/* * Cppcheck - A tool for static C/C++ code analysis * Copyright (C) 2007-2021 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 "threadexecutor.h" #include "color.h" #include "config.h" #include "cppcheck.h" #include "cppcheckexecutor.h" #include "errortypes.h" #include "importproject.h" #include "settings.h" #include "suppressions.h" #include #include #include #include #include #include #include #ifdef __SVR4 // Solaris #include #endif #ifdef THREADING_MODEL_FORK #if defined(__linux__) #include #endif #include #include #include #include #include #endif #ifdef THREADING_MODEL_WIN #include #include #endif // required for FD_ZERO using std::memset; ThreadExecutor::ThreadExecutor(const std::map &files, Settings &settings, ErrorLogger &errorLogger) : mFiles(files), mSettings(settings), mErrorLogger(errorLogger), mFileCount(0) { #if defined(THREADING_MODEL_FORK) mWpipe = 0; #elif defined(THREADING_MODEL_WIN) mProcessedFiles = 0; mTotalFiles = 0; mProcessedSize = 0; mTotalFileSize = 0; #endif } ThreadExecutor::~ThreadExecutor() {} // cppcheck-suppress unusedFunction - only used in unit tests void ThreadExecutor::addFileContent(const std::string &path, const std::string &content) { mFileContents[path] = content; } void ThreadExecutor::reportErr(const ErrorMessage &msg) { report(msg, MessageType::REPORT_ERROR); } void ThreadExecutor::reportInfo(const ErrorMessage &msg) { report(msg, MessageType::REPORT_INFO); } /////////////////////////////////////////////////////////////////////////////// ////// This code is for platforms that support fork() only //////////////////// /////////////////////////////////////////////////////////////////////////////// #if defined(THREADING_MODEL_FORK) int ThreadExecutor::handleRead(int rpipe, unsigned int &result) { char type = 0; if (read(rpipe, &type, 1) <= 0) { if (errno == EAGAIN) return 0; // need to increment so a missing pipe (i.e. premature exit of forked process) results in an error exitcode ++result; return -1; } if (type != REPORT_OUT && type != REPORT_ERROR && type != REPORT_INFO && type != CHILD_END) { std::cerr << "#### ThreadExecutor::handleRead error, type was:" << type << std::endl; std::exit(EXIT_FAILURE); } unsigned int len = 0; if (read(rpipe, &len, sizeof(len)) <= 0) { std::cerr << "#### ThreadExecutor::handleRead error, type was:" << type << std::endl; std::exit(EXIT_FAILURE); } // Don't rely on incoming data being null-terminated. // Allocate +1 element and null-terminate the buffer. char *buf = new char[len + 1]; const ssize_t readIntoBuf = read(rpipe, buf, len); if (readIntoBuf <= 0) { std::cerr << "#### ThreadExecutor::handleRead error, type was:" << type << std::endl; std::exit(EXIT_FAILURE); } buf[readIntoBuf] = 0; if (type == REPORT_OUT) { mErrorLogger.reportOut(buf); } else if (type == REPORT_ERROR || type == REPORT_INFO) { ErrorMessage msg; try { msg.deserialize(buf); } catch (const InternalError& e) { std::cerr << "#### ThreadExecutor::handleRead error, internal error:" << e.errorMessage << std::endl; std::exit(EXIT_FAILURE); } if (!mSettings.nomsg.isSuppressed(msg.toSuppressionsErrorMessage())) { // Alert only about unique errors std::string errmsg = msg.toString(mSettings.verbose); if (std::find(mErrorList.begin(), mErrorList.end(), errmsg) == mErrorList.end()) { mErrorList.emplace_back(errmsg); if (type == REPORT_ERROR) mErrorLogger.reportErr(msg); else mErrorLogger.reportInfo(msg); } } } else if (type == CHILD_END) { std::istringstream iss(buf); unsigned int fileResult = 0; iss >> fileResult; result += fileResult; delete[] buf; return -1; } delete[] buf; return 1; } bool ThreadExecutor::checkLoadAverage(size_t nchildren) { #if defined(__CYGWIN__) || defined(__QNX__) || defined(__HAIKU__) // getloadavg() is unsupported on Cygwin, Qnx, Haiku. return true; #else if (!nchildren || !mSettings.loadAverage) { return true; } double sample(0); if (getloadavg(&sample, 1) != 1) { // disable load average checking on getloadavg error return true; } else if (sample < mSettings.loadAverage) { return true; } return false; #endif } unsigned int ThreadExecutor::check() { mFileCount = 0; unsigned int result = 0; std::size_t totalfilesize = 0; for (std::map::const_iterator i = mFiles.begin(); i != mFiles.end(); ++i) { totalfilesize += i->second; } std::list rpipes; std::map childFile; std::map pipeFile; std::size_t processedsize = 0; std::map::const_iterator iFile = mFiles.begin(); std::list::const_iterator iFileSettings = mSettings.project.fileSettings.begin(); for (;;) { // Start a new child size_t nchildren = childFile.size(); if ((iFile != mFiles.end() || iFileSettings != mSettings.project.fileSettings.end()) && nchildren < mSettings.jobs && checkLoadAverage(nchildren)) { int pipes[2]; if (pipe(pipes) == -1) { std::cerr << "#### ThreadExecutor::check, pipe() failed: "<< std::strerror(errno) << std::endl; std::exit(EXIT_FAILURE); } int flags = 0; if ((flags = fcntl(pipes[0], F_GETFL, 0)) < 0) { std::cerr << "#### ThreadExecutor::check, fcntl(F_GETFL) failed: "<< std::strerror(errno) << std::endl; std::exit(EXIT_FAILURE); } if (fcntl(pipes[0], F_SETFL, flags | O_NONBLOCK) < 0) { std::cerr << "#### ThreadExecutor::check, fcntl(F_SETFL) failed: "<< std::strerror(errno) << std::endl; std::exit(EXIT_FAILURE); } pid_t pid = fork(); if (pid < 0) { // Error std::cerr << "#### ThreadExecutor::check, Failed to create child process: "<< std::strerror(errno) << std::endl; std::exit(EXIT_FAILURE); } else if (pid == 0) { #if defined(__linux__) prctl(PR_SET_PDEATHSIG, SIGHUP); #endif close(pipes[0]); mWpipe = pipes[1]; CppCheck fileChecker(*this, false, CppCheckExecutor::executeCommand); fileChecker.settings() = mSettings; unsigned int resultOfCheck = 0; if (iFileSettings != mSettings.project.fileSettings.end()) { resultOfCheck = fileChecker.check(*iFileSettings); } else if (!mFileContents.empty() && mFileContents.find(iFile->first) != mFileContents.end()) { // File content was given as a string resultOfCheck = fileChecker.check(iFile->first, mFileContents[iFile->first]); } else { // Read file from a file resultOfCheck = fileChecker.check(iFile->first); } std::ostringstream oss; oss << resultOfCheck; writeToPipe(CHILD_END, oss.str()); std::exit(EXIT_SUCCESS); } close(pipes[1]); rpipes.push_back(pipes[0]); if (iFileSettings != mSettings.project.fileSettings.end()) { childFile[pid] = iFileSettings->filename + ' ' + iFileSettings->cfg; pipeFile[pipes[0]] = iFileSettings->filename + ' ' + iFileSettings->cfg; ++iFileSettings; } else { childFile[pid] = iFile->first; pipeFile[pipes[0]] = iFile->first; ++iFile; } } if (!rpipes.empty()) { fd_set rfds; FD_ZERO(&rfds); for (std::list::const_iterator rp = rpipes.begin(); rp != rpipes.end(); ++rp) FD_SET(*rp, &rfds); struct timeval tv; // for every second polling of load average condition tv.tv_sec = 1; tv.tv_usec = 0; int r = select(*std::max_element(rpipes.begin(), rpipes.end()) + 1, &rfds, nullptr, nullptr, &tv); if (r > 0) { std::list::iterator rp = rpipes.begin(); while (rp != rpipes.end()) { if (FD_ISSET(*rp, &rfds)) { int readRes = handleRead(*rp, result); if (readRes == -1) { std::size_t size = 0; std::map::iterator p = pipeFile.find(*rp); if (p != pipeFile.end()) { std::string name = p->second; pipeFile.erase(p); std::map::const_iterator fs = mFiles.find(name); if (fs != mFiles.end()) { size = fs->second; } } mFileCount++; processedsize += size; if (!mSettings.quiet) CppCheckExecutor::reportStatus(mFileCount, mFiles.size() + mSettings.project.fileSettings.size(), processedsize, totalfilesize); close(*rp); rp = rpipes.erase(rp); } else ++rp; } else ++rp; } } } if (!childFile.empty()) { int stat = 0; pid_t child = waitpid(0, &stat, WNOHANG); if (child > 0) { std::string childname; std::map::iterator c = childFile.find(child); if (c != childFile.end()) { childname = c->second; childFile.erase(c); } if (WIFEXITED(stat)) { const int exitstatus = WEXITSTATUS(stat); if (exitstatus != EXIT_SUCCESS) { std::ostringstream oss; oss << "Child process exited with " << exitstatus; reportInternalChildErr(childname, oss.str()); } } else if (WIFSIGNALED(stat)) { std::ostringstream oss; oss << "Child process crashed with signal " << WTERMSIG(stat); reportInternalChildErr(childname, oss.str()); } } } if (iFile == mFiles.end() && iFileSettings == mSettings.project.fileSettings.end() && rpipes.empty() && childFile.empty()) { // All done break; } } return result; } void ThreadExecutor::writeToPipe(PipeSignal type, const std::string &data) { unsigned int len = static_cast(data.length() + 1); char *out = new char[len + 1 + sizeof(len)]; out[0] = static_cast(type); std::memcpy(&(out[1]), &len, sizeof(len)); std::memcpy(&(out[1+sizeof(len)]), data.c_str(), len); if (write(mWpipe, out, len + 1 + sizeof(len)) <= 0) { delete[] out; out = nullptr; std::cerr << "#### ThreadExecutor::writeToPipe, Failed to write to pipe" << std::endl; std::exit(EXIT_FAILURE); } delete[] out; } void ThreadExecutor::reportOut(const