/* * Cppcheck - A tool for static C/C++ code analysis * Copyright (C) 2007-2018 Cppcheck team. * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ //--------------------------------------------------------------------------- #include "symboldatabase.h" #include "errorlogger.h" #include "platform.h" #include "settings.h" #include "token.h" #include "tokenize.h" #include "tokenlist.h" #include "utils.h" #include "valueflow.h" #include #include #include #include #include //--------------------------------------------------------------------------- SymbolDatabase::SymbolDatabase(const Tokenizer *tokenizer, const Settings *settings, ErrorLogger *errorLogger) : _tokenizer(tokenizer), _settings(settings), _errorLogger(errorLogger) { cpp = isCPP(); if (_settings->defaultSign == 's' || _settings->defaultSign == 'S') defaultSignedness = ValueType::SIGNED; else if (_settings->defaultSign == 'u' || _settings->defaultSign == 'U') defaultSignedness = ValueType::UNSIGNED; else defaultSignedness = ValueType::UNKNOWN_SIGN; createSymbolDatabaseFindAllScopes(); createSymbolDatabaseClassInfo(); createSymbolDatabaseVariableInfo(); createSymbolDatabaseCopyAndMoveConstructors(); createSymbolDatabaseFunctionScopes(); createSymbolDatabaseClassAndStructScopes(); createSymbolDatabaseFunctionReturnTypes(); createSymbolDatabaseNeedInitialization(); createSymbolDatabaseVariableSymbolTable(); createSymbolDatabaseSetScopePointers(); createSymbolDatabaseSetFunctionPointers(true); createSymbolDatabaseSetVariablePointers(); createSymbolDatabaseSetTypePointers(); createSymbolDatabaseEnums(); createSymbolDatabaseUnknownArrayDimensions(); } static const Token* skipScopeIdentifiers(const Token* tok) { if (tok && tok->str() == "::") { tok = tok->next(); } while (Token::Match(tok, "%name% ::") || (Token::Match(tok, "%name% <") && Token::simpleMatch(tok->linkAt(1), "> ::"))) { if (tok->strAt(1) == "::") tok = tok->tokAt(2); else tok = tok->linkAt(1)->tokAt(2); } return tok; } void SymbolDatabase::createSymbolDatabaseFindAllScopes() { // create global scope scopeList.emplace_back(this, nullptr, nullptr); // pointer to current scope Scope *scope = &scopeList.back(); // Store current access in each scope (depends on evaluation progress) std::map access; // find all scopes for (const Token *tok = _tokenizer->tokens(); tok; tok = tok ? tok->next() : nullptr) { // #5593 suggested to add here: if (_errorLogger) _errorLogger->reportProgress(_tokenizer->list.getSourceFilePath(), "SymbolDatabase", tok->progressValue()); // Locate next class if ((_tokenizer->isCPP() && ((Token::Match(tok, "class|struct|union|namespace ::| %name% {|:|::|<") && !Token::Match(tok->previous(), "new|friend|const|enum|typedef|mutable|volatile|)|(|<")) || (Token::Match(tok, "enum class| %name% {") || Token::Match(tok, "enum class| %name% : %name% {")))) || (_tokenizer->isC() && Token::Match(tok, "struct|union|enum %name% {"))) { const Token *tok2 = tok->tokAt(2); if (tok->strAt(1) == "::") tok2 = tok2->next(); else if (_tokenizer->isCPP() && tok->strAt(1) == "class") tok2 = tok2->next(); while (Token::Match(tok2, ":: %name%")) tok2 = tok2->tokAt(2); while (Token::Match(tok2, "%name% :: %name%")) tok2 = tok2->tokAt(2); // skip over template args while (tok2 && tok2->str() == "<" && tok2->link()) { tok2 = tok2->link()->next(); while (Token::Match(tok2, ":: %name%")) tok2 = tok2->tokAt(2); } // skip over final if (_tokenizer->isCPP() && Token::simpleMatch(tok2, "final")) tok2 = tok2->next(); // make sure we have valid code if (!Token::Match(tok2, "{|:")) { // check for qualified variable if (tok2 && tok2->next()) { if (tok2->next()->str() == ";") tok = tok2->next(); else if (Token::simpleMatch(tok2->next(), "= {") && Token::simpleMatch(tok2->linkAt(2), "} ;")) tok = tok2->linkAt(2)->next(); else if (Token::Match(tok2->next(), "(|{") && tok2->next()->link()->strAt(1) == ";") tok = tok2->next()->link()->next(); // skip variable declaration else if (Token::Match(tok2, "*|&|>")) continue; else if (Token::Match(tok2, "%name% (") && _tokenizer->isFunctionHead(tok2->next(), "{;")) continue; else if (Token::Match(tok2, "%name% [")) continue; // skip template else if (Token::simpleMatch(tok2, ";") && Token::Match(tok->previous(), "template|> class|struct")) { tok = tok2; continue; } // forward declaration else if (Token::simpleMatch(tok2, ";") && Token::Match(tok, "class|struct|union")) { // TODO: see if it can be used tok = tok2; continue; } // skip constructor else if (Token::simpleMatch(tok2, "(") && Token::simpleMatch(tok2->link(), ") ;")) { tok = tok2->link()->next(); continue; } else throw InternalError(tok2, "SymbolDatabase bailout; unhandled code", InternalError::SYNTAX); continue; } break; // bail } const Token * name = tok->next(); if (name->str() == "class" && name->strAt(-1) == "enum") name = name->next(); Scope *new_scope = findScope(name, scope); if (new_scope) { // only create base list for classes and structures if (new_scope->isClassOrStruct()) { // goto initial '{' if (!new_scope->definedType) _tokenizer->syntaxError(nullptr); // #6808 tok2 = new_scope->definedType->initBaseInfo(tok, tok2); // make sure we have valid code if (!tok2) { break; } } // definition may be different than declaration if (_tokenizer->isCPP() && tok->str() == "class") { access[new_scope] = Private; new_scope->type = Scope::eClass; } else if (tok->str() == "struct") { access[new_scope] = Public; new_scope->type = Scope::eStruct; } new_scope->classDef = tok; new_scope->bodyStart = tok2; new_scope->bodyEnd = tok2->link(); // make sure we have valid code if (!new_scope->bodyEnd) { _tokenizer->syntaxError(tok); } scope = new_scope; tok = tok2; } else { scopeList.emplace_back(this, tok, scope); new_scope = &scopeList.back(); if (tok->str() == "class") access[new_scope] = Private; else if (tok->str() == "struct" || tok->str() == "union") access[new_scope] = Public; // fill typeList... if (new_scope->isClassOrStructOrUnion() || new_scope->type == Scope::eEnum) { Type* new_type = findType(name, scope); if (!new_type) { typeList.emplace_back(new_scope->classDef, new_scope, scope); new_type = &typeList.back(); scope->definedTypesMap[new_type->name()] = new_type; } else new_type->classScope = new_scope; new_scope->definedType = new_type; } // only create base list for classes and structures if (new_scope->isClassOrStruct()) { // goto initial '{' tok2 = new_scope->definedType->initBaseInfo(tok, tok2); // make sure we have valid code if (!tok2) { _tokenizer->syntaxError(tok); } } else if (new_scope->type == Scope::eEnum) { if (tok2->str() == ":") tok2 = tok2->tokAt(2); } new_scope->bodyStart = tok2; new_scope->bodyEnd = tok2->link(); // make sure we have valid code if (!new_scope->bodyEnd) { _tokenizer->syntaxError(tok); } if (new_scope->type == Scope::eEnum) { tok2 = new_scope->addEnum(tok, _tokenizer->isCPP()); scope->nestedList.push_back(new_scope); if (!tok2) _tokenizer->syntaxError(tok); } else { // make the new scope the current scope scope->nestedList.push_back(new_scope); scope = new_scope; } tok = tok2; } } // Namespace and unknown macro (#3854) else if (_tokenizer->isCPP() && Token::Match(tok, "namespace %name% %type% (") && tok->tokAt(2)->isUpperCaseName() && Token::simpleMatch(tok->linkAt(3), ") {")) { scopeList.emplace_back(this, tok, scope); Scope *new_scope = &scopeList.back(); access[new_scope] = Public; const Token *tok2 = tok->linkAt(3)->next(); new_scope->bodyStart = tok2; new_scope->bodyEnd = tok2->link(); // make sure we have valid code if (!new_scope->bodyEnd) { scopeList.pop_back(); break; } // make the new scope the current scope scope->nestedList.push_back(new_scope); scope = &scopeList.back(); tok = tok2; } // forward declaration else if (Token::Match(tok, "class|struct|union %name% ;") && tok->strAt(-1) != "friend") { if (!findType(tok->next(), scope)) { // fill typeList.. typeList.emplace_back(tok, nullptr, scope); Type* new_type = &typeList.back(); scope->definedTypesMap[new_type->name()] = new_type; } tok = tok->tokAt(2); } // using namespace else if (_tokenizer->isCPP() && Token::Match(tok, "using namespace ::| %type% ;|::")) { Scope::UsingInfo using_info; using_info.start = tok; // save location using_info.scope = findNamespace(tok->tokAt(2), scope); scope->usingList.push_back(using_info); // check for global namespace if (tok->strAt(2) == "::") tok = tok->tokAt(4); else tok = tok->tokAt(3); // skip over qualification while (Token::Match(tok, "%type% ::")) tok = tok->tokAt(2); } // using type alias else if (_tokenizer->isCPP() && Token::Match(tok, "using %name% =")) { if (tok->strAt(-1) != ">" && !findType(tok->next(), scope)) { // fill typeList.. typeList.emplace_back(tok, nullptr, scope); Type* new_type = &typeList.back(); scope->definedTypesMap[new_type->name()] = new_type; } tok = tok->tokAt(3); while (tok && tok->str() != ";") tok = tok->next(); } // unnamed struct and union else if (Token::Match(tok, "struct|union {") && Token::Match(tok->next()->link(), "} *|&| %name% ;|[")) { scopeList.emplace_back(this, tok, scope); Scope *new_scope = &scopeList.back(); access[new_scope] = Public; const Token* varNameTok = tok->next()->link()->next(); if (varNameTok->str() == "*") { varNameTok = varNameTok->next(); } else if (varNameTok->str() == "&") { varNameTok = varNameTok->next(); } typeList.emplace_back(tok, new_scope, scope); { Type* new_type = &typeList.back(); new_scope->definedType = new_type; scope->definedTypesMap[new_type->name()] = new_type; } scope->addVariable(varNameTok, tok, tok, access[scope], new_scope->definedType, scope, &_settings->library); const Token *tok2 = tok->next(); new_scope->bodyStart = tok2; new_scope->bodyEnd = tok2->link(); // make sure we have valid code if (!new_scope->bodyEnd) { scopeList.pop_back(); break; } // make the new scope the current scope scope->nestedList.push_back(new_scope); scope = new_scope; tok = tok2; } // anonymous struct, union and namespace else if ((Token::Match(tok, "struct|union {") && Token::simpleMatch(tok->next()->link(), "} ;")) || Token::simpleMatch(tok, "namespace {")) { scopeList.emplace_back(this, tok, scope); Scope *new_scope = &scopeList.back(); access[new_scope] = Public; const Token *tok2 = tok->next(); new_scope->bodyStart = tok2; new_scope->bodyEnd = tok2->link(); typeList.emplace_back(tok, new_scope, scope); { Type* new_type = &typeList.back(); new_scope->definedType = new_type; scope->definedTypesMap[new_type->name()] = new_type; } // make sure we have valid code if (!new_scope->bodyEnd) { scopeList.pop_back(); break; } // make the new scope the current scope scope->nestedList.push_back(new_scope); scope = new_scope; tok = tok2; } // forward declared enum else if (Token::Match(tok, "enum class| %name% ;") || Token::Match(tok, "enum class| %name% : %name% ;")) { typeList.emplace_back(tok, nullptr, scope); Type* new_type = &typeList.back(); scope->definedTypesMap[new_type->name()] = new_type; tok = tok->tokAt(2); } // check for end of scope else if (tok == scope->bodyEnd) { access.erase(scope); scope = const_cast(scope->nestedIn); continue; } // check if in class or structure or union else if (scope->isClassOrStructOrUnion()) { const Token *funcStart = nullptr; const Token *argStart = nullptr; const Token *declEnd = nullptr; // What section are we in.. if (tok->str() == "private:") access[scope] = Private; else if (tok->str() == "protected:") access[scope] = Protected; else if (tok->str() == "public:" || tok->str() == "__published:") access[scope] = Public; else if (Token::Match(tok, "public|protected|private %name% :")) { if (tok->str() == "private") access[scope] = Private; else if (tok->str() == "protected") access[scope] = Protected; else access[scope] = Public; tok = tok->tokAt(2); } // class function? else if (isFunction(tok, scope, &funcStart, &argStart, &declEnd)) { if (tok->previous()->str() != "::" || tok->strAt(-2) == scope->className) { Function function(_tokenizer, tok, scope, funcStart, argStart); // save the access type function.access = access[scope]; const Token *end = function.argDef->link(); // count the number of constructors if (function.isConstructor()) scope->numConstructors++; // assume implementation is inline (definition and implementation same) function.token = function.tokenDef; function.arg = function.argDef; // out of line function if (const Token *endTok = _tokenizer->isFunctionHead(end, ";")) { tok = endTok; scope->addFunction(function); } // inline function else { // find start of function '{' bool foundInitList = false; while (end && end->str() != "{" && end->str() != ";") { if (end->link() && Token::Match(end, "(|<")) { end = end->link(); } else if (foundInitList && Token::Match(end, "%name%|> {") && Token::Match(end->linkAt(1), "} ,|{")) { end = end->linkAt(1); } else { if (end->str() == ":") foundInitList = true; end = end->next(); } } if (!end || end->str() == ";") continue; scope->addFunction(function); Function* funcptr = &scope->functionList.back(); const Token *tok2 = funcStart; addNewFunction(&scope, &tok2); if (scope) { scope->functionOf = function.nestedIn; scope->function = funcptr; scope->function->functionScope = scope; } tok = tok2; } } // nested class or friend function? else { /** @todo check entire qualification for match */ Scope * nested = scope->findInNestedListRecursive(tok->strAt(-2)); if (nested) addClassFunction(&scope, &tok, argStart); else { /** @todo handle friend functions */ } } } // friend class declaration? else if (_tokenizer->isCPP() && Token::Match(tok, "friend class| ::| %any% ;|::")) { Type::FriendInfo friendInfo; // save the name start friendInfo.nameStart = tok->strAt(1) == "class" ? tok->tokAt(2) : tok->next(); friendInfo.nameEnd = friendInfo.nameStart; // skip leading "::" if (friendInfo.nameEnd->str() == "::") friendInfo.nameEnd = friendInfo.nameEnd->next(); // skip qualification "name ::" while (friendInfo.nameEnd && friendInfo.nameEnd->strAt(1) == "::") friendInfo.nameEnd = friendInfo.nameEnd->tokAt(2); // fill this in after parsing is complete friendInfo.type = nullptr; if (!scope->definedType) _tokenizer->syntaxError(tok); scope->definedType->friendList.push_back(friendInfo); } } else if (scope->type == Scope::eNamespace || scope->type == Scope::eGlobal) { const Token *funcStart = nullptr; const Token *argStart = nullptr; const Token *declEnd = nullptr; // function? if (isFunction(tok, scope, &funcStart, &argStart, &declEnd)) { // has body? if (declEnd && declEnd->str() == "{") { tok = funcStart; // class function if (tok->previous() && tok->previous()->str() == "::") addClassFunction(&scope, &tok, argStart); // class destructor else if (tok->previous() && tok->previous()->str() == "~" && tok->strAt(-2) == "::") addClassFunction(&scope, &tok, argStart); // regular function else { Function* function = addGlobalFunction(scope, tok, argStart, funcStart); if (!function) _tokenizer->syntaxError(tok); } // syntax error? if (!scope) _tokenizer->syntaxError(tok); } // function prototype? else if (declEnd && declEnd->str() == ";") { bool newFunc = true; // Is this function already in the database? for (std::multimap::const_iterator i = scope->functionMap.find(tok->str()); i != scope->functionMap.end() && i->first == tok->str(); ++i) { if (Function::argsMatch(scope, i->second->argDef->next(), argStart->next(), emptyString, 0)) { newFunc = false; break; } } // save function prototype in database if (newFunc) { addGlobalFunctionDecl(scope, tok, argStart, funcStart); } tok = declEnd; continue; } } } else if (scope->isExecutable()) { if (Token::Match(tok, "else|try|do {")) { const Token* tok1 = tok->next(); if (tok->str() == "else") scopeList.emplace_back(this, tok, scope, Scope::eElse, tok1); else if (tok->str() == "do") scopeList.emplace_back(this, tok, scope, Scope::eDo, tok1); else //if (tok->str() == "try") scopeList.emplace_back(this, tok, scope, Scope::eTry, tok1); tok = tok1; scope->nestedList.push_back(&scopeList.back()); scope = &scopeList.back(); } else if (Token::Match(tok, "if|for|while|catch|switch (") && Token::simpleMatch(tok->next()->link(), ") {")) { const Token *scopeStartTok = tok->next()->link()->next(); if (tok->str() == "if") scopeList.emplace_back(this, tok, scope, Scope::eIf, scopeStartTok); else if (tok->str() == "for") { scopeList.emplace_back(this, tok, scope, Scope::eFor, scopeStartTok); } else if (tok->str() == "while") scopeList.emplace_back(this, tok, scope, Scope::eWhile, scopeStartTok); else if (tok->str() == "catch") { scopeList.emplace_back(this, tok, scope, Scope::eCatch, scopeStartTok); } else // if (tok->str() == "switch") scopeList.emplace_back(this, tok, scope, Scope::eSwitch, scopeStartTok); scope->nestedList.push_back(&scopeList.back()); scope = &scopeList.back(); if (scope->type == Scope::eFor) scope->checkVariable(tok->tokAt(2), Local, &_settings->library); // check for variable declaration and add it to new scope if found else if (scope->type == Scope::eCatch) scope->checkVariable(tok->tokAt(2), Throw, &_settings->library); // check for variable declaration and add it to new scope if found tok = scopeStartTok; } else if (tok->str() == "{") { if (tok->previous()->varId()) tok = tok->link(); else { const Token* tok2 = tok->previous(); while (!Token::Match(tok2, ";|}|{|)")) tok2 = tok2->previous(); if (tok2->next() != tok && tok2->strAt(1) != ".") tok2 = nullptr; // No lambda if (tok2 && tok2->str() == ")" && tok2->link()->strAt(-1) == "]") { scopeList.emplace_back(this, tok2->link()->linkAt(-1), scope, Scope::eLambda, tok); scope->nestedList.push_back(&scopeList.back()); scope = &scopeList.back(); } else if (!Token::Match(tok->previous(), "=|,|(|return") && !