/************************************************************************** ** ** This file is part of Qt Creator ** ** Copyright (c) 2011 Nokia Corporation and/or its subsidiary(-ies). ** ** Contact: Nokia Corporation (info@qt.nokia.com) ** ** ** GNU Lesser General Public License Usage ** ** This file may be used under the terms of the GNU Lesser General Public ** License version 2.1 as published by the Free Software Foundation and ** appearing in the file LICENSE.LGPL included in the packaging of this file. ** Please review the following information to ensure the GNU Lesser General ** Public License version 2.1 requirements will be met: ** http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain additional ** rights. These rights are described in the Nokia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** Other Usage ** ** Alternatively, this file may be used in accordance with the terms and ** conditions contained in a signed written agreement between you and Nokia. ** ** If you have questions regarding the use of this file, please contact ** Nokia at qt-info@nokia.com. ** **************************************************************************/ // Copyright (c) 2008 Roberto Raggi // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN // THE SOFTWARE. #include "Bind.h" #include "AST.h" #include "TranslationUnit.h" #include "Control.h" #include "Names.h" #include "Symbols.h" #include "CoreTypes.h" #include "Literals.h" #include "Scope.h" #include #include #include #include using namespace CPlusPlus; const int Bind::kMaxDepth(100); Bind::Bind(TranslationUnit *unit) : ASTVisitor(unit), _scope(0), _expression(0), _name(0), _declaratorId(0), _visibility(Symbol::Public), _objcVisibility(Symbol::Public), _methodKey(Function::NormalMethod), _skipFunctionBodies(false), _depth(0) { } bool Bind::skipFunctionBodies() const { return _skipFunctionBodies; } void Bind::setSkipFunctionBodies(bool skipFunctionBodies) { _skipFunctionBodies = skipFunctionBodies; } unsigned Bind::location(DeclaratorAST *ast, unsigned defaultLocation) const { if (! ast) return defaultLocation; else if (ast->core_declarator) return location(ast->core_declarator, defaultLocation); return ast->firstToken(); } unsigned Bind::location(CoreDeclaratorAST *ast, unsigned defaultLocation) const { if (! ast) return defaultLocation; else if (NestedDeclaratorAST *nested = ast->asNestedDeclarator()) return location(nested->declarator, defaultLocation); else if (DeclaratorIdAST *id = ast->asDeclaratorId()) return location(id->name, defaultLocation); return ast->firstToken(); } unsigned Bind::location(NameAST *name, unsigned defaultLocation) const { if (! name) return defaultLocation; else if (DestructorNameAST *dtor = name->asDestructorName()) return dtor->identifier_token; else if (TemplateIdAST *templId = name->asTemplateId()) return templId->identifier_token; else if (QualifiedNameAST *q = name->asQualifiedName()) { if (q->unqualified_name) return location(q->unqualified_name, defaultLocation); } return name->firstToken(); } void Bind::setDeclSpecifiers(Symbol *symbol, const FullySpecifiedType &declSpecifiers) { if (! symbol) return; int storage = Symbol::NoStorage; if (declSpecifiers.isFriend()) storage = Symbol::Friend; else if (declSpecifiers.isAuto()) storage = Symbol::Auto; else if (declSpecifiers.isRegister()) storage = Symbol::Register; else if (declSpecifiers.isStatic()) storage = Symbol::Static; else if (declSpecifiers.isExtern()) storage = Symbol::Extern; else if (declSpecifiers.isMutable()) storage = Symbol::Mutable; else if (declSpecifiers.isTypedef()) storage = Symbol::Typedef; symbol->setStorage(storage); if (Function *funTy = symbol->asFunction()) { if (declSpecifiers.isVirtual()) { funTy->setVirtual(true); } } if (declSpecifiers.isDeprecated()) symbol->setDeprecated(true); if (declSpecifiers.isUnavailable()) symbol->setUnavailable(true); } Scope *Bind::switchScope(Scope *scope) { if (! scope) return _scope; std::swap(_scope, scope); return scope; } int Bind::switchVisibility(int visibility) { std::swap(_visibility, visibility); return visibility; } int Bind::switchObjCVisibility(int visibility) { std::swap(_objcVisibility, visibility); return visibility; } int Bind::switchMethodKey(int methodKey) { std::swap(_methodKey, methodKey); return methodKey; } void Bind::operator()(TranslationUnitAST *ast, Namespace *globalNamespace) { Scope *previousScope = switchScope(globalNamespace); translationUnit(ast); (void) switchScope(previousScope); } void Bind::operator()(DeclarationAST *ast, Scope *scope) { Scope *previousScope = switchScope(scope); declaration(ast); (void) switchScope(previousScope); } FullySpecifiedType Bind::operator()(ExpressionAST *ast, Scope *scope) { Scope *previousScope = switchScope(scope); FullySpecifiedType ty = expression(ast); (void) switchScope(previousScope); return ty; } FullySpecifiedType Bind::operator()(NewTypeIdAST *ast, Scope *scope) { Scope *previousScope = switchScope(scope); FullySpecifiedType ty = newTypeId(ast); (void) switchScope(previousScope); return ty; } void Bind::statement(StatementAST *ast) { accept(ast); } Bind::ExpressionTy Bind::expression(ExpressionAST *ast) { ExpressionTy value = ExpressionTy(); std::swap(_expression, value); accept(ast); std::swap(_expression, value); return value; } void Bind::declaration(DeclarationAST *ast) { accept(ast); } const Name *Bind::name(NameAST *ast) { const Name *value = 0; std::swap(_name, value); accept(ast); std::swap(_name, value); return value; } FullySpecifiedType Bind::specifier(SpecifierAST *ast, const FullySpecifiedType &init) { FullySpecifiedType value = init; std::swap(_type, value); accept(ast); std::swap(_type, value); return value; } FullySpecifiedType Bind::ptrOperator(PtrOperatorAST *ast, const FullySpecifiedType &init) { FullySpecifiedType value = init; std::swap(_type, value); accept(ast); std::swap(_type, value); return value; } FullySpecifiedType Bind::coreDeclarator(CoreDeclaratorAST *ast, const FullySpecifiedType &init) { FullySpecifiedType value = init; std::swap(_type, value); accept(ast); std::swap(_type, value); return value; } FullySpecifiedType Bind::postfixDeclarator(PostfixDeclaratorAST *ast, const FullySpecifiedType &init) { FullySpecifiedType value = init; std::swap(_type, value); accept(ast); std::swap(_type, value); return value; } bool Bind::preVisit(AST *) { ++_depth; if (_depth > kMaxDepth) return false; return true; } void Bind::postVisit(AST *) { --_depth; } // AST bool Bind::visit(ObjCSelectorArgumentAST *ast) { (void) ast; assert(!"unreachable"); return false; } const Name *Bind::objCSelectorArgument(ObjCSelectorArgumentAST *ast, bool *hasArg) { if (! (ast && ast->name_token)) return 0; if (ast->colon_token) *hasArg = true; return identifier(ast->name_token); } bool Bind::visit(AttributeAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::attribute(AttributeAST *ast) { if (! ast) return; // unsigned identifier_token = ast->identifier_token; if (const Identifier *id = identifier(ast->identifier_token)) { if (id == control()->deprecatedId()) _type.setDeprecated(true); else if (id == control()->unavailableId()) _type.setUnavailable(true); } // unsigned lparen_token = ast->lparen_token; // unsigned tag_token = ast->tag_token; for (ExpressionListAST *it = ast->expression_list; it; it = it->next) { ExpressionTy value = this->expression(it->value); } // unsigned rparen_token = ast->rparen_token; } bool Bind::visit(DeclaratorAST *ast) { (void) ast; assert(!"unreachable"); return false; } FullySpecifiedType Bind::declarator(DeclaratorAST *ast, const FullySpecifiedType &init, DeclaratorIdAST **declaratorId) { FullySpecifiedType type = init; if (! ast) return type; std::swap(_declaratorId, declaratorId); for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { type = this->specifier(it->value, type); } for (PtrOperatorListAST *it = ast->ptr_operator_list; it; it = it->next) { type = this->ptrOperator(it->value, type); } for (PostfixDeclaratorListAST *it = ast->postfix_declarator_list; it; it = it->next) { type = this->postfixDeclarator(it->value, type); } type = this->coreDeclarator(ast->core_declarator, type); for (SpecifierListAST *it = ast->post_attribute_list; it; it = it->next) { type = this->specifier(it->value, type); } // unsigned equals_token = ast->equals_token; ExpressionTy initializer = this->expression(ast->initializer); std::swap(_declaratorId, declaratorId); return type; } bool Bind::visit(QtPropertyDeclarationItemAST *ast) { (void) ast; assert(!"unreachable"); return false; } bool Bind::visit(QtInterfaceNameAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::qtInterfaceName(QtInterfaceNameAST *ast) { if (! ast) return; /*const Name *interface_name =*/ this->name(ast->interface_name); for (NameListAST *it = ast->constraint_list; it; it = it->next) { /*const Name *value =*/ this->name(it->value); } } bool Bind::visit(BaseSpecifierAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::baseSpecifier(BaseSpecifierAST *ast, unsigned colon_token, Class *klass) { if (! ast) return; unsigned sourceLocation = location(ast->name, ast->firstToken()); if (! sourceLocation) sourceLocation = std::max(colon_token, klass->sourceLocation()); const Name *baseClassName = this->name(ast->name); BaseClass *baseClass = control()->newBaseClass(sourceLocation, baseClassName); if (ast->virtual_token) baseClass->setVirtual(true); if (ast->access_specifier_token) { const int visibility = visibilityForAccessSpecifier(tokenKind(ast->access_specifier_token)); baseClass->setVisibility(visibility); // ### well, not exactly. } klass->addBaseClass(baseClass); ast->symbol = baseClass; } bool