/**************************************************************************** ** ** Copyright (C) 2013 Digia Plc and/or its subsidiary(-ies). ** Contact: http://www.qt-project.org/legal ** ** This file is part of the QtCore module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and Digia. For licensing terms and ** conditions see http://qt.digia.com/licensing. For further information ** use the contact form at http://qt.digia.com/contact-us. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Digia gives you certain additional ** rights. These rights are described in the Digia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 3.0 as published by the Free Software ** Foundation and appearing in the file LICENSE.GPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU General Public License version 3.0 requirements will be ** met: http://www.gnu.org/copyleft/gpl.html. ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ //#define QPROCESS_DEBUG #include "qdebug.h" #ifndef QT_NO_PROCESS #if defined QPROCESS_DEBUG #include "qstring.h" #include /* Returns a human readable representation of the first \a len characters in \a data. */ QT_BEGIN_NAMESPACE static QByteArray qt_prettyDebug(const char *data, int len, int maxSize) { if (!data) return "(null)"; QByteArray out; for (int i = 0; i < len; ++i) { char c = data[i]; if (isprint(c)) { out += c; } else switch (c) { case '\n': out += "\\n"; break; case '\r': out += "\\r"; break; case '\t': out += "\\t"; break; default: QString tmp; tmp.sprintf("\\%o", c); out += tmp.toLatin1(); } } if (len < maxSize) out += "..."; return out; } QT_END_NAMESPACE #endif #include "qplatformdefs.h" #include "qprocess.h" #include "qprocess_p.h" #include "private/qcore_unix_p.h" #ifdef Q_OS_MAC #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef Q_OS_QNX #include "qvarlengtharray.h" #include #include #endif QT_BEGIN_NAMESPACE // POSIX requires PIPE_BUF to be 512 or larger // so we will use 512 static const int errorBufferMax = 512; static int qt_qprocess_deadChild_pipe[2]; static struct sigaction qt_sa_old_sigchld_handler; static void qt_sa_sigchld_handler(int signum) { qt_safe_write(qt_qprocess_deadChild_pipe[1], "", 1); #if defined (QPROCESS_DEBUG) fprintf(stderr, "*** SIGCHLD\n"); #endif // load it as volatile void (*oldAction)(int) = ((volatile struct sigaction *)&qt_sa_old_sigchld_handler)->sa_handler; if (oldAction && oldAction != SIG_IGN) oldAction(signum); } static inline void add_fd(int &nfds, int fd, fd_set *fdset) { FD_SET(fd, fdset); if ((fd) > nfds) nfds = fd; } struct QProcessInfo { QProcess *process; int deathPipe; int exitResult; pid_t pid; int serialNumber; }; class QProcessManager : public QThread { Q_OBJECT public: QProcessManager(); ~QProcessManager(); void run(); void catchDeadChildren(); void add(pid_t pid, QProcess *process); void remove(QProcess *process); void lock(); void unlock(); private: QMutex mutex; QHash children; }; static QProcessManager *processManagerInstance = 0; static QProcessManager *processManager() { // The constructor of QProcessManager should be called only once // so we cannot use Q_GLOBAL_STATIC directly for QProcessManager static QBasicMutex processManagerGlobalMutex; QMutexLocker locker(&processManagerGlobalMutex); if (!processManagerInstance) new QProcessManager; Q_ASSERT(processManagerInstance); return processManagerInstance; } QProcessManager::QProcessManager() { #if defined (QPROCESS_DEBUG) qDebug() << "QProcessManager::QProcessManager()"; #endif // initialize the dead child pipe and make it non-blocking. in the // extremely unlikely event that the pipe fills up, we do not under any // circumstances want to block. qt_safe_pipe(qt_qprocess_deadChild_pipe, O_NONBLOCK); // set