/* * Cppcheck - A tool for static C/C++ code analysis * Copyright (C) 2007-2022 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 "cppcheckexecutor.h" #include "analyzerinfo.h" #include "cmdlineparser.h" #include "color.h" #include "config.h" #include "cppcheck.h" #include "errortypes.h" #include "filelister.h" #include "importproject.h" #include "library.h" #include "path.h" #include "pathmatch.h" #include "preprocessor.h" #include "settings.h" #include "suppressions.h" #include "threadexecutor.h" #include "utils.h" #include "checkunusedfunctions.h" #include #include #include #include #include // EXIT_SUCCESS and EXIT_FAILURE #include #include #include #include #include #include #include #include #if !defined(NO_UNIX_SIGNAL_HANDLING) && defined(__GNUC__) && !defined(__MINGW32__) && !defined(__OS2__) #define USE_UNIX_SIGNAL_HANDLING #include #if defined(__APPLE__) # define _XOPEN_SOURCE // ucontext.h APIs can only be used on Mac OSX >= 10.7 if _XOPEN_SOURCE is defined # include # undef _XOPEN_SOURCE #elif !defined(__OpenBSD__) && !defined(__HAIKU__) # include #endif #ifdef __linux__ #include #endif #endif #if !defined(NO_UNIX_BACKTRACE_SUPPORT) && defined(USE_UNIX_SIGNAL_HANDLING) && defined(__GNUC__) && defined(__GLIBC__) && !defined(__CYGWIN__) && !defined(__MINGW32__) && !defined(__NetBSD__) && !defined(__SVR4) && !defined(__QNX__) #define USE_UNIX_BACKTRACE_SUPPORT #include #include #endif #if defined(_WIN32) #if defined(_MSC_VER) #define USE_WINDOWS_SEH #endif #if defined (__MINGW32__) # include # include # include #else # include # include # include #endif #include #endif /*static*/ FILE* CppCheckExecutor::mExceptionOutput = stdout; CppCheckExecutor::CppCheckExecutor() : mSettings(nullptr), mLatestProgressOutputTime(0), mErrorOutput(nullptr), mBugHuntingReport(nullptr), mShowAllErrors(false) {} CppCheckExecutor::~CppCheckExecutor() { delete mErrorOutput; delete mBugHuntingReport; } bool CppCheckExecutor::parseFromArgs(CppCheck *cppcheck, int argc, const char* const argv[]) { Settings& settings = cppcheck->settings(); CmdLineParser parser(&settings); const bool success = parser.parseFromArgs(argc, argv); if (success) { if (parser.getShowVersion() && !parser.getShowErrorMessages()) { const char * const extraVersion = CppCheck::extraVersion(); if (*extraVersion != 0) std::cout << "Cppcheck " << CppCheck::version() << " (" << extraVersion << ')' << std::endl; else std::cout << "Cppcheck " << CppCheck::version() << std::endl; } if (parser.getShowErrorMessages()) { mShowAllErrors = true; std::cout << ErrorMessage::getXMLHeader(); cppcheck->getErrorMessages(); std::cout << ErrorMessage::getXMLFooter() << std::endl; } if (parser.exitAfterPrinting()) { Settings::terminate(); return true; } } else { return false; } // Check that all include paths exist { for (std::list::iterator iter = settings.includePaths.begin(); iter != settings.includePaths.end(); ) { const std::string path(Path::toNativeSeparators(*iter)); if (FileLister::isDirectory(path)) ++iter; else { // If the include path is not found, warn user and remove the non-existing path from the list. if (settings.severity.isEnabled(Severity::information)) std::cout << "(information) Couldn't find path given by -I '" << path << '\'' << std::endl; iter = settings.includePaths.erase(iter); } } } // Output a warning for the user if he tries to exclude headers bool warn = false; const std::vector& ignored = parser.getIgnoredPaths(); for (const std::string &i : ignored) { if (Path::isHeader(i)) { warn = true; break; } } if (warn) { std::cout << "cppcheck: filename exclusion does not apply to header (.h and .hpp) files." << std::endl; std::cout << "cppcheck: Please use --suppress for ignoring results from the header files." << std::endl; } const std::vector& pathnames = parser.getPathNames(); #if defined(_WIN32) // For Windows we want case-insensitive path matching const bool caseSensitive = false; #else const bool caseSensitive = true; #endif if (!mSettings->project.fileSettings.empty() && !mSettings->fileFilters.empty()) { // filter only for the selected filenames from all project files std::list newList; for (const ImportProject::FileSettings &fsetting : settings.project.fileSettings) { if (matchglobs(mSettings->fileFilters, fsetting.filename)) { newList.emplace_back(fsetting); } } if (!newList.empty()) settings.project.fileSettings = newList; else { std::cout << "cppcheck: error: could not find any files matching the filter." << std::endl; return