Bind::visit(CtorInitializerAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::ctorInitializer(CtorInitializerAST *ast, Function *fun) { if (! ast) return; // unsigned colon_token = ast->colon_token; for (MemInitializerListAST *it = ast->member_initializer_list; it; it = it->next) { this->memInitializer(it->value, fun); } // unsigned dot_dot_dot_token = ast->dot_dot_dot_token; } bool Bind::visit(EnumeratorAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::enumerator(EnumeratorAST *ast, Enum *symbol) { (void) symbol; if (! ast) return; // unsigned identifier_token = ast->identifier_token; // unsigned equal_token = ast->equal_token; ExpressionTy expression = this->expression(ast->expression); if (ast->identifier_token) { const Name *name = identifier(ast->identifier_token); Declaration *e = control()->newDeclaration(ast->identifier_token, name); e->setType(control()->integerType(IntegerType::Int)); // ### introduce IntegerType::Enumerator symbol->addMember(e); } } bool Bind::visit(ExceptionSpecificationAST *ast) { (void) ast; assert(!"unreachable"); return false; } FullySpecifiedType Bind::exceptionSpecification(ExceptionSpecificationAST *ast, const FullySpecifiedType &init) { FullySpecifiedType type = init; if (! ast) return type; // unsigned throw_token = ast->throw_token; // unsigned lparen_token = ast->lparen_token; // unsigned dot_dot_dot_token = ast->dot_dot_dot_token; for (ExpressionListAST *it = ast->type_id_list; it; it = it->next) { ExpressionTy value = this->expression(it->value); } // unsigned rparen_token = ast->rparen_token; return type; } bool Bind::visit(MemInitializerAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::memInitializer(MemInitializerAST *ast, Function *fun) { if (! ast) return; /*const Name *name =*/ this->name(ast->name); Scope *previousScope = switchScope(fun); for (ExpressionListAST *it = ast->expression_list; it; it = it->next) { /*ExpressionTy value =*/ this->expression(it->value); } (void) switchScope(previousScope); } bool Bind::visit(NestedNameSpecifierAST *ast) { (void) ast; assert(!"unreachable"); return false; } const Name *Bind::nestedNameSpecifier(NestedNameSpecifierAST *ast) { if (! ast) return 0; const Name *class_or_namespace_name = this->name(ast->class_or_namespace_name); return class_or_namespace_name; } bool Bind::visit(NewPlacementAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::newPlacement(NewPlacementAST *ast) { if (! ast) return; // unsigned lparen_token = ast->lparen_token; for (ExpressionListAST *it = ast->expression_list; it; it = it->next) { ExpressionTy value = this->expression(it->value); } // unsigned rparen_token = ast->rparen_token; } bool Bind::visit(NewArrayDeclaratorAST *ast) { (void) ast; assert(!"unreachable"); return false; } FullySpecifiedType Bind::newArrayDeclarator(NewArrayDeclaratorAST *ast, const FullySpecifiedType &init) { FullySpecifiedType type = init; if (! ast) return type; // unsigned lbracket_token = ast->lbracket_token; ExpressionTy expression = this->expression(ast->expression); // unsigned rbracket_token = ast->rbracket_token; return type; } bool Bind::visit(NewInitializerAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::newInitializer(NewInitializerAST *ast) { if (! ast) return; // unsigned lparen_token = ast->lparen_token; ExpressionTy expression = this->expression(ast->expression); // unsigned rparen_token = ast->rparen_token; } bool Bind::visit(NewTypeIdAST *ast) { (void) ast; assert(!"unreachable"); return false; } FullySpecifiedType Bind::newTypeId(NewTypeIdAST *ast) { FullySpecifiedType type; if (! ast) return type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } for (PtrOperatorListAST *it = ast->ptr_operator_list; it; it = it->next) { type = this->ptrOperator(it->value, type); } for (NewArrayDeclaratorListAST *it = ast->new_array_declarator_list; it; it = it->next) { type = this->newArrayDeclarator(it->value, type); } return type; } bool Bind::visit(OperatorAST *ast) { (void) ast; assert(!"unreachable"); return false; } OperatorNameId::Kind Bind::cppOperator(OperatorAST *ast) { OperatorNameId::Kind kind = OperatorNameId::InvalidOp; if (! ast) return kind; // unsigned op_token = ast->op_token; // unsigned open_token = ast->open_token; // unsigned close_token = ast->close_token; switch (tokenKind(ast->op_token)) { case T_NEW: if (ast->open_token) kind = OperatorNameId::NewArrayOp; else kind = OperatorNameId::NewOp; break; case T_DELETE: if (ast->open_token) kind = OperatorNameId::DeleteArrayOp; else kind = OperatorNameId::DeleteOp; break; case T_PLUS: kind = OperatorNameId::PlusOp; break; case T_MINUS: kind = OperatorNameId::MinusOp; break; case T_STAR: kind = OperatorNameId::StarOp; break; case T_SLASH: kind = OperatorNameId::SlashOp; break; case T_PERCENT: kind = OperatorNameId::PercentOp; break; case T_CARET: kind = OperatorNameId::CaretOp; break; case T_AMPER: kind = OperatorNameId::AmpOp; break; case T_PIPE: kind = OperatorNameId::PipeOp; break; case T_TILDE: kind = OperatorNameId::TildeOp; break; case T_EXCLAIM: kind = OperatorNameId::ExclaimOp; break; case T_EQUAL: kind = OperatorNameId::EqualOp; break; case T_LESS: kind = OperatorNameId::LessOp; break; case T_GREATER: kind = OperatorNameId::GreaterOp; break; case T_PLUS_EQUAL: kind = OperatorNameId::PlusEqualOp; break; case T_MINUS_EQUAL: kind = OperatorNameId::MinusEqualOp; break; case T_STAR_EQUAL: kind = OperatorNameId::StarEqualOp; break; case T_SLASH_EQUAL: kind = OperatorNameId::SlashEqualOp; break; case T_PERCENT_EQUAL: kind = OperatorNameId::PercentEqualOp; break; case T_CARET_EQUAL: kind = OperatorNameId::CaretEqualOp; break; case T_AMPER_EQUAL: kind = OperatorNameId::AmpEqualOp; break; case T_PIPE_EQUAL: kind = OperatorNameId::PipeEqualOp; break; case T_LESS_LESS: kind = OperatorNameId::LessLessOp; break; case T_GREATER_GREATER: kind = OperatorNameId::GreaterGreaterOp; break; case T_LESS_LESS_EQUAL: kind = OperatorNameId::LessLessEqualOp; break; case T_GREATER_GREATER_EQUAL: kind = OperatorNameId::GreaterGreaterEqualOp; break; case T_EQUAL_EQUAL: kind = OperatorNameId::EqualEqualOp; break; case T_EXCLAIM_EQUAL: kind = OperatorNameId::ExclaimEqualOp; break; case T_LESS_EQUAL: kind = OperatorNameId::LessEqualOp; break; case T_GREATER_EQUAL: kind = OperatorNameId::GreaterEqualOp; break; case T_AMPER_AMPER: kind = OperatorNameId::AmpAmpOp; break; case T_PIPE_PIPE: kind = OperatorNameId::PipePipeOp; break; case T_PLUS_PLUS: kind = OperatorNameId::PlusPlusOp; break; case T_MINUS_MINUS: kind = OperatorNameId::MinusMinusOp; break; case T_COMMA: kind = OperatorNameId::CommaOp; break; case T_ARROW_STAR: kind = OperatorNameId::ArrowStarOp; break; case T_ARROW: kind = OperatorNameId::ArrowOp; break; case T_LPAREN: kind = OperatorNameId::FunctionCallOp; break; case T_LBRACKET: kind = OperatorNameId::ArrayAccessOp; break; default: kind = OperatorNameId::InvalidOp; } // switch return kind; } bool Bind::visit(ParameterDeclarationClauseAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::parameterDeclarationClause(ParameterDeclarationClauseAST *ast, unsigned lparen_token, Function *fun) { if (! ast) return; if (! fun) { translationUnit()->warning(lparen_token, "undefined function"); return; } Scope *previousScope = switchScope(fun); for (ParameterDeclarationListAST *it = ast->parameter_declaration_list; it; it = it->next) { this->declaration(it->value); } if (ast->dot_dot_dot_token) fun->setVariadic(true); (void) switchScope(previousScope); } bool Bind::visit(TranslationUnitAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::translationUnit(TranslationUnitAST *ast) { if (! ast) return; for (DeclarationListAST *it = ast->declaration_list; it; it = it->next) { this->declaration(it->value); } } bool Bind::visit(ObjCProtocolRefsAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::objCProtocolRefs(ObjCProtocolRefsAST *ast, Symbol *objcClassOrProtocol) { if (! ast) return; for (NameListAST *it = ast->identifier_list; it; it = it->next) { const Name *protocolName = this->name(it->value); ObjCBaseProtocol *baseProtocol = control()->newObjCBaseProtocol(it->value->firstToken(), protocolName); if (ObjCClass *klass = objcClassOrProtocol->asObjCClass()) klass->addProtocol(baseProtocol); else if (ObjCProtocol *proto = objcClassOrProtocol->asObjCProtocol()) proto->addProtocol(baseProtocol); } } bool Bind::visit(ObjCMessageArgumentAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::objCMessageArgument(ObjCMessageArgumentAST *ast) { if (! ast) return; ExpressionTy parameter_value_expression = this->expression(ast->parameter_value_expression); } bool Bind::visit(ObjCTypeNameAST *ast) { (void) ast; assert(!"unreachable"); return false; } FullySpecifiedType Bind::objCTypeName(ObjCTypeNameAST *ast) { if (! ast) return FullySpecifiedType(); // unsigned type_qualifier_token = ast->type_qualifier_token; ExpressionTy type_id = this->expression(ast->type_id); return type_id; } bool Bind::visit(ObjCInstanceVariablesDeclarationAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::objCInstanceVariablesDeclaration(ObjCInstanceVariablesDeclarationAST *ast, ObjCClass *klass) { (void) klass; if (! ast) return; // unsigned lbrace_token = ast->lbrace_token; for (DeclarationListAST *it = ast->instance_variable_list; it; it = it->next) { this->declaration(it->value); } // unsigned rbrace_token = ast->rbrace_token; } bool Bind::visit(ObjCPropertyAttributeAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::objCPropertyAttribute(ObjCPropertyAttributeAST *ast) { if (! ast) return; // unsigned attribute_identifier_token = ast->attribute_identifier_token; // unsigned equals_token = ast->equals_token; /*const Name *method_selector =*/ this->name(ast->method_selector); } bool