up the SIGCHLD handler, which writes a single byte to the dead // child pipe every time a child dies. struct sigaction action; memset(&action, 0, sizeof(action)); action.sa_handler = qt_sa_sigchld_handler; action.sa_flags = SA_NOCLDSTOP; ::sigaction(SIGCHLD, &action, &qt_sa_old_sigchld_handler); processManagerInstance = this; } QProcessManager::~QProcessManager() { // notify the thread that we're shutting down. qt_safe_write(qt_qprocess_deadChild_pipe[1], "@", 1); qt_safe_close(qt_qprocess_deadChild_pipe[1]); wait(); // on certain unixes, closing the reading end of the pipe will cause // select in run() to block forever, rather than return with EBADF. qt_safe_close(qt_qprocess_deadChild_pipe[0]); qt_qprocess_deadChild_pipe[0] = -1; qt_qprocess_deadChild_pipe[1] = -1; qDeleteAll(children.values()); children.clear(); struct sigaction currentAction; ::sigaction(SIGCHLD, 0, ¤tAction); if (currentAction.sa_handler == qt_sa_sigchld_handler) { ::sigaction(SIGCHLD, &qt_sa_old_sigchld_handler, 0); } processManagerInstance = 0; } void QProcessManager::run() { forever { fd_set readset; FD_ZERO(&readset); FD_SET(qt_qprocess_deadChild_pipe[0], &readset); #if defined (QPROCESS_DEBUG) qDebug() << "QProcessManager::run() waiting for children to die"; #endif // block forever, or until activity is detected on the dead child // pipe. the only other peers are the SIGCHLD signal handler, and the // QProcessManager destructor. int nselect = select(qt_qprocess_deadChild_pipe[0] + 1, &readset, 0, 0, 0); if (nselect < 0) { if (errno == EINTR) continue; break; } // empty only one byte from the pipe, even though several SIGCHLD // signals may have been delivered in the meantime, to avoid race // conditions. char c; if (qt_safe_read(qt_qprocess_deadChild_pipe[0], &c, 1) < 0 || c == '@') break; // catch any and all children that we can. catchDeadChildren(); } } void QProcessManager::catchDeadChildren() { QMutexLocker locker(&mutex); // try to catch all children whose pid we have registered, and whose // deathPipe is still valid (i.e, we have not already notified it). QHash::Iterator it = children.begin(); while (it != children.end()) { // notify all children that they may have died. they need to run // waitpid() in their own thread. QProcessInfo *info = it.value(); qt_safe_write(info->deathPipe, "", 1); #if defined (QPROCESS_DEBUG) qDebug() << "QProcessManager::run() sending death notice to" << info->process; #endif ++it; } } static QBasicAtomicInt idCounter = Q_BASIC_ATOMIC_INITIALIZER(1); void QProcessManager::add(pid_t pid, QProcess *process) { #if defined (QPROCESS_DEBUG) qDebug() << "QProcessManager::add() adding pid" << pid << "process" << process; #endif // insert a new info structure for this process QProcessInfo *info = new QProcessInfo; info->process = process; info->deathPipe = process->d_func()->deathPipe[1]; info->exitResult = 0; info->pid = pid; int serial = idCounter.fetchAndAddRelaxed(1); process->d_func()->serial = serial; children.insert(serial, info); } void QProcessManager::remove(QProcess *process) { QMutexLocker locker(&mutex); int serial = process->d_func()->serial; QProcessInfo *info = children.take(serial); #if defined (QPROCESS_DEBUG) if (info) qDebug() << "QProcessManager::remove() removing pid" << info->pid << "process" << info->process; #endif delete info; } void QProcessManager::lock() { mutex.lock(); } void QProcessManager::unlock() { mutex.unlock(); } static int qt_create_pipe(int *pipe) { if (pipe[0] != -1) qt_safe_close(pipe[0]); if (pipe[1] != -1) qt_safe_close(pipe[1]); int pipe_ret = qt_safe_pipe(pipe); if (pipe_ret != 0) { qWarning("QProcessPrivate::createPipe: Cannot create pipe %p: %s", pipe, qPrintable(qt_error_string(errno))); } return