/* * Cppcheck - A tool for static C/C++ code analysis * Copyright (C) 2007-2019 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 . */ //--------------------------------------------------------------------------- #ifndef libraryH #define libraryH //--------------------------------------------------------------------------- #include "config.h" #include "errorlogger.h" #include "mathlib.h" #include "standards.h" #include #include #include #include #include #include class Token; namespace tinyxml2 { class XMLDocument; class XMLElement; } /// @addtogroup Core /// @{ /** * @brief Library definitions handling */ class CPPCHECKLIB Library { friend class TestSymbolDatabase; // For testing only public: Library(); enum ErrorCode { OK, FILE_NOT_FOUND, BAD_XML, UNKNOWN_ELEMENT, MISSING_ATTRIBUTE, BAD_ATTRIBUTE_VALUE, UNSUPPORTED_FORMAT, DUPLICATE_PLATFORM_TYPE, PLATFORM_TYPE_REDEFINED }; class Error { public: Error() : errorcode(OK) {} explicit Error(ErrorCode e) : errorcode(e) {} template Error(ErrorCode e, T&& r) : errorcode(e), reason(r) {} ErrorCode errorcode; std::string reason; }; Error load(const char exename [], const char path []); Error load(const tinyxml2::XMLDocument &doc); /** this is primarily meant for unit tests. it only returns true/false */ bool loadxmldata(const char xmldata[], std::size_t len); struct AllocFunc { int groupId; int arg; enum class BufferSize {none,malloc,calloc,strdup}; BufferSize bufferSize; int bufferSizeArg1; int bufferSizeArg2; int reallocArg; }; /** get allocation info for function */ const AllocFunc* getAllocFuncInfo(const Token *tok) const; /** get deallocation info for function */ const AllocFunc* getDeallocFuncInfo(const Token *tok) const; /** get reallocation info for function */ const AllocFunc* getReallocFuncInfo(const Token *tok) const; /** get allocation id for function */ int getAllocId(const Token *tok, int arg) const; /** get deallocation id for function */ int getDeallocId(const Token *tok, int arg) const; /** get reallocation id for function */ int getReallocId(const Token *tok, int arg) const; /** get allocation info for function by name (deprecated, use other alloc) */ const AllocFunc* getAllocFuncInfo(const char name[]) const { return getAllocDealloc(mAlloc, name); } /** get deallocation info for function by name (deprecated, use other alloc) */ const AllocFunc* getDeallocFuncInfo(const char name[]) const { return getAllocDealloc(mDealloc, name); } /** get allocation id for function by name (deprecated, use other alloc) */ int allocId(const char name[]) const { const AllocFunc* af = getAllocDealloc(mAlloc, name); return af ? af->groupId : 0; } /** get deallocation id for function by name (deprecated, use other alloc) */ int deallocId(const char name[]) const { const AllocFunc* af = getAllocDealloc(mDealloc, name); return af ? af->groupId : 0; } /** set allocation id for function */ void setalloc(const std::string &functionname, int id, int arg) { mAlloc[functionname].groupId = id; mAlloc[functionname].arg = arg; } void setdealloc(const std::string &functionname, int id, int arg) { mDealloc[functionname].groupId = id; mDealloc[functionname].arg = arg; } void setrealloc(const std::string &functionname, int id, int arg, int reallocArg = 1) { mRealloc[functionname].groupId = id; mRealloc[functionname].arg = arg; mRealloc[functionname].reallocArg = reallocArg; } /** add noreturn function setting */ void setnoreturn(const std::string& funcname, bool noreturn) { mNoReturn[funcname] = noreturn; } /** is allocation type memory? */ static bool ismemory(const int id) { return ((id > 0) && ((id & 1) == 0)); } static bool ismemory(const AllocFunc* const func) { return ((func->groupId > 0) && ((func->groupId & 1) == 0)); } /** is allocation type resource? */ static bool isresource(const int id) { return ((id > 0) && ((id & 1) == 