Bind::visit(ObjCMessageArgumentDeclarationAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::objCMessageArgumentDeclaration(ObjCMessageArgumentDeclarationAST *ast, ObjCMethod *method) { if (! ast) return; FullySpecifiedType type = this->objCTypeName(ast->type_name); for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { type = this->specifier(it->value, type); } const Name *param_name = this->name(ast->param_name); Argument *arg = control()->newArgument(location(ast->param_name, ast->firstToken()), param_name); arg->setType(type); ast->argument = arg; method->addMember(arg); } bool Bind::visit(ObjCMethodPrototypeAST *ast) { (void) ast; assert(!"unreachable"); return false; } ObjCMethod *Bind::objCMethodPrototype(ObjCMethodPrototypeAST *ast) { if (! ast) return 0; // unsigned method_type_token = ast->method_type_token; FullySpecifiedType returnType = this->objCTypeName(ast->type_name); const Name *selector = this->name(ast->selector); const unsigned sourceLocation = location(ast->selector, ast->firstToken()); ObjCMethod *method = control()->newObjCMethod(sourceLocation, selector); // ### set the offsets method->setReturnType(returnType); if (isObjCClassMethod(tokenKind(ast->method_type_token))) method->setStorage(Symbol::Static); method->setVisibility(_objcVisibility); ast->symbol = method; Scope *previousScope = switchScope(method); for (ObjCMessageArgumentDeclarationListAST *it = ast->argument_list; it; it = it->next) { this->objCMessageArgumentDeclaration(it->value, method); } (void) switchScope(previousScope); if (ast->dot_dot_dot_token) method->setVariadic(true); FullySpecifiedType specifiers; for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { specifiers = this->specifier(it->value, specifiers); } //setDeclSpecifiers(method, specifiers); return method; } bool Bind::visit(ObjCSynthesizedPropertyAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::objCSynthesizedProperty(ObjCSynthesizedPropertyAST *ast) { if (! ast) return; // unsigned property_identifier_token = ast->property_identifier_token; // unsigned equals_token = ast->equals_token; // unsigned alias_identifier_token = ast->alias_identifier_token; } bool Bind::visit(LambdaIntroducerAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::lambdaIntroducer(LambdaIntroducerAST *ast) { if (! ast) return; // unsigned lbracket_token = ast->lbracket_token; this->lambdaCapture(ast->lambda_capture); // unsigned rbracket_token = ast->rbracket_token; } bool Bind::visit(LambdaCaptureAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::lambdaCapture(LambdaCaptureAST *ast) { if (! ast) return; // unsigned default_capture_token = ast->default_capture_token; for (CaptureListAST *it = ast->capture_list; it; it = it->next) { this->capture(it->value); } } bool Bind::visit(CaptureAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::capture(CaptureAST *ast) { if (! ast) return; } bool Bind::visit(LambdaDeclaratorAST *ast) { (void) ast; assert(!"unreachable"); return false; } void Bind::lambdaDeclarator(LambdaDeclaratorAST *ast) { if (! ast) return; Function *fun = 0; // ### implement me // unsigned lparen_token = ast->lparen_token; FullySpecifiedType type; this->parameterDeclarationClause(ast->parameter_declaration_clause, ast->lparen_token, fun); // unsigned rparen_token = ast->rparen_token; for (SpecifierListAST *it = ast->attributes; it; it = it->next) { type = this->specifier(it->value, type); } // unsigned mutable_token = ast->mutable_token; type = this->exceptionSpecification(ast->exception_specification, type); type = this->trailingReturnType(ast->trailing_return_type, type); } bool Bind::visit(TrailingReturnTypeAST *ast) { (void) ast; assert(!"unreachable"); return false; } FullySpecifiedType Bind::trailingReturnType(TrailingReturnTypeAST *ast, const FullySpecifiedType &init) { FullySpecifiedType type = init; if (! ast) return type; // unsigned arrow_token = ast->arrow_token; for (SpecifierListAST *it = ast->attributes; it; it = it->next) { type = this->specifier(it->value, type); } for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } DeclaratorIdAST *declaratorId = 0; type = this->declarator(ast->declarator, type, &declaratorId); return type; } // StatementAST bool Bind::visit(QtMemberDeclarationAST *ast) { const Name *name = 0; if (tokenKind(ast->q_token) == T_Q_D) name = control()->identifier("d"); else name = control()->identifier("q"); FullySpecifiedType declTy = this->expression(ast->type_id); if (tokenKind(ast->q_token) == T_Q_D) { if (NamedType *namedTy = declTy->asNamedType()) { if (const Identifier *nameId = namedTy->name()->asNameId()) { std::string privateClass; privateClass += nameId->identifier()->chars(); privateClass += "Private"; const Name *privName = control()->identifier(privateClass.c_str(), privateClass.size()); declTy.setType(control()->namedType(privName)); } } } Declaration *symbol = control()->newDeclaration(/*generated*/ 0, name); symbol->setType(control()->pointerType(declTy)); _scope->addMember(symbol); return false; } bool Bind::visit(CaseStatementAST *ast) { ExpressionTy expression = this->expression(ast->expression); this->statement(ast->statement); return false; } bool Bind::visit(CompoundStatementAST *ast) { Block *block = control()->newBlock(ast->firstToken()); unsigned startScopeToken = ast->lbrace_token ? ast->lbrace_token : ast->firstToken(); block->setStartOffset(tokenAt(startScopeToken).end()); block->setEndOffset(tokenAt(ast->lastToken() - 1).end()); ast->symbol = block; _scope->addMember(block); Scope *previousScope = switchScope(block); for (StatementListAST *it = ast->statement_list; it; it = it->next) { this->statement(it->value); } (void) switchScope(previousScope); return false; } bool Bind::visit(DeclarationStatementAST *ast) { this->declaration(ast->declaration); return false; } bool Bind::visit(DoStatementAST *ast) { this->statement(ast->statement); ExpressionTy expression = this->expression(ast->expression); return false; } bool Bind::visit(ExpressionOrDeclarationStatementAST *ast) { this->statement(ast->expression); this->statement(ast->declaration); return false; } bool Bind::visit(ExpressionStatementAST *ast) { ExpressionTy expression = this->expression(ast->expression); // unsigned semicolon_token = ast->semicolon_token; return false; } bool Bind::visit(ForeachStatementAST *ast) { Block *block = control()->newBlock(ast->firstToken()); const unsigned startScopeToken = ast->lparen_token ? ast->lparen_token : ast->firstToken(); block->setStartOffset(tokenAt(startScopeToken).end()); block->setEndOffset(tokenAt(ast->lastToken()).begin()); _scope->addMember(block); ast->symbol = block; Scope *previousScope = switchScope(block); FullySpecifiedType type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } DeclaratorIdAST *declaratorId = 0; type = this->declarator(ast->declarator, type, &declaratorId); if (declaratorId && declaratorId->name) { unsigned sourceLocation = location(declaratorId->name, ast->firstToken()); Declaration *decl = control()->newDeclaration(sourceLocation, declaratorId->name->name); decl->setType(type); block->addMember(decl); } /*ExpressionTy initializer =*/ this->expression(ast->initializer); /*ExpressionTy expression =*/ this->expression(ast->expression); this->statement(ast->statement); (void) switchScope(previousScope); return false; } bool Bind::visit(ForStatementAST *ast) { Block *block = control()->newBlock(ast->firstToken()); const unsigned startScopeToken = ast->lparen_token ? ast->lparen_token : ast->firstToken(); block->setStartOffset(tokenAt(startScopeToken).end()); block->setEndOffset(tokenAt(ast->lastToken()).begin()); _scope->addMember(block); ast->symbol = block; Scope *previousScope = switchScope(block); this->statement(ast->initializer); /*ExpressionTy condition =*/ this->expression(ast->condition); // unsigned semicolon_token = ast->semicolon_token; /*ExpressionTy expression =*/ this->expression(ast->expression); // unsigned rparen_token = ast->rparen_token; this->statement(ast->statement); (void) switchScope(previousScope); return false; } bool Bind::visit(IfStatementAST *ast) { Block *block = control()->newBlock(ast->firstToken()); const unsigned startScopeToken = ast->lparen_token ? ast->lparen_token : ast->firstToken(); block->setStartOffset(tokenAt(startScopeToken).end()); block->setEndOffset(tokenAt(ast->lastToken()).begin()); _scope->addMember(block); ast->symbol = block; Scope *previousScope = switchScope(block); /*ExpressionTy condition =*/ this->expression(ast->condition); this->statement(ast->statement); this->statement(ast->else_statement); (void) switchScope(previousScope); return false; } bool Bind::visit(LabeledStatementAST *ast) { // unsigned label_token = ast->label_token; // unsigned colon_token = ast->colon_token; this->statement(ast->statement); return false; } bool Bind::visit(BreakStatementAST *ast) { (void) ast; // unsigned break_token = ast->break_token; // unsigned semicolon_token = ast->semicolon_token; return false; } bool Bind::visit(ContinueStatementAST *ast) { (void) ast; // unsigned continue_token = ast->continue_token; // unsigned semicolon_token = ast->semicolon_token; return false; } bool Bind::visit(GotoStatementAST *ast) { (void) ast; // unsigned goto_token = ast->goto_token; // unsigned identifier_token = ast->identifier_token; // unsigned semicolon_token = ast->semicolon_token; return false; } bool Bind::visit(ReturnStatementAST *ast) { ExpressionTy expression = this->expression(ast->expression); return false; } bool Bind::visit(SwitchStatementAST *ast) { Block *block = control()->newBlock(ast->firstToken()); const unsigned startScopeToken = ast->lparen_token ? ast->lparen_token : ast->firstToken(); block->setStartOffset(tokenAt(startScopeToken).end()); block->setEndOffset(tokenAt(ast->lastToken()).begin()); _scope->addMember(block); ast->symbol = block; Scope *previousScope = switchScope(block); /*ExpressionTy condition =*/ this->expression(ast->condition); this->statement(ast->statement); (void) switchScope(previousScope); return false; } bool Bind::visit(TryBlockStatementAST *ast) { // unsigned try_token = ast->try_token; this->statement(ast->statement); for (CatchClauseListAST *it = ast->catch_clause_list; it; it = it->next) { this->statement(it->value); } return false; } bool Bind::visit(CatchClauseAST *ast) { Block *block = control()->newBlock(ast->firstToken()); const unsigned startScopeToken = ast->lparen_token ? ast->lparen_token : ast->firstToken(); block->setStartOffset(tokenAt(startScopeToken).end()); block->setEndOffset(tokenAt(ast->lastToken()).begin()); _scope->addMember(block); ast->symbol = block; Scope *previousScope = switchScope(block); this->declaration(ast->exception_declaration); // unsigned rparen_token = ast->rparen_token; this->statement(ast->statement); (void) switchScope(previousScope); return false; } bool Bind::visit(WhileStatementAST *ast) { Block *block = control()->newBlock(ast->firstToken()); const unsigned startScopeToken = ast->lparen_token ? ast->lparen_token : ast->firstToken(); block->setStartOffset(tokenAt(startScopeToken).end()); block->setEndOffset(tokenAt(ast->lastToken()).begin()); _scope->addMember(block); ast->symbol = block; Scope *previousScope = switchScope(block); /*ExpressionTy condition =*/ this->expression(ast->condition); this->statement(ast->statement); (void) switchScope(previousScope); return false; } bool Bind::visit(ObjCFastEnumerationAST *ast) { Block *block = control()->newBlock(ast->firstToken()); const unsigned startScopeToken = ast->lparen_token ? ast->lparen_token : ast->firstToken(); block->setStartOffset(tokenAt(startScopeToken).end()); block->setEndOffset(tokenAt(ast->lastToken()).begin()); _scope->addMember(block); ast->symbol = block; Scope *previousScope = switchScope(block); FullySpecifiedType type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } DeclaratorIdAST *declaratorId = 0; type = this->declarator(ast->declarator, type, &declaratorId); if (declaratorId && declaratorId->name) { unsigned sourceLocation = location(declaratorId->name, ast->firstToken()); Declaration *decl = control()->newDeclaration(sourceLocation, declaratorId->name->name); decl->setType(type); block->addMember(decl); } /*ExpressionTy initializer =*/ this->expression(ast->initializer); /*ExpressionTy fast_enumeratable_expression =*/ this->expression(ast->fast_enumeratable_expression); this->statement(ast->statement); (void) switchScope(previousScope); return false; } bool Bind::visit(ObjCSynchronizedStatementAST *ast) { // unsigned synchronized_token = ast->synchronized_token; // unsigned lparen_token = ast->lparen_token; ExpressionTy synchronized_object = this->expression(ast->synchronized_object); // unsigned rparen_token = ast->rparen_token; this->statement(ast->statement); return false; } // ExpressionAST bool Bind::visit(IdExpressionAST *ast) { /*const Name *name =*/ this->name(ast->name); return false; } bool Bind::visit(CompoundExpressionAST *ast) { // unsigned lparen_token = ast->lparen_token; this->statement(ast->statement); // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(CompoundLiteralAST *ast) { // unsigned lparen_token = ast->lparen_token; ExpressionTy type_id = this->expression(ast->type_id); // unsigned rparen_token = ast->rparen_token; ExpressionTy initializer = this->expression(ast->initializer); return false; } bool Bind::visit(QtMethodAST *ast) { // unsigned method_token = ast->method_token; // unsigned lparen_token = ast->lparen_token; FullySpecifiedType type; DeclaratorIdAST *declaratorId = 0; type = this->declarator(ast->declarator, type, &declaratorId); // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(BinaryExpressionAST *ast) { ExpressionTy left_expression = this->expression(ast->left_expression); // unsigned binary_op_token = ast->binary_op_token; ExpressionTy right_expression = this->expression(ast->right_expression); return false; } bool Bind::visit(CastExpressionAST *ast) { // unsigned lparen_token = ast->lparen_token; ExpressionTy type_id = this->expression(ast->type_id); // unsigned rparen_token = ast->rparen_token; ExpressionTy expression = this->expression(ast->expression); return false; } bool Bind::visit(ConditionAST *ast) { FullySpecifiedType type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } DeclaratorIdAST *declaratorId = 0; type = this->declarator(ast->declarator, type, &declaratorId); if (declaratorId && declaratorId->name) { unsigned sourceLocation = location(declaratorId->name, ast->firstToken()); Declaration *decl = control()->newDeclaration(sourceLocation, declaratorId->name->name); decl->setType(type); _scope->addMember(decl); } return false; } bool Bind::visit(ConditionalExpressionAST *ast) { ExpressionTy condition = this->expression(ast->condition); // unsigned question_token = ast->question_token; ExpressionTy left_expression = this->expression(ast->left_expression); // unsigned colon_token = ast->colon_token; ExpressionTy right_expression = this->expression(ast->right_expression); return false; } bool Bind::visit(CppCastExpressionAST *ast) { // unsigned cast_token = ast->cast_token; // unsigned less_token = ast->less_token; ExpressionTy type_id = this->expression(ast->type_id); // unsigned greater_token = ast->greater_token; // unsigned lparen_token = ast->lparen_token; ExpressionTy expression = this->expression(ast->expression); // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(DeleteExpressionAST *ast) { // unsigned scope_token = ast->scope_token; // unsigned delete_token = ast->delete_token; // unsigned lbracket_token = ast->lbracket_token; // unsigned rbracket_token = ast->rbracket_token; ExpressionTy expression = this->expression(ast->expression); return false; } bool Bind::visit(ArrayInitializerAST *ast) { // unsigned lbrace_token = ast->lbrace_token; for (ExpressionListAST *it = ast->expression_list; it; it = it->next) { ExpressionTy value = this->expression(it->value); } // unsigned rbrace_token = ast->rbrace_token; return false; } bool Bind::visit(NewExpressionAST *ast) { // unsigned scope_token = ast->scope_token; // unsigned new_token = ast->new_token; this->newPlacement(ast->new_placement); // unsigned lparen_token = ast->lparen_token; ExpressionTy type_id = this->expression(ast->type_id); // unsigned rparen_token = ast->rparen_token; this->newTypeId(ast->new_type_id); this->newInitializer(ast->new_initializer); return false; } bool Bind::visit(TypeidExpressionAST *ast) { // unsigned typeid_token = ast->typeid_token; // unsigned lparen_token = ast->lparen_token; ExpressionTy expression = this->expression(ast->expression); // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(TypenameCallExpressionAST *ast) { // unsigned typename_token = ast->typename_token; /*const Name *name =*/ this->name(ast->name); // unsigned lparen_token = ast->lparen_token; for (ExpressionListAST *it = ast->expression_list; it; it = it->next) { ExpressionTy value = this->expression(it->value); } // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(TypeConstructorCallAST *ast) { FullySpecifiedType type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } // unsigned lparen_token = ast->lparen_token; for (ExpressionListAST *it = ast->expression_list; it; it = it->next) { ExpressionTy value = this->expression(it->value); } // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(SizeofExpressionAST *ast) { // unsigned sizeof_token = ast->sizeof_token; // unsigned dot_dot_dot_token = ast->dot_dot_dot_token; // unsigned lparen_token = ast->lparen_token; ExpressionTy expression = this->expression(ast->expression); // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(NumericLiteralAST *ast) { (void) ast; // unsigned literal_token = ast->literal_token; return false; } bool Bind::visit(BoolLiteralAST *ast) { (void) ast; // unsigned literal_token = ast->literal_token; return false; } bool Bind::visit(ThisExpressionAST *ast) { (void) ast; // unsigned this_token = ast->this_token; return false; } bool Bind::visit(NestedExpressionAST *ast) { // unsigned lparen_token = ast->lparen_token; ExpressionTy expression = this->expression(ast->expression); // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(StringLiteralAST *ast) { // unsigned literal_token = ast->literal_token; ExpressionTy next = this->expression(ast->next); return false; } bool Bind::visit(ThrowExpressionAST *ast) { // unsigned throw_token = ast->throw_token; ExpressionTy expression = this->expression(ast->expression); return false; } bool Bind::visit(TypeIdAST *ast) { FullySpecifiedType type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } DeclaratorIdAST *declaratorId = 0; type = this->declarator(ast->declarator, type, &declaratorId); _expression = type; return false; } bool Bind::visit(UnaryExpressionAST *ast) { // unsigned unary_op_token = ast->unary_op_token; ExpressionTy expression = this->expression(ast->expression); return false; } bool Bind::visit(ObjCMessageExpressionAST *ast) { // unsigned lbracket_token = ast->lbracket_token; /*ExpressionTy receiver_expression =*/ this->expression(ast->receiver_expression); /*const Name *selector =*/ this->name(ast->selector); for (ObjCMessageArgumentListAST *it = ast->argument_list; it; it = it->next) { this->objCMessageArgument(it->value); } // unsigned rbracket_token = ast->rbracket_token; return false; } bool Bind::visit(ObjCProtocolExpressionAST *ast) { (void) ast; // unsigned