false; } } else if (!pathnames.empty()) { // Execute recursiveAddFiles() to each given file parameter const PathMatch matcher(ignored, caseSensitive); for (const std::string &pathname : pathnames) { std::string err = FileLister::recursiveAddFiles(mFiles, Path::toNativeSeparators(pathname), mSettings->library.markupExtensions(), matcher); if (!err.empty()) { std::cout << "cppcheck: " << err << std::endl; } } } if (mFiles.empty() && settings.project.fileSettings.empty()) { std::cout << "cppcheck: error: could not find or open any of the paths given." << std::endl; if (!ignored.empty()) std::cout << "cppcheck: Maybe all paths were ignored?" << std::endl; return false; } else if (!mSettings->fileFilters.empty() && settings.project.fileSettings.empty()) { std::map newMap; for (std::map::const_iterator i = mFiles.begin(); i != mFiles.end(); ++i) if (matchglobs(mSettings->fileFilters, i->first)) { newMap[i->first] = i->second; } mFiles = newMap; if (mFiles.empty()) { std::cout << "cppcheck: error: could not find any files matching the filter." << std::endl; return false; } } return true; } int CppCheckExecutor::check(int argc, const char* const argv[]) { Preprocessor::missingIncludeFlag = false; Preprocessor::missingSystemIncludeFlag = false; CheckUnusedFunctions::clear(); CppCheck cppCheck(*this, true, executeCommand); const Settings& settings = cppCheck.settings(); mSettings = &settings; if (!parseFromArgs(&cppCheck, argc, argv)) { mSettings = nullptr; return EXIT_FAILURE; } if (Settings::terminated()) { mSettings = nullptr; return EXIT_SUCCESS; } int ret; if (cppCheck.settings().exceptionHandling) ret = check_wrapper(cppCheck); else ret = check_internal(cppCheck); mSettings = nullptr; return ret; } void CppCheckExecutor::setSettings(const Settings &settings) { mSettings = &settings; } /** * Simple helper function: * \return size of array * */ template std::size_t getArrayLength(const T (&)[size]) { return size; } #if defined(USE_UNIX_SIGNAL_HANDLING) /* * Try to print the callstack. * That is very sensitive to the operating system, hardware, compiler and runtime. * The code is not meant for production environment! * One reason is named first: it's using functions not whitelisted for usage in a signal handler function. */ static void print_stacktrace(FILE* output, bool demangling, int maxdepth, bool lowMem) { #if defined(USE_UNIX_BACKTRACE_SUPPORT) // 32 vs. 64bit #define ADDRESSDISPLAYLENGTH ((sizeof(long)==8)?12:8) const int fd = fileno(output); void *callstackArray[32]= {nullptr}; // the less resources the better... const int currentdepth = backtrace(callstackArray, (int)getArrayLength(callstackArray)); const int offset=2; // some entries on top are within our own exception handling code or libc if (maxdepth<0) maxdepth=currentdepth-offset; else maxdepth = std::min(maxdepth, currentdepth); if (lowMem) { fputs("Callstack (symbols only):\n", output); backtrace_symbols_fd(callstackArray+offset, maxdepth, fd); } else { char **symbolStringList = backtrace_symbols(callstackArray, currentdepth); if (symbolStringList) { fputs("Callstack:\n", output); char demangle_buffer[2048]= {0}; for (int i = offset; i < maxdepth; ++i) { const char * const symbolString = symbolStringList[i]; char * realnameString = nullptr; const char * const firstBracketName = strchr(symbolString, '('); const char * const firstBracketAddress = strchr(symbolString, '['); const char * const secondBracketAddress = strchr(firstBracketAddress, ']'); const char * const beginAddress = firstBracketAddress+3; const int addressLen = int(secondBracketAddress-beginAddress); const int padLen = int(ADDRESSDISPLAYLENGTH-addressLen); if (demangling && firstBracketName) { const char * const plus = strchr(firstBracketName, '+'); if (plus && (plus>(firstBracketName+1))) { char input_buffer[1024]= {0}; strncpy(input_buffer, firstBracketName+1, plus-firstBracketName-1); size_t length = getArrayLength(demangle_buffer); int status=0; // We're violating the specification - passing stack address instead of malloc'ed heap. // Benefit is that no further heap is required, while there is sufficient stack... realnameString = abi::__cxa_demangle(input_buffer, demangle_buffer, &length, &status); // non-NULL on success } } const int ordinal=i-offset; fprintf(output, "#%-2d 0x", ordinal); if (padLen>0) fprintf(output, "%0*d", padLen, 0); if (realnameString) { fprintf(output, "%.*s in %s\n", (int)(secondBracketAddress-firstBracketAddress-3), firstBracketAddress+3, realnameString); } else { fprintf(output, "%.