1)); } static bool isresource(const AllocFunc* const func) { return ((func->groupId > 0) && ((func->groupId & 1) == 1)); } bool formatstr_function(const Token* ftok) const; int formatstr_argno(const Token* ftok) const; bool formatstr_scan(const Token* ftok) const; bool formatstr_secure(const Token* ftok) const; struct WarnInfo { std::string message; Standards standards; Severity::SeverityType severity; }; std::map functionwarn; const WarnInfo* getWarnInfo(const Token* ftok) const; // returns true if ftok is not a library function bool isNotLibraryFunction(const Token *ftok) const; bool matchArguments(const Token *ftok, const std::string &functionName) const; bool isUseRetVal(const Token* ftok) const; const std::string& returnValue(const Token *ftok) const; const std::string& returnValueType(const Token *ftok) const; int returnValueContainer(const Token *ftok) const; bool returnValueSafeValues(const Token *ftok, MathLib::bigint *v1, MathLib::bigint *v2) const; bool isnoreturn(const Token *ftok) const; bool isnotnoreturn(const Token *ftok) const; bool isScopeNoReturn(const Token *end, std::string *unknownFunc) const; class Container { public: Container() : type_templateArgNo(-1), size_templateArgNo(-1), arrayLike_indexOp(false), stdStringLike(false), stdAssociativeLike(false), opLessAllowed(true) { } enum Action { RESIZE, CLEAR, PUSH, POP, FIND, INSERT, ERASE, CHANGE_CONTENT, CHANGE, CHANGE_INTERNAL, NO_ACTION }; enum Yield { AT_INDEX, ITEM, BUFFER, BUFFER_NT, START_ITERATOR, END_ITERATOR, ITERATOR, SIZE, EMPTY, NO_YIELD }; struct Function { Action action; Yield yield; }; std::string startPattern, startPattern2, endPattern, itEndPattern; std::map functions; int type_templateArgNo; int size_templateArgNo; bool arrayLike_indexOp; bool stdStringLike; bool stdAssociativeLike; bool opLessAllowed; Action getAction(const std::string& function) const { const std::map::const_iterator i = functions.find(function); if (i != functions.end()) return i->second.action; return NO_ACTION; } Yield getYield(const std::string& function) const { const std::map::const_iterator i = functions.find(function); if (i != functions.end()) return i->second.yield; return NO_YIELD; } }; std::map containers; const Container* detectContainer(const Token* typeStart, bool iterator = false) const; class ArgumentChecks { public: ArgumentChecks() : notbool(false), notnull(false), notuninit(false), formatstr(false), strz(false), optional(false), variadic(false), iteratorInfo(), direction(DIR_UNKNOWN) { } bool notbool; bool notnull; bool notuninit; bool formatstr; bool strz; bool optional; bool variadic; std::string valid; class IteratorInfo { public: IteratorInfo() : container(0), it(false), first(false), last(false) {} int container; bool it; bool first; bool last; }; IteratorInfo iteratorInfo; class MinSize { public: enum Type { NONE, STRLEN, ARGVALUE, SIZEOF, MUL, VALUE }; MinSize(Type t, int a) : type(t), arg(a), arg2(0), value(0) {} Type type; int arg; int arg2; long long value; }; std::vector minsizes; enum Direction { DIR_IN, ///< Input to called function. Data is treated as read-only. DIR_OUT, ///< Output to caller. Data is passed by reference or address and is potentially written. DIR_INOUT, ///< Input to called function, and output to caller. Data is passed by reference or address and is potentially modified. DIR_UNKNOWN ///< direction not known / specified }; Direction direction; }; struct Function { std::map argumentChecks; // argument nr => argument data bool use; bool leakignore; bool isconst; bool ispure; bool useretval; bool ignore; // ignore functions/macros from a library (gtk, qt etc) bool formatstr; bool formatstr_scan; bool formatstr_secure; Function() : use(false), leakignore(false), isconst(false), ispure(false), useretval(false), ignore(false), formatstr(false), formatstr_scan(false), formatstr_secure(false) {} }; std::map