(tok->strAt(-1) == ")" && Token::Match(tok->linkAt(-1)->previous(), "=|,|(|return"))) { scopeList.emplace_back(this, tok, scope, Scope::eUnconditional, tok); scope->nestedList.push_back(&scopeList.back()); scope = &scopeList.back(); } else { tok = tok->link(); } } } } } } void SymbolDatabase::createSymbolDatabaseClassInfo() { if (_tokenizer->isC()) return; // fill in using info for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { for (std::list::iterator i = it->usingList.begin(); i != it->usingList.end(); ++i) { // only find if not already found if (i->scope == nullptr) { // check scope for match Scope *scope = findScope(i->start->tokAt(2), &(*it)); if (scope) { // set found scope i->scope = scope; break; } } } } // fill in base class info for (std::list::iterator it = typeList.begin(); it != typeList.end(); ++it) { // finish filling in base class info for (unsigned int i = 0; i < it->derivedFrom.size(); ++i) { const Type* found = findType(it->derivedFrom[i].nameTok, it->enclosingScope); if (found && found->findDependency(&(*it))) { // circular dependency //_tokenizer->syntaxError(nullptr); } else { it->derivedFrom[i].type = found; } } } // fill in friend info for (std::list::iterator it = typeList.begin(); it != typeList.end(); ++it) { for (std::vector::iterator i = it->friendList.begin(); i != it->friendList.end(); ++i) { i->type = findType(i->nameStart, it->enclosingScope); } } } void SymbolDatabase::createSymbolDatabaseVariableInfo() { // fill in variable info for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { // find variables it->getVariableList(&_settings->library); } // fill in function arguments for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { std::list::iterator func; for (func = it->functionList.begin(); func != it->functionList.end(); ++func) { // add arguments func->addArguments(this, &*it); } } } void SymbolDatabase::createSymbolDatabaseCopyAndMoveConstructors() { // fill in class and struct copy/move constructors for (std::list::iterator scope = scopeList.begin(); scope != scopeList.end(); ++scope) { if (!scope->isClassOrStruct()) continue; std::list::iterator func; for (func = scope->functionList.begin(); func != scope->functionList.end(); ++func) { if (!func->isConstructor() || func->minArgCount() != 1) continue; const Variable* firstArg = func->getArgumentVar(0); if (firstArg->type() == scope->definedType) { if (firstArg->isRValueReference()) func->type = Function::eMoveConstructor; else if (firstArg->isReference() && !firstArg->isPointer()) func->type = Function::eCopyConstructor; } if (func->type == Function::eCopyConstructor || func->type == Function::eMoveConstructor) scope->numCopyOrMoveConstructors++; } } } void SymbolDatabase::createSymbolDatabaseFunctionScopes() { // fill in function scopes for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { if (it->type == Scope::eFunction) functionScopes.push_back(&*it); } } void SymbolDatabase::createSymbolDatabaseClassAndStructScopes() { // fill in class and struct scopes for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { if (it->isClassOrStruct()) classAndStructScopes.push_back(&*it); } } void SymbolDatabase::createSymbolDatabaseFunctionReturnTypes() { // fill in function return types for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { std::list::iterator func; for (func = it->functionList.begin(); func != it->functionList.end(); ++func) { // add return types if (func->retDef) { const Token *type = func->retDef; while (Token::Match(type, "static|const|struct|union|enum")) type = type->next(); if (type) { func->retType = findVariableTypeInBase(&*it, type); if (!func->retType) func->retType = findTypeInNested(type, func->nestedIn); } } } } } void SymbolDatabase::createSymbolDatabaseNeedInitialization() { if (_tokenizer->isC()) { // For C code it is easy, as there are no constructors and no default values for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { Scope *scope = &(*it); if (scope->definedType) scope->definedType->needInitialization = Type::True; } } else { // For C++, it is more difficult: Determine if user defined type needs initialization... unsigned int unknowns = 0; // stop checking when there are no unknowns unsigned int retry = 0; // bail if we don't resolve all the variable types for some reason do { unknowns = 0; for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { Scope *scope = &(*it); if (!scope->definedType) { _blankTypes.push_back(Type()); scope->definedType = &_blankTypes.back(); } if (scope->isClassOrStruct() && scope->definedType->needInitialization == Type::Unknown) { // check for default constructor bool hasDefaultConstructor = false; std::list::const_iterator func; for (func = scope->functionList.begin(); func != scope->functionList.end(); ++func) { if (func->type == Function::eConstructor) { // check for no arguments: func ( ) if (func->argCount() == 0) { hasDefaultConstructor = true; break; } /** check for arguments with default values */ else if (func->argCount() == func->initializedArgCount()) { hasDefaultConstructor = true; break; } } } // User defined types with user defined default constructor doesn't need initialization. // We assume the default constructor initializes everything. // Another check will figure out if the constructor actually initializes everything. if (hasDefaultConstructor) scope->definedType->needInitialization = Type::False; // check each member variable to see if it needs initialization else { bool needInitialization = false; bool unknown = false; std::list::const_iterator var; for (var = scope->varlist.begin(); var != scope->varlist.end() && !needInitialization; ++var) { if (var->isClass()) { if (var->type()) { // does this type need initialization? if (var->type()->needInitialization == Type::True) needInitialization = true; else if (var->type()->needInitialization == Type::Unknown) unknown = true; } } else if (!var->hasDefault()) needInitialization = true; } if (needInitialization) scope->definedType->needInitialization = Type::True; else if (!unknown) scope->definedType->needInitialization = Type::False; else { if (scope->definedType->needInitialization == Type::Unknown) unknowns++; } } } else if (scope->type == Scope::eUnion && scope->definedType->needInitialization == Type::Unknown) scope->definedType->needInitialization = Type::True; } retry++; } while (unknowns && retry < 100); // this shouldn't happen so output a debug warning if (retry == 100 && _settings->debugwarnings) { for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { const Scope *scope = &(*it); if (scope->isClassOrStruct() && scope->definedType->needInitialization == Type::Unknown) debugMessage(scope->classDef, "SymbolDatabase::SymbolDatabase couldn't resolve all user defined types."); } } } } void SymbolDatabase::createSymbolDatabaseVariableSymbolTable() { // create variable symbol table _variableList.resize(_tokenizer->varIdCount() + 1); std::fill_n(_variableList.begin(), _variableList.size(), (const Variable*)nullptr); // check all scopes for variables for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { Scope *scope = &(*it); // add all variables for (std::list::iterator var = scope->varlist.begin(); var != scope->varlist.end(); ++var) { unsigned int varId = var->declarationId(); if (varId) _variableList[varId] = &(*var); // fix up variables without type if (!var->type() && !var->typeStartToken()->isStandardType()) { const Type *type = findType(var->typeStartToken(), scope); if (type) var->type(type); } } // add all function parameters for (std::list::iterator func = scope->functionList.begin(); func != scope->functionList.end(); ++func) { for (std::list::iterator arg = func->argumentList.begin(); arg != func->argumentList.end(); ++arg) { // check for named parameters if (arg->nameToken() && arg->declarationId()) { const unsigned int declarationId = arg->declarationId(); if (declarationId > 0U) _variableList[declarationId] = &(*arg); // fix up parameters without type if (!arg->type() && !arg->typeStartToken()->isStandardType()) { const Type *type = findTypeInNested(arg->typeStartToken(), scope); if (type) arg->type(type); } } } } } // fill in missing variables if possible const std::size_t functions = functionScopes.size(); for (std::size_t i = 0; i < functions; ++i) { const Scope *func = functionScopes[i]; for (const Token *tok = func->bodyStart->next(); tok && tok != func->bodyEnd; tok = tok->next()) { // check for member variable if (tok->varId() && tok->next() && (tok->next()->str() == "." || (tok->next()->str() == "[" && tok->linkAt(1)->strAt(1) == "."))) { const Token *tok1 = tok->next()->str() == "." ? tok->tokAt(2) : tok->linkAt(1)->tokAt(2); if (tok1 && tok1->varId() && _variableList[tok1->varId()] == 0) { const Variable *var = _variableList[tok->varId()]; if (var && var->typeScope()) { // find the member variable of this variable const Variable *var1 = var->typeScope()->getVariable(tok1->str()); if (var1) { // add this variable to the look up table _variableList[tok1->varId()] = var1; } } } } } } } void SymbolDatabase::createSymbolDatabaseSetScopePointers() { // Set scope pointers for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { Token* start = const_cast(it->bodyStart); Token* end = const_cast(it->bodyEnd); if (it->type == Scope::eGlobal) { start = const_cast(_tokenizer->list.front()); end = const_cast(_tokenizer->list.back()); } assert(start && end); end->scope(&*it); for (Token* tok = start; tok != end; tok = tok->next()) { if (start != end && tok->str() == "{") { bool isEndOfScope = false; for (std::list::const_iterator innerScope = it->nestedList.begin(); innerScope != it->nestedList.end(); ++innerScope) { if (tok == (*innerScope)->bodyStart) { // Is begin of inner scope tok = tok->link(); if (tok->next() == end || !tok->next()) { isEndOfScope = true; break; } tok = tok->next(); break; } } if (isEndOfScope) break; } tok->scope(&*it); } } } void SymbolDatabase::createSymbolDatabaseSetFunctionPointers(bool firstPass) { if (firstPass) { // Set function definition and declaration pointers for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { for (std::list::const_iterator func = it->functionList.begin(); func != it->functionList.end(); ++func) { if (func->tokenDef) const_cast(func->tokenDef)->function(&*func); if (func->token) const_cast(func->token)->function(&*func); } } } // Set function call pointers for (const Token* tok = _tokenizer->list.front(); tok != _tokenizer->list.back(); tok = tok->next()) { if (!tok->function() && tok->varId() == 0 && Token::Match(tok, "%name% (") && !isReservedName(tok->str())) { const Function *function = findFunction(tok); if (function) const_cast(tok)->function(function); } } // Set C++ 11 delegate constructor function call pointers for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { for (std::list::const_iterator func = it->functionList.begin(); func != it->functionList.end(); ++func) { // look for initializer list if (func->isConstructor() && func->functionScope && func->functionScope->functionOf && func->arg) { const Token * tok = func->arg->link()->next(); if (tok->str() == "noexcept") { const Token * closingParenTok = tok->linkAt(1); if (!closingParenTok || !closingParenTok->next()) { continue; } tok = closingParenTok->next(); } if (tok->str() != ":") { continue; } tok = tok->next(); while (tok && tok != func->functionScope->bodyStart) { if (Token::Match(tok, "%name% {|(")) { if (tok->str() == func->tokenDef->str()) { const Function *function = func->functionScope->functionOf->findFunction(tok); if (function) const_cast(tok)->function(function); break; } tok = tok->linkAt(1); } tok = tok->next(); } } } } } void SymbolDatabase::createSymbolDatabaseSetTypePointers() { std::set typenames; for (const Type &t : typeList) { typenames.insert(t.name()); } // Set type pointers for (const Token* tok = _tokenizer->list.front(); tok != _tokenizer->list.back(); tok = tok->next()) { if (!tok->isName() || tok->varId() || tok->function() || tok->type() || tok->enumerator()) continue; if (typenames.find(tok->str()) == typenames.end()) continue; const Type *type = findVariableType(tok->scope(), tok); if (type) const_cast(tok)->type(type); } } void SymbolDatabase::fixVarId(VarIdMap & varIds, const Token * vartok, Token * membertok, const Variable * membervar) { VarIdMap::iterator varId = varIds.find(vartok->varId()); if (varId == varIds.end()) { MemberIdMap memberId; if (membertok->varId() == 0) { memberId[membervar->nameToken()->varId()] = const_cast(_tokenizer)->newVarId(); _variableList.push_back(membervar); } else _variableList[membertok->varId()] = membervar; varIds.insert(std::make_pair(vartok->varId(), memberId)); varId = varIds.find(vartok->varId()); } MemberIdMap::iterator memberId = varId->second.find(membervar->nameToken()->varId()); if (memberId == varId->second.end()) { if (membertok->varId() == 0) { varId->second.insert(std::make_pair(membervar->nameToken()->varId(), const_cast(_tokenizer)->newVarId())); _variableList.push_back(membervar); memberId = varId->second.find(membervar->nameToken()->varId()); } else _variableList[membertok->varId()] = membervar; } if (membertok->varId() == 0) membertok->varId(memberId->second); } void SymbolDatabase::createSymbolDatabaseSetVariablePointers() { VarIdMap varIds; // Set variable pointers for (const Token* tok = _tokenizer->list.front(); tok != _tokenizer->list.back(); tok = tok->next()) { if (tok->varId()) const_cast(tok)->variable(getVariableFromVarId(tok->varId())); // Set Token::variable pointer for array member variable // Since it doesn't point at a fixed location it doesn't have varid if (tok->variable() != nullptr && (tok->variable()->typeScope() || (tok->valueType() && tok->valueType()->type == ValueType::CONTAINER)) && Token::Match(tok, "%name% [|.")) { Token *tok2 = tok->next(); // Locate "]" while (tok2 && tok2->str() == "[") tok2 = tok2->link()->next(); Token *membertok = nullptr; if (Token::Match(tok2, ". %name%")) membertok = tok2->next(); else if (Token::Match(tok2, ") . %name%") && tok->strAt(-1) == "(") membertok = tok2->tokAt(2); if (membertok) { const Variable *var = tok->variable(); if (var && var->typeScope()) { const Variable *membervar = var->typeScope()->getVariable(membertok->str()); if (membervar) { membertok->variable(membervar); if (membertok->varId() == 0 || _variableList[membertok->varId()] == nullptr) fixVarId(varIds, tok, const_cast(membertok), membervar); } } else if (var && tok->valueType() && tok->valueType()->type == ValueType::CONTAINER) { if (Token::Match(var->typeStartToken(), "std :: %type% < %type% *| *| >")) { const Type * type = var->typeStartToken()->tokAt(4)->type(); if (type && type->classScope && type->classScope->definedType) { const Variable *membervar = type->classScope->getVariable(membertok->str()); if (membervar) { membertok->variable(membervar); if (membertok->varId() == 0 || _variableList[membertok->varId()] == nullptr) fixVarId(varIds, tok, const_cast(membertok), membervar); } } } } } } // check for function returning record type // func(...).var // func(...)[...].var else if (tok->function() && tok->next()->str() == "(" && (Token::Match(tok->next()->link(), ") . %name% !!(") || (Token::Match(tok->next()->link(), ") [") && Token::Match(tok->next()->link()->next()->link(), "] . %name% !!(")))) { const Type *type = tok->function()->retType; if (type) { Token *membertok; if (tok->next()->link()->next()->str() == ".") membertok = tok->next()->link()->next()->next(); else membertok = tok->next()->link()->next()->link()->next()->next(); const Variable *membervar = membertok->variable(); if (!membervar) { if (type->classScope) { membervar = type->classScope->getVariable(membertok->str()); if (membervar) { membertok->variable(membervar); if (membertok->varId() == 0 || _variableList[membertok->varId()] == nullptr) { if (tok->function()->retDef) fixVarId(varIds, tok->function()->retDef, const_cast(membertok), membervar); } } } } } } } } void SymbolDatabase::createSymbolDatabaseEnums() { // fill in enumerators in enum for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { if (it->type != Scope::eEnum) continue; // add enumerators to enumerator tokens for (std::size_t i = 0, end = it->enumeratorList.size(); i < end; ++i) const_cast(it->enumeratorList[i].name)->enumerator(&it->enumeratorList[i]); } // fill in enumerator values for (std::list::iterator it = scopeList.begin(); it != scopeList.end(); ++it) { if (it->type != Scope::eEnum) continue; MathLib::bigint value = 0; for (std::size_t i = 0, end = it->enumeratorList.size(); i < end; ++i) { Enumerator & enumerator = it->enumeratorList[i]; // look for initialization tokens that can be converted to enumerators and convert them if (enumerator.start) { if (!enumerator.end) _tokenizer->syntaxError(enumerator.start); for (const Token * tok3 = enumerator.start; tok3 && tok3 != enumerator.end->next(); tok3 = tok3->next()) { if (tok3->tokType() == Token::eName) { const Enumerator * e = findEnumerator(tok3); if (e) const_cast(tok3)->enumerator(e); } } // look for possible constant folding expressions // rhs of operator: const Token *rhs = enumerator.start->previous()->astOperand2(); // constant folding of expression: ValueFlow::valueFlowConstantFoldAST(rhs, _settings); // get constant folded value: if (rhs && rhs->values().size() == 1U && rhs->values().front().isKnown()) { enumerator.value = rhs->values().front().intvalue; enumerator.value_known = true; value = enumerator.value + 1; } } // not initialized so use default value else { enumerator.value = value++; enumerator.value_known = true; } } } // find enumerators for (const Token* tok = _tokenizer->list.front(); tok != _tokenizer->list.back(); tok = tok->next()) { if (tok->tokType() != Token::eName) continue; const Enumerator * enumerator = findEnumerator(tok); if (enumerator) const_cast(tok)->enumerator(enumerator); } } void SymbolDatabase::createSymbolDatabaseUnknownArrayDimensions() { // set all unknown array dimensions for (std::size_t i = 1; i <= _tokenizer->varIdCount(); i++) { // check each array variable if (_variableList[i] && _variableList[i]->isArray()) { // check each array dimension const std::vector& dimensions = _variableList[i]->dimensions(); for (std::size_t j = 0; j < dimensions.size(); j++) { Dimension &dimension = const_cast(dimensions[j]); if (dimension.num == 0) { dimension.known = false; // check for a single token dimension if (dimension.start && (dimension.start == dimension.end)) { // check for an enumerator if (dimension.start->enumerator()) { if (dimension.start->enumerator()->value_known) { dimension.num = dimension.start->enumerator()->value; dimension.known = true; } } // check for a variable else if (dimension.start->varId()) { // get maximum size from type // find where this type is defined const Variable *var = getVariableFromVarId(dimension.start->varId()); // make sure it is in the database if (!var) break; // get type token const Token *index_type = var->typeEndToken(); if (index_type->str() == "char") { if (index_type->isUnsigned()) dimension.num = UCHAR_MAX + 1; else if (index_type->isSigned()) dimension.num = SCHAR_MAX + 1; else dimension.num = CHAR_MAX + 1; } else if (index_type->str() == "short") { if (index_type->isUnsigned()) dimension.num = USHRT_MAX + 1; else dimension.num = SHRT_MAX + 1; } // checkScope assumes size is signed int so we limit the following sizes to INT_MAX else if (index_type->str() == "int") { if (index_type->isUnsigned()) dimension.num = UINT_MAX + 1ULL; else dimension.num = INT_MAX + 1ULL; } else if (index_type->str() == "long") { if (index_type->isUnsigned()) { if (index_type->isLong()) dimension.num = ULLONG_MAX; // should be ULLONG_MAX + 1ULL else dimension.num = ULONG_MAX; // should be ULONG_MAX + 1ULL } else { if (index_type->isLong()) dimension.num = LLONG_MAX; // should be LLONG_MAX + 1LL else dimension.num = LONG_MAX; // should be LONG_MAX + 1LL } } } } // check for qualified enumerator else if (dimension.start) { // rhs of [ const Token *rhs = dimension.start->previous()->astOperand2(); // constant folding of expression: ValueFlow::valueFlowConstantFoldAST(rhs, _settings); // get constant folded value: if (rhs && rhs->values().size() == 1U && rhs->values().front().isKnown()) { dimension.num = rhs->values().front().intvalue; dimension.known = true; } } } } } } } SymbolDatabase::~SymbolDatabase() { // Clear scope, type, function and variable pointers for (const Token* tok = _tokenizer->list.front(); tok; tok = tok->next()) { const_cast(tok)->scope(nullptr); const_cast(tok)->type(nullptr); const_cast(tok)->function(nullptr); const_cast(tok)->variable(nullptr); const_cast(tok)->enumerator(nullptr); const_cast(tok)->setValueType(nullptr); } } bool SymbolDatabase::isFunction(const Token *tok, const Scope* outerScope, const Token **funcStart, const Token **argStart, const Token** declEnd) const { if (tok->varId()) return false; // function returning function pointer? '... ( ... %name% ( ... ))( ... ) {' // function returning reference to array '... ( & %name% ( ... ))[ ... ] {' // TODO: Activate this again if (false && tok->str() == "(" && tok->strAt(1) != "*" && (tok->link()->previous()->str() == ")" || Token::simpleMatch(tok->link()->tokAt(-2), ") const"))) { const Token* tok2 = tok->link()->next(); if (tok2 && tok2->str() == "(" && Token::Match(tok2->link()->next(), "{|;|const|=")) { const Token* argStartTok; if (tok->link()->previous()->str() == "const") argStartTok = tok->link()->linkAt(-2); else argStartTok = tok->link()->linkAt(-1); *funcStart = argStartTok->previous(); *argStart = argStartTok; *declEnd = Token::findmatch(tok2->link()->next(), "{|;"); return true; } else if (tok2 && tok2->str() == "[") { while (tok2 && tok2->str() == "[") tok2 = tok2->link()->next(); if (Token::Match(tok2, "{|;|const|=")) { const Token* argStartTok; if (tok->link()->previous()->str() == "const") argStartTok = tok->link()->linkAt(-2); else argStartTok = tok->link()->linkAt(-1); *funcStart = argStartTok->previous(); *argStart = argStartTok; *declEnd = Token::findmatch(tok2, "{|;"); return true; } } } // regular function? else if (Token::Match(tok, "%name% (") && !isReservedName(tok->str()) && tok->previous() && (Token::Match(tok->previous(), "%name%|>|&|*|::|~") || // Either a return type or scope qualifier in front of tok outerScope->isClassOrStructOrUnion())) { // or a ctor/dtor const Token* tok1 = tok->previous(); const Token* tok2 = tok->next()->link()->next(); if (!