/* * 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 "astutils.h" #include "library.h" #include "mathlib.h" #include "settings.h" #include "symboldatabase.h" #include "token.h" #include "valueflow.h" #include #include static bool astIsCharWithSign(const Token *tok, ValueType::Sign sign) { if (!tok) return false; const ValueType *valueType = tok->valueType(); if (!valueType) return false; return valueType->type == ValueType::Type::CHAR && valueType->pointer == 0U && valueType->sign == sign; } bool astIsSignedChar(const Token *tok) { return astIsCharWithSign(tok, ValueType::Sign::SIGNED); } bool astIsUnknownSignChar(const Token *tok) { return astIsCharWithSign(tok, ValueType::Sign::UNKNOWN_SIGN); } bool astIsIntegral(const Token *tok, bool unknown) { const ValueType *vt = tok ? tok->valueType() : nullptr; if (!vt) return unknown; return vt->isIntegral() && vt->pointer == 0U; } bool astIsFloat(const Token *tok, bool unknown) { const ValueType *vt = tok ? tok->valueType() : nullptr; if (!vt) return unknown; return vt->type >= ValueType::Type::FLOAT && vt->pointer == 0U; } bool astIsBool(const Token *tok) { return tok && (tok->isBoolean() || (tok->valueType() && tok->valueType()->type == ValueType::Type::BOOL && !tok->valueType()->pointer)); } std::string astCanonicalType(const Token *expr) { if (!expr) return ""; if (expr->variable()) { const Variable *var = expr->variable(); std::string ret; for (const Token *type = var->typeStartToken(); Token::Match(type,"%name%|::") && type != var->nameToken(); type = type->next()) { if (!Token::Match(type, "const|static")) ret += type->str(); } return ret; } // TODO: handle expressions return ""; } static bool match(const Token *tok, const std::string &rhs) { if (tok->str() == rhs) return true; if (tok->isName() && !tok->varId() && tok->values().size() == 1U && tok->values().front().isKnown() && MathLib::toString(tok->values().front().intvalue) == rhs) return true; return false; } const Token * astIsVariableComparison(const Token *tok, const std::string &comp, const std::string &rhs, const Token **vartok) { if (!tok) return nullptr; const Token *ret = nullptr; if (tok->isComparisonOp()) { if (tok->astOperand1() && match(tok->astOperand1(), rhs)) { // Invert comparator std::string s = tok->str(); if (s[0] == '>') s[0] = '<'; else if (s[0] == '<') s[0] = '>'; if (s == comp) { ret = tok->astOperand2(); } } else if (tok->str() == comp && tok->astOperand2() && match(tok->astOperand2(), rhs)) { ret = tok->astOperand1(); } } else if (comp == "!=" && rhs == std::string("0")) { ret = tok; } else if (comp == "==" && rhs == std::string("0")) { if (tok->str() == "!") ret = tok->astOperand1(); } while (ret && ret->str() == ".") ret = ret->astOperand2(); if (ret && ret->varId() == 0U) ret = nullptr; if (vartok) *vartok = ret; return ret; } static const Token * getVariableInitExpression(const Variable * var) { if (!var || !var->declEndToken()) return nullptr; if (Token::Match(var->declEndToken(), "; %varid% =", var->declarationId())) return var->declEndToken()->tokAt(2)->astOperand2(); return var->declEndToken()->astOperand2(); } static bool isInLoopCondition(const Token * tok) { return Token::Match(tok->astTop()->previous(), "for|while ("); } /// This takes a token that refers to a variable and it will return the token /// to the expression that the variable is assigned to. If its not valid to /// make such substitution then it will return the original token. static const Token * followVariableExpression(const Token * tok, bool cpp) { if (!tok) return tok; // Skip array access if (Token::Match(tok, "%var% [")) return tok; // Skip pointer indirection if (tok->astParent() && tok->isUnaryOp("*")) return tok; // Skip following variables if it is used in an assignment if (Token::Match(tok->astTop(), "%assign%") || Token::Match(tok->next(), "%assign%")) return tok; // Skip references if (Token::Match(tok->astTop(), "& %var% ;") && Token::Match(tok->astTop()->astOperand1(), "%type%")) return tok; const Variable * var = tok->variable(); const Token * varTok = getVariableInitExpression(var); if (!varTok) return tok; // Skip array access if (Token::simpleMatch(varTok, "[")) return tok; if (var->isVolatile()) return tok; if (!var->isLocal() && !var->isConst()) return tok; if (var->isStatic() && !var->isConst()) return tok; if (var->isArgument()) return tok; // If this is in a loop then check if variables are modified in the entire scope const Token * endToken = (isInLoopCondition(tok) || isInLoopCondition(varTok) || var->scope() != tok->scope()) ? var->scope()->bodyEnd : tok; if (!var->isConst() && isVariableChanged(varTok, endToken, tok->varId(), false, nullptr, cpp)) return tok; // Start at beginning of initialization const Token * startToken = varTok; while (Token::Match(startToken, "%op%|.|(|{") && startToken->astOperand1()) startToken = startToken->astOperand1(); // Skip if the variable its referring to is modified for (const Token * tok2 = startToken; tok2 != endToken; tok2 = tok2->next()) { if (Token::simpleMatch(tok2, ";")) break; if (tok2->astParent() && tok2->isUnaryOp("*")) return tok; if (tok2->tokType() == Token::eIncDecOp || tok2->isAssignmentOp() || Token::Match(tok2, "%name% .|[|++|--|%assign%")) { return tok; } if (const Variable * var2 = tok2->variable()) { if(!var2->scope()) return tok; const Token * endToken2 = var2->scope() != tok->scope() ? var2->scope()->bodyEnd : endToken; if (!var2->isLocal() && !var2->isConst() && !var2->isArgument()) return tok; if (var2->isStatic() && !var2->isConst()) return tok; if (!var2->isConst() && isVariableChanged(tok2, endToken2, tok2->varId(), false, nullptr, cpp)) return tok; // Recognized as a variable but the declaration is unknown } else if(tok2->varId() > 0) { return tok; } } return varTok; } static void followVariableExpressionError(const Token *tok1, const Token *tok2, ErrorPath* errors) { if (!errors) return; if (!tok1) return; if (!tok2) return; ErrorPathItem item = std::make_pair(tok2, "'" + tok1->str() + "' is assigned value '" + tok2->expressionString() + "' here."); if (std::find(errors->begin(), errors->end(), item) != errors->end()) return; errors->push_back(item); } bool isSameExpression(bool cpp, bool macro, const Token *tok1, const Token *tok2, const Library& library, bool pure, ErrorPath* errors) { if (tok1 == nullptr && tok2 == nullptr) return true; if (tok1 == nullptr || tok2 == nullptr) return false; if (cpp) { if (tok1->str() == "." && tok1->astOperand1() && tok1->astOperand1()->str() == "this") tok1 = tok1->astOperand2(); if (tok2->str() == "." && tok2->astOperand1() && tok2->astOperand1()->str() == "this") tok2 = tok2->astOperand2(); } // Skip double not if (Token::simpleMatch(tok1, "!") && Token::simpleMatch(tok1->astOperand1(), "!") && !Token::simpleMatch(tok1->astParent(), "=")) { return isSameExpression(cpp, macro, tok1->astOperand1()->astOperand1(), tok2, library, pure, errors); } if (Token::simpleMatch(tok2, "!") && Token::simpleMatch(tok2->astOperand1(), "!") && !Token::simpleMatch(tok2->astParent(), "=")) { return isSameExpression(cpp, macro, tok1, tok2->astOperand1()->astOperand1(), library, pure, errors); } if (tok1->str() != tok2->str() && (Token::Match(tok1, "%var%") || Token::Match(tok2, "%var%"))) { const Token * varTok1 = followVariableExpression(tok1, cpp); if (varTok1->str() == tok2->str()) { followVariableExpressionError(tok1, varTok1, errors); return isSameExpression(cpp, macro, varTok1, tok2, library, pure, errors); } const Token * varTok2 = followVariableExpression(tok2, cpp); if (tok1->str() == varTok2->str()) { followVariableExpressionError(tok2, varTok2, errors); return isSameExpression(cpp, macro, tok1, varTok2, library, pure, errors); } if (varTok1->str() == varTok2->str()) { followVariableExpressionError(tok1, varTok1, errors); followVariableExpressionError(tok2, varTok2, errors); return isSameExpression(cpp, macro, varTok1, varTok2, library, pure, errors); } } if (tok1->varId() != tok2->varId() || tok1->str() != tok2->str() || tok1->originalName() != tok2->originalName()) { if ((Token::Match(tok1,"<|>") && Token::Match(tok2,"<|>")) || (Token::Match(tok1,"<=|>=") && Token::Match(tok2,"<=|>="))) { return isSameExpression(cpp, macro, tok1->astOperand1(), tok2->astOperand2(), library, pure, errors) && isSameExpression(cpp, macro, tok1->astOperand2(), tok2->astOperand1(), library, pure, errors); } return false; } if (macro && (tok1->isExpandedMacro() || tok2->isExpandedMacro() || tok1->isTemplateArg() || tok2->isTemplateArg())) return false; if (tok1->isComplex() != tok2->isComplex()) return false; if (tok1->isLong() != tok2->isLong()) return false; if (tok1->isUnsigned() != tok2->isUnsigned()) return false; if (tok1->isSigned() != tok2->isSigned()) return false; if (pure && tok1->isName() && tok1->next()->str() == "(" && tok1->str() != "sizeof") { if (!tok1->function()) { if (!Token::Match(tok1->previous(), ".|::") && !library.isFunctionConst(tok1) && !tok1->isAttributeConst() && !tok1->isAttributePure()) return false; if (Token::simpleMatch(tok1->previous(), ".")) { const Token *lhs = tok1->previous(); while (Token::Match(lhs, "(|.|[")) lhs = lhs->astOperand1(); bool lhsIsConst = (lhs->variable() && lhs->variable()->isConst()) || (lhs->valueType() && lhs->valueType()->constness > 0) || (Token::Match(lhs, "%var% . %name% (") && library.isFunctionConst(lhs->tokAt(2))); if (!lhsIsConst) return false; } } else { if (tok1->function() && !tok1->function()->isConst() && !tok1->function()->isAttributeConst() && !tok1->function()->isAttributePure()) return false; } } // templates/casts if ((Token::Match(tok1, "%name% <") && tok1->next()->link()) || (Token::Match(tok2, "%name% <") && tok2->next()->link())) { // non-const template function that is not a dynamic_cast => return false if (Token::simpleMatch(tok1->next()->link(), "> (") && !(tok1->function() && tok1->function()->isConst()) && tok1->str() != "dynamic_cast") return false; // some template/cast stuff.. check that the template arguments are same const Token *t1 = tok1->next(); const Token *t2 = tok2->next(); const Token *end1 = t1->link(); const Token *end2 = t2->link(); while (t1 && t2 && t1 != end1 && t2 != end2) { if (t1->str() != t2->str()) return false; t1 = t1->next(); t2 = t2->next(); } if (t1 != end1 || t2 != end2) return false; } if (tok1->tokType() == Token::eIncDecOp || tok1->isAssignmentOp()) return false; // bailout when we see ({..}) if (tok1->str() == "{") return false; if (tok1->str() == "(" && tok1->previous() && !tok1->previous()->isName()) { // cast => assert that the casts are equal const Token *t1 = tok1->next(); const Token *t2 = tok2->next(); while (t1 && t2 && t1->str() == t2->str() && t1->isLong() == t2->isLong() && t1->isUnsigned() == t2->isUnsigned() && t1->isSigned() == t2->isSigned() && (t1->isName() || t1->str() == "*")) { t1 = t1->next(); t2 = t2->next(); } if (!t1 || !t2 || t1->str() != ")" || t2->str() != ")") return false; } bool noncommutativeEquals = isSameExpression(cpp, macro, tok1->astOperand1(), tok2->astOperand1(), library, pure, errors); noncommutativeEquals = noncommutativeEquals && isSameExpression(cpp, macro, tok1->astOperand2(), tok2->astOperand2(), library, pure, errors); if (noncommutativeEquals) return true; // in c++, a+b might be different to b+a, depending on the type of a and b if (cpp && tok1->str() == "+" && tok1->isBinaryOp()) { const ValueType* vt1 = tok1->astOperand1()->valueType(); const ValueType* vt2 = tok1->astOperand2()->valueType(); if (!(vt1 && (vt1->type >= ValueType::VOID || vt1->pointer) && vt2 && (vt2->type >= ValueType::VOID || vt2->pointer))) return false; } const bool commutative = tok1->isBinaryOp() && Token::Match(tok1, "%or%|%oror%|+|*|&|&&|^|==|!