*s in %.*s\n", (int)(secondBracketAddress-firstBracketAddress-3), firstBracketAddress+3, (int)(firstBracketAddress-symbolString), symbolString); } } free(symbolStringList); } else { fputs("Callstack could not be obtained\n", output); } } #undef ADDRESSDISPLAYLENGTH #else (void)output; (void)demangling; (void)maxdepth; (void)lowMem; #endif } #ifdef __USE_DYNAMIC_STACK_SIZE static const size_t MYSTACKSIZE = 16*1024+32768; // wild guess about a reasonable buffer #else static const size_t MYSTACKSIZE = 16*1024+SIGSTKSZ; // wild guess about a reasonable buffer #endif static char mytstack[MYSTACKSIZE]= {0}; // alternative stack for signal handler static bool bStackBelowHeap=false; // lame attempt to locate heap vs. stack address space. See CppCheckExecutor::check_wrapper() /** * \param[in] ptr address to be examined. * \return true if address is supposed to be on stack (contrary to heap). If ptr is 0 false will be returned. * If unknown better return false. */ static bool IsAddressOnStack(const void* ptr) { if (nullptr==ptr) return false; char a; if (bStackBelowHeap) return ptr < &a; else return ptr > &a; } /* (declare this list here, so it may be used in signal handlers in addition to main()) * A list of signals available in ISO C * Check out http://pubs.opengroup.org/onlinepubs/009695399/basedefs/signal.h.html * For now we only want to detect abnormal behaviour for a few selected signals: */ #define DECLARE_SIGNAL(x) std::make_pair(x, #x) using Signalmap_t = std::map; static const Signalmap_t listofsignals = { DECLARE_SIGNAL(SIGABRT), DECLARE_SIGNAL(SIGBUS), DECLARE_SIGNAL(SIGFPE), DECLARE_SIGNAL(SIGILL), DECLARE_SIGNAL(SIGINT), DECLARE_SIGNAL(SIGQUIT), DECLARE_SIGNAL(SIGSEGV), DECLARE_SIGNAL(SIGSYS), // don't care: SIGTERM DECLARE_SIGNAL(SIGUSR1), //DECLARE_SIGNAL(SIGUSR2) no usage currently }; #undef DECLARE_SIGNAL /* * Entry pointer for signal handlers * It uses functions which are not safe to be called from a signal handler, * (http://pubs.opengroup.org/onlinepubs/9699919799/functions/V2_chap02.html#tag_15_04 has a whitelist) * but when ending up here something went terribly wrong anyway. * And all which is left is just printing some information and terminate. */ static void CppcheckSignalHandler(int signo, siginfo_t * info, void * context) { int type = -1; pid_t killid; #if defined(__linux__) && defined(REG_ERR) const ucontext_t* const uc = reinterpret_cast(context); killid = (pid_t) syscall(SYS_gettid); if (uc) { type = (int)uc->uc_mcontext.gregs[REG_ERR] & 2; } #else (void)context; killid = getpid(); #endif const Signalmap_t::const_iterator it=listofsignals.find(signo); const char * const signame = (it==listofsignals.end()) ? "unknown" : it->second.c_str(); bool printCallstack=true; // try to print a callstack? bool lowMem=false; // was low-memory condition detected? Be careful then! Avoid allocating much more memory then. bool unexpectedSignal=true; // unexpected indicates program failure bool terminate=true; // exit process/thread const bool isAddressOnStack = IsAddressOnStack(info->si_addr); FILE* output = CppCheckExecutor::getExceptionOutput(); switch (signo) { case SIGABRT: fputs("Internal error: cppcheck received signal ", output); fputs(signame, output); fputs( #ifdef NDEBUG " - out of memory?\n", #else " - out of memory or assertion?\n", #endif output); lowMem=true; // educated guess break; case SIGBUS: fputs("Internal error: cppcheck received signal ", output); fputs(signame, output); switch (info->si_code) { case BUS_ADRALN: // invalid address alignment fputs(" - BUS_ADRALN", output); break; case BUS_ADRERR: // nonexistent physical address fputs(" - BUS_ADRERR", output); break; case BUS_OBJERR: // object-specific hardware error fputs(" - BUS_OBJERR", output); break; #ifdef BUS_MCEERR_AR case BUS_MCEERR_AR: // Hardware memory error consumed on a machine check; fputs(" - BUS_MCEERR_AR", output); break; #endif #ifdef BUS_MCEERR_AO case BUS_MCEERR_AO: // Hardware memory error detected in process but not consumed fputs(" - BUS_MCEERR_AO", output); break; #endif default: break; } fprintf(output, " (at 0x%lx).