_tokenizer->isFunctionHead(tok->next(), ";:{")) return false; // skip over destructor "~" if (tok1->str() == "~") tok1 = tok1->previous(); // skip over qualification while (Token::simpleMatch(tok1, "::")) { tok1 = tok1->previous(); if (Token::Match(tok1, "%name%")) tok1 = tok1->previous(); else if (tok1 && tok1->str() == ">" && tok1->link() && Token::Match(tok1->link()->previous(), "%name%")) tok1 = tok1->link()->tokAt(-2); } // skip over const, noexcept, throw, override, final and volatile specifiers while (Token::Match(tok2, "const|noexcept|throw|override|final|volatile")) { tok2 = tok2->next(); if (tok2 && tok2->str() == "(") tok2 = tok2->link()->next(); } if (tok2 && tok2->str() == ".") { for (tok2 = tok2->next(); tok2; tok2 = tok2->next()) { if (Token::Match(tok2, ";|{|=")) break; if (tok2->link() && Token::Match(tok2, "<|[|(")) tok2 = tok2->link(); } } // done if constructor or destructor if (!Token::Match(tok1, "{|}|;|public:|protected:|private:") && tok1) { // skip over pointers and references while (Token::Match(tok1, "%type%|*|&") && !endsWith(tok1->str(), ':') && (!isReservedName(tok1->str()) || tok1->str() == "const")) tok1 = tok1->previous(); // skip over template if (tok1 && tok1->str() == ">") { if (tok1->link()) tok1 = tok1->link()->previous(); else return false; } // function can't have number or variable as return type if (tok1 && (tok1->isNumber() || tok1->varId())) return false; // skip over return type if (Token::Match(tok1, "%name%")) { if (tok1->str() == "return") return false; tok1 = tok1->previous(); } // skip over qualification while (Token::simpleMatch(tok1, "::")) { tok1 = tok1->previous(); if (Token::Match(tok1, "%name%")) tok1 = tok1->previous(); else if (tok1 && tok1->str() == ">" && tok1->link() && Token::Match(tok1->link()->previous(), "%name%")) tok1 = tok1->link()->tokAt(-2); } // skip over modifiers and other stuff while (Token::Match(tok1, "const|static|extern|template|virtual|struct|class|enum|%name%")) { // friend type func(); is not a function if (isCPP() && tok1->str() == "friend" && tok2->str() == ";") return false; tok1 = tok1->previous(); } // should be at a sequence point if this is a function if (!Token::Match(tok1, ">|{|}|;|public:|protected:|private:") && tok1) return false; } if (tok2 && (Token::Match(tok2, ";|{|=") || (tok2->isUpperCaseName() && Token::Match(tok2, "%name% ;|{")) || (tok2->isUpperCaseName() && Token::Match(tok2, "%name% (") && tok2->next()->link()->strAt(1) == "{") || Token::Match(tok2, ": ::| %name% (|::|<|{") || Token::Match(tok2, "&|&&| ;|{") || Token::Match(tok2, "= delete|default ;"))) { *funcStart = tok; *argStart = tok->next(); *declEnd = Token::findmatch(tok2, "{|;"); return true; } } // UNKNOWN_MACRO(a,b) { ... } else if (outerScope->type == Scope::eGlobal && Token::Match(tok, "%name% (") && tok->isUpperCaseName() && Token::simpleMatch(tok->linkAt(1), ") {") && (!tok->previous() || Token::Match(tok->previous(), "[;{}]"))) { *funcStart = tok; *argStart = tok->next(); *declEnd = tok->linkAt(1)->next(); return true; } // template constructor? else if (Token::Match(tok, "%name% <") && Token::simpleMatch(tok->next()->link(), "> (")) { const Token* tok2 = tok->next()->link()->next()->link(); if (Token::Match(tok2, ") const| ;|{|=") || Token::Match(tok2, ") : ::| %name% (|::|<|{") || Token::Match(tok2, ") const| noexcept {|;|(")) { *funcStart = tok; *argStart = tok2->link(); *declEnd = Token::findmatch(tok2->next(), "{|;"); return true; } } // regular C function with missing return or invalid C++ ? else if (Token::Match(tok, "%name% (") && !isReservedName(tok->str()) && Token::simpleMatch(tok->linkAt(1), ") {") && (!tok->previous() || Token::Match(tok->previous(), ";|}"))) { if (_tokenizer->isC()) { debugMessage(tok, "SymbolDatabase::isFunction found C function '" + tok->str() + "' without a return type."); *funcStart = tok; *argStart = tok->next(); *declEnd = tok->linkAt(1)->next(); return true; } _tokenizer->syntaxError(tok); } return false; } void SymbolDatabase::validateExecutableScopes() const { const std::size_t functions = functionScopes.size(); for (std::size_t i = 0; i < functions; ++i) { const Scope* const scope = functionScopes[i]; const Function* const function = scope->function; if (scope->isExecutable() && !function) { const std::list callstack(1, scope->classDef); const std::string msg = std::string("Executable scope '") + scope->classDef->str() + "' with unknown function."; const ErrorLogger::ErrorMessage errmsg(callstack, &_tokenizer->list, Severity::debug, "symbolDatabaseWarning", msg, false); _errorLogger->reportErr(errmsg); } } } namespace { const Function* getFunctionForArgumentvariable(const Variable * const var, const std::vector& functionScopes) { const std::size_t functions = functionScopes.size(); for (std::size_t i = 0; i < functions; ++i) { const Scope* const scope = functionScopes[i]; const Function* const function = scope->function; if (function) { for (std::size_t arg=0; arg < function->argCount(); ++arg) { if (var==function->getArgumentVar(arg)) return function; } } } return nullptr; } } void SymbolDatabase::validateVariables() const { for (std::vector::const_iterator iter = _variableList.begin(); iter!=_variableList.end(); ++iter) { const Variable * const var = *iter; if (var) { if (!var->scope()) { const Function* function = getFunctionForArgumentvariable(var, functionScopes); if (!var->isArgument() || (function && function->hasBody())) { throw InternalError(var->nameToken(), "Analysis failed (variable without scope). If the code is valid then please report this failure.", InternalError::INTERNAL); //std::cout << "!!!Variable found without scope: " << var->nameToken()->str() << std::endl; } } } } } void SymbolDatabase::validate() const { if (_settings->debugwarnings) { validateExecutableScopes(); } //validateVariables(); } bool Variable::isPointerArray() const { return isArray() && nameToken() && nameToken()->previous() && (nameToken()->previous()->str() == "*"); } const Token * Variable::declEndToken() const { Token const * declEnd = typeStartToken(); while (declEnd && !Token::Match(declEnd, "[;,)={]")) { if (declEnd->link() && Token::Match(declEnd,"(|[")) declEnd = declEnd->link(); declEnd = declEnd->next(); } return declEnd; } void Variable::evaluate(const Library* lib) { unsigned int pointer = 0; _constness = 0; if (_name) setFlag(fIsArray, arrayDimensions(lib)); const Token* tok = _start; while (tok && tok->previous() && tok->previous()->isName()) tok = tok->previous(); const Token* end = _end; if (end) end = end->next(); while (tok != end) { if (tok->str() == "static") setFlag(fIsStatic, true); else if (tok->str() == "extern") setFlag(fIsExtern, true); else if (tok->str() == "volatile") setFlag(fIsVolatile, true); else if (tok->str() == "mutable") setFlag(fIsMutable, true); else if (tok->str() == "const") { setFlag(fIsConst, true); _constness |= 1 << pointer; } else if (tok->str() == "*") { setFlag(fIsPointer, !isArray() || Token::Match(tok->previous(), "( * %name% )")); setFlag(fIsConst, false); // Points to const, isn't necessarily const itself ++pointer; } else if (tok->str() == "&") { if (isReference()) setFlag(fIsRValueRef, true); setFlag(fIsReference, true); } else if (tok->str() == "&&") { // Before simplification, && isn't split up setFlag(fIsRValueRef, true); setFlag(fIsReference, true); // Set also fIsReference } if (tok->str() == "<" && tok->link()) tok = tok->link(); else tok = tok->next(); } while (Token::Match(_start, "static|const|volatile %any%")) _start = _start->next(); while (_end && _end->previous() && Token::Match(_end, "const|volatile")) _end = _end->previous(); if (_start) { std::string strtype = _start->str(); for (const Token *typeToken = _start; Token::Match(typeToken, "%type% :: %type%"); typeToken = typeToken->tokAt(2)) strtype += "::" + typeToken->strAt(2); setFlag(fIsClass, !lib->podtype(strtype) && !_start->isStandardType() && !isPointer() && !isReference()); setFlag(fIsStlType, Token::simpleMatch(_start, "std ::")); setFlag(fIsStlString, isStlType() && (Token::Match(_start->tokAt(2), "string|wstring|u16string|u32string !!::") || (Token::simpleMatch(_start->tokAt(2), "basic_string <") && !Token::simpleMatch(_start->linkAt(3), "> ::")))); } if (_access == Argument) { tok = _name; if (!tok) { // Argument without name tok = _end; // back up to start of array dimensions while (tok && tok->str() == "]") tok = tok->link()->previous(); // add array dimensions if present if (tok && tok->next()->str() == "[") setFlag(fIsArray, arrayDimensions(lib)); } if (!tok) return; tok = tok->next(); while (tok->str() == "[") tok = tok->link(); setFlag(fHasDefault, tok->str() == "="); } // check for C++11 member initialization if (_scope && _scope->isClassOrStruct()) { // type var = x or // type var = {x} // type var = x; gets simplified to: type var ; var = x ; Token const * declEnd = declEndToken(); if ((Token::Match(declEnd, "; %name% =") && declEnd->strAt(1) == _name->str()) || Token::Match(declEnd, "=|{")) setFlag(fHasDefault, true); } if (_start) { if (Token::Match(_start, "float|double")) setFlag(fIsFloatType, true); } } Function::Function(const Tokenizer *_tokenizer, const Token *tok, const Scope *scope, const Token *tokDef, const Token *tokArgDef) : tokenDef(tokDef), argDef(tokArgDef), token(nullptr), arg(nullptr), retDef(nullptr), retType(nullptr), functionScope(nullptr), nestedIn(scope), initArgCount(0), type(eFunction), access(Public), noexceptArg(nullptr), throwArg(nullptr), flags(0) { // operator function if (tokenDef->isOperatorKeyword()) { isOperator(true); // 'operator =' is special if (tokenDef->str() == "operator=") type = Function::eOperatorEqual; } // class constructor/destructor else if (tokenDef->str() == scope->className) { // destructor if (tokenDef->previous()->str() == "~") type = Function::eDestructor; // constructor of any kind else type = Function::eConstructor; isExplicit(tokenDef->previous()->str() == "explicit"); } const Token *tok1 = tok; // look for end of previous statement while (tok1->previous() && !Token::Match(tok1->previous(), ";|}|{|public:|protected:|private:")) { tok1 = tok1->previous(); // extern function if (tok1->str() == "extern") { isExtern(true); } // virtual function else if (tok1->str() == "virtual") { isVirtual(true); } // static function else if (tok1->str() == "static") { isStatic(true); if (scope->type == Scope::eNamespace || scope->type == Scope::eGlobal) isStaticLocal(true); } // friend function else if (tok1->str() == "friend") { isFriend(true); } // Function template else if (tok1->link() && tok1->str() == ">" && Token::simpleMatch(tok1->link()->previous(), "template <")) break; } // find the return type if (!isConstructor() && !isDestructor()) { if (argDef->link()->strAt(1) == ".") // Trailing return type retDef = argDef->link()->tokAt(2); else { if (tok1->str() == ">") tok1 = tok1->next(); while (Token::Match(tok1, "extern|virtual|static|friend|struct|union|enum")) tok1 = tok1->next(); retDef = tok1; } } const Token *end = argDef->link(); // parse function attributes.. tok = end->next(); while (tok) { if (tok->str() == "const") isConst(true); else if (tok->str() == "&") hasLvalRefQualifier(true); else if (tok->str() == "&&") hasRvalRefQualifier(true); else if (tok->str() == "override") setFlag(fHasOverrideSpecifier, true); else if (tok->str() == "final") setFlag(fHasFinalSpecifier, true); else if (tok->str() == "volatile") isVolatile(true); else if (tok->str() == "noexcept") { isNoExcept(!Token::simpleMatch(tok->next(), "( false )")); if (tok->next()->str() == "(") tok = tok->linkAt(1); } else if (Token::simpleMatch(tok, "throw (")) { isThrow(true); if (tok->strAt(2) != ")") throwArg = tok->next(); tok = tok->linkAt(1); } else if (Token::Match(tok, "= 0|default|delete ;")) { const std::string& modifier = tok->strAt(1); isPure(modifier == "0"); isDefault(modifier == "default"); isDelete(modifier == "delete"); } else break; tok = tok->next(); } if (_tokenizer->isFunctionHead(end, ":{")) { // assume implementation is inline (definition and implementation same) token = tokenDef; arg = argDef; isInline(true); hasBody(true); } } bool Function::argsMatch(const Scope *scope, const Token *first, const Token *second, const std::string &path, unsigned int path_length) { const bool isCPP = scope->check->isCPP(); if (!isCPP) // C does not support overloads return true; // skip "struct" if (first->str() == "struct" || first->str() == "enum") first = first->next(); if (second->str() == "struct" || second->str() == "enum") second = second->next(); // skip const on type passed by value if (Token::Match(first, "const %type% %name%|,|)")) first = first->next(); if (Token::Match(second, "const %type% %name%|,|)")) second = second->next(); unsigned int arg_path_length = path_length; while (first->str() == second->str() && first->isLong() == second->isLong() && first->isUnsigned() == second->isUnsigned()) { // at end of argument list if (first->str() == ")") { return true; } // skip default value assignment else if (first->next()->str() == "=") { first = first->nextArgument(); if (first) first = first->tokAt(-2); if (second->next()->str() == "=") { second = second->nextArgument(); if (second) second = second->tokAt(-2); if (!first || !second) { // End of argument list (first or second) return !first && !second; } } else if (!first) { // End of argument list (first) return !second->nextArgument(); // End of argument list (second) } } else if (second->next()->str() == "=") { second = second->nextArgument(); if (second) second = second->tokAt(-2); if (!second) { // End of argument list (second) return false; } } // definition missing variable name else if ((first->next()->str() == "," && second->next()->str() != ",") || (first->next()->str() == ")" && second->next()->str() != ")")) { second = second->next(); // skip default value assignment if (second->next()->str() == "=") { do { second = second->next(); } while (!Token::Match(second->next(), ",|)")); } } else if (first->next()->str() == "[" && second->next()->str() != "[") second = second->next(); // function missing variable name else if ((second->next()->str() == "," && first->next()->str() != ",") || (second->next()->str() == ")" && first->next()->str() != ")")) { first = first->next(); // skip default value assignment if (first->next()->str() == "=") { do { first = first->next(); } while (!Token::Match(first->next(), ",|)")); } } else if (second->next()->str() == "[" && first->next()->str() != "[") first = first->next(); // argument list has different number of arguments else if (second->str() == ")") break; // ckeck for type * x == type x[] else if (Token::Match(first->next(), "* %name%| ,|)|=") && Token::Match(second->next(), "%name%| [ ] ,|)")) { do { first = first->next(); } while (!Token::Match(first->next(), ",|)")); do { second = second->next(); } while (!Token::Match(second->next(), ",|)")); } // const after * else if (first->next()->str() == "*" && first->strAt(2) != "const" && second->next()->str() == "*" && second->strAt(2) == "const") { first = first->next(); second = second->tokAt(2); } // variable names are different else if ((Token::Match(first->next(), "%name% ,|)|=|[") && Token::Match(second->next(), "%name% ,|)|[")) && (first->next()->str() != second->next()->str())) { // skip variable names first = first->next(); second = second->next(); // skip default value assignment if (first->next()->str() == "=") { do { first = first->next(); } while (!Token::Match(first->next(), ",|)")); } } // variable with class path else if (arg_path_length && Token::Match(first->next(), "%name%") && first->strAt(1) != "const") { std::string param = path; if (Token::simpleMatch(second->next(), param.c_str())) { second = second->tokAt(int(arg_path_length)); arg_path_length = 0; } // nested or base class variable else if (arg_path_length <= 2 && Token::Match(first->next(), "%name%") && (Token::Match(second->next(), "%name% :: %name%") || (Token::Match(second->next(), "%name% <") && Token::Match(second->linkAt(1), "> :: %name%"))) && ((second->next()->str() == scope->className) || (scope->definedType && scope->definedType->isDerivedFrom(second->next()->str()))) && (first->next()->str() == second->strAt(3))) { if (Token::Match(second->next(), "%name% <")) second = second->linkAt(1)->next(); else second = second->tokAt(2); } // remove class name else if (arg_path_length > 2) { std::string short_path = path; unsigned int short_path_length = arg_path_length; // remove last " :: " short_path.resize(short_path.size() - 4); short_path_length--; // remove last name std::string::size_type lastSpace = short_path.find_last_of(' '); if (lastSpace != std::string::npos) { short_path.resize(lastSpace+1); short_path_length--; if (short_path[short_path.size() - 1] == '>') { short_path.resize(short_path.size() - 3); while (short_path[short_path.size() - 1] == '<') { lastSpace = short_path.find_last_of(' '); short_path.resize(lastSpace+1); short_path_length--; } } } param = short_path; if (Token::simpleMatch(second->next(), param.c_str())) { second = second->tokAt(int(short_path_length)); arg_path_length = 0; } } } first = first->next(); second = second->next(); // reset path length if (first->str() == "," || second->str() == ",") arg_path_length = path_length; // skip "struct" if (first->str() == "struct" || first->str() == "enum") first = first->next(); if (second->str() == "struct" || second->str() == "enum") second = second->next(); // skip const on type passed by value if (Token::Match(first, "const %type% %name%|,|)") && !Token::Match(first, "const %type% %name%| [")) first = first->next(); if (Token::Match(second, "const %type% %name%|,|)") && !Token::Match(second, "const %type% %name%| [")) second = second->next(); } return false; } const Token * Function::constructorMemberInitialization() const { if (!isConstructor() || !functionScope || !functionScope->bodyStart) return nullptr; if (Token::Match(token, "%name% (") && Token::simpleMatch(token->linkAt(1), ") :")) return token->linkAt(1)->next(); return nullptr; } Function* SymbolDatabase::addGlobalFunction(Scope*& scope, const Token*& tok, const Token *argStart, const Token* funcStart) { Function* function = nullptr; for (std::multimap::iterator i = scope->functionMap.find(tok->str()); i != scope->functionMap.end() && i->first == tok->str(); ++i) { if (Function::argsMatch(scope, i->second->argDef->next(), argStart->next(), emptyString, 0)) { function = const_cast(i->second); break; } } if (!function) function = addGlobalFunctionDecl(scope, tok, argStart, funcStart); function->arg = argStart; function->token = funcStart; function->hasBody(true); addNewFunction(&scope, &tok); if (scope) { scope->function = function; function->functionScope = scope; return function; } return nullptr; } Function* SymbolDatabase::addGlobalFunctionDecl(Scope*& scope, const Token *tok, const Token *argStart, const Token* funcStart) { Function function(_tokenizer, tok, scope, funcStart, argStart); scope->addFunction(function); return &scope->functionList.back(); } void SymbolDatabase::addClassFunction(Scope **scope, const Token **tok, const Token *argStart) { const bool destructor((*tok)->previous()->str() == "~"); const bool has_const(argStart->link()->strAt(1) == "const"); const bool lval(argStart->link()->strAt(has_const ? 2 : 1) == "&"); const bool rval(argStart->link()->strAt(has_const ? 2 : 1) == "&&"); int count = 0; std::string path; unsigned int path_length = 0; const Token *tok1 = (*tok); if (destructor) tok1 = tok1->previous(); // back up to head of path while (tok1 && tok1->previous() && tok1->previous()->str() == "::" && tok1->tokAt(-2) && (tok1->tokAt(-2)->isName() || (tok1->strAt(-2) == ">" && tok1->linkAt(-2) && Token::Match(tok1->linkAt(-2)->previous(), "%name%")))) { count++; const Token * tok2 = tok1->tokAt(-2); if (tok2->str() == ">") tok2 = tok2->link()->previous(); if (tok2) { do { path = tok1->previous()->str() + " " + path; tok1 = tok1->previous(); path_length++; } while (tok1 != tok2); } else return; // syntax error ? } // syntax error? if (!tok1) return; std::list::iterator it1; // search for match for (it1 = scopeList.begin(); it1 != scopeList.end(); ++it1) { Scope *scope1 = &(*it1); bool match = false; // check in namespace if using found if (*scope == scope1 && !scope1->usingList.empty()) { std::list::const_iterator it2; for (it2 = scope1->usingList.begin(); it2 != scope1->usingList.end(); ++it2) { if (it2->scope) { Function * func = findFunctionInScope(tok1, it2->scope, path, path_length); if (func) { if (!func->hasBody()) { func->hasBody(true); func->token = *tok; func->arg = argStart; addNewFunction(scope, tok); if (*scope) { (*scope)->functionOf = func->nestedIn; (*scope)->function = func; (*scope)->function->functionScope = *scope; } return; } } } } } if (scope1->className == tok1->str() && (scope1->type != Scope::eFunction)) { // do the scopes match (same scope) or do their names match (multiple namespaces) if ((*scope == scope1->nestedIn) || (*scope && (*scope)->className == scope1->nestedIn->className && !