functions; bool isUse(const std::string& functionName) const; bool isLeakIgnore(const std::string& functionName) const; bool isFunctionConst(const std::string& functionName, bool pure) const; bool isFunctionConst(const Token *ftok) const; bool isboolargbad(const Token *ftok, int argnr) const { const ArgumentChecks *arg = getarg(ftok, argnr); return arg && arg->notbool; } bool isnullargbad(const Token *ftok, int argnr) const; bool isuninitargbad(const Token *ftok, int argnr) const; bool isargformatstr(const Token *ftok, int argnr) const { const ArgumentChecks *arg = getarg(ftok, argnr); return arg && arg->formatstr; } bool isargstrz(const Token *ftok, int argnr) const { const ArgumentChecks *arg = getarg(ftok, argnr); return arg && arg->strz; } bool isIntArgValid(const Token *ftok, int argnr, const MathLib::bigint argvalue) const; bool isFloatArgValid(const Token *ftok, int argnr, double argvalue) const; const std::string& validarg(const Token *ftok, int argnr) const { const ArgumentChecks *arg = getarg(ftok, argnr); return arg ? arg->valid : emptyString; } const ArgumentChecks::IteratorInfo *getArgIteratorInfo(const Token *ftok, int argnr) const { const ArgumentChecks *arg = getarg(ftok, argnr); return arg && arg->iteratorInfo.it ? &arg->iteratorInfo : nullptr; } bool hasminsize(const Token *ftok) const; const std::vector *argminsizes(const Token *ftok, int argnr) const { const ArgumentChecks *arg = getarg(ftok, argnr); return arg ? &arg->minsizes : nullptr; } ArgumentChecks::Direction getArgDirection(const Token *ftok, int argnr) const { const ArgumentChecks *arg = getarg(ftok, argnr); return arg ? arg->direction : ArgumentChecks::Direction::DIR_UNKNOWN; } bool markupFile(const std::string &path) const; bool processMarkupAfterCode(const std::string &path) const; const std::set &markupExtensions() const { return mMarkupExtensions; } bool reportErrors(const std::string &path) const; bool ignorefunction(const std::string &functionName) const; bool isexecutableblock(const std::string &file, const std::string &token) const; int blockstartoffset(const std::string &file) const; const std::string& blockstart(const std::string &file) const; const std::string& blockend(const std::string &file) const; bool iskeyword(const std::string &file, const std::string &keyword) const; bool isexporter(const std::string &prefix) const { return mExporters.find(prefix) != mExporters.end(); } bool isexportedprefix(const std::string &prefix, const std::string &token) const { const std::map::const_iterator it = mExporters.find(prefix); return (it != mExporters.end() && it->second.isPrefix(token)); } bool isexportedsuffix(const std::string &prefix, const std::string &token) const { const std::map::const_iterator it = mExporters.find(prefix); return (it != mExporters.end() && it->second.isSuffix(token)); } bool isimporter(const std::string& file, const std::string &importer) const; bool isreflection(const std::string &token) const { return mReflection.find(token) != mReflection.end(); } int reflectionArgument(const std::string &token) const { const std::map::const_iterator it = mReflection.find(token); if (it != mReflection.end()) return it->second; return -1; } std::set returnuninitdata; std::vector defines; // to provide some library defines std::set smartPointers; bool isSmartPointer(const Token *tok) const; struct PodType { unsigned int size; char sign; }; const struct PodType *podtype(const std::string &name) const { const std::map::const_iterator it = mPodTypes.find(name); return (it != mPodTypes.end()) ? &(it->second) : nullptr; } struct PlatformType { PlatformType() : _signed(false) , _unsigned(false) , _long(false) , _pointer(false) , _ptr_ptr(false) , _const_ptr(false) { } bool operator == (const PlatformType & type) const { return (_signed == type._signed && _unsigned == type._unsigned && _long == type._long && _pointer == type._pointer && _ptr_ptr == type._ptr_ptr && _const_ptr == type._const_ptr && mType == type.mType); } bool operator != (const PlatformType & type) const { return !