protocol_token = ast->protocol_token; // unsigned lparen_token = ast->lparen_token; // unsigned identifier_token = ast->identifier_token; // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(ObjCEncodeExpressionAST *ast) { // unsigned encode_token = ast->encode_token; FullySpecifiedType type = this->objCTypeName(ast->type_name); return false; } bool Bind::visit(ObjCSelectorExpressionAST *ast) { // unsigned selector_token = ast->selector_token; // unsigned lparen_token = ast->lparen_token; /*const Name *selector =*/ this->name(ast->selector); // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(LambdaExpressionAST *ast) { this->lambdaIntroducer(ast->lambda_introducer); this->lambdaDeclarator(ast->lambda_declarator); this->statement(ast->statement); return false; } bool Bind::visit(BracedInitializerAST *ast) { // unsigned lbrace_token = ast->lbrace_token; for (ExpressionListAST *it = ast->expression_list; it; it = it->next) { ExpressionTy value = this->expression(it->value); } // unsigned comma_token = ast->comma_token; // unsigned rbrace_token = ast->rbrace_token; return false; } static int methodKeyForInvokableToken(int kind) { if (kind == T_Q_SIGNAL) return Function::SignalMethod; else if (kind == T_Q_SLOT) return Function::SlotMethod; else if (kind == T_Q_INVOKABLE) return Function::InvokableMethod; return Function::NormalMethod; } // DeclarationAST bool Bind::visit(SimpleDeclarationAST *ast) { int methodKey = _methodKey; if (ast->qt_invokable_token) methodKey = methodKeyForInvokableToken(tokenKind(ast->qt_invokable_token)); // unsigned qt_invokable_token = ast->qt_invokable_token; FullySpecifiedType type; for (SpecifierListAST *it = ast->decl_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } List **symbolTail = &ast->symbols; if (! ast->declarator_list) { ElaboratedTypeSpecifierAST *elabTypeSpec = 0; for (SpecifierListAST *it = ast->decl_specifier_list; ! elabTypeSpec && it; it = it->next) elabTypeSpec = it->value->asElaboratedTypeSpecifier(); if (elabTypeSpec && tokenKind(elabTypeSpec->classkey_token) != T_TYPENAME) { unsigned sourceLocation = elabTypeSpec->firstToken(); const Name *name = 0; if (elabTypeSpec->name) { sourceLocation = location(elabTypeSpec->name, sourceLocation); name = elabTypeSpec->name->name; } ForwardClassDeclaration *decl = control()->newForwardClassDeclaration(sourceLocation, name); setDeclSpecifiers(decl, type); _scope->addMember(decl); *symbolTail = new (translationUnit()->memoryPool()) List(decl); symbolTail = &(*symbolTail)->next; } } for (DeclaratorListAST *it = ast->declarator_list; it; it = it->next) { DeclaratorIdAST *declaratorId = 0; FullySpecifiedType declTy = this->declarator(it->value, type.qualifiedType(), &declaratorId); const Name *declName = 0; unsigned sourceLocation = location(it->value, ast->firstToken()); if (declaratorId && declaratorId->name) { declName = declaratorId->name->name; } Declaration *decl = control()->newDeclaration(sourceLocation, declName); decl->setType(declTy); setDeclSpecifiers(decl, type); if (Function *fun = decl->type()->asFunctionType()) { fun->setScope(_scope); setDeclSpecifiers(fun, type); if (declaratorId && declaratorId->name) fun->setName(declaratorId->name->name); // update the function name } if (_scope->isClass()) { decl->setVisibility(_visibility); if (Function *funTy = decl->type()->asFunctionType()) { funTy->setMethodKey(methodKey); if (funTy->isVirtual() && it->value->equal_token) funTy->setPureVirtual(true); } } _scope->addMember(decl); *symbolTail = new (translationUnit()->memoryPool()) List(decl); symbolTail = &(*symbolTail)->next; } return false; } bool Bind::visit(EmptyDeclarationAST *ast) { (void) ast; unsigned semicolon_token = ast->semicolon_token; if (_scope && (_scope->isClass() || _scope->isNamespace())) { const Token &tk = tokenAt(semicolon_token); if (! tk.generated()) translationUnit()->warning(semicolon_token, "extra `;'"); } return false; } bool Bind::visit(AccessDeclarationAST *ast) { const int accessSpecifier = tokenKind(ast->access_specifier_token); _visibility = visibilityForAccessSpecifier(accessSpecifier); if (ast->slots_token) _methodKey = Function::SlotMethod; else if (accessSpecifier == T_Q_SIGNALS) _methodKey = Function::SignalMethod; else _methodKey = Function::NormalMethod; return false; } bool Bind::visit(QtObjectTagAST *ast) { (void) ast; // unsigned q_object_token = ast->q_object_token; return false; } bool Bind::visit(QtPrivateSlotAST *ast) { // unsigned q_private_slot_token = ast->q_private_slot_token; // unsigned lparen_token = ast->lparen_token; // unsigned dptr_token = ast->dptr_token; // unsigned dptr_lparen_token = ast->dptr_lparen_token; // unsigned dptr_rparen_token = ast->dptr_rparen_token; // unsigned comma_token = ast->comma_token; FullySpecifiedType type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } DeclaratorIdAST *declaratorId = 0; type = this->declarator(ast->declarator, type, &declaratorId); // unsigned rparen_token = ast->rparen_token; return false; } static void qtPropertyAttribute(TranslationUnit *unit, ExpressionAST *expression, int *flags, QtPropertyDeclaration::Flag flag, QtPropertyDeclaration::Flag function) { if (!expression) return; *flags &= ~function & ~flag; if (BoolLiteralAST *boollit = expression->asBoolLiteral()) { const int kind = unit->tokenAt(boollit->literal_token).kind(); if (kind == T_TRUE) *flags |= flag; } else { *flags |= function; } } bool Bind::visit(QtPropertyDeclarationAST *ast) { // unsigned property_specifier_token = ast->property_specifier_token; // unsigned lparen_token = ast->lparen_token; ExpressionTy type_id = this->expression(ast->type_id); const Name *property_name = this->name(ast->property_name); unsigned sourceLocation = ast->firstToken(); if (ast->property_name) sourceLocation = ast->property_name->firstToken(); QtPropertyDeclaration *propertyDeclaration = control()->newQtPropertyDeclaration(sourceLocation, property_name); propertyDeclaration->setType(type_id); int flags = QtPropertyDeclaration::DesignableFlag | QtPropertyDeclaration::ScriptableFlag | QtPropertyDeclaration::StoredFlag; for (QtPropertyDeclarationItemListAST *it = ast->property_declaration_item_list; it; it = it->next) { if (!it->value || !it->value->item_name_token) continue; this->expression(it->value->expression); std::string name = spell(it->value->item_name_token); if (name == "CONSTANT") { flags |= QtPropertyDeclaration::ConstantFlag; } else if (name == "FINAL") { flags |= QtPropertyDeclaration::FinalFlag; } else if (name == "READ") { flags |= QtPropertyDeclaration::ReadFunction; } else if (name == "WRITE") { flags |= QtPropertyDeclaration::WriteFunction; } else if (name == "RESET") { flags |= QtPropertyDeclaration::ResetFunction; } else if (name == "NOTIFY") { flags |= QtPropertyDeclaration::NotifyFunction; } else if (name == "DESIGNABLE") { qtPropertyAttribute(translationUnit(), it->value->expression, &flags, QtPropertyDeclaration::DesignableFlag, QtPropertyDeclaration::DesignableFunction); } else if (name == "SCRIPTABLE") { qtPropertyAttribute(translationUnit(), it->value->expression, &flags, QtPropertyDeclaration::ScriptableFlag, QtPropertyDeclaration::ScriptableFunction); } else if (name == "STORED") { qtPropertyAttribute(translationUnit(), it->value->expression, &flags, QtPropertyDeclaration::StoredFlag, QtPropertyDeclaration::StoredFunction); } else if (name == "USER") { qtPropertyAttribute(translationUnit(), it->value->expression, &flags, QtPropertyDeclaration::UserFlag, QtPropertyDeclaration::UserFunction); } } propertyDeclaration->setFlags(flags); _scope->addMember(propertyDeclaration); // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(QtEnumDeclarationAST *ast) { // unsigned enum_specifier_token = ast->enum_specifier_token; // unsigned lparen_token = ast->lparen_token; for (NameListAST *it = ast->enumerator_list; it; it = it->next) { const Name *value = this->name(it->value); if (!value) continue; QtEnum *qtEnum = control()->newQtEnum(it->value->firstToken(), value); _scope->addMember(qtEnum); } // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(QtFlagsDeclarationAST *ast) { // unsigned flags_specifier_token = ast->flags_specifier_token; // unsigned lparen_token = ast->lparen_token; for (NameListAST *it = ast->flag_enums_list; it; it = it->next) { /*const Name *value =*/ this->name(it->value); } // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(QtInterfacesDeclarationAST *ast) { // unsigned interfaces_token = ast->interfaces_token; // unsigned lparen_token = ast->lparen_token; for (QtInterfaceNameListAST *it = ast->interface_name_list; it; it = it->next) { this->qtInterfaceName(it->value); } // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(AsmDefinitionAST *ast) { (void) ast; // unsigned asm_token = ast->asm_token; // unsigned volatile_token = ast->volatile_token; // unsigned lparen_token = ast->lparen_token; // unsigned rparen_token = ast->rparen_token; // unsigned semicolon_token = ast->semicolon_token; return false; } bool Bind::visit(ExceptionDeclarationAST *ast) { FullySpecifiedType type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } DeclaratorIdAST *declaratorId = 0; type = this->declarator(ast->declarator, type, &declaratorId); // unsigned dot_dot_dot_token = ast->dot_dot_dot_token; return false; } bool Bind::visit(FunctionDefinitionAST *ast) { int methodKey = _methodKey; if (ast->qt_invokable_token) methodKey = methodKeyForInvokableToken(tokenKind(ast->qt_invokable_token)); FullySpecifiedType declSpecifiers; for (SpecifierListAST *it = ast->decl_specifier_list; it; it = it->next) { declSpecifiers = this->specifier(it->value, declSpecifiers); } DeclaratorIdAST *declaratorId = 