(*scope)->className.empty() && (*scope)->type == scope1->nestedIn->type)) { // nested scopes => check that they match { const Scope *s1 = *scope; const Scope *s2 = scope1->nestedIn; while (s1 && s2) { if (s1->className != s2->className) break; s1 = s1->nestedIn; s2 = s2->nestedIn; } // Not matching scopes if (s1 || s2) continue; } Scope *scope2 = scope1; while (scope2 && count > 1) { count--; if (tok1->strAt(1) == "<") tok1 = tok1->linkAt(1)->tokAt(2); else tok1 = tok1->tokAt(2); scope2 = scope2->findRecordInNestedList(tok1->str()); } if (count == 1 && scope2) { match = true; scope1 = scope2; } } } if (match) { for (std::multimap::iterator it = scope1->functionMap.find((*tok)->str()); it != scope1->functionMap.end() && it->first == (*tok)->str(); ++it) { Function * func = const_cast(it->second); if (!func->hasBody()) { if (Function::argsMatch(scope1, func->argDef, (*tok)->next(), path, path_length)) { if (func->type == Function::eDestructor && destructor) { func->hasBody(true); } else if (func->type != Function::eDestructor && !destructor) { // normal function? if ((*tok)->next()->link()) { const bool hasConstKeyword = (*tok)->next()->link()->next()->str() == "const"; if ((func->isConst() == hasConstKeyword) && (func->hasLvalRefQualifier() == lval) && (func->hasRvalRefQualifier() == rval)) { func->hasBody(true); } } } if (func->hasBody()) { func->token = *tok; func->arg = argStart; addNewFunction(scope, tok); if (*scope) { (*scope)->functionOf = scope1; (*scope)->function = func; (*scope)->function->functionScope = *scope; } return; } } } } } } // class function of unknown class addNewFunction(scope, tok); } void SymbolDatabase::addNewFunction(Scope **scope, const Token **tok) { const Token *tok1 = *tok; scopeList.emplace_back(this, tok1, *scope); Scope *newScope = &scopeList.back(); // find start of function '{' bool foundInitList = false; while (tok1 && tok1->str() != "{" && tok1->str() != ";") { if (tok1->link() && Token::Match(tok1, "(|<")) { tok1 = tok1->link(); } else if (foundInitList && Token::Match(tok1, "%name%|> {") && Token::Match(tok1->linkAt(1), "} ,|{")) { tok1 = tok1->linkAt(1); } else { if (tok1->str() == ":") foundInitList = true; tok1 = tok1->next(); } } if (tok1 && tok1->str() == "{") { newScope->bodyStart = tok1; newScope->bodyEnd = tok1->link(); // syntax error? if (!newScope->bodyEnd) { scopeList.pop_back(); while (tok1->next()) tok1 = tok1->next(); *scope = nullptr; *tok = tok1; return; } (*scope)->nestedList.push_back(newScope); *scope = newScope; *tok = tok1; } else { scopeList.pop_back(); *scope = nullptr; *tok = nullptr; } } const Token *Type::initBaseInfo(const Token *tok, const Token *tok1) { // goto initial '{' const Token *tok2 = tok1; while (tok2 && tok2->str() != "{") { // skip unsupported templates if (tok2->str() == "<") tok2 = tok2->link(); // check for base classes else if (Token::Match(tok2, ":|,")) { tok2 = tok2->next(); // check for invalid code if (!tok2 || !tok2->next()) return nullptr; Type::BaseInfo base; if (tok2->str() == "virtual") { base.isVirtual = true; tok2 = tok2->next(); } if (tok2->str() == "public") { base.access = Public; tok2 = tok2->next(); } else if (tok2->str() == "protected") { base.access = Protected; tok2 = tok2->next(); } else if (tok2->str() == "private") { base.access = Private; tok2 = tok2->next(); } else { if (tok->str() == "class") base.access = Private; else if (tok->str() == "struct") base.access = Public; } if (!tok2) return nullptr; if (tok2->str() == "virtual") { base.isVirtual = true; tok2 = tok2->next(); } if (!tok2) return nullptr; base.nameTok = tok2; // handle global namespace if (tok2->str() == "::") { tok2 = tok2->next(); } // handle derived base classes while (Token::Match(tok2, "%name% ::")) { tok2 = tok2->tokAt(2); } if (!tok2) return nullptr; base.name = tok2->str(); tok2 = tok2->next(); // add unhandled templates if (tok2 && tok2->link() && tok2->str() == "<") { for (const Token* const end = tok2->link()->next(); tok2 != end; tok2 = tok2->next()) { base.name += tok2->str(); } } // save pattern for base class name derivedFrom.push_back(base); } else tok2 = tok2->next(); } return tok2; } const std::string& Type::name() const { const Token* next = classDef->next(); if (classScope && classScope->enumClass && isEnumType()) return next->strAt(1); else if (next->str() == "class") return next->strAt(1); else if (next->isName()) return next->str(); return emptyString; } void SymbolDatabase::debugMessage(const Token *tok, const std::string &msg) const { if (tok && _settings->debugwarnings) { const std::list locationList(1, tok); const ErrorLogger::ErrorMessage errmsg(locationList, &_tokenizer->list, Severity::debug, "debug", msg, false); if (_errorLogger) _errorLogger->reportErr(errmsg); } } const Function* Type::getFunction(const std::string& funcName) const { if (classScope) { const std::multimap::const_iterator it = classScope->functionMap.find(funcName); if (it != classScope->functionMap.end()) return it->second; } for (std::size_t i = 0; i < derivedFrom.size(); i++) { if (derivedFrom[i].type) { const Function* const func = derivedFrom[i].type->getFunction(funcName); if (func) return func; } } return nullptr; } bool Type::hasCircularDependencies(std::set* ancestors) const { std::set knownAncestors; if (!ancestors) { ancestors=&knownAncestors; } for (std::vector::const_iterator parent=derivedFrom.begin(); parent!=derivedFrom.end(); ++parent) { if (!parent->type) continue; else if (this==parent->type) return true; else if (ancestors->find(*parent)!=ancestors->end()) return true; else { ancestors->insert(*parent); if (parent->type->hasCircularDependencies(ancestors)) return true; } } return false; } bool Type::findDependency(const Type* ancestor) const { if (this==ancestor) return true; for (std::vector::const_iterator parent=derivedFrom.begin(); parent!=derivedFrom.end(); ++parent) { if (parent->type && parent->type->findDependency(ancestor)) return true; } return false; } bool Type::isDerivedFrom(const std::string & ancestor) const { for (std::vector::const_iterator parent=derivedFrom.begin(); parent!=derivedFrom.end(); ++parent) { if (parent->name == ancestor) return true; if (parent->type && parent->type->isDerivedFrom(ancestor)) return true; } return false; } bool Variable::arrayDimensions(const Library* lib) { const Library::Container* container = lib->detectContainer(_start); if (container && container->arrayLike_indexOp && container->size_templateArgNo > 0) { const Token* tok = Token::findsimplematch(_start, "<"); if (tok) { Dimension dimension_; tok = tok->next(); for (int i = 0; i < container->size_templateArgNo && tok; i++) { tok = tok->nextTemplateArgument(); } if (tok) { dimension_.start = tok; dimension_.end = Token::findmatch(tok, ",|>"); if (dimension_.end) dimension_.end = dimension_.end->previous(); if (dimension_.start == dimension_.end) { dimension_.num = MathLib::toLongNumber(dimension_.start->str()); dimension_.known = true; } } assert((dimension_.start == nullptr) == (dimension_.end == nullptr)); _dimensions.push_back(dimension_); return true; } } const Token *dim = _name; if (!dim) { // Argument without name dim = _end; // back up to start of array dimensions while (dim && dim->str() == "]") dim = dim->link()->previous(); } if (dim) dim = dim->next(); if (dim && dim->str() == ")") dim = dim->next(); bool arr = false; while (dim && dim->next() && dim->str() == "[") { Dimension dimension_; // check for empty array dimension [] if (dim->next()->str() != "]") { dimension_.start = dim->next(); dimension_.end = dim->link()->previous(); if (dimension_.start == dimension_.end && dimension_.start->isNumber()) { dimension_.num = MathLib::toLongNumber(dimension_.start->str()); dimension_.known = true; } } assert((dimension_.start == nullptr) == (dimension_.end == nullptr)); _dimensions.push_back(dimension_); dim = dim->link()->next(); arr = true; } return arr; } void Variable::setFlags(const ValueType &valuetype) { if (valuetype.constness) setFlag(fIsConst,true); if (valuetype.pointer) setFlag(fIsPointer,true); } static std::ostream & operator << (std::ostream & s, Scope::ScopeType type) { s << (type == Scope::eGlobal ? "Global" : type == Scope::eClass ? "Class" : type == Scope::eStruct ? "Struct" : type == Scope::eUnion ? "Union" : type == Scope::eNamespace ? "Namespace" : type == Scope::eFunction ? "Function" : type == Scope::eIf ? "If" : type == Scope::eElse ? "Else" : type == Scope::eFor ? "For" : type == Scope::eWhile ? "While" : type == Scope::eDo ? "Do" : type == Scope::eSwitch ? "Switch" : type == Scope::eTry ? "Try" : type == Scope::eCatch ? "Catch" : type == Scope::eUnconditional ? "Unconditional" : type == Scope::eLambda ? "Lambda" : type == Scope::eEnum ? "Enum" : "Unknown"); return s; } static std::string accessControlToString(const AccessControl& access) { switch (access) { case Public: return "Public"; case Protected: return "Protected"; case Private: return "Private"; case Global: return "Global"; case Namespace: return "Namespace"; case Argument: return "Argument"; case Local: return "Local"; case Throw: return "Throw"; } return "Unknown"; } static std::string tokenToString(const Token* tok, const Tokenizer* tokenizer) { std::ostringstream oss; if (tok) { oss << tok->str() << " "; oss << tokenizer->list.fileLine(tok) << " "; } oss << tok; return oss.str(); } static std::string scopeToString(const Scope* scope, const Tokenizer* tokenizer) { std::ostringstream oss; if (scope) { oss << scope->type << " "; if (scope->classDef) oss << tokenizer->list.fileLine(scope->classDef) << " "; } oss << scope; return oss.str(); } static std::string tokenType(const Token * tok) { std::ostringstream oss; if (tok) { if (tok->isUnsigned()) oss << "unsigned "; else if (tok->isSigned()) oss << "signed "; if (tok->isComplex()) oss << "_Complex "; if (tok->isLong()) oss << "long "; oss << tok->str(); } return oss.str(); } void SymbolDatabase::printVariable(const Variable *var, const char *indent) const { std::cout << indent << "_name: " << tokenToString(var->nameToken(), _tokenizer) << std::endl; if (var->nameToken()) { std::cout << indent << " declarationId: " << var->declarationId() << std::endl; } std::cout << indent << "_start: " << tokenToString(var->typeStartToken(), _tokenizer) << std::endl; std::cout << indent << "_end: " << tokenToString(var->typeEndToken(), _tokenizer) << std::endl; const Token * autoTok = nullptr; std::cout << indent << " "; for (const Token * tok = var->typeStartToken(); tok != var->typeEndToken()->next(); tok = tok->next()) { std::cout << " " << tokenType(tok); if (tok->str() == "auto") autoTok = tok; } std::cout << std::endl; if (autoTok) { const ValueType * valueType = autoTok->valueType(); std::cout << indent << " auto valueType: " << valueType << std::endl; if (var->typeStartToken()->valueType()) { std::cout << indent << " " << valueType->str() << std::endl; } } std::cout << indent << "_index: " << var->index() << std::endl; std::cout << indent << "_access: " << (var->isPublic() ? "Public" : var->isProtected() ? "Protected" : var->isPrivate() ? "Private" : var->isGlobal() ? "Global" : var->isNamespace() ? "Namespace" : var->isArgument() ? "Argument" : var->isLocal() ? "Local" : var->isThrow() ? "Throw" : "Unknown") << std::endl; std::cout << indent << "_flags: " << std::endl; std::cout << indent << " isMutable: " << var->isMutable() << std::endl; std::cout << indent << " isStatic: " << var->isStatic() << std::endl; std::cout << indent << " isExtern: " << var->isExtern() << std::endl; std::cout << indent << " isLocal: " << var->isLocal() << std::endl; std::cout << indent << " isConst: " << var->isConst() << std::endl; std::cout << indent << " isClass: " << var->isClass() << std::endl; std::cout << indent << " isArray: " << var->isArray() << std::endl; std::cout << indent << " isPointer: " << var->isPointer() << std::endl; std::cout << indent << " isReference: " << var->isReference() << std::endl; std::cout << indent << " isRValueRef: " << var->isRValueReference() << std::endl; std::cout << indent << " hasDefault: " << var->hasDefault() << std::endl; std::cout << indent << " isStlType: " << var->isStlType() << std::endl; std::cout << indent << "_type: "; if (var->type()) { std::cout << var->type()->type() << " " << var->type()->name(); std::cout << " " << _tokenizer->list.fileLine(var->type()->classDef); std::cout << " " << var->type() << std::endl; } else std::cout << "none" << std::endl; if (var->nameToken()) { const ValueType * valueType = var->nameToken()->valueType(); std::cout << indent << "valueType: " << valueType << std::endl; if (valueType) { std::cout << indent << " " << valueType->str() << std::endl; } } std::cout << indent << "_scope: " << scopeToString(var->scope(), _tokenizer) << std::endl; std::cout << indent << "_dimensions:"; for (std::size_t i = 0; i < var->dimensions().size(); i++) { std::cout << " " << var->dimension(i); if (!var->dimensions()[i].known) std::cout << "?"; } std::cout << std::endl; } void SymbolDatabase::printOut(const char *title) const { std::cout << std::setiosflags(std::ios::boolalpha); if (title) std::cout << "\n### " << title << " ###\n"; for (std::list::const_iterator scope = scopeList.begin(); scope != scopeList.end(); ++scope) { std::cout << "Scope: " << &*scope << " " << scope->type << std::endl; std::cout << " className: " << scope->className << std::endl; std::cout << " classDef: " << tokenToString(scope->classDef, _tokenizer) << std::endl; std::cout << " bodyStart: " << tokenToString(scope->bodyStart, _tokenizer) << std::endl; std::cout << " bodyEnd: " << tokenToString(scope->bodyEnd, _tokenizer) << std::endl; std::list::const_iterator func; // find the function body if not implemented inline for (func = scope->functionList.begin(); func != scope->functionList.end(); ++func) { std::cout << " Function: " << &*func << std::endl; std::cout << " name: " << tokenToString(func->tokenDef, _tokenizer) << std::endl; std::cout << " type: " << (func->type == Function::eConstructor? "Constructor" : func->type == Function::eCopyConstructor ? "CopyConstructor" : func->type == Function::eMoveConstructor ? "MoveConstructor" : func->type == Function::eOperatorEqual ? "OperatorEqual" : func->type == Function::eDestructor ? "Destructor" : func->type == Function::eFunction ? "Function" : "Unknown") << std::endl; std::cout << " access: " << (func->access == Public ? "Public" : func->access == Protected ? "Protected" : func->access == Private ? "Private" : "Unknown") << std::endl; std::cout << " hasBody: " << func->hasBody() << std::endl; std::cout << " isInline: " << func->isInline() << std::endl; std::cout << " isConst: " << func->isConst() << std::endl; std::cout << " isVirtual: " << func->isVirtual() << std::endl; std::cout << " isPure: " << func->isPure() << std::endl; std::cout << " isStatic: " << func->isStatic() << std::endl; std::cout << " isStaticLocal: " << func->isStaticLocal() << std::endl; std::cout << " isExtern: " << func->isExtern() << std::endl; std::cout << " isFriend: " << func->isFriend() << std::endl; std::cout << " isExplicit: " << func->isExplicit() << std::endl; std::cout << " isDefault: " << func->isDefault() << std::endl; std::cout << " isDelete: " << func->isDelete() << std::endl; std::cout << " isNoExcept: " << func->isNoExcept() << std::endl; std::cout << " isThrow: " << func->isThrow() << std::endl; std::cout << " isOperator: " << func->isOperator() << std::endl; std::cout << " hasLvalRefQual: " << func->hasLvalRefQualifier() << std::endl; std::cout << " hasRvalRefQual: " << func->hasRvalRefQualifier() << std::endl; std::cout << " isVariadic: " << func->isVariadic() << std::endl; std::cout << " isVolatile: " << func->isVolatile() << std::endl; std::cout << " attributes:"; if (func->isAttributeConst()) std::cout << " const "; if (func->isAttributePure()) std::cout << " pure "; if (func->isAttributeNoreturn()) std::cout << " noreturn "; if (func->isAttributeNothrow()) std::cout << " nothrow "; if (func->isAttributeConstructor()) std::cout << " constructor "; if (func->isAttributeDestructor()) std::cout << " destructor "; std::cout << std::endl; std::cout << " noexceptArg: " << (func->noexceptArg ? func->noexceptArg->str() : "none") << std::endl; std::cout << " throwArg: " << (func->throwArg ? func->throwArg->str() : "none") << std::endl; std::cout << " tokenDef: " << tokenToString(func->tokenDef, _tokenizer) << std::endl; std::cout << " argDef: " << tokenToString(func->argDef, _tokenizer) << std::endl; if (!func->isConstructor() && !func->isDestructor()) std::cout << " retDef: " << tokenToString(func->retDef, _tokenizer) << std::endl; if (func->retDef) { std::cout << " "; for (const Token * tok = func->retDef; tok && tok != func->tokenDef && !Token::Match(tok, "{|;"); tok = tok->next()) std::cout << " " << tokenType(tok); std::cout << std::endl; } std::cout << " retType: " << func->retType << std::endl; if (func->tokenDef->next()->valueType()) { const ValueType * valueType = func->tokenDef->next()->valueType(); std::cout << " valueType: " << valueType << std::endl; if (valueType) { std::cout << " " << valueType->str() << std::endl; } } if (func->hasBody()) { std::cout << " token: " << tokenToString(func->token, _tokenizer) << std::endl; std::cout << " arg: " << tokenToString(func->arg, _tokenizer) << std::endl; } std::cout << " nestedIn: " << scopeToString(func->nestedIn, _tokenizer) << std::endl; std::cout << " functionScope: " << scopeToString(func->functionScope, _tokenizer) << std::endl; std::list::const_iterator var; for (var = func->argumentList.begin(); var != func->argumentList.end(); ++var) { std::cout << " Variable: " << &*var << std::endl; printVariable(&*var, " "); } } std::list::const_iterator var; for (var = scope->varlist.begin(); var != scope->varlist.end(); ++var) { std::cout << " Variable: " << &*var << std::endl; printVariable(&*var, " "); } if (scope->type == Scope::eEnum) { std::cout << " enumType: "; if (scope->enumType) scope->enumType->stringify(std::cout, false, true, false); else std::cout << "int"; std::cout << std::endl; std::cout << " enumClass: " << scope->enumClass << std::endl; for (std::vector::const_iterator enumerator = scope->enumeratorList.begin(); enumerator != scope->enumeratorList.end(); ++enumerator) { std::cout << " Enumerator: " << enumerator->name->str() << " = "; if (enumerator->value_known) { std::cout << enumerator->value; } if (enumerator->start) { const Token * tok = enumerator->start; std::cout << (enumerator->value_known ? " " : "") << "[" << tok->str(); while (tok && tok != enumerator->end) { if (tok->next()) std::cout << " " << tok->next()->str(); tok = tok->next(); } std::cout << "]"; } std::cout << std::endl; } } std::cout << " nestedIn: " << scope->nestedIn; if (scope->nestedIn) { std::cout << " " << scope->nestedIn->type << " " << scope->nestedIn->className; } std::cout << std::endl; std::cout << " definedType: " << scope->definedType << std::endl; std::cout << " nestedList[" << scope->nestedList.size() << "] = ("; std::list::const_iterator nsi; std::size_t count = scope->nestedList.size(); for (nsi = scope->nestedList.begin(); nsi != scope->nestedList.end(); ++nsi) { std::cout << " " << (*nsi) << " " << (*nsi)->type << " " << (*nsi)->className; if (count-- > 1) std::cout << ","; } std::cout << " )" << std::endl; std::list::const_iterator use; for (use = scope->usingList.begin(); use != scope->usingList.end(); ++use) { std::cout << " using: " << use->scope << " " << use->start->strAt(2); const Token *tok1 = use->start->tokAt(3); while (tok1 && tok1->str() == "::") { std::cout << "::" << tok1->strAt(1); tok1 = tok1->tokAt(2); } std::cout << " " << _tokenizer->list.fileLine(use->start) << std::endl; } std::cout << " functionOf: " << scopeToString(scope->functionOf, _tokenizer) << std::endl; std::cout << " function: " << scope->function; if (scope->function) std::cout << " " << scope->function->name(); std::cout << std::endl; } for (std::list::const_iterator type = typeList.begin(); type != typeList.end(); ++type) { std::cout << "Type: " << &(*type) << std::endl; std::cout << " name: " << type->name() << std::endl; std::cout << " classDef: " << tokenToString(type->classDef, _tokenizer) << std::endl; std::cout << " classScope: " << type->classScope << std::endl; std::cout << " enclosingScope: " << type->enclosingScope << std::endl; std::cout << " needInitialization: " << (type->needInitialization == Type::Unknown ? "Unknown" : type->needInitialization == Type::True ? "True" : type->needInitialization == Type::False ? "False" : "Invalid") << std::endl; std::cout << " derivedFrom[" << type->derivedFrom.size() << "] = ("; std::size_t count = type->derivedFrom.size(); for (std::size_t i = 0; i < type->derivedFrom.size(); ++i) { if (type->derivedFrom[i].isVirtual) std::cout << "Virtual "; std::cout << (type->derivedFrom[i].access == Public ? " Public" : type->derivedFrom[i].access == Protected ? " Protected" : type->derivedFrom[i].access == Private ? " Private" : " Unknown"); if (type->derivedFrom[i].type) std::cout << " " << type->derivedFrom[i].type; else std::cout << " Unknown"; std::cout << " " << type->derivedFrom[i].name; if (count-- > 1) std::cout << ","; } std::cout << " )" << std::endl; std::cout << " friendList[" << type->friendList.size() << "] = ("; for (size_t i = 0; i < type->friendList.size(); i++) { if (type->friendList[i].type) std::cout << type->friendList[i].type; else std::cout << " Unknown"; std::cout << ' '; if (type->friendList[i].nameEnd) std::cout << type->friendList[i].nameEnd->str(); if (i+1 < type->friendList.size()) std::cout << ','; } std::cout << " )" << std::endl; } for (std::size_t i = 1; i < _variableList.size(); i++) { std::cout << "_variableList[" << i << "]: " << _variableList[i]; if (_variableList[i]) { std::cout << " " << _variableList[i]->name() << " " << _tokenizer->list.fileLine(_variableList[i]->nameToken()); } std::cout << std::endl; } std::cout << std::resetiosflags(std::ios::boolalpha); } void SymbolDatabase::printXml(std::ostream &out) const { out << std::setiosflags(std::ios::boolalpha); std::set variables; // Scopes.. out << " " << std::endl; for (std::list::const_iterator scope = scopeList.begin(); scope != scopeList.end(); ++scope) { out << " type << "\""; if (!scope->className.empty()) out << " className=\"" << ErrorLogger::toxml(scope->className) << "\""; if (scope->bodyStart) out << " bodyStart=\"" << scope->bodyStart << '\"'; if (scope->bodyEnd) out << " bodyEnd=\"" << scope->bodyEnd << '\"'; if (scope->nestedIn) out << " nestedIn=\"" << scope->nestedIn << "\""; if (scope->function) out << " function=\"" << scope->function << "\""; if (scope->functionList.empty() && scope->varlist.empty()) out << "/>" << std::endl; else { out << '>' << std::endl; if (!scope->functionList.empty()) { out << " " << std::endl; for (std::list::const_iterator function = scope->functionList.begin(); function != scope->functionList.end(); ++function) { out << " tokenDef << "\" name=\"" << ErrorLogger::toxml(function->name()) << '\"'; out << " type=\"" << (function->type == Function::eConstructor? "Constructor" : function->type == Function::eCopyConstructor ? "CopyConstructor" : function->type == Function::eMoveConstructor ? "MoveConstructor" : function->type == Function::eOperatorEqual ? "OperatorEqual" : function->type == Function::eDestructor ? "Destructor" : function->type == Function::eFunction ? "Function" : "Unknown") << '\"'; if (function->nestedIn->definedType) { if (function->isVirtual()) out << " isVirtual=\"true\""; else if (function->isImplicitlyVirtual()) out << " isImplicitlyVirtual=\"true\""; } if (function->argCount() == 0U) out << "/>" << std::endl; else { out << ">" << std::endl; for (unsigned int argnr = 0; argnr < function->argCount(); ++argnr) { const Variable *arg = function->getArgumentVar(argnr); out << " " << std::endl; variables.insert(arg); } out << " " << std::endl; } } out << " " << std::endl; } if (!scope->varlist.empty()) { out << " " << std::endl; for (std::list::const_iterator var = scope->varlist.begin(); var != scope->varlist.end(); ++var) out << " " << std::endl; out << " " << std::endl; } out << " " << std::endl; } } out << " " << std::endl; // Variables.. for (const Variable *var : _variableList) variables.insert(var); out << " " << std::endl; for (const Variable *var : variables) { if (!var) continue; out << " nameToken() << '\"'; out << " typeStartToken=\"" << var->typeStartToken() << '\"'; out << " typeEndToken=\"" << var->typeEndToken() << '\"'; out << " isArgument=\"" << var->isArgument() << '\"'; out << " isArray=\"" << var->isArray() << '\"'; out << " isClass=\"" << var->isClass() << '\"'; out << " isConst=\"" << var->isConst() << '\"'; out << " isExtern=\"" << var->isExtern() << '\"'; out << " isLocal=\"" << var->isLocal() << '\"'; out << " isPointer=\"" << var->isPointer() << '\"'; out << " isReference=\"" << var->isReference() << '\"'; out << " isStatic=\"" << var->isStatic() << '\"'; out << " constness=\"" << var->constness() << '\"'; out << " access=\"" << accessControlToString(var->_access) << '\"'; out << "/>" << std::endl; } out << " " << std::endl; out << std::resetiosflags(std::ios::boolalpha); } //--------------------------------------------------------------------------- static const Type* findVariableTypeIncludingUsedNamespaces(const SymbolDatabase* symbolDatabase, const Scope* scope, const Token* typeTok) { const Type* argType = symbolDatabase->findVariableType(scope, typeTok); if (argType) return argType; // look for variable type in any using namespace in this scope or above while (scope) { for (const Scope::UsingInfo &ui : scope->usingList) { if (ui.scope) { argType = symbolDatabase->findVariableType(ui.scope, typeTok); if (argType) return argType; } } scope = scope->nestedIn; } return nullptr; } //--------------------------------------------------------------------------- void Function::addArguments(const SymbolDatabase *symbolDatabase, const Scope *scope) { // check for non-empty argument list "( ... )" const Token * start = arg ? arg : argDef; if (!(start && start->link() != start->next() && !Token::simpleMatch(start, "( void )"))) return; unsigned int count = 0; for (const Token* tok = start->next(); tok; tok = tok->next()) { if (Token::Match(tok, ",|)")) return; // Syntax error const Token* startTok = tok; const Token* endTok = nullptr; const Token* nameTok = nullptr; do { if (tok->varId() != 0) { nameTok = tok; endTok = tok->previous(); } else if (tok->str() == "[") { // skip array dimension(s) tok = tok->link(); while (tok->next()->str() == "[") tok = tok->next()->link(); } else if (tok->str() == "<") { tok = tok->link(); if (!tok) // something is wrong so just bail out return; } tok = tok->next(); if (!tok) // something is wrong so just bail return; } while (tok->str() != "," && tok->str() != ")" && tok->str() != "="); const Token *typeTok = startTok; // skip over stuff to get to type while (Token::Match(typeTok, "const|volatile|enum|struct|::")) typeTok = typeTok->next(); if (Token::Match(typeTok, ",|)")) { // #8333 symbolDatabase->_tokenizer->syntaxError(typeTok); return; } // skip over qualification while (Token::Match(typeTok, "%type% ::")) typeTok = typeTok->tokAt(2); // check for argument with no name or missing varid if (!endTok) { if (tok->previous()->isName() && !Token::Match(tok->tokAt(-1), "const|volatile")) { if (tok->previous() != typeTok) { nameTok = tok->previous(); endTok = nameTok->previous(); if (hasBody()) symbolDatabase->debugMessage(nameTok, "Function::addArguments found argument \'" + nameTok->str() + "\' with varid 0."); } else endTok = typeTok; } else endTok = tok->previous(); } const ::Type *argType = nullptr; if (!typeTok->isStandardType()) { argType = findVariableTypeIncludingUsedNamespaces(symbolDatabase, scope, typeTok); // save type const_cast(typeTok)->type(argType); } // skip default values if (tok->str() == "=") { do { if (tok->link() && Token::Match(tok, "[{[(<]")) tok = tok->link(); tok = tok->next(); } while (tok->str() != "," && tok->str() != ")"); } // skip over stuff before type while (Token::Match(startTok, "enum|struct|const|volatile")) startTok = startTok->next(); argumentList.emplace_back(nameTok, startTok, endTok, count++, Argument, argType, functionScope, &symbolDatabase->_settings->library); if (tok->str() == ")") { // check for a variadic function if (Token::simpleMatch(startTok, ". . .")) isVariadic(true); break; } } // count default arguments for (const Token* tok = argDef->next(); tok && tok != argDef->link(); tok = tok->next()) { if (tok->str() == "=") initArgCount++; } } bool Function::isImplicitlyVirtual(bool defaultVal) const { if (isVirtual()) return true; bool foundAllBaseClasses = true; if (getOverridenFunction(&foundAllBaseClasses)) return true; if (foundAllBaseClasses) return false; return defaultVal; } const Function *Function::getOverridenFunction(bool *foundAllBaseClasses) const { if (foundAllBaseClasses) *foundAllBaseClasses = true; if (!nestedIn->isClassOrStruct()) return nullptr; return getOverridenFunctionRecursive(nestedIn->definedType, foundAllBaseClasses); } const Function * Function::getOverridenFunctionRecursive(const ::Type* baseType, bool *foundAllBaseClasses) const { // check each base class for (std::size_t i = 0; i < baseType->derivedFrom.size(); ++i) { const ::Type* derivedFromType = baseType->derivedFrom[i].type; // check if base class exists in database if (!derivedFromType || !derivedFromType->classScope) { if (foundAllBaseClasses) *foundAllBaseClasses = false; continue; } const Scope *parent = derivedFromType->classScope; // check if function defined in base class for (std::multimap::const_iterator it = parent->functionMap.find(tokenDef->str()); it != parent->functionMap.end() && it->first == tokenDef->str(); ++it) { const Function * func = it->second; if (func->isVirtual()) { // Base is virtual and of same name const Token *temp1 = func->tokenDef->previous(); const Token *temp2 = tokenDef->previous(); bool match = true; // check for matching return parameters while (temp1->str() != "virtual") { if (temp1->str() != temp2->str() && !(temp1->str() == derivedFromType->name() && temp2->str() == baseType->name())) { match = false; break; } temp1 = temp1->previous(); temp2 = temp2->previous(); } // check for matching function parameters if (match && argsMatch(baseType->classScope, func->argDef, argDef, emptyString, 0)) { return func; } } } if (!derivedFromType->derivedFrom.empty() && !derivedFromType->hasCircularDependencies()) { // avoid endless recursion, see #5289 Crash: Stack overflow in isImplicitlyVirtual_rec when checking SVN and // #5590 with a loop within the class hierarchy. const Function *func = getOverridenFunctionRecursive(derivedFromType, foundAllBaseClasses); if (func) { return func; } } } return nullptr; } const Variable* Function::getArgumentVar(std::size_t num) const { for (std::list::const_iterator i = argumentList.begin(); i != argumentList.end(); ++i) { if (i->index() == num) return (&*i); else if (i->index() > num) return nullptr; } return nullptr; } //--------------------------------------------------------------------------- Scope::Scope(const SymbolDatabase *check_, const Token *classDef_, const Scope *nestedIn_, ScopeType type_, const Token *start_) : check(check_), classDef(classDef_), bodyStart(start_), bodyEnd(start_->link()), nestedIn(nestedIn_), numConstructors(0), numCopyOrMoveConstructors(0), type(type_), definedType(nullptr), functionOf(nullptr), function(nullptr), enumType(nullptr), enumClass(false) { } Scope::Scope(const SymbolDatabase *check_, const Token *classDef_, const Scope *nestedIn_) : check(check_), classDef(classDef_), bodyStart(nullptr), bodyEnd(nullptr), nestedIn(nestedIn_), numConstructors(0), numCopyOrMoveConstructors(0), definedType(nullptr), functionOf(nullptr), function(nullptr), enumType(nullptr), enumClass(false) { const Token *nameTok = classDef; if (!classDef) { type = Scope::eGlobal; } else if (classDef->str() == "class" && check && check->isCPP()) { type = Scope::eClass; nameTok = nameTok->next(); } else if (classDef->str() == "struct") { type = Scope::eStruct; nameTok = nameTok->next(); } else if (classDef->str() == "union") { type = Scope::eUnion; nameTok = nameTok->next(); } else if (classDef->str() == "namespace") { type = Scope::eNamespace; nameTok = nameTok->next(); } else if (classDef->str() == "enum") { type = Scope::eEnum; nameTok = nameTok->next(); if (nameTok->str() == "class") { enumClass = true; nameTok = nameTok->next(); } } else { type = Scope::eFunction; } // skip over qualification if present nameTok = skipScopeIdentifiers(nameTok); if (nameTok && ((type == Scope::eEnum && Token::Match(nameTok, ":|{")) || nameTok->str() != "{")) // anonymous and unnamed structs/unions don't have a name className = nameTok->str(); } bool Scope::hasDefaultConstructor() const { if (numConstructors) { std::list::const_iterator func; for (func = functionList.begin(); func != functionList.end(); ++func) { if (func->type == Function::eConstructor && func->argCount() == 0) return true; } } return false; } AccessControl Scope::defaultAccess() const { switch (type) { case eGlobal: return Global; case eClass: return Private; case eStruct: return Public; case eUnion: return Public; case eNamespace: return Namespace; default: return Local; } } // Get variable list.. void Scope::getVariableList(const Library* lib) { const Token *start; if (bodyStart) start = bodyStart->next(); // global scope else if (className.empty()) start = check->_tokenizer->tokens(); // forward declaration else return; AccessControl varaccess = defaultAccess(); for (const Token *tok = start; tok && tok != bodyEnd; tok = tok->next()) { // syntax error? if (tok->next() == nullptr) break; // Is it a function? else if (tok->str() == "{") { tok = tok->link(); continue; } // Is it a nested class or structure? else if (Token::Match(tok, "class|struct|union|namespace %type% :|{")) { tok = tok->tokAt(2); while (tok && tok->str() != "{") tok = tok->next(); if (tok) { // skip implementation tok = tok->link(); continue; } else break; } else if (Token::Match(tok, "struct|union {")) { if (Token::Match(tok->next()->link(), "} %name% ;|[")) { tok = tok->next()->link()->tokAt(2); continue; } else if (Token::simpleMatch(tok->next()->link(), "} ;")) { tok = tok->next(); continue; } } // Borland C++: Skip all variables in the __published section. // These are automatically initialized. else if (tok->str() == "__published:") { for (; tok; tok = tok->next()) { if (tok->str() == "{") tok = tok->link(); if (Token::Match(tok->next(), "private:|protected:|public:")) break; } if (tok) continue; else break; } // "private:" "public:" "protected:" etc else if (tok->str() == "public:") { varaccess = Public; continue; } else if (tok->str() == "protected:") { varaccess = Protected; continue; } else if (tok->str() == "private:") { varaccess = Private; continue; } // Is it a forward declaration? else if (Token::Match(tok, "class|struct|union %name% ;")) { tok = tok->tokAt(2); continue; } // Borland C++: Ignore properties.. else if (tok->str() == "__property") continue; // skip return, goto and delete else if (Token::Match(tok, "return|delete|goto")) { while (tok->next() && tok->next()->str() != ";" && tok->next()->str() != "}" /* ticket #4994 */) { tok = tok->next(); } continue; } // Search for start of statement.. else if (tok->previous() && !Token::Match(tok->previous(), ";|{|}|public:|protected:|private:")) continue; else if (tok->str() == ";") continue; tok = checkVariable(tok, varaccess, lib); if (!tok) break; } } const Token *Scope::checkVariable(const Token *tok, AccessControl varaccess, const Library* lib) { // Is it a throw..? if (Token::Match(tok, "throw %any% (") && Token::simpleMatch(tok->linkAt(2), ") ;")) { return tok->linkAt(2); } if ((Token::Match(tok, "throw %any% :: %any% (") && Token::simpleMatch(tok->linkAt(4), ") ;"))) { return tok->linkAt(4); } // friend? if (Token::Match(tok, "friend %type%") && tok->next()->varId() == 0) { const Token *next = Token::findmatch(tok->tokAt(2), ";|{"); if (next && next->str() == "{") next = next->link(); return next; } // skip const|volatile|static|mutable|extern while (Token::Match(tok, "const|volatile|static|mutable|extern")) { tok = tok->next(); } // the start of the type tokens does not include the above modifiers const Token *typestart = tok; if (Token::Match(tok, "class|struct|union|enum")) { tok = tok->next(); } // This is the start of a statement const Token *vartok = nullptr; const Token *typetok = nullptr; if (tok && isVariableDeclaration(tok, vartok, typetok)) { // If the vartok was set in the if-blocks above, create a entry for this variable.. tok = vartok->next(); while (Token::Match(tok, "[|{")) tok = tok->link()->next(); if (vartok->varId() == 0) { if (!vartok->isBoolean()) check->debugMessage(vartok, "Scope::checkVariable found variable \'" + vartok->str() + "\' with varid 0."); return tok; } const Type *vType = nullptr; if (typetok) { vType = findVariableTypeIncludingUsedNamespaces(check, this, typetok); const_cast(typetok)->type(vType); } // skip "enum" or "struct" if (Token::Match(typestart, "enum|struct")) typestart = typestart->next(); addVariable(vartok, typestart, vartok->previous(), varaccess, vType, this, lib); } return tok; } const Variable *Scope::getVariable(const std::string &varname) const { std::list::const_iterator iter; for (iter = varlist.begin(); iter != varlist.end(); ++iter) { if (iter->name() == varname) return &*iter; } return nullptr; } static const Token* skipPointers(const Token* tok) { while (Token::Match(tok, "*|&|&&") || (Token::Match(tok, "( [*&]") && Token::Match(tok->link()->next(), "(|["))) { tok = tok->next(); if (tok->strAt(-1) == "(" && Token::Match(tok, "%type% ::")) tok = tok->tokAt(2); } return tok; } bool Scope::isVariableDeclaration(const Token* const tok, const Token*& vartok, const Token*& typetok) const { const bool isCPP = check && check->_tokenizer->isCPP(); if (isCPP && Token::Match(tok, "throw|new")) return false; const bool isCPP11 = isCPP && check->_settings->standards.cpp >= Standards::CPP11; if (isCPP11 && tok->str() == "using") return false; const Token* localTypeTok = skipScopeIdentifiers(tok); const Token* localVarTok = nullptr; if (Token::Match(localTypeTok, "%type% <")) { if (Token::Match(tok, "const_cast|dynamic_cast|reinterpret_cast|static_cast <")) return false; const Token* closeTok = localTypeTok->next()->link(); if (closeTok) { localVarTok = skipPointers(closeTok->next()); if (Token::Match(localVarTok, ":: %type% %name% [;=({]")) { if (localVarTok->strAt(3) != "(" || Token::Match(localVarTok->linkAt(3), "[)}] ;")) { localTypeTok = localVarTok->next(); localVarTok = localVarTok->tokAt(2); } } } } else if (Token::Match(localTypeTok, "%type%")) { localVarTok = skipPointers(localTypeTok->strAt(1)=="const"?localTypeTok->tokAt(2):localTypeTok->next()); } if (!localVarTok) return false; if (localVarTok->str() == "const") localVarTok = localVarTok->next(); if (Token::Match(localVarTok, "%name% ;|=") || (localVarTok && localVarTok->varId() && localVarTok->strAt(1) == ":")) { vartok = localVarTok; typetok = localTypeTok; } else if (Token::Match(localVarTok, "%name% )|[") && localVarTok->str() != "operator") { vartok = localVarTok; typetok = localTypeTok; } else if (localVarTok && localVarTok->varId() && Token::Match(localVarTok, "%name% (|{") && Token::Match(localVarTok->next()->link(), ")|} ;")) { vartok = localVarTok; typetok = localTypeTok; } else if (type == eCatch && Token::Match(localVarTok, "%name% )")) { vartok = localVarTok; typetok = localTypeTok; } return nullptr != vartok; } const Token * Scope::addEnum(const Token * tok, bool isCpp) { const Token * tok2 = tok->next(); // skip over class if present if (isCpp && tok2->str() == "class") tok2 = tok2->next(); // skip over name tok2 = tok2->next(); // save type if present if (tok2->str() == ":") { tok2 = tok2->next(); enumType = tok2; tok2 = tok2->next(); } // add enumerators if (tok2->str() == "{") { const Token * end = tok2->link(); tok2 = tok2->next(); while (Token::Match(tok2, "%name% =|,|}") || (Token::Match(tok2, "%name% (") && Token::Match(tok2->linkAt(1), ") ,|}"))) { Enumerator enumerator(this); // save enumerator name enumerator.name = tok2; // skip over name tok2 = tok2->next(); if (tok2->str() == "=") { // skip over "=" tok2 = tok2->next(); if (tok2->str() == "}") return nullptr; enumerator.start = tok2; while (!Token::Match(tok2, ",|}")) { if (tok2->link()) tok2 = tok2->link(); enumerator.end = tok2; tok2 = tok2->next(); } } else if (tok2->str() == "(") { // skip over unknown macro tok2 = tok2->link()->next(); } if (tok2->str() == ",") { enumeratorList.push_back(enumerator); tok2 = tok2->next(); } else if (tok2->str() == "}") { enumeratorList.push_back(enumerator); break; } } if (tok2 == end) { tok2 = tok2->next(); if (tok2 && tok2->str() != ";") tok2 = nullptr; } else tok2 = nullptr; } else tok2 = nullptr; return tok2; } const Enumerator * SymbolDatabase::findEnumerator(const Token * tok) const { const Scope * scope = tok->scope(); const std::string &tokStr = tok->str(); if (tokensThatAreNotEnumeratorValues.find(tokStr) != tokensThatAreNotEnumeratorValues.end()) { return nullptr; } // check for qualified name if (tok->strAt(-1) == "::") { // find first scope const Token *tok1 = tok; while (Token::Match(tok1->tokAt(-2), "%name% ::")) tok1 = tok1->tokAt(-2); if (tok1->strAt(-1) == "::") scope = &scopeList.front(); else { // FIXME search base class here // find first scope while (scope && scope->nestedIn) { const Scope * temp = scope->nestedIn->findRecordInNestedList(tok1->str()); if (temp) { scope = temp; break; } scope = scope->nestedIn; } } if (scope) { tok1 = tok1->tokAt(2); while (scope && Token::Match(tok1, "%name% ::")) { scope = scope->findRecordInNestedList(tok1->str()); tok1 = tok1->tokAt(2); } if (scope) { const Enumerator * enumerator = scope->findEnumerator(tokStr); if (enumerator) // enum class return enumerator; // enum else { for (std::list::const_iterator it = scope->nestedList.begin(), end = scope->nestedList.end(); it != end; ++it) { enumerator = (*it)->findEnumerator(tokStr); if (enumerator) return enumerator; } } } } } else { const Enumerator * enumerator = scope->findEnumerator(tokStr); if (enumerator) return enumerator; for (std::list::const_iterator s = scope->nestedList.begin(); s != scope->nestedList.end(); ++s) { enumerator = (*s)->findEnumerator(tokStr); if (enumerator) return enumerator; } if (scope->definedType) { const std::vector & derivedFrom = scope->definedType->derivedFrom; for (size_t i = 0, end = derivedFrom.size(); i < end; ++i) { const Type *derivedFromType = derivedFrom[i].type; if (derivedFromType && derivedFromType ->classScope) { enumerator = derivedFromType->classScope->findEnumerator(tokStr); if (enumerator) return enumerator; } } } while (scope->nestedIn) { if (scope->type == Scope::eFunction && scope->functionOf) scope = scope->functionOf; else scope = scope->nestedIn; enumerator = scope->findEnumerator(tokStr); if (enumerator) return enumerator; for (std::list::const_iterator s = scope->nestedList.begin(); s != scope->nestedList.end(); ++s) { enumerator = (*s)->findEnumerator(tokStr); if (enumerator) return enumerator; } } } tokensThatAreNotEnumeratorValues.insert(tokStr); return nullptr; } //--------------------------------------------------------------------------- const Type* SymbolDatabase::findVariableTypeInBase(const Scope* scope, const Token* typeTok) const { if (scope && scope->definedType && !scope->definedType->derivedFrom.empty()) { const std::vector &derivedFrom = scope->definedType->derivedFrom; for (std::size_t i = 0; i < derivedFrom.size(); ++i) { const Type *base = derivedFrom[i].type; if (base && base->classScope) { const Type * type = base->classScope->findType(typeTok->str()); if (type) return type; type = findVariableTypeInBase(base->classScope, typeTok); if (type) return type; } } } return nullptr; } //--------------------------------------------------------------------------- const Type* SymbolDatabase::findVariableType(const Scope *start, const Token *typeTok) const { const Scope *scope = start; // check if type does not have a namespace if (typeTok->strAt(-1) != "::" && typeTok->strAt(1) != "::") { // check if type same as scope if (start->isClassOrStruct() && typeTok->str() == start->className) return start->definedType; while (scope) { // look for type in this scope const Type * type = scope->findType(typeTok->str()); if (type) return type; // look for type in base classes if possible if (scope->isClassOrStruct()) { type = findVariableTypeInBase(scope, typeTok); if (type) return type; } // check if in member function class to see if it's present in class if (scope->type == Scope::eFunction && scope->functionOf) { const Scope *scope1 = scope->functionOf; type = scope1->findType(typeTok->str()); if (type) return type; type = findVariableTypeInBase(scope1, typeTok); if (type) return type; } scope = scope->nestedIn; } } // check for a qualified name and use it when given else if (typeTok->strAt(-1) == "::") { // check if type is not part of qualification if (typeTok->strAt(1) == "::") return nullptr; // find start of qualified function name const Token *tok1 = typeTok; while (Token::Match(tok1->tokAt(-2), "%type% ::") || (Token::simpleMatch(tok1->tokAt(-2), "> ::") && tok1->linkAt(-2) && Token::Match(tok1->linkAt(-2)->tokAt(-1), "%type%"))) { if (tok1->strAt(-1) == "::") tok1 = tok1->tokAt(-2); else tok1 = tok1->linkAt(-2)->tokAt(-1); } // check for global scope if (tok1->strAt(-1) == "::") { scope = &scopeList.front(); scope = scope->findRecordInNestedList(tok1->str()); } // find start of qualification else { while (scope) { if (scope->className == tok1->str()) break; else { const Scope *scope1 = scope->findRecordInNestedList(tok1->str()); if (scope1) { scope = scope1; break; } else if (scope->type == Scope::eFunction && scope->functionOf) scope = scope->functionOf; else scope = scope->nestedIn; } } } if (scope) { // follow qualification while (scope && (Token::Match(tok1, "%type% ::") || (Token::Match(tok1, "%type% <") && Token::simpleMatch(tok1->linkAt(1), "> ::")))) { if (tok1->strAt(1) == "::") tok1 = tok1->tokAt(2); else tok1 = tok1->linkAt(1)->tokAt(2); const Scope * temp = scope->findRecordInNestedList(tok1->str()); if (!temp) { // look in base classes const Type * type = findVariableTypeInBase(scope, tok1); if (type) return type; } scope = temp; } if (scope && scope->definedType) return scope->definedType; } } return nullptr; } bool Scope::hasInlineOrLambdaFunction() const { for (std::list::const_iterator it = nestedList.begin(); it != nestedList.end(); ++it) { const Scope *s = *it; // Inline function if (s->type == Scope::eUnconditional && Token::simpleMatch(s->bodyStart->previous(), ") {")) return true; // Lambda function if (s->type == Scope::eLambda) return true; } return false; } void Scope::findFunctionInBase(const std::string & name, size_t args, std::vector & matches) const { if (isClassOrStruct() && definedType && !definedType->derivedFrom.empty()) { const std::vector &derivedFrom = definedType->derivedFrom; for (std::size_t i = 0; i < derivedFrom.size(); ++i) { const Type *base = derivedFrom[i].type; if (base && base->classScope) { if (base->classScope == this) // Ticket #5120, #5125: Recursive class; tok should have been found already continue; for (std::multimap::const_iterator it = base->classScope->functionMap.find(name); it != base->classScope->functionMap.end() && it->first == name; ++it) { const Function *func = it->second; if (args == func->argCount() || (args < func->argCount() && args >= func->minArgCount())) { matches.push_back(func); } } base->classScope->findFunctionInBase(name, args, matches); } } } } //--------------------------------------------------------------------------- static void checkVariableCallMatch(const Variable* callarg, const Variable* funcarg, size_t& same, size_t& fallback1, size_t& fallback2) { if (callarg) { bool ptrequals = callarg->isArrayOrPointer() == funcarg->isArrayOrPointer(); bool constEquals = !callarg->isArrayOrPointer() || ((callarg->typeStartToken()->strAt(-1) == "const") == (funcarg->typeStartToken()->strAt(-1) == "const")); if (ptrequals && constEquals && callarg->typeStartToken()->str() == funcarg->typeStartToken()->str() && callarg->typeStartToken()->isUnsigned() == funcarg->typeStartToken()->isUnsigned() && callarg->typeStartToken()->isLong() == funcarg->typeStartToken()->isLong()) { same++; } else if (callarg->isArrayOrPointer()) { if (ptrequals && constEquals && funcarg->typeStartToken()->str() == "void") fallback1++; else if (constEquals && funcarg->isStlStringType() && Token::Match(callarg->typeStartToken(), "char|wchar_t")) fallback2++; } else if (ptrequals) { const bool takesInt = Token::Match(funcarg->typeStartToken(), "char|short|int|long"); const bool takesFloat = Token::Match(funcarg->typeStartToken(), "float|double"); const bool passesInt = Token::Match(callarg->typeStartToken(), "char|short|int|long"); const bool passesFloat = Token::Match(callarg->typeStartToken(), "float|double"); if ((takesInt && passesInt) || (takesFloat && passesFloat)) fallback1++; else if ((takesInt && passesFloat) || (takesFloat && passesInt)) fallback2++; } } } static bool valueTypeMatch(const ValueType * valuetype, const Token * type) { if (valuetype->typeScope && type->type() && type->type()->classScope == valuetype->typeScope) return true; return ((((type->str() == "bool" && valuetype->type == ValueType::BOOL) || (type->str() == "char" && valuetype->type == ValueType::CHAR) || (type->str() == "short" && valuetype->type == ValueType::SHORT) || (type->str() == "int" && valuetype->type == ValueType::INT) || ((type->str() == "long" && type->isLong()) && valuetype->type == ValueType::LONGLONG) || (type->str() == "long" && valuetype->type == ValueType::LONG) || (type->str() == "float" && valuetype->type == ValueType::FLOAT) || ((type->str() == "double" && type->isLong()) && valuetype->type == ValueType::LONGDOUBLE) || (type->str() == "double" && valuetype->type == ValueType::DOUBLE)) && (type->isUnsigned() == (valuetype->sign == ValueType::UNSIGNED))) || (valuetype->isEnum() && type->isEnumType() && valuetype->typeScope->className == type->str())); } const Function* Scope::findFunction(const Token *tok, bool requireConst) const { // make sure this is a function call const Token *end = tok->linkAt(1); if (!end) return nullptr; std::vector arguments; // find all the arguments for this function call for (const Token *arg = tok->tokAt(2); arg && arg != end; arg = arg->nextArgument()) { arguments.push_back(arg); } std::vector matches; // find all the possible functions that could match const std::size_t args = arguments.size(); for (std::multimap::const_iterator it = functionMap.find(tok->str()); it != functionMap.cend() && it->first == tok->str(); ++it) { const Function *func = it->second; if (args == func->argCount() || (func->isVariadic() && args >= (func->argCount() - 1)) || (args < func->argCount() && args >= func->minArgCount())) { matches.push_back(func); } } // check in base classes findFunctionInBase(tok->str(), args, matches); const Function* fallback1Func = nullptr; const Function* fallback2Func = nullptr; // check each function against the arguments in the function call for a match for (std::size_t i = 0; i < matches.size();) { bool constFallback = false; const Function * func = matches[i]; size_t same = 0; if (!requireConst || !func->isConst()) { // get the function this call is in const Scope * scope = tok->scope(); // check if this function is a member function if (scope && scope->functionOf && scope->functionOf->isClassOrStruct() && scope->function) { // check if isConst mismatches if (scope->function->isConst() != func->isConst()) { if (scope->function->isConst()) { ++i; continue; } constFallback = true; } } } size_t fallback1 = 0; size_t fallback2 = 0; bool erased = false; for (std::size_t j = 0; j < args; ++j) { // don't check variadic arguments if (func->isVariadic() && j > (func->argCount() - 1)) { break; } const Variable *funcarg = func->getArgumentVar(j); // check for a match with a variable if (Token::Match(arguments[j], "%var% ,|)")) { const Variable * callarg = check->getVariableFromVarId(arguments[j]->varId()); checkVariableCallMatch(callarg, funcarg, same, fallback1, fallback2); } // check for a match with reference of a variable else if (Token::Match(arguments[j], "* %var% ,|)")) { const Variable * callarg = check->getVariableFromVarId(arguments[j]->next()->varId()); if (callarg) { const bool funcargref = (funcarg->typeEndToken()->str() == "&"); if (funcargref && (callarg->typeStartToken()->str() == funcarg->typeStartToken()->str() && callarg->typeStartToken()->isUnsigned() == funcarg->typeStartToken()->isUnsigned() && callarg->typeStartToken()->isLong() == funcarg->typeStartToken()->isLong())) { same++; } else { // can't match so remove this function from possible matches matches.erase(matches.begin() + i); erased = true; break; } } } // check for a match with address of a variable else if (Token::Match(arguments[j], "& %var% ,|)")) { const Variable * callarg = check->getVariableFromVarId(arguments[j]->next()->varId()); if (callarg) { const bool funcargptr = (funcarg->typeEndToken()->str() == "*"); if (funcargptr && (callarg->typeStartToken()->str() == funcarg->typeStartToken()->str() && callarg->typeStartToken()->isUnsigned() == funcarg->typeStartToken()->isUnsigned() && callarg->typeStartToken()->isLong() == funcarg->typeStartToken()->isLong())) { same++; } else if (funcargptr && funcarg->typeStartToken()->str() == "void") { fallback1++; } else { // can't match so remove this function from possible matches matches.erase(matches.begin() + i); erased = true; break; } } } // check for a match with a numeric literal else if (Token::Match(arguments[j], "%num% ,|)")) { if (MathLib::isInt(arguments[j]->str()) && (!funcarg->isPointer() || MathLib::isNullValue(arguments[j]->str()))) { bool exactMatch = false; if (arguments[j]->str().find("ll") != std::string::npos || arguments[j]->str().find("LL") != std::string::npos) { if (arguments[j]->str().find('u') != std::string::npos || arguments[j]->str().find('U') != std::string::npos) { if (funcarg->typeStartToken()->isLong() && funcarg->typeStartToken()->isUnsigned() && funcarg->typeStartToken()->str() == "long") { exactMatch = true; } } else { if (funcarg->typeStartToken()->isLong() && !funcarg->typeStartToken()->isUnsigned() && funcarg->typeStartToken()->str() == "long") { exactMatch = true; } } } else if (arguments[j]->str().find('l') != std::string::npos || arguments[j]->str().find('L') != std::string::npos) { if (arguments[j]->str().find('u') != std::string::npos || arguments[j]->str().find('U') != std::string::npos) { if (!funcarg->typeStartToken()->isLong() && funcarg->typeStartToken()->isUnsigned() && funcarg->typeStartToken()->str() == "long") { exactMatch = true; } } else { if (!funcarg->typeStartToken()->isLong() && !funcarg->typeStartToken()->isUnsigned() && funcarg->typeStartToken()->str() == "long") { exactMatch = true; } } } else if (arguments[j]->str().find('u') != std::string::npos || arguments[j]->str().find('U') != std::string::npos) { if (funcarg->typeStartToken()->isUnsigned() && funcarg->typeStartToken()->str() == "int") { exactMatch = true; } else if (Token::Match(funcarg->typeStartToken(), "char|short")) { exactMatch = true; } } else { if (Token::Match(funcarg->typeStartToken(), "wchar_t|char|short|int|long")) { exactMatch = true; } } if (exactMatch) if (funcarg->isPointer()) fallback2++; else same++; else { if (funcarg->isPointer() || Token::Match(funcarg->typeStartToken(), "wchar_t|char|short|int|long")) fallback1++; else if (Token::Match(funcarg->typeStartToken(), "float|double")) fallback2++; } } else if (!funcarg->isPointer()) { bool exactMatch = false; if (arguments[j]->str().find('f') != std::string::npos || arguments[j]->str().find('F') != std::string::npos) { if (funcarg->typeStartToken()->str() == "float") { exactMatch = true; } } else if (arguments[j]->str().find('l') != std::string::npos || arguments[j]->str().find('L') != std::string::npos) { if (funcarg->typeStartToken()->isLong() && funcarg->typeStartToken()->str() == "double") { exactMatch = true; } } else { if (!funcarg->typeStartToken()->isLong() && funcarg->typeStartToken()->str() == "double") { exactMatch = true; } } if (exactMatch) same++; else { if (Token::Match(funcarg->typeStartToken(), "float|double")) fallback1++; else if (Token::Match(funcarg->typeStartToken(), "wchar_t|char|short|int|long")) fallback2++; } } } // check for a match with a string literal else if (Token::Match(arguments[j], "%str% ,|)")) { if (funcarg->typeStartToken() != funcarg->typeEndToken() && ((!arguments[j]->isLong() && Token::simpleMatch(funcarg->typeStartToken(), "char *")) || (arguments[j]->isLong() && Token::simpleMatch(funcarg->typeStartToken(), "wchar_t *")))) same++; else if (Token::simpleMatch(funcarg->typeStartToken(), "void *")) fallback1++; else if (funcarg->isStlStringType()) fallback2++; } // check for a match with a char literal else if (!funcarg->isArrayOrPointer() && Token::Match(arguments[j], "%char% ,|)")) { if (arguments[j]->isLong() && funcarg->typeStartToken()->str() == "wchar_t") same++; else if (!arguments[j]->isLong() && funcarg->typeStartToken()->str() == "char") same++; else if (Token::Match(funcarg->typeStartToken(), "wchar_t|char|short|int|long")) fallback1++; } // check for a match with a boolean literal else if (!funcarg->isArrayOrPointer() && Token::Match(arguments[j], "%bool% ,|)")) { if (Token::Match(funcarg->typeStartToken(), "bool|_Bool")) same++; else if (Token::Match(funcarg->typeStartToken(), "wchar_t|char|short|int|long")) fallback1++; } // check for a match with nullptr else if (funcarg->isPointer() && Token::Match(arguments[j], "nullptr|NULL ,|)")) { same++; } // check that function argument type is not mismatching else if (funcarg->isReference() && arguments[j]->str() == "&") { // can't match so remove this function from possible matches matches.erase(matches.begin() + i); erased = true; break; } // Try to evaluate the apparently more complex expression else { const Token* argtok = arguments[j]; while (argtok->astParent() && argtok->astParent() != tok->next() && argtok->astParent()->str() != ",") { argtok = argtok->astParent(); } if (argtok && argtok->valueType()) { const ValueType* valuetype = argtok->valueType(); const bool isArrayOrPointer = valuetype->pointer; const bool ptrequals = isArrayOrPointer == funcarg->isArrayOrPointer(); const bool constEquals = !isArrayOrPointer || ((valuetype->constness > 0) == (funcarg->typeStartToken()->strAt(-1) == "const")); if (ptrequals && constEquals && valueTypeMatch(valuetype, funcarg->typeStartToken())) { same++; } else if (isArrayOrPointer) { if (ptrequals && constEquals && valuetype->type == ValueType::VOID) fallback1++; else if (constEquals && funcarg->isStlStringType() && valuetype->type == ValueType::CHAR) fallback2++; } else if (ptrequals) { const bool takesInt = Token::Match(funcarg->typeStartToken(), "bool|char|short|int|long") || funcarg->typeStartToken()->isEnumType(); const bool takesFloat = Token::Match(funcarg->typeStartToken(), "float|double"); const bool passesInt = valuetype->isIntegral() || valuetype->isEnum(); const bool passesFloat = valuetype->isFloat(); if ((takesInt && passesInt) || (takesFloat && passesFloat)) fallback1++; else if ((takesInt && passesFloat) || (takesFloat && passesInt)) fallback2++; } } else { while (Token::Match(argtok, ".