pipe_ret; } void QProcessPrivate::destroyPipe(int *pipe) { if (pipe[1] != -1) { qt_safe_close(pipe[1]); pipe[1] = -1; } if (pipe[0] != -1) { qt_safe_close(pipe[0]); pipe[0] = -1; } } void QProcessPrivate::destroyChannel(Channel *channel) { destroyPipe(channel->pipe); } /* Create the pipes to a QProcessPrivate::Channel. This function must be called in order: stdin, stdout, stderr */ bool QProcessPrivate::createChannel(Channel &channel) { Q_Q(QProcess); if (&channel == &stderrChannel && processChannelMode == QProcess::MergedChannels) { channel.pipe[0] = -1; channel.pipe[1] = -1; return true; } if (channel.type == Channel::Normal) { // we're piping this channel to our own process if (qt_create_pipe(channel.pipe) != 0) return false; // create the socket notifiers if (threadData->eventDispatcher) { if (&channel == &stdinChannel) { channel.notifier = new QSocketNotifier(channel.pipe[1], QSocketNotifier::Write, q); channel.notifier->setEnabled(false); QObject::connect(channel.notifier, SIGNAL(activated(int)), q, SLOT(_q_canWrite())); } else { channel.notifier = new QSocketNotifier(channel.pipe[0], QSocketNotifier::Read, q); const char *receiver; if (&channel == &stdoutChannel) receiver = SLOT(_q_canReadStandardOutput()); else receiver = SLOT(_q_canReadStandardError()); QObject::connect(channel.notifier, SIGNAL(activated(int)), q, receiver); } } return true; } else if (channel.type == Channel::Redirect) { // we're redirecting the channel to/from a file QByteArray fname = QFile::encodeName(channel.file); if (&channel == &stdinChannel) { // try to open in read-only mode channel.pipe[1] = -1; if ( (channel.pipe[0] = qt_safe_open(fname, O_RDONLY)) != -1) return true; // success q->setErrorString(QProcess::tr("Could not open input redirection for reading")); } else { int mode = O_WRONLY | O_CREAT; if (channel.append) mode |= O_APPEND; else mode |= O_TRUNC; channel.pipe[0] = -1; if ( (channel.pipe[1] = qt_safe_open(fname, mode, 0666)) != -1) return true; // success q->setErrorString(QProcess::tr("Could not open output redirection for writing")); } // could not open file processError = QProcess::FailedToStart; emit q->error(processError); cleanup(); return false; } else { Q_ASSERT_X(channel.process, "QProcess::start", "Internal error"); Channel *source; Channel *sink; if (channel.type == Channel::PipeSource) { // we are the source source = &channel; sink = &channel.process->stdinChannel; Q_ASSERT(source == &stdoutChannel); Q_ASSERT(sink->process == this && sink->type == Channel::PipeSink); } else { // we are the sink; source = &channel.process->stdoutChannel; sink = &channel; Q_ASSERT(sink == &stdinChannel); Q_ASSERT(source->process == this && source->type == Channel::PipeSource); } if (source->pipe[1] != INVALID_Q_PIPE || sink->pipe[0] != INVALID_Q_PIPE) { // already created, do nothing return true; } else { Q_ASSERT(source->pipe[0] == INVALID_Q_PIPE && source->pipe[1] == INVALID_Q_PIPE); Q_ASSERT(sink->pipe[0] == INVALID_Q_PIPE && sink->pipe[1] == INVALID_Q_PIPE); Q_PIPE pipe[2] = { -1, -1 }; if (qt_create_pipe(pipe) != 0) return false; sink->pipe[0] = pipe[0]; source->pipe[1] = pipe[1]; return true; } } } QT_BEGIN_INCLUDE_NAMESPACE #if defined(Q_OS_MAC) && !defined(Q_OS_IOS) # include # define environ (*_NSGetEnviron()) #else extern char **environ; #endif QT_END_INCLUDE_NAMESPACE QProcessEnvironment QProcessEnvironment::systemEnvironment() { QProcessEnvironment env; #if !defined(Q_OS_IOS) const char *entry; for (int count = 0; (entry = environ[count]); ++count) { const char *equal = strchr(entry, '='); if (!equal) continue; QByteArray name(entry, equal - entry); QByteArray value(equal + 1); env.d->hash.insert(QProcessEnvironmentPrivate::Key(name), QProcessEnvironmentPrivate::Value(value)); } #endif