auto& arg_ref = arg_refs[i]; auto arg_ref_type = semantics_->GetType(arg_ref); const auto& param_ref = param_refs[i]; auto param_ref_type = semantics_->GetType(param_ref); auto result_type = CanTypeConvert(arg_ref_type, param_ref_type); if (!result_type.is_valid()) { // TODO: This should use type names instead of nodes. CARBON_DIAGNOSTIC( CallArgTypeMismatch, Note, "Type mismatch: cannot convert argument {0} from {1} to {2}.", size_t, std::string, std::string); emitter_->Build(arg_parse_node, NoMatchingCall) .Note(param_parse_node, CallArgTypeMismatch, i, semantics_->StringifyNode(arg_ref_type), semantics_->StringifyNode(param_ref_type)) .Emit(); return false; } } return true; } auto SemanticsParseTreeHandler::ParamOrArgStart() -> void { params_or_args_stack_.Push(); node_block_stack_.Push(); } auto SemanticsParseTreeHandler::ParamOrArgComma(ParseTree::Node parse_node) -> bool { node_stack_.Push(parse_node); // Copy the last node added to the IR block into the params block. if (!ParamOrArgSave()) { emitter_->Emit( parse_node, SemanticsTodo, "Should have a param before comma, will need error recovery"); return false; } return true; } auto SemanticsParseTreeHandler::ParamOrArgEnd( ParseNodeKind start_kind, ParseNodeKind comma_kind, std::function on_start) -> bool { // If there's a node in the IR block that has yet to be added to the params // block, add it now. ParamOrArgSave(); while (true) { auto parse_kind = parse_tree_->node_kind(node_stack_.PeekParseNode()); if (parse_kind == start_kind) { return on_start(node_block_stack_.Pop(), params_or_args_stack_.Pop()); } else if (parse_kind == comma_kind) { node_stack_.PopAndDiscardSoloParseNode(comma_kind); } else { node_stack_.PopAndIgnore(); } } } auto SemanticsParseTreeHandler::ParamOrArgSave() -> bool { // Copy the last node added to the IR block into the params block. auto ir_id = node_block_stack_.Peek(); if (!ir_id.is_valid()) { return false; } // We get params before ir because it may add a node block, which can // invalidate the ir reference. auto& params = semantics_->GetNodeBlock(params_or_args_stack_.PeekForAdd()); auto& ir = semantics_->GetNodeBlock(ir_id); CARBON_CHECK(!ir.empty()) << "Should only have a valid ID if a node was added"; auto& param = ir.back(); if (!params.empty() && param == params.back()) { // The param was already added after a comma. return false; } params.push_back(ir.back()); return true; } auto SemanticsParseTreeHandler::HandleAddress(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleAddress"); return false; } auto SemanticsParseTreeHandler::HandleBreakStatement(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleBreakStatement"); return false; } auto SemanticsParseTreeHandler::HandleBreakStatementStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleBreakStatementStart"); return false; } auto SemanticsParseTreeHandler::HandleCallExpression(ParseTree::Node parse_node) -> bool { auto on_start = [&](SemanticsNodeBlockId ir_id, SemanticsNodeBlockId refs_id) -> bool { // TODO: Convert to call expression. auto [call_expr_parse_node, name_id] = node_stack_.PopForParseNodeAndNodeId( ParseNodeKind::CallExpressionStart); auto name_node = semantics_->GetNode(name_id); if (name_node.kind() != SemanticsNodeKind::FunctionDeclaration) { // TODO: Work on error. emitter_->Emit(parse_node, SemanticsTodo, "Not a callable name"); node_stack_.Push(parse_node, name_id); return true; } auto [_, callable_id] = name_node.GetAsFunctionDeclaration(); auto callable = semantics_->GetCallable(callable_id); if (!TryTypeConversionOnArgs(call_expr_parse_node, ir_id, refs_id, name_node.parse_node(), callable.param_refs_id)) { node_stack_.Push(parse_node, SemanticsNodeId::BuiltinInvalidType); return true; } auto call_id = semantics_->AddCall({ir_id, refs_id}); // TODO: Propagate return types from callable. auto call_node_id = AddNode(SemanticsNode::MakeCall( call_expr_parse_node, SemanticsNodeId::BuiltinEmptyTuple, call_id, callable_id)); node_stack_.Push(parse_node, call_node_id); return