std::string &outmsg, Color c) { writeToPipe(REPORT_OUT, ::toString(c) + outmsg + ::toString(Color::Reset)); } void ThreadExecutor::bughuntingReport(const std::string &str) { writeToPipe(REPORT_VERIFICATION, str); } void ThreadExecutor::report(const ErrorMessage &msg, MessageType msgType) { PipeSignal pipeSignal; switch (msgType) { case MessageType::REPORT_ERROR: pipeSignal = REPORT_ERROR; break; case MessageType::REPORT_INFO: pipeSignal = REPORT_INFO; break; } writeToPipe(pipeSignal, msg.serialize()); } void ThreadExecutor::reportInternalChildErr(const std::string &childname, const std::string &msg) { std::list locations; locations.emplace_back(childname, 0, 0); const ErrorMessage errmsg(locations, emptyString, Severity::error, "Internal error: " + msg, "cppcheckError", Certainty::normal); if (!mSettings.nomsg.isSuppressed(errmsg.toSuppressionsErrorMessage())) mErrorLogger.reportErr(errmsg); } #elif defined(THREADING_MODEL_WIN) unsigned int ThreadExecutor::check() { std::vector> threadFutures; threadFutures.reserve(mSettings.jobs); mItNextFile = mFiles.begin(); mItNextFileSettings = mSettings.project.fileSettings.begin(); mProcessedFiles = 0; mProcessedSize = 0; mTotalFiles = mFiles.size() + mSettings.project.fileSettings.size(); mTotalFileSize = 0; for (std::map::const_iterator i = mFiles.begin(); i != mFiles.end(); ++i) { mTotalFileSize += i->second; } for (unsigned int i = 0; i < mSettings.jobs; ++i) { try { threadFutures.emplace_back(std::async(std::launch::async, threadProc, this)); } catch (const std::system_error &e) { std::cerr << "#### ThreadExecutor::check exception :" << e.what() << std::endl; exit(EXIT_FAILURE); } } return std::accumulate(threadFutures.begin(), threadFutures.end(), 0U, [](unsigned int v, std::future& f) { return v + f.get(); }); } unsigned int __stdcall ThreadExecutor::threadProc(ThreadExecutor* threadExecutor) { unsigned int result = 0; std::map::const_iterator &itFile = threadExecutor->mItNextFile; std::list::const_iterator &itFileSettings = threadExecutor->mItNextFileSettings; // guard static members of CppCheck against concurrent access threadExecutor->mFileSync.lock(); for (;;) { if (itFile == threadExecutor->mFiles.end() && itFileSettings == threadExecutor->mSettings.project.fileSettings.end()) { threadExecutor->mFileSync.unlock(); break; } CppCheck fileChecker(*threadExecutor, false, CppCheckExecutor::executeCommand); fileChecker.settings() = threadExecutor->mSettings; std::size_t fileSize = 0; if (itFile != threadExecutor->mFiles.end()) { const std::string &file = itFile->first; fileSize = itFile->second; ++itFile; threadExecutor->mFileSync.unlock(); const std::map::const_iterator fileContent = threadExecutor->mFileContents.find(file); if (fileContent != threadExecutor->mFileContents.end()) { // File content was given as a string result += fileChecker.check(file, fileContent->second); } else { // Read file from a file result += fileChecker.check(file); } } else { // file settings.. const ImportProject::FileSettings &fs = *itFileSettings; ++itFileSettings; threadExecutor->mFileSync.unlock(); result += fileChecker.check(fs); if (threadExecutor->mSettings.clangTidy) fileChecker.analyseClangTidy(fs); } threadExecutor->mFileSync.lock(); threadExecutor->mProcessedSize += fileSize; threadExecutor->mProcessedFiles++; if (!threadExecutor->mSettings.quiet) { std::lock_guard lg(threadExecutor->mReportSync); CppCheckExecutor::reportStatus(threadExecutor->mProcessedFiles, threadExecutor->mTotalFiles, threadExecutor->mProcessedSize, threadExecutor->mTotalFileSize); } } return result; } void ThreadExecutor::reportOut(const std::string &outmsg, Color c) { std::lock_guard lg(mReportSync); mErrorLogger.reportOut(outmsg, c); } void ThreadExecutor::bughuntingReport(const std::string & /*str*/) { // TODO } void ThreadExecutor::report(const ErrorMessage &msg, MessageType msgType) { if (mSettings.nomsg.isSuppressed(msg.toSuppressionsErrorMessage())) return; // Alert only about unique errors bool reportError = false; const std::string errmsg = msg.toString(mSettings.verbose); { std::lock_guard lg(mErrorSync); if (std::find(mErrorList.begin(), mErrorList.end(), errmsg) == mErrorList.end()) { mErrorList.emplace_back(errmsg); reportError = true; } } if (reportError) { std::lock_guard lg(mReportSync); switch (msgType) { case MessageType::REPORT_ERROR: mErrorLogger.reportErr(msg); break; case MessageType::REPORT_INFO: mErrorLogger.reportInfo(msg); break; } } } #endif