return env; } static char **_q_dupEnvironment(const QProcessEnvironmentPrivate::Hash &environment, int *envc) { *envc = 0; if (environment.isEmpty()) return 0; // if LD_LIBRARY_PATH exists in the current environment, but // not in the environment list passed by the programmer, then // copy it over. #if defined(Q_OS_MAC) static const char libraryPath[] = "DYLD_LIBRARY_PATH"; #else static const char libraryPath[] = "LD_LIBRARY_PATH"; #endif const QByteArray envLibraryPath = qgetenv(libraryPath); bool needToAddLibraryPath = !envLibraryPath.isEmpty() && !environment.contains(QProcessEnvironmentPrivate::Key(QByteArray(libraryPath))); char **envp = new char *[environment.count() + 2]; envp[environment.count()] = 0; envp[environment.count() + 1] = 0; QProcessEnvironmentPrivate::Hash::ConstIterator it = environment.constBegin(); const QProcessEnvironmentPrivate::Hash::ConstIterator end = environment.constEnd(); for ( ; it != end; ++it) { QByteArray key = it.key().key; QByteArray value = it.value().bytes(); key.reserve(key.length() + 1 + value.length()); key.append('='); key.append(value); envp[(*envc)++] = ::strdup(key.constData()); } if (needToAddLibraryPath) envp[(*envc)++] = ::strdup(QByteArray(QByteArray(libraryPath) + '=' + envLibraryPath).constData()); return envp; } void QProcessPrivate::startProcess() { Q_Q(QProcess); #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::startProcess()"); #endif processManager()->start(); // Initialize pipes if (!createChannel(stdinChannel) || !createChannel(stdoutChannel) || !createChannel(stderrChannel) || qt_create_pipe(childStartedPipe) != 0 || qt_create_pipe(deathPipe) != 0) { processError = QProcess::FailedToStart; q->setErrorString(qt_error_string(errno)); emit q->error(processError); cleanup(); return; } if (threadData->eventDispatcher) { startupSocketNotifier = new QSocketNotifier(childStartedPipe[0], QSocketNotifier::Read, q); QObject::connect(startupSocketNotifier, SIGNAL(activated(int)), q, SLOT(_q_startupNotification())); deathNotifier = new QSocketNotifier(deathPipe[0], QSocketNotifier::Read, q); QObject::connect(deathNotifier, SIGNAL(activated(int)), q, SLOT(_q_processDied())); } // Start the process (platform dependent) q->setProcessState(QProcess::Starting); // Create argument list with right number of elements, and set the final // one to 0. char **argv = new char *[arguments.count() + 2]; argv[arguments.count() + 1] = 0; // Encode the program name. QByteArray encodedProgramName = QFile::encodeName(program); #ifdef Q_OS_MAC // allow invoking of .app bundles on the Mac. QFileInfo fileInfo(program); if (encodedProgramName.endsWith(".app") && fileInfo.isDir()) { QCFType url = CFURLCreateWithFileSystemPath(0, QCFString(fileInfo.absoluteFilePath()), kCFURLPOSIXPathStyle, true); { // CFBundle is not reentrant, since CFBundleCreate might return a reference // to a cached bundle object. Protect the bundle calls with a mutex lock. static QBasicMutex cfbundleMutex; QMutexLocker lock(&cfbundleMutex); QCFType bundle = CFBundleCreate(0, url); url = CFBundleCopyExecutableURL(bundle); } if (url) { QCFString str = CFURLCopyFileSystemPath(url, kCFURLPOSIXPathStyle); encodedProgramName += "/Contents/MacOS/" + QCFString::toQString(str).toUtf8(); } } #endif // Add the program name to the argument list. char *dupProgramName = ::strdup(encodedProgramName.constData()); argv[0] = dupProgramName; // Add every argument to the list for (int i = 0; i < arguments.count(); ++i) argv[i + 1] = ::strdup(QFile::encodeName(arguments.at(i)).constData()); // Duplicate the environment. int envc = 0; char **envp = 0; if (environment.d.constData()) envp = _q_dupEnvironment(environment.d.constData()->hash, &envc); // Encode