true; }; return ParamOrArgEnd(ParseNodeKind::CallExpressionStart, ParseNodeKind::CallExpressionComma, on_start); } auto SemanticsParseTreeHandler::HandleCallExpressionComma( ParseTree::Node parse_node) -> bool { return ParamOrArgComma(parse_node); } auto SemanticsParseTreeHandler::HandleCallExpressionStart( ParseTree::Node parse_node) -> bool { auto name_id = node_stack_.PopForNodeId(ParseNodeKind::NameReference); node_stack_.Push(parse_node, name_id); ParamOrArgStart(); return true; } auto SemanticsParseTreeHandler::HandleClassDeclaration( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleClassDeclaration"); return false; } auto SemanticsParseTreeHandler::HandleClassDefinition( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleClassDefinition"); return false; } auto SemanticsParseTreeHandler::HandleClassDefinitionStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleClassDefinitionStart"); return false; } auto SemanticsParseTreeHandler::HandleClassIntroducer( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleClassIntroducer"); return false; } auto SemanticsParseTreeHandler::HandleCodeBlock(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleCodeBlock"); return false; } auto SemanticsParseTreeHandler::HandleCodeBlockStart(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleCodeBlockStart"); return false; } auto SemanticsParseTreeHandler::HandleContinueStatement( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleContinueStatement"); return false; } auto SemanticsParseTreeHandler::HandleContinueStatementStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleContinueStatementStart"); return false; } auto SemanticsParseTreeHandler::HandleDeclaredName(ParseTree::Node parse_node) -> bool { // The parent is responsible for binding the name. node_stack_.Push(parse_node); return true; } auto SemanticsParseTreeHandler::HandleDeducedParameterList( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleDeducedParameterList"); return false; } auto SemanticsParseTreeHandler::HandleDeducedParameterListStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleDeducedParameterListStart"); return false; } auto SemanticsParseTreeHandler::HandleDesignatedName(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleDesignatedName"); return false; } auto SemanticsParseTreeHandler::HandleDesignatorExpression( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleDesignatorExpression"); return false; } auto SemanticsParseTreeHandler::HandleEmptyDeclaration( ParseTree::Node parse_node) -> bool { // Empty declarations have no actions associated, but we still balance the // tree. node_stack_.Push(parse_node); return true; } auto SemanticsParseTreeHandler::HandleExpressionStatement( ParseTree::Node parse_node) -> bool { // Pop the expression without investigating its contents. // TODO: This will probably eventually need to do some "do not discard" // analysis. node_stack_.PopAndDiscardId(); node_stack_.Push(parse_node); return true; } auto SemanticsParseTreeHandler::HandleFileEnd(ParseTree::Node /*parse_node*/) -> bool { // Do nothing, no need to balance this node. return true; } auto SemanticsParseTreeHandler::HandleForHeader(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleForHeader"); return false; } auto SemanticsParseTreeHandler::HandleForHeaderStart(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleForHeaderStart"); return false; } auto SemanticsParseTreeHandler::HandleForIn(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleForIn"); return false; } auto SemanticsParseTreeHandler::HandleForStatement(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleForStatement"); return false; } auto SemanticsParseTreeHandler::HandleFunctionDeclaration( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleFunctionDeclaration"); return false; } auto SemanticsParseTreeHandler::HandleFunctionDefinition( ParseTree::Node parse_node) -> bool { // Merges code block children up under the FunctionDefinitionStart. while (parse_tree_->node_kind(node_stack_.PeekParseNode()) != ParseNodeKind::FunctionDefinitionStart) { node_stack_.PopAndIgnore(); } auto decl_id = node_stack_.PopForNodeId(ParseNodeKind::FunctionDefinitionStart); return_scope_stack_.pop_back(); PopScope(); auto block_id = node_block_stack_.Pop(); AddNode(SemanticsNode::MakeFunctionDefinition(parse_node, decl_id, block_id)); node_stack_.Push(parse_node); return true; } auto SemanticsParseTreeHandler::HandleFunctionDefinitionStart( ParseTree::Node parse_node) -> bool { SemanticsNodeId return_type_id = SemanticsNodeId::Invalid; if (parse_tree_->node_kind(node_stack_.PeekParseNode()) == ParseNodeKind::ReturnType) { return_type_id = node_stack_.PopForNodeId(ParseNodeKind::ReturnType); } node_stack_.PopForSoloParseNode(ParseNodeKind::ParameterList); auto [param_ir_id, param_refs_id] = finished_params_stack_.pop_back_val(); auto name_node = node_stack_.PopForSoloParseNode(ParseNodeKind::DeclaredName); auto fn_node = node_stack_.PopForSoloParseNode(ParseNodeKind::FunctionIntroducer); auto name_str = parse_tree_->GetNodeText(name_node); auto name_id = semantics_->AddString(name_str); auto callable_id = semantics_->AddCallable({.param_ir_id = param_ir_id, .param_refs_id = param_refs_id, .return_type_id = return_type_id}); auto decl_id = AddNode( SemanticsNode::MakeFunctionDeclaration(fn_node, name_id, callable_id)); AddNameToLookup(name_node, name_id, decl_id); node_block_stack_.Push(); PushScope(); return_scope_stack_.push_back(decl_id); node_stack_.Push(parse_node, decl_id); return true; } auto SemanticsParseTreeHandler::HandleFunctionIntroducer( ParseTree::Node parse_node) -> bool { // No action, just a bracketing node. node_stack_.Push(parse_node); return true; } auto SemanticsParseTreeHandler::HandleGenericPatternBinding( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "GenericPatternBinding"); return false; } auto SemanticsParseTreeHandler::HandleIfCondition(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleIfCondition"); return false; } auto SemanticsParseTreeHandler::HandleIfConditionStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleIfConditionStart"); return false; } auto SemanticsParseTreeHandler::HandleIfStatement(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleIfStatement"); return false; } auto SemanticsParseTreeHandler::HandleIfStatementElse( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleIfStatementElse"); return false; } auto SemanticsParseTreeHandler::HandleInfixOperator(ParseTree::Node parse_node) -> bool { auto rhs_id = node_stack_.PopForNodeId(); auto lhs_id = node_stack_.PopForNodeId(); SemanticsNodeId result_type = TryTypeConversion(parse_node, lhs_id, rhs_id, /*can_convert_lhs=*/true); // Figure out the operator for the token. auto token = parse_tree_->node_token(parse_node); switch (auto token_kind = tokens_->GetKind(token)) { case TokenKind::Plus: AddNodeAndPush(parse_node, SemanticsNode::MakeBinaryOperatorAdd( parse_node, result_type, lhs_id, rhs_id)); break; default: emitter_->Emit(parse_node, SemanticsTodo, llvm::formatv("Handle {0}", token_kind)); return false; } return true; } auto SemanticsParseTreeHandler::HandleInterfaceDeclaration( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleInterfaceDeclaration"); return false; } auto SemanticsParseTreeHandler::HandleInterfaceDefinition( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleInterfaceDefinition"); return false; } auto SemanticsParseTreeHandler::HandleInterfaceDefinitionStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleInterfaceDefinitionStart"); return false; } auto SemanticsParseTreeHandler::HandleInterfaceIntroducer( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleInterfaceIntroducer"); return false; } auto SemanticsParseTreeHandler::HandleLiteral(ParseTree::Node parse_node) -> bool { auto token = parse_tree_->node_token(parse_node); switch (auto token_kind = tokens_->GetKind(token)) { case TokenKind::IntegerLiteral: { auto id = semantics_->AddIntegerLiteral(tokens_->GetIntegerLiteral(token)); AddNodeAndPush(parse_node, SemanticsNode::MakeIntegerLiteral(parse_node, id)); break; } case TokenKind::RealLiteral: { auto token_value = tokens_->GetRealLiteral(token); auto id = semantics_->AddRealLiteral({.mantissa = token_value.Mantissa(), .exponent = token_value.Exponent(), .is_decimal = token_value.IsDecimal()}); AddNodeAndPush(parse_node, SemanticsNode::MakeRealLiteral(parse_node, id)); break; } case TokenKind::StringLiteral: { auto id = semantics_->AddString(tokens_->GetStringLiteral(token)); AddNodeAndPush(parse_node, SemanticsNode::MakeStringLiteral(parse_node, id)); break; } case TokenKind::IntegerTypeLiteral: { auto text = tokens_->GetTokenText(token); if (text != "i32") { emitter_->Emit(parse_node, SemanticsTodo, "Currently only i32 is allowed"); return false; } node_stack_.Push(parse_node, SemanticsNodeId::BuiltinIntegerType); break; } case TokenKind::FloatingPointTypeLiteral: { auto text = tokens_->GetTokenText(token); if (text != "f64") { emitter_->Emit(parse_node, SemanticsTodo, "Currently only f64 is allowed"); return false; } node_stack_.Push(parse_node, SemanticsNodeId::BuiltinFloatingPointType); break; } case TokenKind::StringTypeLiteral: { node_stack_.Push(parse_node, SemanticsNodeId::BuiltinStringType); break; } default: { emitter_->Emit(parse_node, SemanticsTodo, llvm::formatv("Handle {0}", token_kind)); return false; } } return true; } auto SemanticsParseTreeHandler::HandleNameReference(ParseTree::Node parse_node) -> bool { auto name_str = parse_tree_->GetNodeText(parse_node); auto name_not_found = [&] { CARBON_DIAGNOSTIC(NameNotFound, Error, "Name {0} not found", llvm::StringRef); emitter_->Emit(parse_node, NameNotFound, name_str); node_stack_.Push(parse_node, SemanticsNodeId::BuiltinInvalidType); }; auto name_id = semantics_->GetStringID(name_str); if (!name_id) { name_not_found(); return true; } auto it = name_lookup_.find(*name_id); if (it == name_lookup_.end()) { name_not_found(); return true; } CARBON_CHECK(!it->second.empty()) << "Should have been erased: " << name_str; // TODO: Check for ambiguous lookups. node_stack_.Push(parse_node, it->second.back()); return true; } auto SemanticsParseTreeHandler::HandleNamedConstraintDeclaration( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleNamedConstraintDeclaration"); return false; } auto SemanticsParseTreeHandler::HandleNamedConstraintDefinition( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleNamedConstraintDefinition"); return false; } auto SemanticsParseTreeHandler::HandleNamedConstraintDefinitionStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleNamedConstraintDefinitionStart"); return false; } auto SemanticsParseTreeHandler::HandleNamedConstraintIntroducer( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleNamedConstraintIntroducer"); return false; } auto SemanticsParseTreeHandler::HandlePackageApi(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandlePackageApi"); return false; } auto SemanticsParseTreeHandler::HandlePackageDirective( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandlePackageDirective"); return false; } auto SemanticsParseTreeHandler::HandlePackageImpl(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandlePackageImpl"); return false; } auto SemanticsParseTreeHandler::HandlePackageIntroducer( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandlePackageIntroducer"); return false; } auto SemanticsParseTreeHandler::HandlePackageLibrary(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandlePackageLibrary"); return false; } auto SemanticsParseTreeHandler::HandleParameterList(ParseTree::Node parse_node) -> bool { auto on_start = [&](SemanticsNodeBlockId ir_id, SemanticsNodeBlockId refs_id) -> bool { PopScope(); node_stack_.PopAndDiscardSoloParseNode(ParseNodeKind::ParameterListStart); finished_params_stack_.push_back({ir_id, refs_id}); node_stack_.Push(parse_node); return true; }; return ParamOrArgEnd(ParseNodeKind::ParameterListStart, ParseNodeKind::ParameterListComma, on_start); } auto