="); bool commutativeEquals = commutative && isSameExpression(cpp, macro, tok1->astOperand2(), tok2->astOperand1(), library, pure, errors); commutativeEquals = commutativeEquals && isSameExpression(cpp, macro, tok1->astOperand1(), tok2->astOperand2(), library, pure, errors); return commutativeEquals; } bool isEqualKnownValue(const Token * const tok1, const Token * const tok2) { return tok1->hasKnownValue() && tok2->hasKnownValue() && tok1->values() == tok2->values(); } bool isDifferentKnownValues(const Token * const tok1, const Token * const tok2) { return tok1->hasKnownValue() && tok2->hasKnownValue() && tok1->values() != tok2->values(); } static bool isZeroBoundCond(const Token * const cond) { if (cond == nullptr) return false; // Assume unsigned // TODO: Handle reverse conditions const bool isZero = cond->astOperand2()->getValue(0); if (cond->str() == "==" || cond->str() == ">=") return isZero; if (cond->str() == "<=") return true; if (cond->str() == "<") return !isZero; if (cond->str() == ">") return false; return false; } bool isOppositeCond(bool isNot, bool cpp, const Token * const cond1, const Token * const cond2, const Library& library, bool pure, ErrorPath* errors) { if (!cond1 || !cond2) return false; if (cond1->str() == "!") { if (cond2->str() == "!=") { if (cond2->astOperand1() && cond2->astOperand1()->str() == "0") return isSameExpression(cpp, true, cond1->astOperand1(), cond2->astOperand2(), library, pure, errors); if (cond2->astOperand2() && cond2->astOperand2()->str() == "0") return isSameExpression(cpp, true, cond1->astOperand1(), cond2->astOperand1(), library, pure, errors); } return isSameExpression(cpp, true, cond1->astOperand1(), cond2, library, pure, errors); } if (cond2->str() == "!") return isOppositeCond(isNot, cpp, cond2, cond1, library, pure); if (!isNot) { if (cond1->str() == "==" && cond2->str() == "==") { if (isSameExpression(cpp, true, cond1->astOperand1(), cond2->astOperand1(), library, pure, errors)) return isDifferentKnownValues(cond1->astOperand2(), cond2->astOperand2()); if (isSameExpression(cpp, true, cond1->astOperand2(), cond2->astOperand2(), library, pure, errors)) return isDifferentKnownValues(cond1->astOperand1(), cond2->astOperand1()); } // TODO: Handle reverse conditions if (Library::isContainerYield(cond1, Library::Container::EMPTY, "empty") && Library::isContainerYield(cond2->astOperand1(), Library::Container::SIZE, "size") && cond1->astOperand1()->astOperand1()->varId() == cond2->astOperand1()->astOperand1()->astOperand1()->varId()) { return !isZeroBoundCond(cond2); } if (Library::isContainerYield(cond2, Library::Container::EMPTY, "empty") && Library::isContainerYield(cond1->astOperand1(), Library::Container::SIZE, "size") && cond2->astOperand1()->astOperand1()->varId() == cond1->astOperand1()->astOperand1()->astOperand1()->varId()) { return !isZeroBoundCond(cond1); } } if (!cond1->isComparisonOp() || !cond2->isComparisonOp()) return false; const std::string &comp1 = cond1->str(); // condition found .. get comparator std::string comp2; if (isSameExpression(cpp, true, cond1->astOperand1(), cond2->astOperand1(), library, pure) && isSameExpression(cpp, true, cond1->astOperand2(), cond2->astOperand2(), library, pure)) { comp2 = cond2->str(); } else if (isSameExpression(cpp, true, cond1->astOperand1(), cond2->astOperand2(), library, pure) && isSameExpression(cpp, true, cond1->astOperand2(), cond2->astOperand1(), library, pure)) { comp2 = cond2->str(); if (comp2[0] == '>') comp2[0] = '<'; else if (comp2[0] == '<') comp2[0] = '>'; } if (!isNot && comp2.empty()) { const Token *expr1 = nullptr, *value1 = nullptr, *expr2 = nullptr, *value2 = nullptr; std::string op1 = cond1->str(), op2 = cond2->str(); if (cond1->astOperand2()->hasKnownIntValue()) { expr1 = cond1->astOperand1(); value1 = cond1->astOperand2(); } else if (cond1->astOperand1()->hasKnownIntValue()) { expr1 = cond1->astOperand2(); value1 = cond1->astOperand1(); if (op1[0] == '>') op1[0] = '<'; else if (op1[0] == '<') op1[0] = '>'; } if (cond2->astOperand2()->hasKnownIntValue()) { expr2 = cond2->astOperand1(); value2 = cond2->astOperand2(); } else if (cond2->astOperand1()->hasKnownIntValue()) { expr2 = cond2->astOperand2(); value2 = cond2->astOperand1(); if (op2[0] == '>') op2[0] = '<'; else if (op2[0] == '<') op2[0] = '>'; } if (!expr1 || !value1 || !expr2 || !value2) { return false; } if (!isSameExpression(cpp, true, expr1, expr2, library, pure, errors)) return false; const ValueFlow::Value &rhsValue1 = value1->values().front(); const ValueFlow::Value &rhsValue2 = value2->values().front(); if (op1 == "<" || op1 == "<=") return (op2 == "==" || op2 == ">" || op2 == ">=") && (rhsValue1.intvalue < rhsValue2.intvalue); else if (op1 == ">=" || op1 == ">") return (op2 == "==" || op2 == "<" || op2 == "<=") && (rhsValue1.intvalue > rhsValue2.intvalue); return false; } // is condition opposite? return ((comp1 == "==" && comp2 == "!=") || (comp1 == "!=" && comp2 == "==") || (comp1 == "<" && comp2 == ">=") || (comp1 == "<=" && comp2 == ">") || (comp1 == ">" && comp2 == "<=") || (comp1 == ">=" && comp2 == "<") || (!isNot && ((comp1 == "<" && comp2 == ">") || (comp1 == ">" && comp2 == "<") || (comp1 == "==" && (comp2 == "!=" || comp2 == ">" || comp2 == "<")) || ((comp1 == "!=" || comp1 == ">" || comp1 == "<") && comp2 == "==") ))); } bool isOppositeExpression(bool cpp, const Token * const tok1, const Token * const tok2, const Library& library, bool pure, ErrorPath* errors) { if (!tok1 || !tok2) return false; if (isOppositeCond(true, cpp, tok1, tok2, library, pure)) return true; if (tok1->isUnaryOp("-")) return isSameExpression(cpp, true, tok1->astOperand1(), tok2, library, pure, errors); if (tok2->isUnaryOp("-")) return isSameExpression(cpp, true, tok2->astOperand1(), tok1, library, pure, errors); return false; } bool isConstExpression(const Token *tok, const Library& library, bool pure) { if (!tok) return true; if (tok->isName() && tok->next()->str() == "(") { if (!tok->function() && !Token::Match(tok->previous(), ".|::") && !library.isFunctionConst(tok->str(), pure)) return false; else if (tok->function() && !tok->function()->isConst()) return false; } if (tok->tokType() == Token::eIncDecOp) return false; // bailout when we see ({..}) if (tok->str() == "{") return false; return isConstExpression(tok->astOperand1(), library, pure) && isConstExpression(tok->astOperand2(), library, pure); } bool isWithoutSideEffects(bool cpp, const Token* tok) { if (!cpp) return true; while (tok && tok->astOperand2() && tok->astOperand2()->str() != "(") tok = tok->astOperand2(); if (tok && tok->varId()) { const Variable* var = tok->variable(); return var && (!var->isClass() || var->isPointer() || var->isStlType()); } return true; } bool isUniqueExpression(const Token* tok) { if (!tok) return true; if (tok->function()) { const Function * fun = tok->function(); const Scope * scope = fun->nestedIn; if (!scope) return true; const std::string returnType = fun->retType ? fun->retType->name() : fun->retDef->stringifyList(fun->tokenDef); for (const Function& f:scope->functionList) { if (f.type != Function::eFunction) continue; const std::string freturnType = f.retType ? f.retType->name() : f.retDef->stringifyList(f.tokenDef); if (f.argumentList.size() == fun->argumentList.size() && returnType == freturnType && f.name() != fun->name()) { return false; } } } else if (tok->variable()) { const Variable * var = tok->variable(); const Scope * scope = var->scope(); if (!scope) return true; const Type * varType = var->type(); // Iterate over the variables in scope and the parameters of the function if possible const Function * fun = scope->function; const std::list* setOfVars[] = {&scope->varlist, fun ? &fun->argumentList : nullptr}; if (varType) { for (const std::list* vars:setOfVars) { if (!vars) continue; for (const Variable& v:*vars) { if (v.type() && v.type()->name() == varType->name() && v.name() != var->name()) { return false; } } } } else { for (const std::list* vars:setOfVars) { if (!vars) continue; for (const Variable& v:*vars) { if (v.isFloatingType() == var->isFloatingType() && v.isEnumType() == var->isEnumType() && v.isClass() == var->isClass() && v.isArray() == var->isArray() && v.isPointer() == var->isPointer() && v.name() != var->name()) return false; } } } } else if (!isUniqueExpression(tok->astOperand1())) { return false; } return isUniqueExpression(tok->astOperand2()); } bool isReturnScope(const Token * const endToken) { if (!endToken || endToken->str() != "}") return false; const Token *prev = endToken->previous(); while (prev && Token::simpleMatch(prev->previous(), "; ;")) prev = prev->previous(); if (prev && Token::simpleMatch(prev->previous(), "} ;")) prev = prev->previous(); if (Token::simpleMatch(prev, "}")) { if (Token::simpleMatch(prev->link()->tokAt(-2), "} else {")) return isReturnScope(prev) && isReturnScope(prev->link()->tokAt(-2)); if (Token::simpleMatch(prev->link()->previous(), ") {") && Token::simpleMatch(prev->link()->linkAt(-1)->previous(), "switch (") && !Token::findsimplematch(prev->link(), "break", prev)) { return true; } if (Token::simpleMatch(prev->link()->previous(), ") {") && Token::simpleMatch(prev->link()->linkAt(-1)->previous(), "return (")) { return true; } if (Token::Match(prev->link()->previous(), "[;{}] {")) return isReturnScope(prev); } else if (Token::simpleMatch(prev, ";")) { // noreturn function if (Token::simpleMatch(prev->previous(), ") ;") && Token::Match(prev->linkAt(-1)->tokAt(-2), "[;{}] %name% (")) return true; // return/goto statement prev = prev->previous(); while (prev && !Token::Match(prev, ";|{|}|return|goto|throw|continue|break")) prev = prev->previous(); return prev && prev->isName(); } return false; } bool isVariableChangedByFunctionCall(const Token *tok, unsigned int varid, const Settings *settings, bool *inconclusive) { if (!tok) return false; if (tok->varId() == varid) return isVariableChangedByFunctionCall(tok, settings, inconclusive); return isVariableChangedByFunctionCall(tok->astOperand1(), varid, settings, inconclusive) || isVariableChangedByFunctionCall(tok->astOperand2(), varid, settings, inconclusive); } bool isVariableChangedByFunctionCall(const Token *tok, const Settings *settings, bool *inconclusive) { if (!tok) return false; // address of variable const bool addressOf = Token::simpleMatch(tok->previous(), "&"); // passing variable to subfunction? if (Token::Match(tok->tokAt(-2), ") & %name% [,)]") && Token::Match(tok->linkAt(-2)->previous(), "[,(] (")) ; else if (Token::Match(tok->tokAt(addressOf?-2:-1), "[(,] &| %name% [,)]")) ; else if (Token::Match(tok->tokAt(addressOf?-2:-1), "[?:] &| %name% [:,)]")) { const Token *parent = tok->astParent(); if (parent == tok->previous() && parent->str() == "&") parent = parent->astParent(); while (Token::Match(parent, "[?:]")) parent = parent->astParent(); while (Token::simpleMatch(parent, ",")) parent = parent->astParent(); if (!parent || parent->str() != "(") return false; } else return false; // reinterpret_cast etc.. if (Token::Match(tok->tokAt(-3), "> ( & %name% ) [,)]") && tok->linkAt(-3) && Token::Match(tok->linkAt(-3)->tokAt(-2), "[,(] %type% <")) tok = tok->linkAt(-3); // goto start of function call and get argnr unsigned int argnr = 0; while (tok && tok->str() != "(") { if (tok->str() == ",") ++argnr; else if (tok->str() == ")") tok = tok->link(); tok = tok->previous(); } tok = tok ? tok->previous() : nullptr; if (tok && tok->link() && tok->str() == ">") tok = tok->link()->previous(); if (!Token::Match(tok, "%name% [(<]")) return false; // not a function => variable not changed // Constructor call if (tok->variable() && tok->variable()->nameToken() == tok) { // Find constructor.. const unsigned int argCount = numberOfArguments(tok); const Scope *typeScope = tok->variable()->typeScope(); if (typeScope) { for (std::list::const_iterator it = typeScope->functionList.begin(); it != typeScope->functionList.end(); ++it) { if (!it->isConstructor() || it->argCount() < argCount) continue; const Variable *arg = it->getArgumentVar(argnr); if (arg && arg->isReference() && !arg->isConst()) return true; } return false; } if (inconclusive) *inconclusive = true; return false; } if (!tok->function()) { // if the library says 0 is invalid // => it is assumed that parameter is an in parameter (TODO: this is a bad heuristic) if (!addressOf && settings && settings->library.isnullargbad(tok, 1+argnr)) return false; // addressOf => inconclusive if (!addressOf) { if (inconclusive != nullptr) *inconclusive = true; return false; } return true; } const Variable *arg = tok->function()->getArgumentVar(argnr); if (addressOf) { if (!