(*this == type); } std::string mType; bool _signed; bool _unsigned; bool _long; bool _pointer; bool _ptr_ptr; bool _const_ptr; }; struct Platform { const PlatformType *platform_type(const std::string &name) const { const std::map::const_iterator it = mPlatformTypes.find(name); return (it != mPlatformTypes.end()) ? &(it->second) : nullptr; } std::map mPlatformTypes; }; const PlatformType *platform_type(const std::string &name, const std::string & platform) const { const std::map::const_iterator it = mPlatforms.find(platform); if (it != mPlatforms.end()) { const PlatformType * const type = it->second.platform_type(name); if (type) return type; } const std::map::const_iterator it2 = mPlatformTypes.find(name); return (it2 != mPlatformTypes.end()) ? &(it2->second) : nullptr; } /** * Get function name for function call */ std::string getFunctionName(const Token *ftok) const; static bool isContainerYield(const Token * const cond, Library::Container::Yield y, const std::string& fallback=""); private: // load a xml node Error loadFunction(const tinyxml2::XMLElement * const node, const std::string &name, std::set &unknown_elements); class ExportedFunctions { public: void addPrefix(const std::string& prefix) { mPrefixes.insert(prefix); } void addSuffix(const std::string& suffix) { mSuffixes.insert(suffix); } bool isPrefix(const std::string& prefix) const { return (mPrefixes.find(prefix) != mPrefixes.end()); } bool isSuffix(const std::string& suffix) const { return (mSuffixes.find(suffix) != mSuffixes.end()); } private: std::set mPrefixes; std::set mSuffixes; }; class CodeBlock { public: CodeBlock() : mOffset(0) {} void setStart(const char* s) { mStart = s; } void setEnd(const char* e) { mEnd = e; } void setOffset(const int o) { mOffset = o; } void addBlock(const char* blockName) { mBlocks.insert(blockName); } const std::string& start() const { return mStart; } const std::string& end() const { return mEnd; } int offset() const { return mOffset; } bool isBlock(const std::string& blockName) const { return mBlocks.find(blockName) != mBlocks.end(); } private: std::string mStart; std::string mEnd; int mOffset; std::set mBlocks; }; int mAllocId; std::set mFiles; std::map mAlloc; // allocation functions std::map mDealloc; // deallocation functions std::map mRealloc; // reallocation functions std::map mNoReturn; // is function noreturn? std::map mReturnValue; std::map mReturnValueType; std::map mReturnValueContainer; struct SafeValues { MathLib::bigint minValue; MathLib::bigint maxValue; }; std::map mReturnSafeValues; std::map mReportErrors; std::map mProcessAfterCode; std::set mMarkupExtensions; // file extensions of markup files std::map > mKeywords; // keywords for code in the library std::map mExecutableBlocks; // keywords for blocks of executable code std::map mExporters; // keywords that export variables/functions to libraries (meta-code/macros) std::map > mImporters; // keywords that import variables/functions std::map mReflection; // invocation of reflection std::map mPodTypes; // pod types std::map mPlatformTypes; // platform independent typedefs std::map mPlatforms; // platform dependent typedefs const ArgumentChecks * getarg(const Token *ftok, int argnr) const; std::string getFunctionName(const Token *ftok, bool *error) const; static const AllocFunc* getAllocDealloc(const std::map &data, const std::string &name) { const std::map::const_iterator it = data.find(name); return (it == data.end()) ? nullptr : &it->second; } }; /// @} //--------------------------------------------------------------------------- #endif // libraryH