0; FullySpecifiedType type = this->declarator(ast->declarator, declSpecifiers.qualifiedType(), &declaratorId); Function *fun = type->asFunctionType(); ast->symbol = fun; if (fun) { setDeclSpecifiers(fun, declSpecifiers); if (_scope->isClass()) { fun->setVisibility(_visibility); fun->setMethodKey(methodKey); } if (declaratorId && declaratorId->name) { fun->setSourceLocation(location(declaratorId, ast->firstToken()), translationUnit()); fun->setName(declaratorId->name->name); } _scope->addMember(fun); } else translationUnit()->warning(ast->firstToken(), "expected a function declarator"); this->ctorInitializer(ast->ctor_initializer, fun); if (fun && ! _skipFunctionBodies && ast->function_body) { Scope *previousScope = switchScope(fun); this->statement(ast->function_body); (void) switchScope(previousScope); if (CompoundStatementAST *c = ast->function_body->asCompoundStatement()) { if (c->symbol) { fun->setEndOffset(c->symbol->endOffset()); } } } return false; } bool Bind::visit(LinkageBodyAST *ast) { // unsigned lbrace_token = ast->lbrace_token; for (DeclarationListAST *it = ast->declaration_list; it; it = it->next) { this->declaration(it->value); } // unsigned rbrace_token = ast->rbrace_token; return false; } bool Bind::visit(LinkageSpecificationAST *ast) { // unsigned extern_token = ast->extern_token; // unsigned extern_type_token = ast->extern_type_token; this->declaration(ast->declaration); return false; } bool Bind::visit(NamespaceAST *ast) { // unsigned namespace_token = ast->namespace_token; // unsigned identifier_token = ast->identifier_token; FullySpecifiedType type; for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { type = this->specifier(it->value, type); } unsigned sourceLocation = ast->firstToken(); const Name *namespaceName = 0; if (ast->identifier_token) { sourceLocation = ast->identifier_token; namespaceName = identifier(ast->identifier_token); } Namespace *ns = control()->newNamespace(sourceLocation, namespaceName); ns->setStartOffset(tokenAt(sourceLocation).end()); // the scope starts after the namespace or the identifier token. ns->setEndOffset(tokenAt(ast->lastToken() - 1).end()); ast->symbol = ns; _scope->addMember(ns); Scope *previousScope = switchScope(ns); this->declaration(ast->linkage_body); (void) switchScope(previousScope); return false; } bool Bind::visit(NamespaceAliasDefinitionAST *ast) { unsigned sourceLocation = ast->firstToken(); const Name *name = 0; if (ast->namespace_name_token) { sourceLocation = ast->namespace_name_token; name = identifier(ast->namespace_name_token); } NamespaceAlias *namespaceAlias = control()->newNamespaceAlias(sourceLocation, name); namespaceAlias->setNamespaceName(this->name(ast->name)); _scope->addMember(namespaceAlias); return false; } bool Bind::visit(ParameterDeclarationAST *ast) { FullySpecifiedType type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } DeclaratorIdAST *declaratorId = 0; type = this->declarator(ast->declarator, type, &declaratorId); // unsigned equal_token = ast->equal_token; ExpressionTy expression = this->expression(ast->expression); unsigned sourceLocation = ast->firstToken(); if (declaratorId) sourceLocation = declaratorId->firstToken(); const Name *argName = 0; if (declaratorId && declaratorId->name) argName = declaratorId->name->name; Argument *arg = control()->newArgument(location(declaratorId, ast->firstToken()), argName); arg->setType(type); if (ast->expression) { unsigned startOfExpression = ast->expression->firstToken(); unsigned endOfExpression = ast->expression->lastToken(); std::string buffer; for (unsigned index = startOfExpression; index != endOfExpression; ++index) { const Token &tk = tokenAt(index); if (tk.whitespace() || tk.newline()) buffer += ' '; buffer += tk.spell(); } const StringLiteral *initializer = control()->stringLiteral(buffer.c_str(), buffer.size()); arg->setInitializer(initializer); } _scope->addMember(arg); ast->symbol = arg; return false; } bool Bind::visit(TemplateDeclarationAST *ast) { Template *templ = control()->newTemplate(ast->firstToken(), 0); templ->setStartOffset(tokenAt(ast->firstToken()).begin()); templ->setEndOffset(tokenAt(ast->lastToken() - 1).end()); ast->symbol = templ; Scope *previousScope = switchScope(templ); for (DeclarationListAST *it = ast->template_parameter_list; it; it = it->next) { this->declaration(it->value); } // unsigned greater_token = ast->greater_token; this->declaration(ast->declaration); (void) switchScope(previousScope); if (Symbol *decl = templ->declaration()) { templ->setSourceLocation(decl->sourceLocation(), translationUnit()); templ->setName(decl->name()); } _scope->addMember(templ); return false; } bool Bind::visit(TypenameTypeParameterAST *ast) { unsigned sourceLocation = location(ast->name, ast->firstToken()); // unsigned classkey_token = ast->classkey_token; // unsigned dot_dot_dot_token = ast->dot_dot_dot_token; const Name *name = this->name(ast->name); ExpressionTy type_id = this->expression(ast->type_id); TypenameArgument *arg = control()->newTypenameArgument(sourceLocation, name); arg->setType(type_id); ast->symbol = arg; _scope->addMember(arg); return false; } bool Bind::visit(TemplateTypeParameterAST *ast) { unsigned sourceLocation = location(ast->name, ast->firstToken()); // unsigned template_token = ast->template_token; // unsigned less_token = ast->less_token; // ### process the template prototype #if 0 for (DeclarationListAST *it = ast->template_parameter_list; it; it = it->next) { this->declaration(it->value); } #endif // unsigned greater_token = ast->greater_token; // unsigned class_token = ast->class_token; // unsigned dot_dot_dot_token = ast->dot_dot_dot_token; const Name *name = this->name(ast->name); ExpressionTy type_id = this->expression(ast->type_id); // ### introduce TemplateTypeArgument TypenameArgument *arg = control()->newTypenameArgument(sourceLocation, name); arg->setType(type_id); ast->symbol = arg; _scope->addMember(arg); return false; } bool Bind::visit(UsingAST *ast) { unsigned sourceLocation = location(ast->name, ast->firstToken()); const Name *name = this->name(ast->name); UsingDeclaration *symbol = control()->newUsingDeclaration(sourceLocation, name); ast->symbol = symbol; _scope->addMember(symbol); return false; } bool Bind::visit(UsingDirectiveAST *ast) { unsigned sourceLocation = location(ast->name, ast->firstToken()); const Name *name = this->name(ast->name); UsingNamespaceDirective *symbol = control()->newUsingNamespaceDirective(sourceLocation, name); ast->symbol = symbol; _scope->addMember(symbol); return false; } bool Bind::visit(ObjCClassForwardDeclarationAST *ast) { FullySpecifiedType declSpecifiers; for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { declSpecifiers = this->specifier(it->value, declSpecifiers); } List **symbolTail = &ast->symbols; // unsigned class_token = ast->class_token; for (NameListAST *it = ast->identifier_list; it; it = it->next) { const Name *name = this->name(it->value); const unsigned sourceLocation = location(it->value, ast->firstToken()); ObjCForwardClassDeclaration *fwd = control()->newObjCForwardClassDeclaration(sourceLocation, name); setDeclSpecifiers(fwd, declSpecifiers); _scope->addMember(fwd); *symbolTail = new (translationUnit()->memoryPool()) List(fwd); symbolTail = &(*symbolTail)->next; } return false; } unsigned Bind::calculateScopeStart(ObjCClassDeclarationAST *ast) const { if (ast->inst_vars_decl) if (unsigned pos = ast->inst_vars_decl->lbrace_token) return tokenAt(pos).end(); if (ast->protocol_refs) if (unsigned pos = ast->protocol_refs->lastToken()) return tokenAt(pos - 1).end(); if (ast->superclass) if (unsigned pos = ast->superclass->lastToken()) return tokenAt(pos - 1).end(); if (ast->colon_token) return tokenAt(ast->colon_token).end(); if (ast->rparen_token) return tokenAt(ast->rparen_token).end(); if (ast->category_name) if (unsigned pos = ast->category_name->lastToken()) return tokenAt(pos - 1).end(); if (ast->lparen_token) return tokenAt(ast->lparen_token).end(); if (ast->class_name) if (unsigned pos = ast->class_name->lastToken()) return tokenAt(pos - 1).end(); return tokenAt(ast->firstToken()).begin(); } bool Bind::visit(ObjCClassDeclarationAST *ast) { FullySpecifiedType declSpecifiers; for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { declSpecifiers = this->specifier(it->value, declSpecifiers); } const Name *class_name = this->name(ast->class_name); const Name *category_name = this->name(ast->category_name); const unsigned sourceLocation = location(ast->class_name, ast->firstToken()); ObjCClass *klass = control()->newObjCClass(sourceLocation, class_name); ast->symbol = klass; _scope->addMember(klass); klass->setStartOffset(calculateScopeStart(ast)); klass->setEndOffset(tokenAt(ast->lastToken() - 1).begin()); if (ast->interface_token) klass->setInterface(true); klass->setCategoryName(category_name); Scope *previousScope = switchScope(klass); if (const Name *superclass = this->name(ast->superclass)) { ObjCBaseClass *superKlass = control()->newObjCBaseClass(ast->superclass->firstToken(), superclass); klass->setBaseClass(superKlass); } this->objCProtocolRefs(ast->protocol_refs, klass); const int previousObjCVisibility = switchObjCVisibility(Function::Protected); this->objCInstanceVariablesDeclaration(ast->inst_vars_decl, klass); (void) switchObjCVisibility(Function::Public); for (DeclarationListAST *it = ast->member_declaration_list; it; it = it->next) { this->declaration(it->value); } (void) switchObjCVisibility(previousObjCVisibility); (void) switchScope(previousScope); return false; } bool Bind::visit(ObjCProtocolForwardDeclarationAST *ast) { FullySpecifiedType declSpecifiers; for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { declSpecifiers = this->specifier(it->value, declSpecifiers); } List **symbolTail = &ast->symbols; // unsigned class_token = ast->class_token; for (NameListAST *it = ast->identifier_list; it; it = it->next) { const Name *name = this->name(it->value); const unsigned sourceLocation = location(it->value, ast->firstToken()); ObjCForwardProtocolDeclaration *fwd = control()->newObjCForwardProtocolDeclaration(sourceLocation, name); setDeclSpecifiers(fwd, declSpecifiers); _scope->addMember(fwd); *symbolTail = new (translationUnit()->memoryPool()) List(fwd); symbolTail = &(*symbolTail)->next; } return false; } unsigned Bind::calculateScopeStart(ObjCProtocolDeclarationAST *ast) const { if (ast->protocol_refs) if (unsigned pos = ast->protocol_refs->lastToken()) return tokenAt(pos - 1).end(); if (ast->name) if (unsigned pos = ast->name->lastToken()) return tokenAt(pos - 1).end(); return tokenAt(ast->firstToken()).begin(); } bool Bind::visit(ObjCProtocolDeclarationAST *ast) { FullySpecifiedType type; for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { type = this->specifier(it->value, type); } // unsigned protocol_token = ast->protocol_token; const Name *name = this->name(ast->name); const unsigned sourceLocation = location(ast->name, ast->firstToken()); ObjCProtocol *protocol = control()->newObjCProtocol(sourceLocation, name); protocol->setStartOffset(calculateScopeStart(ast)); protocol->setEndOffset(tokenAt(ast->lastToken() - 1).end()); ast->symbol = protocol; _scope->addMember(protocol); Scope *previousScope = switchScope(protocol); const int previousObjCVisibility = switchObjCVisibility(Function::Public); this->objCProtocolRefs(ast->protocol_refs, protocol); for (DeclarationListAST *it = ast->member_declaration_list; it; it = it->next) { this->declaration(it->value); } (void) switchObjCVisibility(previousObjCVisibility); (void) switchScope(previousScope); return false; } bool Bind::visit(ObjCVisibilityDeclarationAST *ast) { _objcVisibility = visibilityForObjCAccessSpecifier(tokenKind(ast->visibility_token)); return false; } bool Bind::visit(ObjCPropertyDeclarationAST *ast) { (void) ast; FullySpecifiedType type; for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { type = this->specifier(it->value, type); } // unsigned property_token = ast->property_token; // unsigned lparen_token = ast->lparen_token; for (ObjCPropertyAttributeListAST *it = ast->property_attribute_list; it; it = it->next) { this->objCPropertyAttribute(it->value); } // unsigned rparen_token = ast->rparen_token; this->declaration(ast->simple_declaration); // List *symbols = ast->symbols; return false; } bool Bind::visit(ObjCMethodDeclarationAST *ast) { ObjCMethod *method = this->objCMethodPrototype(ast->method_prototype); if (! ast->function_body) { const Name *name = method->name(); unsigned sourceLocation = ast->firstToken(); Declaration *decl = control()->newDeclaration(sourceLocation, name); decl->setType(method); _scope->addMember(decl); } else if (! _skipFunctionBodies && ast->function_body) { Scope *previousScope = switchScope(method); this->statement(ast->function_body); (void) switchScope(previousScope); _scope->addMember(method); } return false; } bool Bind::visit(ObjCSynthesizedPropertiesDeclarationAST *ast) { // unsigned synthesized_token = ast->synthesized_token; for (ObjCSynthesizedPropertyListAST *it = ast->property_identifier_list; it; it = it->next) { this->objCSynthesizedProperty(it->value); } // unsigned semicolon_token = ast->semicolon_token; return false; } bool Bind::visit(ObjCDynamicPropertiesDeclarationAST *ast) { // unsigned dynamic_token = ast->dynamic_token; for (NameListAST *it = ast->property_identifier_list; it; it = it->next) { /*const Name *value =*/ this->name(it->value); } // unsigned semicolon_token = ast->semicolon_token; return false; } // NameAST bool Bind::visit(ObjCSelectorAST *ast) // ### review { std::vector arguments; bool hasArgs = false; for (ObjCSelectorArgumentListAST *it = ast->selector_argument_list; it; it = it->next) { if (const Name *selector_argument = this->objCSelectorArgument(it->value, &hasArgs)) arguments.push_back(selector_argument); } if (! arguments.empty()) { _name = control()->selectorNameId(&arguments[0], arguments.size(), hasArgs); ast->name = _name; } return false; } bool Bind::visit(QualifiedNameAST *ast) { for (NestedNameSpecifierListAST *it = ast->nested_name_specifier_list; it; it = it->next) { const Name *class_or_namespace_name = this->nestedNameSpecifier(it->value); if (_name || ast->global_scope_token) _name = control()->qualifiedNameId(_name, class_or_namespace_name); else _name = class_or_namespace_name; } const Name *unqualified_name = this->name(ast->unqualified_name); if (_name || ast->global_scope_token) _name = control()->qualifiedNameId(_name, unqualified_name); else _name = unqualified_name; ast->name = _name; return false; } bool Bind::visit(OperatorFunctionIdAST *ast) { const OperatorNameId::Kind op = this->cppOperator(ast->op); ast->name = _name = control()->operatorNameId(op); return false; } bool Bind::visit(ConversionFunctionIdAST *ast) { FullySpecifiedType type; for (SpecifierListAST *it = ast->type_specifier_list; it; it = it->next) { type = this->specifier(it->value, type); } for (PtrOperatorListAST *it = ast->ptr_operator_list; it; it = it->next) { type = this->ptrOperator(it->value, type); } ast->name = _name = control()->conversionNameId(type); return false; } bool Bind::visit(SimpleNameAST *ast) { const Identifier *id = identifier(ast->identifier_token); _name = id; ast->name = _name; return false; } bool Bind::visit(DestructorNameAST *ast) { const Identifier *id = identifier(ast->identifier_token); _name = control()->destructorNameId(id); ast->name = _name; return false; } bool Bind::visit(TemplateIdAST *ast) { // collect the template parameters std::vector templateArguments; for (ExpressionListAST *it = ast->template_argument_list; it; it = it->next) { ExpressionTy value = this->expression(it->value); templateArguments.push_back(value); } const Identifier *id = identifier(ast->identifier_token); if (templateArguments.empty()) _name = control()->templateNameId(id); else _name = control()->templateNameId(id, &templateArguments[0], templateArguments.size()); ast->name = _name; return false; } // SpecifierAST bool Bind::visit(SimpleSpecifierAST *ast) { switch (tokenKind(ast->specifier_token)) { case T_CONST: if (_type.isConst()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setConst(true); break; case T_VOLATILE: if (_type.isVolatile()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setVolatile(true); break; case T_FRIEND: if (_type.isFriend()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setFriend(true); break; case T_AUTO: if (_type.isAuto()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setAuto(true); break; case T_REGISTER: if (_type.isRegister()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setRegister(true); break; case T_STATIC: if (_type.isStatic()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setStatic(true); break; case T_EXTERN: if (_type.isExtern()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setExtern(true); break; case T_MUTABLE: if (_type.isMutable()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setMutable(true); break; case T_TYPEDEF: if (_type.isTypedef()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setTypedef(true); break; case T_INLINE: if (_type.isInline()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setInline(true); break; case T_VIRTUAL: if (_type.isVirtual()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setVirtual(true); break; case T_EXPLICIT: if (_type.isExplicit()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setExplicit(true); break; case T_SIGNED: if (_type.isSigned()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setSigned(true); break; case T_UNSIGNED: if (_type.isUnsigned()) translationUnit()->error(ast->specifier_token, "duplicate `%s'", spell(ast->specifier_token)); _type.setUnsigned(true); break; case T_CHAR: if (_type) translationUnit()->error(ast->specifier_token, "duplicate data type in declaration"); _type.setType(control()->integerType(IntegerType::Char)); break; case T_WCHAR_T: if (_type) translationUnit()->error(ast->specifier_token, "duplicate data type in declaration"); _type.setType(control()->integerType(IntegerType::WideChar)); break; case T_BOOL: if (_type) translationUnit()->error(ast->specifier_token, "duplicate data type in declaration"); _type.setType(control()->integerType(IntegerType::Bool)); break; case T_SHORT: if (_type) { IntegerType *intType = control()->integerType(IntegerType::Int); if (_type.type() != intType) translationUnit()->error(ast->specifier_token, "duplicate data type in declaration"); } _type.setType(control()->integerType(IntegerType::Short)); break; case T_INT: if (_type) { Type *tp = _type.type(); IntegerType *shortType = control()->integerType(IntegerType::Short); IntegerType *longType = control()->integerType(IntegerType::Long); IntegerType *longLongType = control()->integerType(IntegerType::LongLong); if (tp == shortType || tp == longType || tp == longLongType) break; translationUnit()->error(ast->specifier_token, "duplicate data type in declaration"); } _type.setType(control()->integerType(IntegerType::Int)); break; case T_LONG: if (_type) { Type *tp = _type.type(); IntegerType *intType = control()->integerType(IntegerType::Int); IntegerType *longType = control()->integerType(IntegerType::Long); FloatType *doubleType = control()->floatType(FloatType::Double); if (tp == longType) { _type.setType(control()->integerType(IntegerType::LongLong)); break; } else if (tp == doubleType) { _type.setType(control()->floatType(FloatType::LongDouble)); break; } else if (tp != intType) { translationUnit()->error(ast->specifier_token, "duplicate data type in declaration"); } } _type.setType(control()->integerType(IntegerType::Long)); break; case T_FLOAT: if (_type) translationUnit()->error(ast->specifier_token, "duplicate data type in declaration"); _type.setType(control()->floatType(FloatType::Float)); break; case T_DOUBLE: if (_type) { IntegerType *longType = control()->integerType(IntegerType::Long); if (_type.type() == longType) { _type.setType(control()->floatType(FloatType::LongDouble)); break; } translationUnit()->error(ast->specifier_token, "duplicate data type in declaration"); } _type.setType(control()->floatType(FloatType::Double)); break; case T_VOID: if (_type) translationUnit()->error(ast->specifier_token, "duplicate data type in declaration"); _type.setType(control()->voidType()); break; default: break; } // switch return false; } bool Bind::visit(AttributeSpecifierAST *ast) { // unsigned attribute_token = ast->attribute_token; // unsigned first_lparen_token = ast->first_lparen_token; // unsigned second_lparen_token = ast->second_lparen_token; for (AttributeListAST *it = ast->attribute_list; it; it = it->next) { this->attribute(it->value); } // unsigned first_rparen_token = ast->first_rparen_token; // unsigned second_rparen_token = ast->second_rparen_token; return false; } bool Bind::visit(TypeofSpecifierAST *ast) { ExpressionTy expression = this->expression(ast->expression); _type = expression; return false; } bool Bind::visit(ClassSpecifierAST *ast) { // unsigned classkey_token = ast->classkey_token; unsigned sourceLocation = ast->firstToken(); unsigned startScopeOffset = tokenAt(sourceLocation).end(); // at the end of the class key for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { _type = this->specifier(it->value, _type); } const Name *className = this->name(ast->name); if (ast->name) { sourceLocation = location(ast->name, sourceLocation); startScopeOffset = tokenAt(sourceLocation).end(); // at the end of the class name if (QualifiedNameAST *q = ast->name->asQualifiedName()) { if (q->unqualified_name) { sourceLocation = q->unqualified_name->firstToken(); startScopeOffset = tokenAt(q->unqualified_name->lastToken() - 1).end(); // at the end of the unqualified name } } } Class *klass = control()->newClass(sourceLocation, className); klass->setStartOffset(startScopeOffset); klass->setEndOffset(tokenAt(ast->lastToken() - 1).end()); _scope->addMember(klass); if (_scope->isClass()) klass->setVisibility(_visibility); // set the class key unsigned classKey = tokenKind(ast->classkey_token); if (classKey == T_CLASS) klass->setClassKey(Class::ClassKey); else if (classKey == T_STRUCT) klass->setClassKey(Class::StructKey); else if (classKey == T_UNION) klass->setClassKey(Class::UnionKey); _type.setType(klass); Scope *previousScope = switchScope(klass); const int previousVisibility = switchVisibility(visibilityForClassKey(classKey)); const int previousMethodKey = switchMethodKey(Function::NormalMethod); for (BaseSpecifierListAST *it = ast->base_clause_list; it; it = it->next) { this->baseSpecifier(it->value, ast->colon_token, klass); } // unsigned dot_dot_dot_token = ast->dot_dot_dot_token; for (DeclarationListAST *it = ast->member_specifier_list; it; it = it->next) { this->declaration(it->value); } (void) switchMethodKey(previousMethodKey); (void) switchVisibility(previousVisibility); (void) switchScope(previousScope); ast->symbol = klass; return false; } bool Bind::visit(NamedTypeSpecifierAST *ast) { _type.setType(control()->namedType(this->name(ast->name))); return false; } bool Bind::visit(ElaboratedTypeSpecifierAST *ast) { // unsigned classkey_token = ast->classkey_token; for (SpecifierListAST *it = ast->attribute_list; it; it = it->next) { _type = this->specifier(it->value, _type); } _type.setType(control()->namedType(this->name(ast->name))); return false; } bool Bind::visit(EnumSpecifierAST *ast) { unsigned sourceLocation = location(ast->name, ast->firstToken()); const Name *enumName = this->name(ast->name); Enum *e = control()->newEnum(sourceLocation, enumName); e->setStartOffset(tokenAt(sourceLocation).end()); // at the end of the enum or identifier token. e->setEndOffset(tokenAt(ast->lastToken() - 1).end()); ast->symbol = e; _scope->addMember(e); if (_scope->isClass()) e->setVisibility(_visibility); Scope *previousScope = switchScope(e); for (EnumeratorListAST *it = ast->enumerator_list; it; it = it->next) { this->enumerator(it->value, e); } if (ast->stray_comma_token /* && ! translationUnit()->cxx0xEnabled()*/) { const Token &tk = tokenAt(ast->stray_comma_token); if (! tk.generated()) translationUnit()->warning(ast->stray_comma_token, "commas at the end of enumerator lists are a C++0x-specific feature"); } (void) switchScope(previousScope); return false; } // PtrOperatorAST bool Bind::visit(PointerToMemberAST *ast) { const Name *memberName = 0; for (NestedNameSpecifierListAST *it = ast->nested_name_specifier_list; it; it = it->next) { const Name *class_or_namespace_name = this->nestedNameSpecifier(it->value); if (memberName || ast->global_scope_token) memberName = control()->qualifiedNameId(memberName, class_or_namespace_name); else memberName = class_or_namespace_name; } FullySpecifiedType type(control()->pointerToMemberType(memberName, _type)); for (SpecifierListAST *it = ast->cv_qualifier_list; it; it = it->next) { type = this->specifier(it->value, type); } _type = type; return false; } bool Bind::visit(PointerAST *ast) { if (_type->isReferenceType()) translationUnit()->error(ast->firstToken(), "cannot declare pointer to a reference"); FullySpecifiedType type(control()->pointerType(_type)); for (SpecifierListAST *it = ast->cv_qualifier_list; it; it = it->next) { type = this->specifier(it->value, type); } _type = type; return false; } bool Bind::visit(ReferenceAST *ast) { const bool rvalueRef = (tokenKind(ast->reference_token) == T_AMPER_AMPER); if (_type->isReferenceType()) translationUnit()->error(ast->firstToken(), "cannot declare reference to a reference"); FullySpecifiedType type(control()->referenceType(_type, rvalueRef)); _type = type; return false; } // PostfixAST bool Bind::visit(CallAST *ast) { /*ExpressionTy base_expression =*/ this->expression(ast->base_expression); // unsigned lparen_token = ast->lparen_token; for (ExpressionListAST *it = ast->expression_list; it; it = it->next) { /*ExpressionTy value =*/ this->expression(it->value); } // unsigned rparen_token = ast->rparen_token; return false; } bool Bind::visit(ArrayAccessAST *ast) { /*ExpressionTy base_expression =*/ this->expression(ast->base_expression); // unsigned lbracket_token = ast->lbracket_token; /*ExpressionTy expression =*/ this->expression(ast->expression); // unsigned rbracket_token = ast->rbracket_token; return false; } bool Bind::visit(PostIncrDecrAST *ast) { ExpressionTy base_expression = this->expression(ast->base_expression); // unsigned incr_decr_token = ast->incr_decr_token; return false; } bool Bind::visit(MemberAccessAST *ast) { ExpressionTy base_expression = this->expression(ast->base_expression); // unsigned access_token = ast->access_token; // unsigned template_token = ast->template_token; /*const Name *member_name =*/ this->name(ast->member_name); return false; } // CoreDeclaratorAST bool Bind::visit(DeclaratorIdAST *ast) { /*const Name *name =*/ this->name(ast->name); *_declaratorId = ast; return false; } bool Bind::visit(NestedDeclaratorAST *ast) { _type = this->declarator(ast->declarator, _type, _declaratorId); return false; } // PostfixDeclaratorAST bool Bind::visit(FunctionDeclaratorAST *ast) { Function *fun = control()->newFunction(0, 0); fun->setStartOffset(tokenAt(ast->firstToken()).begin()); fun->setEndOffset(tokenAt(ast->lastToken() - 1).end()); fun->setReturnType(_type); // unsigned lparen_token = ast->lparen_token; this->parameterDeclarationClause(ast->parameter_declaration_clause, ast->lparen_token, fun); // unsigned rparen_token = ast->rparen_token; FullySpecifiedType type(fun); for (SpecifierListAST *it = ast->cv_qualifier_list; it; it = it->next) { type = this->specifier(it->value, type); } // propagate the cv-qualifiers fun->setConst(type.isConst()); fun->setVolatile(type.isVolatile()); this->exceptionSpecification(ast->exception_specification, type); this->trailingReturnType(ast->trailing_return_type, type); if (ast->as_cpp_initializer != 0) { fun->setAmbiguous(true); /*ExpressionTy as_cpp_initializer =*/ this->expression(ast->as_cpp_initializer); } ast->symbol = fun; _type = type; return false; } bool Bind::visit(ArrayDeclaratorAST *ast) { ExpressionTy expression = this->expression(ast->expression); FullySpecifiedType type(control()->arrayType(_type)); _type = type; return false; } int Bind::visibilityForAccessSpecifier(int tokenKind) { switch (tokenKind) { case T_PUBLIC: return Symbol::Public; case T_PROTECTED: return Symbol::Protected; case T_PRIVATE: return Symbol::Private; case T_Q_SIGNALS: return Symbol::Protected; default: return Symbol::Public; } } int Bind::visibilityForClassKey(int tokenKind) { switch (tokenKind) { case T_CLASS: return Symbol::Private; case T_STRUCT: case T_UNION: return Symbol::Public; default: return Symbol::Public; } } int Bind::visibilityForObjCAccessSpecifier(int tokenKind) { switch (tokenKind) { case T_AT_PUBLIC: return Symbol::Public; case T_AT_PROTECTED: return Symbol::Protected; case T_AT_PRIVATE: return Symbol::Private; case T_AT_PACKAGE: return Symbol::Package; default: return Symbol::Protected; } } bool Bind::isObjCClassMethod(int tokenKind) { switch (tokenKind) { case T_PLUS: return true; case T_MINUS: default: return false; } }