(arg && arg->isConst())) return true; // If const is applied to the pointer, then the value can still be modified if (arg && Token::simpleMatch(arg->typeEndToken(), "* const")) return true; } return arg && !arg->isConst() && arg->isReference(); } bool isVariableChanged(const Token *start, const Token *end, const unsigned int varid, bool globalvar, const Settings *settings, bool cpp) { for (const Token *tok = start; tok != end; tok = tok->next()) { if (tok->varId() != varid) { if (globalvar && Token::Match(tok, "%name% (")) // TODO: Is global variable really changed by function call? return true; continue; } if (Token::Match(tok, "%name% %assign%|++|--")) return true; if (Token::Match(tok->previous(), "++|-- %name%")) return true; if (isLikelyStreamRead(cpp, tok->previous())) return true; // Member function call if (Token::Match(tok, "%name% . %name% (")) { const Variable * var = tok->variable(); bool isConst = var && var->isConst(); if (!isConst && var) { const ValueType * valueType = var->valueType(); isConst = (valueType && valueType->pointer == 1 && valueType->constness == 1); } const Token *ftok = tok->tokAt(2); const Function * fun = ftok->function(); if (!isConst && (!fun || !fun->isConst())) return true; } const Token *ftok = tok; while (ftok && !Token::Match(ftok, "[({[]")) ftok = ftok->astParent(); if (ftok && Token::Match(ftok->link(), ") !!{")) { bool inconclusive = false; bool isChanged = isVariableChangedByFunctionCall(tok, settings, &inconclusive); isChanged |= inconclusive; if (isChanged) return true; } const Token *parent = tok->astParent(); while (Token::Match(parent, ".|::")) parent = parent->astParent(); if (parent && parent->tokType() == Token::eIncDecOp) return true; } return false; } int numberOfArguments(const Token *start) { int arguments=0; const Token* const openBracket = start->next(); if (openBracket && openBracket->str()=="(" && openBracket->next() && openBracket->next()->str()!=")") { const Token* argument=openBracket->next(); while (argument) { ++arguments; argument = argument->nextArgument(); } } return arguments; } static void getArgumentsRecursive(const Token *tok, std::vector *arguments) { if (!tok) return; if (tok->str() == ",") { getArgumentsRecursive(tok->astOperand1(), arguments); getArgumentsRecursive(tok->astOperand2(), arguments); } else { arguments->push_back(tok); } } std::vector getArguments(const Token *ftok) { std::vector arguments; getArgumentsRecursive(ftok->next()->astOperand2(), &arguments); return arguments; } const Token *findLambdaEndToken(const Token *first) { if (!first || first->str() != "[") return nullptr; const Token* tok = first->link(); if (Token::simpleMatch(tok, "] {")) return tok->linkAt(1); if (!Token::simpleMatch(tok, "] (")) return nullptr; tok = tok->linkAt(1)->next(); if (tok && tok->str() == "constexpr") tok = tok->next(); if (tok && tok->str() == "mutable") tok = tok->next(); if (tok && tok->str() == "{") return tok->link(); return nullptr; } bool isLikelyStreamRead(bool cpp, const Token *op) { if (!cpp) return false; if (!Token::Match(op, "&|>>") || !op->isBinaryOp()) return false; if (!Token::Match(op->astOperand2(), "%name%|.|*|[") && op->str() != op->astOperand2()->str()) return false; const Token *parent = op; while (parent->astParent() && parent->astParent()->str() == op->str()) parent = parent->astParent(); if (parent->astParent() && !Token::Match(parent->astParent(), "%oror%|&&|(|,|!")) return false; if (op->str() == "&" && parent->astParent()) return false; if (!parent->astOperand1() || !parent->astOperand2()) return false; return (!parent->astOperand1()->valueType() || !parent->astOperand1()->valueType()->isIntegral()); }