|::")) argtok = argtok->astOperand2(); if (argtok) { const Variable * callarg = check->getVariableFromVarId(argtok->varId()); checkVariableCallMatch(callarg, funcarg, same, fallback1, fallback2); } } } } const size_t hasToBe = func->isVariadic() ? (func->argCount() - 1) : args; // check if all arguments matched if (same == hasToBe) { if (constFallback) fallback1Func = func; else return func; } else if (!fallback1Func) { if (same + fallback1 == hasToBe) fallback1Func = func; else if (!fallback2Func && same + fallback2 + fallback1 == hasToBe) fallback2Func = func; } if (!erased) ++i; } // Fallback cases if (fallback1Func) return fallback1Func; if (fallback2Func) return fallback2Func; // Only one candidate left if (matches.size() == 1) return matches[0]; return nullptr; } //--------------------------------------------------------------------------- const Function* SymbolDatabase::findFunction(const Token *tok) const { // find the scope this function is in const Scope *currScope = tok->scope(); while (currScope && currScope->isExecutable()) { if (currScope->functionOf) currScope = currScope->functionOf; else currScope = currScope->nestedIn; } // check for a qualified name and use it when given if (tok->strAt(-1) == "::") { // find start of qualified function name const Token *tok1 = tok; while (Token::Match(tok1->tokAt(-2), ">|%type% ::")) { if (tok1->strAt(-2) == ">") { if (tok1->linkAt(-2)) tok1 = tok1->linkAt(-2)->tokAt(-1); else { if (_settings->debugwarnings) debugMessage(tok1->tokAt(-2), "SymbolDatabase::findFunction found '>' without link."); return nullptr; } } else tok1 = tok1->tokAt(-2); } // check for global scope if (tok1->strAt(-1) == "::") { currScope = &scopeList.front(); currScope = currScope->findRecordInNestedList(tok1->str()); } // find start of qualification else { while (currScope) { if (currScope->className == tok1->str()) break; else { const Scope *scope = currScope->findRecordInNestedList(tok1->str()); if (scope) { currScope = scope; break; } else currScope = currScope->nestedIn; } } } if (currScope) { while (currScope && !(Token::Match(tok1, "%type% :: %any% (") || (Token::Match(tok1, "%type% <") && Token::Match(tok1->linkAt(1), "> :: %any% (")))) { if (tok1->strAt(1) == "::") tok1 = tok1->tokAt(2); else tok1 = tok1->linkAt(1)->tokAt(2); currScope = currScope->findRecordInNestedList(tok1->str()); } tok1 = tok1->tokAt(2); if (currScope && tok1) return currScope->findFunction(tok1); } } // check for member function else if (Token::Match(tok->tokAt(-2), "!!this .")) { const Token *tok1 = tok->tokAt(-2); if (Token::Match(tok1, "%var% .")) { const Variable *var = getVariableFromVarId(tok1->varId()); if (var && var->typeScope()) return var->typeScope()->findFunction(tok, var->isConst()); } } // check in enclosing scopes else { while (currScope) { const Function *func = currScope->findFunction(tok); if (func) return func; currScope = currScope->nestedIn; } } return nullptr; } //--------------------------------------------------------------------------- const Scope *SymbolDatabase::findScopeByName(const std::string& name) const { for (std::list::const_iterator it = scopeList.begin(); it != scopeList.end(); ++it) { if (it->className == name) return &*it; } return nullptr; } //--------------------------------------------------------------------------- Scope *Scope::findInNestedList(const std::string & name) { std::list::iterator it; for (it = nestedList.begin(); it != nestedList.end(); ++it) { if ((*it)->className == name) return (*it); } return nullptr; } //--------------------------------------------------------------------------- const Scope *Scope::findRecordInNestedList(const std::string & name) const { std::list::const_iterator it; for (it = nestedList.begin(); it != nestedList.end(); ++it) { if ((*it)->className == name && (*it)->type != eFunction) return (*it); } const Type * nested_type = findType(name); if (nested_type) return nested_type->classScope; return nullptr; } //--------------------------------------------------------------------------- const Type* Scope::findType(const std::string & name) const { auto it = definedTypesMap.find(name); // Type was found if (definedTypesMap.end() != it) return (*it).second; // is type defined in anonymous namespace.. it = definedTypesMap.find(""); if (it != definedTypesMap.end()) { for (const Scope *scope : nestedList) { if (scope->className.empty() && (scope->type == eNamespace || scope->isClassOrStructOrUnion())) { const Type *t = scope->findType(name); if (t) return t; } } } // Type was not found return nullptr; } //--------------------------------------------------------------------------- Scope *Scope::findInNestedListRecursive(const std::string & name) { std::list::iterator it; for (it = nestedList.begin(); it != nestedList.end(); ++it) { if ((*it)->className == name) return (*it); } for (it = nestedList.begin(); it != nestedList.end(); ++it) { Scope *child = (*it)->findInNestedListRecursive(name); if (child) return child; } return nullptr; } //--------------------------------------------------------------------------- const Function *Scope::getDestructor() const { std::list::const_iterator it; for (it = functionList.begin(); it != functionList.end(); ++it) { if (it->type == Function::eDestructor) return &(*it); } return nullptr; } //--------------------------------------------------------------------------- bool SymbolDatabase::isCPP() const { return _tokenizer->isCPP(); } //--------------------------------------------------------------------------- const Scope *SymbolDatabase::findScope(const Token *tok, const Scope *startScope) const { const Scope *scope = nullptr; // absolute path if (tok->str() == "::") { tok = tok->next(); scope = &scopeList.front(); } // relative path else if (tok->isName()) { scope = startScope; } while (scope && tok && tok->isName()) { if (tok->strAt(1) == "::") { scope = scope->findRecordInNestedList(tok->str()); tok = tok->tokAt(2); } else if (tok->strAt(1) == "<" && Token::simpleMatch(tok->linkAt(1), "> ::")) { scope = scope->findRecordInNestedList(tok->str()); tok = tok->linkAt(1)->tokAt(2); } else return scope->findRecordInNestedList(tok->str()); } // not a valid path return nullptr; } //--------------------------------------------------------------------------- const Type* SymbolDatabase::findType(const Token *startTok, const Scope *startScope) const { // skip over struct or union if (Token::Match(startTok, "struct|union")) startTok = startTok->next(); // type same as scope if (startTok->str() == startScope->className && startScope->isClassOrStruct() && startTok->strAt(1) != "::") return startScope->definedType; const Scope* start_scope = startScope; // absolute path - directly start in global scope if (startTok->str() == "::") { startTok = startTok->next(); start_scope = &scopeList.front(); } const Token* tok = startTok; const Scope* scope = start_scope; while (scope && tok && tok->isName()) { if (tok->strAt(1) == "::" || (tok->strAt(1) == "<" && Token::simpleMatch(tok->linkAt(1), "> ::"))) { scope = scope->findRecordInNestedList(tok->str()); if (scope) { if (tok->strAt(1) == "::") tok = tok->tokAt(2); else tok = tok->linkAt(1)->tokAt(2); } else { start_scope = start_scope->nestedIn; if (!start_scope) break; scope = start_scope; tok = startTok; } } else { const Type * type = scope->findType(tok->str()); if (type) return type; else break; } } // check using namespaces while (startScope) { for (std::list::const_iterator it = startScope->usingList.begin(); it != startScope->usingList.end(); ++it) { tok = startTok; scope = it->scope; start_scope = startScope; while (scope && tok && tok->isName()) { if (tok->strAt(1) == "::" || (tok->strAt(1) == "<" && Token::simpleMatch(tok->linkAt(1), "> ::"))) { scope = scope->findRecordInNestedList(tok->str()); if (scope) { if (tok->strAt(1) == "::") tok = tok->tokAt(2); else tok = tok->linkAt(1)->tokAt(2); } else { start_scope = start_scope->nestedIn; if (!start_scope) break; scope = start_scope; tok = startTok; } } else { const Type * type = scope->findType(tok->str()); if (type) return type; else break; } } } startScope = startScope->nestedIn; } // not a valid path return nullptr; } //--------------------------------------------------------------------------- const Type* SymbolDatabase::findTypeInNested(const Token *startTok, const Scope *startScope) const { // skip over struct or union if (Token::Match(startTok, "struct|union|enum")) startTok = startTok->next(); // type same as scope if (startTok->str() == startScope->className && startScope->isClassOrStruct()) return startScope->definedType; bool hasPath = false; // absolute path - directly start in global scope if (startTok->str() == "::") { hasPath = true; startTok = startTok->next(); startScope = &scopeList.front(); } const Token* tok = startTok; const Scope* scope = startScope; while (scope && tok && tok->isName()) { if (tok->strAt(1) == "::" || (tok->strAt(1) == "<" && Token::simpleMatch(tok->linkAt(1), "> ::"))) { hasPath = true; scope = scope->findRecordInNestedList(tok->str()); if (scope) { if (tok->strAt(1) == "::") tok = tok->tokAt(2); else tok = tok->linkAt(1)->tokAt(2); } else { startScope = startScope->nestedIn; if (!startScope) break; scope = startScope; tok = startTok; } } else { const Type * type = scope->findType(tok->str()); if (hasPath || type) return type; else { scope = scope->nestedIn; if (!scope) break; } } } // not a valid path return nullptr; } //--------------------------------------------------------------------------- const Scope * SymbolDatabase::findNamespace(const Token * tok, const Scope * scope) const { const Scope * s = findScope(tok, scope); if (s) return s; else if (scope->nestedIn) return findNamespace(tok, scope->nestedIn); return nullptr; } //--------------------------------------------------------------------------- Function * SymbolDatabase::findFunctionInScope(const Token *func, const Scope *ns, const std::string & path, unsigned int path_length) { const Function * function = nullptr; const bool destructor = func->strAt(-1) == "~"; for (std::multimap::const_iterator it = ns->functionMap.find(func->str()); it != ns->functionMap.end() && it->first == func->str(); ++it) { if (Function::argsMatch(ns, it->second->argDef->next(), func->tokAt(2), path, path_length) && it->second->isDestructor() == destructor) { function = it->second; break; } } if (!function) { const Scope * scope = ns->findRecordInNestedList(func->str()); if (scope && Token::Match(func->tokAt(1), "::|<")) { if (func->strAt(1) == "::") func = func->tokAt(2); else if (func->linkAt(1)) func = func->linkAt(1)->tokAt(2); else return nullptr; if (func->str() == "~") func = func->next(); function = findFunctionInScope(func, scope, path, path_length); } } return const_cast(function); } //--------------------------------------------------------------------------- namespace { #define C_KEYWORDS\ "_Bool", "auto", "break", "case", "char", "const", "continue", "default", "do",\ "double", "else", "enum", "extern", "float", "for", "goto", "if", "inline",\ "int", "long", "register", "restrict", "return", "short", "signed", "sizeof",\ "static", "struct", "switch", "typedef", "union", "unsigned", "void", "volatile",\ "while" const std::set c_keywords = { C_KEYWORDS }; const std::set cpp_keywords = { C_KEYWORDS, "alignas", "alignof", "and", "and_eq", "asm", "auto", "bitand", "bitor", "bool", "break", "case", "catch", "char", "class", "compl", "concept", "const", "constexpr", "const_cast", "continue", "decltype", "default", "delete", "do", "double", "dynamic_cast", "else", "enum", "explicit", "export", "extern", "false", "float", "for", "friend", "goto", "if", "inline", "int", "long", "mutable", "namespace", "new", "noexcept", "not", "not_eq", "nullptr", "operator", "or", "or_eq", "private", "protected", "public", "register", "reinterpret_cast", "requires", "return", "short", "signed", "sizeof", "static", "static_assert", "static_cast", "struct", "switch", "template", "this", "thread_local", "throw", "true", "try", "typedef", "typeid", "typename", "union", "unsigned", "using", "virtual", "void", "volatile", "wchar_t", "while", "xor", "xor_eq" }; } bool SymbolDatabase::isReservedName(const std::string& iName) const { if (isCPP()) return cpp_keywords.find(iName) != cpp_keywords.cend(); else return c_keywords.find(iName) != c_keywords.cend(); } unsigned int SymbolDatabase::sizeOfType(const Token *type) const { unsigned int size = _tokenizer->sizeOfType(type); if (size == 0 && type->type() && type->type()->isEnumType() && type->type()->classScope) { size = _settings->sizeof_int; const Token * enum_type = type->type()->classScope->enumType; if (enum_type) size = _tokenizer->sizeOfType(enum_type); } return size; } static const Token * parsedecl(const Token *type, ValueType * const valuetype, ValueType::Sign defaultSignedness, const Settings* settings); void SymbolDatabase::setValueType(Token *tok, const Variable &var) { ValueType valuetype; if (var.nameToken()) valuetype.bits = var.nameToken()->bits(); valuetype.pointer = var.dimensions().size(); valuetype.typeScope = var.typeScope(); if (parsedecl(var.typeStartToken(), &valuetype, defaultSignedness, _settings)) setValueType(tok, valuetype); } void SymbolDatabase::setValueType(Token *tok, const Enumerator &enumerator) { ValueType valuetype; valuetype.typeScope = enumerator.scope; const Token * type = enumerator.scope->enumType; if (type) { valuetype.type = ValueType::typeFromString(type->str(), type->isLong()); if (valuetype.type == ValueType::Type::UNKNOWN_TYPE && type->isStandardType()) valuetype.fromLibraryType(type->str(), _settings); if (valuetype.isIntegral()) { if (type->isSigned()) valuetype.sign = ValueType::Sign::SIGNED; else if (type->isUnsigned()) valuetype.sign = ValueType::Sign::UNSIGNED; else if (valuetype.type == ValueType::Type::CHAR) valuetype.sign = defaultSignedness; else valuetype.sign = ValueType::Sign::SIGNED; } setValueType(tok, valuetype); } else { valuetype.sign = ValueType::SIGNED; valuetype.type = ValueType::INT; setValueType(tok, valuetype); } } static void setAutoTokenProperties(Token * const autoTok) { const ValueType *valuetype = autoTok->valueType(); if (valuetype->isIntegral() || valuetype->isFloat()) autoTok->isStandardType(true); } void SymbolDatabase::setValueType(Token *tok, const ValueType &valuetype) { tok->setValueType(new ValueType(valuetype)); Token *parent = const_cast(tok->astParent()); if (!parent || parent->valueType()) return; if (!parent->astOperand1()) return; const ValueType *vt1 = parent->astOperand1() ? parent->astOperand1()->valueType() : nullptr; const ValueType *vt2 = parent->astOperand2() ? parent->astOperand2()->valueType() : nullptr; if (vt1 && Token::Match(parent, "<<|>>")) { if (!cpp || (vt2 && vt2->isIntegral())) setValueType(parent, *vt1); return; } if (parent->isAssignmentOp()) { if (vt1) setValueType(parent, *vt1); else if (cpp && ((Token::Match(parent->tokAt(-3), "%var% ; %var% =") && parent->strAt(-3) == parent->strAt(-1)) || Token::Match(parent->tokAt(-1), "%var% ="))) { Token *var1Tok = parent->strAt(-2) == ";" ? parent->tokAt(-3) : parent->tokAt(-1); Token *autoTok = nullptr; if (Token::Match(var1Tok->tokAt(-2), ";|{|}|(|const auto")) autoTok = var1Tok->previous(); else if (Token::Match(var1Tok->tokAt(-3), ";|{|}|(|const auto *")) autoTok = var1Tok->tokAt(-2); if (autoTok) { ValueType vt(*vt2); if (autoTok->strAt(1) == "*" && vt.pointer) vt.pointer--; if (autoTok->strAt(-1) == "const") vt.constness |= 1; setValueType(autoTok, vt); setAutoTokenProperties(autoTok); setValueType(var1Tok, *vt2); setValueType(parent->previous(), *vt2); Variable *var = const_cast(parent->previous()->variable()); if (var) { var->setFlags(*vt2); if (vt2->typeScope && vt2->typeScope->definedType) { var->type(vt2->typeScope->definedType); if (autoTok->valueType()->pointer == 0) autoTok->type(vt2->typeScope->definedType); } } } } return; } if (parent->str() == "[" && (!cpp || parent->astOperand1() == tok) && valuetype.pointer > 0U && !Token::Match(parent->previous(), "[{,]")) { const Token *op1 = parent->astOperand1(); while (op1 && op1->str() == "[") op1 = op1->astOperand1(); ValueType vt(valuetype); // the "[" is a dereference unless this is a variable declaration if (!(op1 && op1->variable() && op1->variable()->nameToken() == op1)) vt.pointer -= 1U; setValueType(parent, vt); return; } if (Token::Match(parent->previous(), "%name% (") && parent->astOperand1() == tok && valuetype.pointer > 0U) { ValueType vt(valuetype); vt.pointer -= 1U; setValueType(parent, vt); return; } if (parent->str() == "*" && !parent->astOperand2() && valuetype.pointer > 0U) { ValueType vt(valuetype); vt.pointer -= 1U; setValueType(parent, vt); return; } if (parent->str() == "&" && !parent->astOperand2()) { ValueType vt(valuetype); vt.pointer += 1U; setValueType(parent, vt); return; } if ((parent->str() == "." || parent->str() == "::") && parent->astOperand2() && parent->astOperand2()->isName()) { const Variable* var = parent->astOperand2()->variable(); if (!var && valuetype.typeScope && vt1) { const std::string &name = parent->astOperand2()->str(); const Scope *typeScope = vt1->typeScope; if (!typeScope) return; for (std::list::const_iterator it = typeScope->varlist.begin(); it != typeScope->varlist.end(); ++it) { if (it->nameToken()->str() == name) { var = &*it; break; } } } if (var) setValueType(parent, *var); return; } // range for loop, auto if (vt2 && parent->str() == ":" && Token::Match(parent->astParent(), "( const| auto *|&| %var% :") && !parent->previous()->valueType() && Token::simpleMatch(parent->astParent()->astOperand1(), "for")) { const bool isconst = Token::simpleMatch(parent->astParent()->next(), "const"); Token * const autoToken = const_cast(parent->astParent()->tokAt(isconst ? 