\n", (unsigned long)info->si_addr); break; case SIGFPE: fputs("Internal error: cppcheck received signal ", output); fputs(signame, output); switch (info->si_code) { case FPE_INTDIV: // integer divide by zero fputs(" - FPE_INTDIV", output); break; case FPE_INTOVF: // integer overflow fputs(" - FPE_INTOVF", output); break; case FPE_FLTDIV: // floating-point divide by zero fputs(" - FPE_FLTDIV", output); break; case FPE_FLTOVF: // floating-point overflow fputs(" - FPE_FLTOVF", output); break; case FPE_FLTUND: // floating-point underflow fputs(" - FPE_FLTUND", output); break; case FPE_FLTRES: // floating-point inexact result fputs(" - FPE_FLTRES", output); break; case FPE_FLTINV: // floating-point invalid operation fputs(" - FPE_FLTINV", output); break; case FPE_FLTSUB: // subscript out of range fputs(" - FPE_FLTSUB", output); break; default: break; } fprintf(output, " (at 0x%lx).\n", (unsigned long)info->si_addr); break; case SIGILL: fputs("Internal error: cppcheck received signal ", output); fputs(signame, output); switch (info->si_code) { case ILL_ILLOPC: // illegal opcode fputs(" - ILL_ILLOPC", output); break; case ILL_ILLOPN: // illegal operand fputs(" - ILL_ILLOPN", output); break; case ILL_ILLADR: // illegal addressing mode fputs(" - ILL_ILLADR", output); break; case ILL_ILLTRP: // illegal trap fputs(" - ILL_ILLTRP", output); break; case ILL_PRVOPC: // privileged opcode fputs(" - ILL_PRVOPC", output); break; case ILL_PRVREG: // privileged register fputs(" - ILL_PRVREG", output); break; case ILL_COPROC: // coprocessor error fputs(" - ILL_COPROC", output); break; case ILL_BADSTK: // internal stack error fputs(" - ILL_BADSTK", output); break; default: break; } fprintf(output, " (at 0x%lx).%s\n", (unsigned long)info->si_addr, (isAddressOnStack)?" Stackoverflow?":""); break; case SIGINT: unexpectedSignal=false; // legal usage: interrupt application via CTRL-C fputs("cppcheck received signal ", output); fputs(signame, output); printCallstack=true; fputs(".\n", output); break; case SIGSEGV: fputs("Internal error: cppcheck received signal ", output); fputs(signame, output); switch (info->si_code) { case SEGV_MAPERR: // address not mapped to object fputs(" - SEGV_MAPERR", output); break; case SEGV_ACCERR: // invalid permissions for mapped object fputs(" - SEGV_ACCERR", output); break; default: break; } fprintf(output, " (%sat 0x%lx).%s\n", // cppcheck-suppress knownConditionTrueFalse ; FP (type==-1)? "" : (type==0) ? "reading " : "writing ", (unsigned long)info->si_addr, (isAddressOnStack)?" Stackoverflow?":"" ); break; case SIGUSR1: fputs("cppcheck received signal ", output); fputs(signame, output); fputs(".\n", output); terminate=false; break; default: fputs("Internal error: cppcheck received signal ", output); fputs(signame, output); fputs(".\n", output); break; } if (printCallstack) { print_stacktrace(output, true, -1, lowMem); } if (unexpectedSignal) { fputs("\nPlease report this to the cppcheck developers!\n", output); } fflush(output); if (terminate) { // now let things proceed, shutdown and hopefully dump core for post-mortem analysis struct sigaction act; memset(&act, 0, sizeof(act)); act.sa_handler=SIG_DFL; sigaction(signo, &act, nullptr); kill(killid, signo); } } #endif #ifdef USE_WINDOWS_SEH namespace { const ULONG maxnamelength = 512; struct IMAGEHLP_SYMBOL64_EXT : public IMAGEHLP_SYMBOL64 { TCHAR nameExt[maxnamelength]; // actually no need to worry about character encoding here }; typedef BOOL (WINAPI *fpStackWalk64)(DWORD, HANDLE, HANDLE, LPSTACKFRAME64, PVOID, PREAD_PROCESS_MEMORY_ROUTINE64, PFUNCTION_TABLE_ACCESS_ROUTINE64, PGET_MODULE_BASE_ROUTINE64, PTRANSLATE_ADDRESS_ROUTINE64); fpStackWalk64 pStackWalk64; typedef DWORD64 (WINAPI *fpSymGetModuleBase64)(HANDLE, DWORD64); fpSymGetModuleBase64 pSymGetModuleBase64; typedef BOOL (WINAPI *fpSymGetSymFromAddr64)(HANDLE, DWORD64, PDWORD64, PIMAGEHLP_SYMBOL64); fpSymGetSymFromAddr64 pSymGetSymFromAddr64; typedef BOOL (WINAPI *fpSymGetLineFromAddr64)(HANDLE, DWORD64, PDWORD, PIMAGEHLP_LINE64); fpSymGetLineFromAddr64 pSymGetLineFromAddr64; typedef DWORD (WINAPI *fpUnDecorateSymbolName)(const TCHAR*, PTSTR, DWORD, DWORD); fpUnDecorateSymbolName pUnDecorateSymbolName; typedef PVOID (WINAPI *fpSymFunctionTableAccess64)(HANDLE, DWORD64); fpSymFunctionTableAccess64 pSymFunctionTableAccess64; typedef BOOL (WINAPI *fpSymInitialize)(HANDLE, PCSTR, BOOL); fpSymInitialize pSymInitialize; HMODULE hLibDbgHelp; // avoid explicit dependency on Dbghelp.dll bool loadDbgHelp() { hLibDbgHelp = ::LoadLibraryW(L"Dbghelp.dll"); if (!hLibDbgHelp) return false; pStackWalk64 = (fpStackWalk64) ::GetProcAddress(hLibDbgHelp, "StackWalk64"); pSymGetModuleBase64 = (fpSymGetModuleBase64) ::GetProcAddress(hLibDbgHelp, "SymGetModuleBase64"); pSymGetSymFromAddr64 = (fpSymGetSymFromAddr64) ::GetProcAddress(hLibDbgHelp, "SymGetSymFromAddr64"); pSymGetLineFromAddr64 = (fpSymGetLineFromAddr64)::GetProcAddress(hLibDbgHelp, "SymGetLineFromAddr64"); pSymFunctionTableAccess64 = (fpSymFunctionTableAccess64)::GetProcAddress(hLibDbgHelp, "SymFunctionTableAccess64"); pSymInitialize = (fpSymInitialize) ::GetProcAddress(hLibDbgHelp, "SymInitialize"); pUnDecorateSymbolName = (fpUnDecorateSymbolName)::GetProcAddress(hLibDbgHelp, "UnDecorateSymbolName"); return true; } void printCallstack(FILE* outputFile, PEXCEPTION_POINTERS ex) { if (!loadDbgHelp()) return; const HANDLE hProcess = GetCurrentProcess(); const HANDLE hThread = GetCurrentThread(); pSymInitialize( hProcess, nullptr, TRUE ); CONTEXT context = *(ex->ContextRecord); STACKFRAME64 stack= {0}; #ifdef _M_IX86 stack.AddrPC.Offset = context.Eip; stack.AddrPC.Mode = AddrModeFlat; stack.AddrStack.Offset = context.Esp; stack.AddrStack.Mode = AddrModeFlat; stack.AddrFrame.Offset = context.Ebp; stack.AddrFrame.Mode = AddrModeFlat; #else stack.AddrPC.Offset = context.Rip; stack.AddrPC.Mode = AddrModeFlat; stack.AddrStack.Offset = context.Rsp; stack.AddrStack.Mode = AddrModeFlat; stack.AddrFrame.Offset = context.Rsp; stack.AddrFrame.Mode = AddrModeFlat; #endif IMAGEHLP_SYMBOL64_EXT symbol; symbol.SizeOfStruct = sizeof(IMAGEHLP_SYMBOL64); symbol.MaxNameLength = maxnamelength; DWORD64 displacement = 0; int beyond_main=-1; // emergency exit, see below for (ULONG frame = 0; ; frame++) { BOOL result = pStackWalk64 ( #ifdef _M_IX86 IMAGE_FILE_MACHINE_I386, #else IMAGE_FILE_MACHINE_AMD64, #endif hProcess, hThread, &stack, &context, nullptr, pSymFunctionTableAccess64, pSymGetModuleBase64, nullptr ); if (!result) // official end... break; pSymGetSymFromAddr64(hProcess, (ULONG64)stack.AddrPC.Offset, &displacement, &symbol); TCHAR undname[maxnamelength]= {0}; pUnDecorateSymbolName((const TCHAR*)symbol.Name, (PTSTR)undname, (DWORD)getArrayLength(undname), UNDNAME_COMPLETE); if (beyond_main>=0) ++beyond_main; if (_tcscmp(undname, _T("main"))==0) beyond_main=0; fprintf(outputFile, "%lu. 0x%08I64X in ", frame, (ULONG64)stack.AddrPC.Offset); fputs((const char *)undname, outputFile); fputc('\n', outputFile); if (0==stack.AddrReturn.Offset || beyond_main>2) // StackWalk64() sometimes doesn't reach any end... break; } FreeLibrary(hLibDbgHelp); hLibDbgHelp=nullptr; } void writeMemoryErrorDetails(FILE* outputFile, PEXCEPTION_POINTERS ex, const char* description) { fputs(description, outputFile); fprintf(outputFile, " (instruction: 0x%p) ", ex->ExceptionRecord->ExceptionAddress); // Using %p for ULONG_PTR later on, so it must have size identical to size of pointer // This is not the universally portable solution but good enough for Win32/64 C_ASSERT(sizeof(void*) == sizeof(ex->ExceptionRecord->ExceptionInformation[1])); switch (ex->ExceptionRecord->ExceptionInformation[0]) { case 0: fprintf(outputFile, "reading from 0x%p", reinterpret_cast(ex->ExceptionRecord->ExceptionInformation[1])); break; case 1: fprintf(outputFile, "writing to 0x%p", reinterpret_cast(ex->ExceptionRecord->ExceptionInformation[1])); break; case 8: fprintf(outputFile, "data execution prevention at 0x%p", reinterpret_cast(ex->ExceptionRecord->ExceptionInformation[1])); break; default: break; } } /* * Any evaluation of the exception needs to be done here! */ int filterException(int code, PEXCEPTION_POINTERS ex) { FILE *outputFile = stdout; fputs("Internal error: ", outputFile); switch (ex->ExceptionRecord->ExceptionCode) { case EXCEPTION_ACCESS_VIOLATION: writeMemoryErrorDetails(outputFile, ex, "Access violation"); break; case EXCEPTION_ARRAY_BOUNDS_EXCEEDED: fputs("Out of array bounds", outputFile); break; case EXCEPTION_BREAKPOINT: fputs("Breakpoint", outputFile); break; case EXCEPTION_DATATYPE_MISALIGNMENT: fputs("Misaligned data", outputFile); break; case EXCEPTION_FLT_DENORMAL_OPERAND: fputs("Denormalized floating-point value", outputFile); break; case EXCEPTION_FLT_DIVIDE_BY_ZERO: fputs("Floating-point divide-by-zero", outputFile); break; case EXCEPTION_FLT_INEXACT_RESULT: fputs("Inexact floating-point value", outputFile); break; case EXCEPTION_FLT_INVALID_OPERATION: fputs("Invalid floating-point operation", outputFile); break; case EXCEPTION_FLT_OVERFLOW: fputs("Floating-point overflow", outputFile); break; case EXCEPTION_FLT_STACK_CHECK: fputs("Floating-point stack overflow", outputFile); break; case EXCEPTION_FLT_UNDERFLOW: fputs("Floating-point underflow", outputFile); break; case