SemanticsParseTreeHandler::HandleParameterListComma( ParseTree::Node parse_node) -> bool { return ParamOrArgComma(parse_node); } auto SemanticsParseTreeHandler::HandleParameterListStart( ParseTree::Node parse_node) -> bool { PushScope(); node_stack_.Push(parse_node); ParamOrArgStart(); return true; } auto SemanticsParseTreeHandler::HandleParenExpression( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleParenExpression"); return false; } auto SemanticsParseTreeHandler::HandleParenExpressionOrTupleLiteralStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleParenExpressionOrTupleLiteralStart"); return false; } auto SemanticsParseTreeHandler::HandlePatternBinding(ParseTree::Node parse_node) -> bool { auto type = node_stack_.PopForNodeId(); // Get the name. auto name_node = node_stack_.PopForSoloParseNode(); // Allocate storage, linked to the name for error locations. auto storage_id = AddNode(SemanticsNode::MakeVarStorage(name_node, type)); // Bind the name to storage. auto name_id = BindName(name_node, type, storage_id); // If this node's result is used, it'll be for either the name or the storage // address. The storage address can be found through the name, so we push the // name. node_stack_.Push(parse_node, name_id); return true; } auto SemanticsParseTreeHandler::HandlePostfixOperator( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandlePostfixOperator"); return false; } auto SemanticsParseTreeHandler::HandlePrefixOperator(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandlePrefixOperator"); return false; } auto SemanticsParseTreeHandler::HandleReturnStatement( ParseTree::Node parse_node) -> bool { CARBON_CHECK(!return_scope_stack_.empty()); const auto& fn_node = semantics_->GetNode(return_scope_stack_.back()); const auto callable = semantics_->GetCallable(fn_node.GetAsFunctionDeclaration().second); if (parse_tree_->node_kind(node_stack_.PeekParseNode()) == ParseNodeKind::ReturnStatementStart) { node_stack_.PopAndDiscardSoloParseNode(ParseNodeKind::ReturnStatementStart); if (callable.return_type_id.is_valid()) { // TODO: Stringify types, add a note pointing at the return // type's parse node. CARBON_DIAGNOSTIC(ReturnStatementMissingExpression, Error, "Must return a {0}.", SemanticsNodeId); emitter_ ->Build(parse_node, ReturnStatementMissingExpression, callable.return_type_id) .Emit(); } AddNodeAndPush(parse_node, SemanticsNode::MakeReturn(parse_node)); } else { const auto arg = node_stack_.PopForNodeId(); auto arg_type = semantics_->GetType(arg); node_stack_.PopAndDiscardSoloParseNode(ParseNodeKind::ReturnStatementStart); if (!callable.return_type_id.is_valid()) { CARBON_DIAGNOSTIC( ReturnStatementDisallowExpression, Error, "No return expression should be provided in this context."); CARBON_DIAGNOSTIC(ReturnStatementImplicitNote, Note, "There was no return type provided."); emitter_->Build(parse_node, ReturnStatementDisallowExpression) .Note(fn_node.parse_node(), ReturnStatementImplicitNote) .Emit(); } else { const auto new_type = CanTypeConvert(arg_type, callable.return_type_id); if (!new_type.is_valid()) { // TODO: Stringify types, add a note pointing at the return // type's parse node. CARBON_DIAGNOSTIC(ReturnStatementTypeMismatch, Error, "Cannot convert {0} to {1}.", std::string, std::string); emitter_ ->Build(parse_node, ReturnStatementTypeMismatch, semantics_->StringifyNode(arg_type), semantics_->StringifyNode(callable.return_type_id)) .Emit(); } arg_type = new_type; } AddNodeAndPush(parse_node, SemanticsNode::MakeReturnExpression( parse_node, arg_type, arg)); } return true; } auto SemanticsParseTreeHandler::HandleReturnStatementStart( ParseTree::Node parse_node) -> bool { // No action, just a bracketing node. node_stack_.Push(parse_node); return true; } auto SemanticsParseTreeHandler::HandleReturnType(ParseTree::Node parse_node) -> bool { // Propagate the type expression. node_stack_.Push(parse_node, node_stack_.PopForNodeId()); return true; } auto