2 : 1)); if (vt2->pointer) { ValueType autovt(*vt2); autovt.pointer--; autovt.constness = 0; setValueType(autoToken, autovt); setAutoTokenProperties(autoToken); ValueType varvt(*vt2); varvt.pointer--; if (isconst) varvt.constness |= 1; setValueType(parent->previous(), varvt); Variable *var = const_cast(parent->previous()->variable()); if (var) { var->setFlags(varvt); if (vt2->typeScope && vt2->typeScope->definedType) { var->type(vt2->typeScope->definedType); autoToken->type(vt2->typeScope->definedType); } } } else if (vt2->container) { // TODO: Determine exact type of RHS const Token *typeStart = parent->astOperand2(); while (typeStart) { if (typeStart->variable()) typeStart = typeStart->variable()->typeStartToken(); else if (typeStart->str() == "(" && typeStart->previous() && typeStart->previous()->function()) typeStart = typeStart->previous()->function()->retDef; else break; } // TODO: Get type better if (Token::Match(typeStart, "std :: %type% < %type% *| *| >")) { ValueType autovt; if (parsedecl(typeStart->tokAt(4), &autovt, defaultSignedness, _settings)) { setValueType(autoToken, autovt); setAutoTokenProperties(autoToken); ValueType varvt(autovt); if (isconst) varvt.constness |= 1; setValueType(parent->previous(), varvt); Variable * var = const_cast(parent->previous()->variable()); if (var) { var->setFlags(varvt); const Type * type = typeStart->tokAt(4)->type(); if (type && type->classScope && type->classScope->definedType) { autoToken->type(type->classScope->definedType); var->type(type->classScope->definedType); } } } } } } if (vt1 && vt1->containerTypeToken && parent->str() == "[") { ValueType vtParent; if (parsedecl(vt1->containerTypeToken, &vtParent, defaultSignedness, _settings)) { setValueType(parent, vtParent); return; } } if (!vt1) return; if (parent->astOperand2() && !vt2) return; const bool ternary = parent->str() == ":" && parent->astParent() && parent->astParent()->str() == "?"; if (ternary) { if (vt2 && vt1->pointer == vt2->pointer && vt1->type == vt2->type && vt1->sign == vt2->sign) setValueType(parent, *vt2); parent = const_cast(parent->astParent()); } if (ternary || parent->isArithmeticalOp() || parent->tokType() == Token::eIncDecOp) { if (vt1->pointer != 0U && vt2 && vt2->pointer == 0U) { setValueType(parent, *vt1); return; } if (vt1->pointer == 0U && vt2 && vt2->pointer != 0U) { setValueType(parent, *vt2); return; } if (vt1->pointer != 0U) { if (ternary || parent->tokType() == Token::eIncDecOp) // result is pointer setValueType(parent, *vt1); else // result is pointer diff setValueType(parent, ValueType(ValueType::Sign::SIGNED, ValueType::Type::INT, 0U, 0U, "ptrdiff_t")); return; } if (vt1->type == ValueType::Type::LONGDOUBLE || (vt2 && vt2->type == ValueType::Type::LONGDOUBLE)) { setValueType(parent, ValueType(ValueType::Sign::UNKNOWN_SIGN, ValueType::Type::LONGDOUBLE, 0U)); return; } if (vt1->type == ValueType::Type::DOUBLE || (vt2 && vt2->type == ValueType::Type::DOUBLE)) { setValueType(parent, ValueType(ValueType::Sign::UNKNOWN_SIGN, ValueType::Type::DOUBLE, 0U)); return; } if (vt1->type == ValueType::Type::FLOAT || (vt2 && vt2->type == ValueType::Type::FLOAT)) { setValueType(parent, ValueType(ValueType::Sign::UNKNOWN_SIGN, ValueType::Type::FLOAT, 0U)); return; } // iterator +/- integral = iterator if (vt1->type == ValueType::Type::ITERATOR && vt2 && vt2->isIntegral() && (parent->str() == "+" || parent->str() == "-")) { setValueType(parent, *vt1); return; } } if (vt1->isIntegral() && vt1->pointer == 0U && (!vt2 || (vt2->isIntegral() && vt2->pointer == 0U)) && (ternary || parent->isArithmeticalOp() || parent->tokType() == Token::eBitOp || parent->tokType() == Token::eIncDecOp || parent->isAssignmentOp())) { ValueType vt; if (!vt2 || vt1->type > vt2->type) { vt.type = vt1->type; vt.sign = vt1->sign; vt.originalTypeName = vt1->originalTypeName; } else if (vt1->type == vt2->type) { vt.type = vt1->type; if (vt1->sign == ValueType::Sign::UNSIGNED || vt2->sign == ValueType::Sign::UNSIGNED) vt.sign = ValueType::Sign::UNSIGNED; else if (vt1->sign == ValueType::Sign::UNKNOWN_SIGN || vt2->sign == ValueType::Sign::UNKNOWN_SIGN) vt.sign = ValueType::Sign::UNKNOWN_SIGN; else vt.sign = ValueType::Sign::SIGNED; vt.originalTypeName = (vt1->originalTypeName.empty() ? vt2 : vt1)->originalTypeName; } else { vt.type = vt2->type; vt.sign = vt2->sign; vt.originalTypeName = vt2->originalTypeName; } if (vt.type < ValueType::Type::INT) { vt.type = ValueType::Type::INT; vt.sign = ValueType::Sign::SIGNED; vt.originalTypeName.clear(); } setValueType(parent, vt); return; } } static const Token * parsedecl(const Token *type, ValueType * const valuetype, ValueType::Sign defaultSignedness, const Settings* settings) { const unsigned int pointer0 = valuetype->pointer; while (Token::Match(type->previous(), "%name%")) type = type->previous(); valuetype->sign = ValueType::Sign::UNKNOWN_SIGN; if (!valuetype->typeScope) valuetype->type = ValueType::Type::UNKNOWN_TYPE; else if (valuetype->typeScope->type == Scope::eEnum) { const Token * enum_type = valuetype->typeScope->enumType; if (enum_type) { if (enum_type->isSigned()) valuetype->sign = ValueType::Sign::SIGNED; else if (enum_type->isUnsigned()) valuetype->sign = ValueType::Sign::UNSIGNED; else valuetype->sign = defaultSignedness; const ValueType::Type t = ValueType::typeFromString(enum_type->str(), enum_type->isLong()); if (t != ValueType::Type::UNKNOWN_TYPE) valuetype->type = t; else if (enum_type->isStandardType()) valuetype->fromLibraryType(enum_type->str(), settings); } else valuetype->type = ValueType::Type::INT; } else valuetype->type = ValueType::Type::RECORD; while (Token::Match(type, "%name%|*|&|::") && !type->variable() && !type->function()) { if (type->isSigned()) valuetype->sign = ValueType::Sign::SIGNED; else if (type->isUnsigned()) valuetype->sign = ValueType::Sign::UNSIGNED; if (valuetype->type == ValueType::Type::UNKNOWN_TYPE && type->type() && type->type()->isTypeAlias() && type->type()->typeStart && type->type()->typeStart->str() != type->str()) parsedecl(type->type()->typeStart, valuetype, defaultSignedness, settings); else if (type->str() == "const") valuetype->constness |= (1 << (valuetype->pointer - pointer0)); else if (const Library::Container *container = settings->library.detectContainer(type)) { valuetype->type = ValueType::Type::CONTAINER; valuetype->container = container; while (Token::Match(type, "%name%|::|<")) { if (type->str() == "<" && type->link()) { if (container->type_templateArgNo >= 0) { const Token *templateType = type->next(); for (int j = 0; templateType && j < container->type_templateArgNo; j++) templateType = templateType->nextTemplateArgument(); valuetype->containerTypeToken = templateType; } type = type->link(); } type = type->next(); } continue; } else if (Token::Match(type, "%name% :: %name%")) { std::string typestr; const Token *end = type; while (Token::Match(end, "%name% :: %name%")) { typestr += end->str() + "::"; end = end->tokAt(2); } typestr += end->str(); if (valuetype->fromLibraryType(typestr, settings)) type = end; } else if (ValueType::Type::UNKNOWN_TYPE != ValueType::typeFromString(type->str(), type->isLong())) valuetype->type = ValueType::typeFromString(type->str(), type->isLong()); else if (type->str() == "auto") { const ValueType *vt = type->valueType(); if (!vt) return nullptr; valuetype->type = vt->type; valuetype->pointer = vt->pointer; if (vt->sign != ValueType::Sign::UNKNOWN_SIGN) valuetype->sign = vt->sign; valuetype->constness = vt->constness; while (Token::Match(type, "%name%|*|&|::") && !type->variable()) type = type->next(); break; } else if (!valuetype->typeScope && (type->str() == "struct" || type->str() == "enum")) valuetype->type = type->str() == "struct" ? ValueType::Type::RECORD : ValueType::Type::NONSTD; else if (!valuetype->typeScope && type->type() && type->type()->classScope) { valuetype->type = ValueType::Type::RECORD; valuetype->typeScope = type->type()->classScope; } else if (type->isName() && valuetype->sign != ValueType::Sign::UNKNOWN_SIGN && valuetype->pointer == 0U) return nullptr; else if (type->str() == "*") valuetype->pointer++; else if (type->isStandardType()) valuetype->fromLibraryType(type->str(), settings); if (!type->originalName().empty()) valuetype->originalTypeName = type->originalName(); type = type->next(); } // Set signedness for integral types.. if (valuetype->isIntegral() && valuetype->sign == ValueType::Sign::UNKNOWN_SIGN) { if (valuetype->type == ValueType::Type::CHAR) valuetype->sign = defaultSignedness; else if (valuetype->type >= ValueType::Type::SHORT) valuetype->sign = ValueType::Sign::SIGNED; } return (type && (valuetype->type != ValueType::Type::UNKNOWN_TYPE || valuetype->pointer > 0)) ? type : nullptr; } static const Scope *getClassScope(const Token *tok) { return tok && tok->valueType() && tok->valueType()->typeScope && tok->valueType()->typeScope->isClassOrStruct() ? tok->valueType()->typeScope : nullptr; } static const Function *getOperatorFunction(const Token * const tok) { const std::string functionName("operator" + tok->str()); std::multimap::const_iterator it; const Scope *classScope = getClassScope(tok->astOperand1()); if (classScope) { it = classScope->functionMap.find(functionName); if (it != classScope->functionMap.end()) return it->second; } classScope = getClassScope(tok->astOperand2()); if (classScope) { it = classScope->functionMap.find(functionName); if (it != classScope->functionMap.end()) return it->second; } return nullptr; } void SymbolDatabase::setValueTypeInTokenList() { Token * tokens = const_cast(_tokenizer)->list.front(); for (Token *tok = tokens; tok; tok = tok->next()) tok->setValueType(nullptr); for (Token *tok = tokens; tok; tok = tok->next()) { if (tok->isNumber()) { if (MathLib::isFloat(tok->str())) { ValueType::Type type = ValueType::Type::DOUBLE; const char suffix = tok->str()[tok->str().size() - 1]; if (suffix == 'f' || suffix == 'F') type = ValueType::Type::FLOAT; else if (suffix == 'L' || suffix == 'l') type = ValueType::Type::LONGDOUBLE; setValueType(tok, ValueType(ValueType::Sign::UNKNOWN_SIGN, type, 0U)); } else if (MathLib::isInt(tok->str())) { const bool unsignedSuffix = (tok->str().find_last_of("uU") != std::string::npos); ValueType::Sign sign = unsignedSuffix ? ValueType::Sign::UNSIGNED : ValueType::Sign::SIGNED; ValueType::Type type; const MathLib::bigint value = MathLib::toLongNumber(tok->str()); if (_settings->platformType == cppcheck::Platform::Unspecified) type = ValueType::Type::INT; else if (_settings->isIntValue(unsignedSuffix ? (value >> 1) : value)) type = ValueType::Type::INT; else if (_settings->isLongValue(unsignedSuffix ? (value >> 1) : value)) type = ValueType::Type::LONG; else type = ValueType::Type::LONGLONG; if (MathLib::isIntHex(tok->str())) sign = ValueType::Sign::UNSIGNED; for (std::size_t pos = tok->str().size() - 1U; pos > 0U; --pos) { const char suffix = tok->str()[pos]; if (suffix == 'u' || suffix == 'U') sign = ValueType::Sign::UNSIGNED; else if (suffix == 'l' || suffix == 'L') type = (type == ValueType::Type::INT) ? ValueType::Type::LONG : ValueType::Type::LONGLONG; else if (pos > 2U && suffix == '4' && tok->str()[pos - 1] == '6' && tok->str()[pos - 2] == 'i') { type = ValueType::Type::LONGLONG; pos -= 2; } else break; } setValueType(tok, ValueType(sign, type, 0U)); } } else if (tok->isComparisonOp() || tok->tokType() == Token::eLogicalOp) { if (cpp && tok->isComparisonOp() && (getClassScope(tok->astOperand1()) || getClassScope(tok->astOperand2()))) { const Function *function = getOperatorFunction(tok); if (function) { ValueType vt; parsedecl(function->retDef, &vt, defaultSignedness, _settings); setValueType(tok, vt); continue; } } setValueType(tok, ValueType(ValueType::Sign::UNKNOWN_SIGN, ValueType::Type::BOOL, 0U)); } else if (tok->tokType() == Token::eChar) setValueType(tok, ValueType(ValueType::Sign::UNKNOWN_SIGN, ValueType::Type::CHAR, 0U)); else if (tok->tokType() == Token::eString) { ValueType valuetype(ValueType::Sign::UNKNOWN_SIGN, ValueType::Type::CHAR, 1U, 1U); if (tok->isLong()) { valuetype.originalTypeName = "wchar_t"; valuetype.type = ValueType::Type::SHORT; } setValueType(tok, valuetype); } else if (tok->str() == "(") { // cast if (!tok->astOperand2() && Token::Match(tok, "( %name%")) { ValueType valuetype; if (Token::simpleMatch(parsedecl(tok->next(), &valuetype, defaultSignedness, _settings), ")")) setValueType(tok, valuetype); } // C++ cast if (tok->astOperand2() && Token::Match(tok->astOperand1(), "static_cast|const_cast|dynamic_cast|reinterpret_cast < %name%") && tok->astOperand1()->linkAt(1)) { ValueType valuetype; if (Token::simpleMatch(parsedecl(tok->astOperand1()->tokAt(2), &valuetype, defaultSignedness, _settings), ">")) setValueType(tok, valuetype); } // function else if (tok->previous() && tok->previous()->function() && tok->previous()->function()->retDef) { ValueType valuetype; if (parsedecl(tok->previous()->function()->retDef, &valuetype, defaultSignedness, _settings)) setValueType(tok, valuetype); } else if (Token::simpleMatch(tok->previous(), "sizeof (")) { // TODO: use specified size_t type ValueType valuetype(ValueType::Sign::UNSIGNED, ValueType::Type::LONG, 0U); valuetype.originalTypeName = "size_t"; setValueType(tok, valuetype); if (Token::Match(tok, "( %type% %type%| *| *| )")) { ValueType vt; if (parsedecl(tok->next(), &vt, defaultSignedness, _settings)) { setValueType(tok->next(), vt); } } } // function style cast else if (tok->previous() && tok->previous()->isStandardType()) { ValueType valuetype; valuetype.type = ValueType::typeFromString(tok->previous()->str(), tok->previous()->isLong()); setValueType(tok, valuetype); } // constructor else if (tok->previous() && tok->previous()->type() && tok->previous()->type()->classScope) { ValueType valuetype; valuetype.type = ValueType::RECORD; valuetype.typeScope = tok->previous()->type()->classScope; setValueType(tok, valuetype); } // library function else if (tok->previous()) { const std::string& typestr(_settings->library.returnValueType(tok->previous())); if (typestr.empty() || typestr == "iterator") { if (Token::simpleMatch(tok->astOperand1(), ".") && tok->astOperand1()->astOperand1() && tok->astOperand1()->astOperand2() && tok->astOperand1()->astOperand1()->valueType() && tok->astOperand1()->astOperand1()->valueType()->container) { const Library::Container *cont = tok->astOperand1()->astOperand1()->valueType()->container; const std::map::const_iterator it = cont->functions.find(tok->astOperand1()->astOperand2()->str()); if (it != cont->functions.end()) { if (it->second.yield == Library::Container::Yield::START_ITERATOR || it->second.yield == Library::Container::Yield::END_ITERATOR || it->second.yield == Library::Container::Yield::ITERATOR) { ValueType vt; vt.type = ValueType::Type::ITERATOR; vt.container = cont; setValueType(tok, vt); } } } continue; } TokenList tokenList(_settings); std::istringstream istr(typestr+";"); if (tokenList.createTokens(istr)) { ValueType vt; assert(tokenList.front()); tokenList.simplifyStdType(); if (parsedecl(tokenList.front(), &vt, defaultSignedness, _settings)) { setValueType(tok, vt); } } } } else if (tok->variable()) { setValueType(tok, *tok->variable()); } else if (tok->enumerator()) { setValueType(tok, *tok->enumerator()); } else if (cpp && tok->str() == "new") { const Token *typeTok = tok->next(); if (Token::Match(typeTok, "( std| ::| nothrow )")) typeTok = typeTok->link()->next(); if (const Library::Container *c = _settings->library.detectContainer(typeTok)) { ValueType vt; vt.pointer = 1; vt.container = c; vt.type = ValueType::Type::CONTAINER; setValueType(tok, vt); continue; } std::string typestr; while (Token::Match(typeTok, "%name% :: %name%")) { typestr += typeTok->str() + "::"; typeTok = typeTok->tokAt(2); } if (!Token::Match(typeTok, "%type% ;|[|(")) continue; typestr += typeTok->str(); ValueType vt; vt.pointer = 1; if (typeTok->type() && typeTok->type()->classScope) { vt.type = ValueType::Type::RECORD; vt.typeScope = typeTok->type()->classScope; } else { vt.type = ValueType::typeFromString(typestr, typeTok->isLong()); if (vt.type == ValueType::Type::UNKNOWN_TYPE) vt.fromLibraryType(typestr, _settings); if (vt.type == ValueType::Type::UNKNOWN_TYPE) continue; if (typeTok->isUnsigned()) vt.sign = ValueType::Sign::UNSIGNED; else if (typeTok->isSigned()) vt.sign = ValueType::Sign::SIGNED; if (vt.sign == ValueType::Sign::UNKNOWN_SIGN && vt.isIntegral()) vt.sign = (vt.type == ValueType::Type::CHAR) ? defaultSignedness : ValueType::Sign::SIGNED; } setValueType(tok, vt); } } // Update functions with new type information. createSymbolDatabaseSetFunctionPointers(false); // Update auto variables with new type information. createSymbolDatabaseSetVariablePointers(); } ValueType ValueType::parseDecl(const Token *type, const Settings *settings) { ValueType vt; parsedecl(type, &vt, settings->defaultSign == 'u' ? Sign::UNSIGNED : Sign::SIGNED, settings); return vt; } ValueType::Type ValueType::typeFromString(const std::string &typestr, bool longType) { if (typestr == "void") return ValueType::Type::VOID; if (typestr == "bool" || typestr == "_Bool") return ValueType::Type::BOOL; if (typestr== "char") return ValueType::Type::CHAR; if (typestr == "short") return ValueType::Type::SHORT; if (typestr == "int") return ValueType::Type::INT; if (typestr == "long") return longType ? ValueType::Type::LONGLONG : ValueType::Type::LONG; if (typestr == "float") return ValueType::Type::FLOAT; if (typestr == "double") return longType ? ValueType::Type::LONGDOUBLE : ValueType::Type::DOUBLE; return ValueType::Type::UNKNOWN_TYPE; } bool ValueType::fromLibraryType(const std::string &typestr, const Settings *settings) { const Library::PodType* podtype = settings->library.podtype(typestr); if (podtype && (podtype->sign == 's' || podtype->sign == 'u')) { if (podtype->size == 1) type = ValueType::Type::CHAR; else if (podtype->size == settings->sizeof_int) type = ValueType::Type::INT; else if (podtype->size == settings->sizeof_short) type = ValueType::Type::SHORT; else if (podtype->size == settings->sizeof_long) type = ValueType::Type::LONG; else if (podtype->size == settings->sizeof_long_long) type = ValueType::Type::LONGLONG; else type = ValueType::Type::UNKNOWN_INT; sign = (podtype->sign == 'u') ? ValueType::UNSIGNED : ValueType::SIGNED; return true; } const Library::PlatformType *platformType = settings->library.platform_type(typestr, settings->platformString()); if (platformType) { if (platformType->_type == "char") type = ValueType::Type::CHAR; else if (platformType->_type == "short") type = ValueType::Type::SHORT; else if (platformType->_type == "int") type = platformType->_long ? ValueType::Type::LONG : ValueType::Type::INT; else if (platformType->_type == "long") type = platformType->_long ? ValueType::Type::LONGLONG : ValueType::Type::LONG; if (platformType->_signed) sign = ValueType::SIGNED; else if (platformType->_unsigned) sign = ValueType::UNSIGNED; if (platformType->_pointer) pointer = 1; if (platformType->_ptr_ptr) pointer = 2; if (platformType->_const_ptr) constness = 1; return true; } else if (!podtype && (typestr == "size_t" || typestr == "std::size_t")) { originalTypeName = "size_t"; sign = ValueType::UNSIGNED; if (settings->sizeof_size_t == settings->sizeof_long) type = ValueType::Type::LONG; else if (settings->sizeof_size_t == settings->sizeof_long_long) type = ValueType::Type::LONGLONG; else if (settings->sizeof_size_t == settings->sizeof_int) type = ValueType::Type::INT; else type = ValueType::Type::UNKNOWN_INT; return true; } return false; } std::string ValueType::dump() const { std::ostringstream ret; switch (type) { case UNKNOWN_TYPE: return ""; case NONSTD: ret << "valueType-type=\"nonstd\""; break; case RECORD: ret << "valueType-type=\"record\""; break; case CONTAINER: ret << "valueType-type=\"container\""; break; case ITERATOR: ret << "valueType-type=\"iterator\""; break; case VOID: ret << "valueType-type=\"void\""; break; case BOOL: ret << "valueType-type=\"bool\""; break; case CHAR: ret << "valueType-type=\"char\""; break; case SHORT: ret << "valueType-type=\"short\""; break; case INT: ret << "valueType-type=\"int\""; break; case LONG: ret << "valueType-type=\"long\""; break; case LONGLONG: ret << "valueType-type=\"long long\""; break; case UNKNOWN_INT: ret << "valueType-type=\"unknown int\""; break; case FLOAT: ret << "valueType-type=\"float\""; break; case DOUBLE: ret << "valueType-type=\"double\""; break; case LONGDOUBLE: ret << "valueType-type=\"long double\""; break; }; switch (sign) { case Sign::UNKNOWN_SIGN: break; case Sign::SIGNED: ret << " valueType-sign=\"signed\""; break; case Sign::UNSIGNED: ret << " valueType-sign=\"unsigned\""; break; }; if (bits > 0) ret << " valueType-bits=\"" << bits << '\"'; if (pointer > 0) ret << " valueType-pointer=\"" << pointer << '\"'; if (constness > 0) ret << " valueType-constness=\"" << constness << '\"'; if (typeScope) ret << " valueType-typeScope=\"" << typeScope << '\"'; if (!originalTypeName.empty()) ret << " valueType-originalTypeName=\"" << originalTypeName << '\"'; return ret.str(); } std::string ValueType::str() const { std::string ret; if (constness & 1) ret = " const"; if (type == VOID) ret += " void"; else if (isIntegral()) { if (sign == SIGNED) ret += " signed"; else if (sign == UNSIGNED) ret += " unsigned"; if (type == BOOL) ret += " bool"; else if (type == CHAR) ret += " char"; else if (type == SHORT) ret += " short"; else if (type == INT) ret += " int"; else if (type == LONG) ret += " long"; else if (type == LONGLONG) ret += " long long"; else if (type == UNKNOWN_INT) ret += " unknown_int"; } else if (type == FLOAT) ret += " float"; else if (type == DOUBLE) ret += " double"; else if (type == LONGDOUBLE) ret += " long double"; else if ((type == ValueType::Type::NONSTD || type == ValueType::Type::RECORD) && typeScope) { std::string className(typeScope->className); const Scope *scope = typeScope->nestedIn; while (scope && scope->type != Scope::eGlobal) { if (scope->type == Scope::eClass || scope->type == Scope::eStruct || scope->type == Scope::eNamespace) className = scope->className + "::" + className; scope = scope->nestedIn; } ret += ' ' + className; } else if (type == ValueType::Type::CONTAINER && container) { ret += " container(" + container->startPattern + ')'; } else if (type == ValueType::Type::ITERATOR && container) { ret += " iterator(" + container->startPattern + ')'; } for (unsigned int p = 0; p < pointer; p++) { ret += " *"; if (constness & (2 << p)) ret += " const"; } return ret.empty() ? ret : ret.substr(1); }