EXCEPTION_GUARD_PAGE: fputs("Page-guard access", outputFile); break; case EXCEPTION_ILLEGAL_INSTRUCTION: fputs("Illegal instruction", outputFile); break; case EXCEPTION_IN_PAGE_ERROR: writeMemoryErrorDetails(outputFile, ex, "Invalid page access"); break; case EXCEPTION_INT_DIVIDE_BY_ZERO: fputs("Integer divide-by-zero", outputFile); break; case EXCEPTION_INT_OVERFLOW: fputs("Integer overflow", outputFile); break; case EXCEPTION_INVALID_DISPOSITION: fputs("Invalid exception dispatcher", outputFile); break; case EXCEPTION_INVALID_HANDLE: fputs("Invalid handle", outputFile); break; case EXCEPTION_NONCONTINUABLE_EXCEPTION: fputs("Non-continuable exception", outputFile); break; case EXCEPTION_PRIV_INSTRUCTION: fputs("Invalid instruction", outputFile); break; case EXCEPTION_SINGLE_STEP: fputs("Single instruction step", outputFile); break; case EXCEPTION_STACK_OVERFLOW: fputs("Stack overflow", outputFile); break; default: fprintf(outputFile, "Unknown exception (%d)\n", code); break; } fputc('\n', outputFile); printCallstack(outputFile, ex); fflush(outputFile); return EXCEPTION_EXECUTE_HANDLER; } } #endif /** * Signal/SEH handling * Has to be clean for using with SEH on windows, i.e. no construction of C++ object instances is allowed! * TODO Check for multi-threading issues! * */ int CppCheckExecutor::check_wrapper(CppCheck& cppcheck) { #ifdef USE_WINDOWS_SEH FILE *outputFile = stdout; __try { return check_internal(cppcheck); } __except (filterException(GetExceptionCode(), GetExceptionInformation())) { // reporting to stdout may not be helpful within a GUI application... fputs("Please report this to the cppcheck developers!\n", outputFile); return -1; } #elif defined(USE_UNIX_SIGNAL_HANDLING) // determine stack vs. heap char stackVariable; char *heapVariable=(char*)malloc(1); bStackBelowHeap = &stackVariable < heapVariable; free(heapVariable); // set up alternative stack for signal handler stack_t segv_stack; segv_stack.ss_sp = mytstack; segv_stack.ss_flags = 0; segv_stack.ss_size = MYSTACKSIZE; sigaltstack(&segv_stack, nullptr); // install signal handler struct sigaction act; memset(&act, 0, sizeof(act)); act.sa_flags=SA_SIGINFO|SA_ONSTACK; act.sa_sigaction=CppcheckSignalHandler; for (std::map::const_iterator sig=listofsignals.begin(); sig!=listofsignals.end(); ++sig) { sigaction(sig->first, &act, nullptr); } return check_internal(cppcheck); #else return check_internal(cppcheck); #endif } /* * That is a method which gets called from check_wrapper * */ int CppCheckExecutor::check_internal(CppCheck& cppcheck) { Settings& settings = cppcheck.settings(); mSettings = &settings; const bool std = tryLoadLibrary(settings.library, settings.exename, "std.cfg"); for (const std::string &lib : settings.libraries) { if (!tryLoadLibrary(settings.library, settings.exename, lib.c_str())) { const std::string msg("Failed to load the library " + lib); const std::list callstack; ErrorMessage errmsg(callstack, emptyString, Severity::information, msg, "failedToLoadCfg", Certainty::normal); reportErr(errmsg); return EXIT_FAILURE; } } if (!std) { const std::list callstack; const std::string msg("Failed to load std.cfg. Your Cppcheck installation is broken, please re-install."); #ifdef FILESDIR const std::string details("The Cppcheck binary was compiled with FILESDIR set to \"" FILESDIR "\" and will therefore search for " "std.cfg in " FILESDIR "/cfg."); #else const std::string cfgfolder(Path::fromNativeSeparators(Path::getPathFromFilename(settings.exename)) + "cfg"); const std::string details("The Cppcheck binary was compiled without FILESDIR set. Either the " "std.cfg should be available in " + cfgfolder + " or the FILESDIR " "should be configured."); #endif ErrorMessage errmsg(callstack, emptyString, Severity::information, msg+" "+details, "failedToLoadCfg", Certainty::normal); reportErr(errmsg); return EXIT_FAILURE; } if (settings.reportProgress) mLatestProgressOutputTime = std::time(nullptr); if (!settings.outputFile.empty()) { mErrorOutput = new std::ofstream(settings.outputFile); } if (settings.xml) { reportErr(ErrorMessage::getXMLHeader()); } if (!settings.buildDir.empty()) { settings.loadSummaries(); std::list fileNames; for (std::map::const_iterator i = mFiles.begin(); i != mFiles.end(); ++i) fileNames.emplace_back(i->first); AnalyzerInformation::writeFilesTxt(settings.buildDir, fileNames, settings.userDefines, settings.project.fileSettings); } unsigned int returnValue = 0; if (settings.jobs == 1) { // Single process