SemanticsParseTreeHandler::HandleSelfTypeIdentifier( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleSelfTypeIdentifier"); return false; } auto SemanticsParseTreeHandler::HandleSelfValueIdentifier( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleSelfValueIdentifier"); return false; } auto SemanticsParseTreeHandler::HandleStructComma(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleStructComma"); return false; } auto SemanticsParseTreeHandler::HandleStructFieldDesignator( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleStructFieldDesignator"); return false; } auto SemanticsParseTreeHandler::HandleStructFieldType( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleStructFieldType"); return false; } auto SemanticsParseTreeHandler::HandleStructFieldUnknown( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleStructFieldUnknown"); return false; } auto SemanticsParseTreeHandler::HandleStructFieldValue( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleStructFieldValue"); return false; } auto SemanticsParseTreeHandler::HandleStructLiteral(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleStructLiteral"); return false; } auto SemanticsParseTreeHandler::HandleStructLiteralOrStructTypeLiteralStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleStructLiteralOrStructTypeLiteralStart"); return false; } auto SemanticsParseTreeHandler::HandleStructTypeLiteral( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleStructTypeLiteral"); return false; } auto SemanticsParseTreeHandler::HandleTemplate(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleTemplate"); return false; } auto SemanticsParseTreeHandler::HandleTupleLiteral(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleTupleLiteral"); return false; } auto SemanticsParseTreeHandler::HandleTupleLiteralComma( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleTupleLiteralComma"); return false; } auto SemanticsParseTreeHandler::HandleVariableDeclaration( ParseTree::Node parse_node) -> bool { auto last_child = node_stack_.PopForParseNodeAndNodeId(); if (parse_tree_->node_kind(last_child.first) != ParseNodeKind::PatternBinding) { auto storage_id = node_stack_.PopForNodeId(ParseNodeKind::VariableInitializer); auto binding = node_stack_.PopForParseNodeAndNameId(); // Restore the name now that the initializer is complete. ReaddNameToLookup(binding.second, storage_id); auto storage_type = TryTypeConversion(parse_node, storage_id, last_child.second, /*can_convert_lhs=*/false); AddNode(SemanticsNode::MakeAssign(parse_node, storage_type, storage_id, last_child.second)); } node_stack_.PopAndDiscardSoloParseNode(ParseNodeKind::VariableIntroducer); node_stack_.Push(parse_node); return true; } auto SemanticsParseTreeHandler::HandleVariableIntroducer( ParseTree::Node parse_node) -> bool { // No action, just a bracketing node. node_stack_.Push(parse_node); return true; } auto SemanticsParseTreeHandler::HandleVariableInitializer( ParseTree::Node parse_node) -> bool { // Temporarily remove name lookup entries added by the `var`. These will be // restored by `VariableDeclaration`. // Save the storage ID. auto it = name_lookup_.find(node_stack_.PeekForNameId()); CARBON_CHECK(it != name_lookup_.end()); CARBON_CHECK(!it->second.empty()); auto storage_id = it->second.back(); // Pop the name from lookup. if (it->second.size() == 1) { // Erase names that no longer resolve. name_lookup_.erase(it); } else { it->second.pop_back(); } node_stack_.Push(parse_node, storage_id); return true; } auto SemanticsParseTreeHandler::HandleWhileCondition(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleWhileCondition"); return false; } auto SemanticsParseTreeHandler::HandleWhileConditionStart( ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleWhileConditionStart"); return false; } auto SemanticsParseTreeHandler::HandleWhileStatement(ParseTree::Node parse_node) -> bool { emitter_->Emit(parse_node, SemanticsTodo, "HandleWhileStatement"); return false; } } // namespace Carbon