settings.jointSuppressionReport = true; std::size_t totalfilesize = 0; for (std::map::const_iterator i = mFiles.begin(); i != mFiles.end(); ++i) { totalfilesize += i->second; } std::size_t processedsize = 0; unsigned int c = 0; if (settings.project.fileSettings.empty()) { for (std::map::const_iterator i = mFiles.begin(); i != mFiles.end(); ++i) { if (!mSettings->library.markupFile(i->first) || !mSettings->library.processMarkupAfterCode(i->first)) { returnValue += cppcheck.check(i->first); processedsize += i->second; if (!settings.quiet) reportStatus(c + 1, mFiles.size(), processedsize, totalfilesize); c++; } } } else { // filesettings // check all files of the project for (const ImportProject::FileSettings &fs : settings.project.fileSettings) { returnValue += cppcheck.check(fs); ++c; if (!settings.quiet) reportStatus(c, settings.project.fileSettings.size(), c, settings.project.fileSettings.size()); if (settings.clangTidy) cppcheck.analyseClangTidy(fs); } } // second loop to parse all markup files which may not work until all // c/cpp files have been parsed and checked for (std::map::const_iterator i = mFiles.begin(); i != mFiles.end(); ++i) { if (mSettings->library.markupFile(i->first) && mSettings->library.processMarkupAfterCode(i->first)) { returnValue += cppcheck.check(i->first); processedsize += i->second; if (!settings.quiet) reportStatus(c + 1, mFiles.size(), processedsize, totalfilesize); c++; } } if (cppcheck.analyseWholeProgram()) returnValue++; } else if (!ThreadExecutor::isEnabled()) { std::cout << "No thread support yet implemented for this platform." << std::endl; } else { // Multiple processes ThreadExecutor executor(mFiles, settings, *this); returnValue = executor.check(); } cppcheck.analyseWholeProgram(mSettings->buildDir, mFiles); if (settings.severity.isEnabled(Severity::information) || settings.checkConfiguration) { const bool enableUnusedFunctionCheck = cppcheck.isUnusedFunctionCheckEnabled(); if (settings.jointSuppressionReport) { for (std::map::const_iterator i = mFiles.begin(); i != mFiles.end(); ++i) { const bool err = reportUnmatchedSuppressions(settings.nomsg.getUnmatchedLocalSuppressions(i->first, enableUnusedFunctionCheck)); if (err && returnValue == 0) returnValue = settings.exitCode; } } const bool err = reportUnmatchedSuppressions(settings.nomsg.getUnmatchedGlobalSuppressions(enableUnusedFunctionCheck)); if (err && returnValue == 0) returnValue = settings.exitCode; } if (!settings.checkConfiguration) { cppcheck.tooManyConfigsError("",0U); if (settings.checks.isEnabled(Checks::missingInclude) && (Preprocessor::missingIncludeFlag || Preprocessor::missingSystemIncludeFlag)) { const std::list callStack; ErrorMessage msg(callStack, emptyString, Severity::information, "Cppcheck cannot find all the include files (use --check-config for details)\n" "Cppcheck cannot find all the include files. Cppcheck can check the code without the " "include files found. But the results will probably be more accurate if all the include " "files are found. Please check your project's include directories and add all of them " "as include directories for Cppcheck. To see what files Cppcheck cannot find use " "--check-config.", Preprocessor::missingIncludeFlag ? "missingInclude" : "missingIncludeSystem", Certainty::normal); reportInfo(msg); } } if (settings.xml) { reportErr(ErrorMessage::getXMLFooter()); } mSettings = nullptr; if (returnValue) return settings.exitCode; return 0; } #ifdef _WIN32 // fix trac ticket #439 'Cppcheck reports wrong filename for filenames containing 8-bit ASCII' static inline std::string ansiToOEM(const std::string &msg, bool doConvert) { if (doConvert) { const unsigned msglength = msg.length(); // convert ANSI strings to OEM strings in two steps std::vector wcContainer(msglength); std::string result(msglength, '\0'); // ansi code page characters to wide characters MultiByteToWideChar(CP_ACP, 0, msg.data(), msglength, wcContainer.data(), msglength); // wide characters to oem codepage characters WideCharToMultiByte(CP_OEMCP, 0, wcContainer.data(), msglength, const_cast(result.data()), msglength, nullptr, nullptr); return result; // hope for return value optimization } return msg; } #else // no performance regression on non-windows systems #define ansiToOEM(msg, doConvert) (msg) #endif void CppCheckExecutor::reportErr(const std::string &errmsg) { if (mErrorOutput) *mErrorOutput << errmsg << std::endl; else { std::cerr << ansiToOEM(errmsg, (mSettings == nullptr) ? true : !mSettings->xml) << std::endl; } } void CppCheckExecutor::reportOut(const std::string &outmsg, Color c) { std::cout << c << ansiToOEM(outmsg, true) << Color::Reset << std::endl; } void CppCheckExecutor::reportProgress(const std::string &filename, const char stage[], const std::size_t value) { (void)filename; if (!mLatestProgressOutputTime) return; // Report progress messages every 10 seconds const std::time_t currentTime = std::time(nullptr); if (currentTime >= (mLatestProgressOutputTime + 10)) { mLatestProgressOutputTime = currentTime; // format a progress message std::ostringstream ostr; ostr << "progress: " << stage << ' ' << value << '%'; // Report progress message reportOut(ostr.str()); } } void CppCheckExecutor::reportInfo(const ErrorMessage &msg) { reportErr(msg); } void CppCheckExecutor::reportStatus(std::size_t fileindex, std::size_t filecount, std::size_t sizedone, std::size_t sizetotal) { if (filecount > 1) { std::ostringstream oss; const long percentDone = (sizetotal > 0) ? static_cast(static_cast(sizedone) / sizetotal * 100) : 0; oss << fileindex << '/' << filecount << " files checked " << percentDone << "% done"; std::cout << Color::FgBlue << oss.str() << Color::Reset << std::endl; } } void CppCheckExecutor::reportErr(const ErrorMessage &msg) { if (mShowAllErrors) { reportOut(msg.toXML()); return; } // Alert only about unique errors if (!mShownErrors.insert(msg.toString(mSettings->verbose)).second) return; if (mSettings->xml) reportErr(msg.toXML()); else reportErr(msg.toString(mSettings->verbose, mSettings->templateFormat, mSettings->templateLocation)); } void CppCheckExecutor::bughuntingReport(const std::string &str) { if (!mSettings || str.empty()) return; if (!mBugHuntingReport) mBugHuntingReport = new std::ofstream(mSettings->bugHuntingReport); (*mBugHuntingReport) << str << std::endl; } void CppCheckExecutor::setExceptionOutput(FILE* exceptionOutput) { mExceptionOutput = exceptionOutput; } FILE* CppCheckExecutor::getExceptionOutput() { return mExceptionOutput; } bool CppCheckExecutor::tryLoadLibrary(Library& destination, const std::string& basepath, const char* filename) { const Library::Error err = destination.load(basepath.c_str(), filename); if (err.errorcode == Library::ErrorCode::UNKNOWN_ELEMENT) std::cout << "cppcheck: Found unknown elements in configuration file '" << filename << "': " << err.reason << std::endl; else if (err.errorcode != Library::ErrorCode::OK) { std::cout << "cppcheck: Failed to load library configuration file '" << filename << "'. "; switch (err.errorcode) { case Library::ErrorCode::OK: break; case Library::ErrorCode::FILE_NOT_FOUND: std::cout << "File not found"; break; case Library::ErrorCode::BAD_XML: std::cout << "Bad XML"; break; case Library::ErrorCode::UNKNOWN_ELEMENT: std::cout << "Unexpected element"; break; case Library::ErrorCode::MISSING_ATTRIBUTE: std::cout << "Missing attribute"; break; case Library::ErrorCode::BAD_ATTRIBUTE_VALUE: std::cout << "Bad attribute value"; break; case Library::ErrorCode::UNSUPPORTED_FORMAT: std::cout << "File is of unsupported format version"; break; case Library::ErrorCode::DUPLICATE_PLATFORM_TYPE: std::cout << "Duplicate platform type"; break; case Library::ErrorCode::PLATFORM_TYPE_REDEFINED: std::cout << "Platform type redefined"; break; } if (!err.reason.empty()) std::cout << " '" + err.reason + "'"; std::cout << std::endl; return false; } return true; } /** * Execute a shell command and read the output from it. Returns true if command terminated successfully. */ // cppcheck-suppress passedByValue - "exe" copy needed in _WIN32 code bool CppCheckExecutor::executeCommand(std::string exe, std::vector args, const std::string &redirect, std::string *output_) { output_->clear(); std::string joinedArgs; for (const std::string &arg : args) { if (!joinedArgs.empty()) joinedArgs += " "; if (arg.find(" ") != std::string::npos) joinedArgs += '"' + arg + '"'; else joinedArgs += arg; } #ifdef _WIN32 // Extra quoutes are needed in windows if filename has space if (exe.find(" ") != std::string::npos) exe = "\"" + exe + "\""; const std::string cmd = exe + " " + joinedArgs + " " + redirect; std::unique_ptr pipe(_popen(cmd.c_str(), "r"), _pclose); #else const std::string cmd = exe + " " + joinedArgs + " " + redirect; std::unique_ptr pipe(popen(cmd.c_str(), "r"), pclose); #endif if (!pipe) return false; char buffer[1024]; while (fgets(buffer, sizeof(buffer), pipe.get()) != nullptr) *output_ += buffer; return true; }