the working directory if it's non-empty, otherwise just pass 0. const char *workingDirPtr = 0; QByteArray encodedWorkingDirectory; if (!workingDirectory.isEmpty()) { encodedWorkingDirectory = QFile::encodeName(workingDirectory); workingDirPtr = encodedWorkingDirectory.constData(); } // If the program does not specify a path, generate a list of possible // locations for the binary using the PATH environment variable. char **path = 0; int pathc = 0; if (!program.contains(QLatin1Char('/'))) { const QString pathEnv = QString::fromLocal8Bit(::getenv("PATH")); if (!pathEnv.isEmpty()) { QStringList pathEntries = pathEnv.split(QLatin1Char(':'), QString::SkipEmptyParts); if (!pathEntries.isEmpty()) { pathc = pathEntries.size(); path = new char *[pathc + 1]; path[pathc] = 0; for (int k = 0; k < pathEntries.size(); ++k) { QByteArray tmp = QFile::encodeName(pathEntries.at(k)); if (!tmp.endsWith('/')) tmp += '/'; tmp += encodedProgramName; path[k] = ::strdup(tmp.constData()); } } } } // Start the process manager, and fork off the child process. processManager()->lock(); #if defined(Q_OS_QNX) pid_t childPid = spawnChild(workingDirPtr, argv, envp); #else pid_t childPid = fork(); int lastForkErrno = errno; #endif if (childPid != 0) { // Clean up duplicated memory. free(dupProgramName); for (int i = 1; i <= arguments.count(); ++i) free(argv[i]); for (int i = 0; i < envc; ++i) free(envp[i]); for (int i = 0; i < pathc; ++i) free(path[i]); delete [] argv; delete [] envp; delete [] path; } // This is not a valid check under QNX, because the semantics are // different. While under other platforms where fork() may succeed and exec() can still fail, // causing the childPid to hold a valid value (and thus evaluating the // following if to false), and then signaling the error via // childStartedPipe, under QNX on the other hand, spawn() return value will be assigned // to childPid (which will be -1 in case of failure). This will force // QProcess to cleanup, instead of signaling the error via // childStartedPipe. Since it will invalidade the pipes, functions like // QProcess::waitForStarted() will fail, for childStartedPipe will be // '-1' and mess with the select() calls. #if !defined(Q_OS_QNX) if (childPid < 0) { // Cleanup, report error and return #if defined (QPROCESS_DEBUG) qDebug("fork failed: %s", qPrintable(qt_error_string(lastForkErrno))); #endif processManager()->unlock(); q->setProcessState(QProcess::NotRunning); processError = QProcess::FailedToStart; q->setErrorString(QProcess::tr("Resource error (fork failure): %1").arg(qt_error_string(lastForkErrno))); emit q->error(processError); cleanup(); return; } // Start the child. if (childPid == 0) { execChild(workingDirPtr, path, argv, envp); ::_exit(-1); } #endif // Register the child. In the mean time, we can get a SIGCHLD, so we need // to keep the lock held to avoid a race to catch the child. processManager()->add(childPid, q); pid = Q_PID(childPid); processManager()->unlock(); // parent // close the ends we don't use and make all pipes non-blocking ::fcntl(deathPipe[0], F_SETFL, ::fcntl(deathPipe[0], F_GETFL) | O_NONBLOCK); qt_safe_close(childStartedPipe[1]); childStartedPipe[1] = -1; if (stdinChannel.pipe[0] != -1) { qt_safe_close(stdinChannel.pipe[0]); stdinChannel.pipe[0] = -1; } if (stdinChannel.pipe[1] != -1) ::fcntl(stdinChannel.pipe[1], F_SETFL, ::fcntl(stdinChannel.pipe[1], F_GETFL) | O_NONBLOCK); if (stdoutChannel.pipe[1] != -1) { qt_safe_close(stdoutChannel.pipe[1]); stdoutChannel.pipe[1] = -1; } if (stdoutChannel.pipe[0] != -1) ::fcntl(stdoutChannel.pipe[0], F_SETFL, ::fcntl(stdoutChannel.pipe[0], F_GETFL) | O_NONBLOCK); if (stderrChannel.pipe[1] != -1) { qt_safe_close(stderrChannel.pipe[1]); stderrChannel.pipe[1] = -1; } if (stderrChannel.pipe[0] != -1) ::fcntl(stderrChannel.pipe[0], F_SETFL, ::fcntl(stderrChannel.pipe[0], F_GETFL) | O_NONBLOCK); } #if defined(Q_OS_QNX) static pid_t doSpawn(int fd_count, int fd_map[], char **argv, char **envp, const char *workingDir, bool spawn_detached) { // A multi threaded QNX Process can't fork so we call spawn() instead. struct inheritance inherit; memset(&inherit, 0, sizeof(inherit)); inherit.flags |= SPAWN_SETSID; inherit.flags |= SPAWN_CHECK_SCRIPT; if (spawn_detached) inherit.flags |= SPAWN_NOZOMBIE; inherit.flags |= SPAWN_SETSIGDEF; sigaddset(&inherit.sigdefault, SIGPIPE); // reset the signal that we ignored // enter the working directory const char *oldWorkingDir = 0; char buff[PATH_MAX + 1]; if (workingDir) { //we need to freeze everyone in order to avoid race conditions with //chdir(). if (ThreadCtl(_NTO_TCTL_THREADS_HOLD, 0) == -1) qWarning("ThreadCtl(): cannot hold threads: %s", qPrintable(qt_error_string(errno))); oldWorkingDir = QT_GETCWD(buff, PATH_MAX + 1); if (QT_CHDIR(workingDir) == -1) qWarning("ThreadCtl(): failed to chdir to %s", workingDir); } pid_t childPid; EINTR_LOOP(childPid, ::spawn(argv[0], fd_count, fd_map, &inherit, argv, envp)); if (childPid == -1) { inherit.flags |= SPAWN_SEARCH_PATH; EINTR_LOOP(childPid, ::spawn(argv[0], fd_count, fd_map, &inherit, argv, envp)); } if (oldWorkingDir) { if (QT_CHDIR(oldWorkingDir) == -1) qWarning("ThreadCtl(): failed to chdir to %s", oldWorkingDir); if (ThreadCtl(_NTO_TCTL_THREADS_CONT, 0) == -1) qFatal("ThreadCtl(): cannot resume threads: %s", qPrintable(qt_error_string(errno))); } return childPid; } pid_t QProcessPrivate::spawnChild(const char *workingDir, char **argv, char **envp) { // we need to manually fill in fd_map // to inherit the file descriptors from // the parent const int fd_count = sysconf(_SC_OPEN_MAX); QVarLengthArray fd_map(fd_count); for (int i = 3; i < fd_count; ++i) { // here we rely that fcntl returns -1 and // sets errno to EBADF const int flags = ::fcntl(i, F_GETFD); fd_map[i] = ((flags >= 0) && !(flags & FD_CLOEXEC)) ? i : SPAWN_FDCLOSED; } switch (processChannelMode) { case QProcess::ForwardedChannels: fd_map[0] = stdinChannel.pipe[0]; fd_map[1] = QT_FILENO(stdout); fd_map[2] = QT_FILENO(stderr); break; case QProcess::MergedChannels: fd_map[0] = stdinChannel.pipe[0]; fd_map[1] = stdoutChannel.pipe[1]; fd_map[2] = stdoutChannel.pipe[1]; break; case QProcess::SeparateChannels: fd_map[0] = stdinChannel.pipe[0]; fd_map[1] = stdoutChannel.pipe[1]; fd_map[2] = stderrChannel.pipe[1]; break; } pid_t childPid = doSpawn(fd_count, fd_map.data(), argv, envp, workingDir, false); if (childPid == -1) { QString error = qt_error_string(errno); qt_safe_write(childStartedPipe[1], error.data(), error.length() * sizeof(QChar)); qt_safe_close(childStartedPipe[1]); childStartedPipe[1] = -1; } return childPid; } #else void QProcessPrivate::execChild(const char *workingDir, char **path, char **argv, char **envp) { ::signal(SIGPIPE, SIG_DFL); // reset the signal that we ignored Q_Q(QProcess); // copy the stdin socket (without closing on exec) qt_safe_dup2(stdinChannel.pipe[0], fileno(stdin), 0); // copy the stdout and stderr if asked to if (processChannelMode != QProcess::ForwardedChannels) { qt_safe_dup2(stdoutChannel.pipe[1], fileno(stdout), 0); // merge stdout and stderr if asked to if (processChannelMode == QProcess::MergedChannels) { qt_safe_dup2(fileno(stdout), fileno(stderr), 0); } else { qt_safe_dup2(stderrChannel.pipe[1], fileno(stderr), 0); } } // make sure this fd is closed if execvp() succeeds qt_safe_close(childStartedPipe[0]); // enter the working directory if (workingDir) { if (QT_CHDIR(workingDir) == -1) qWarning("QProcessPrivate::execChild() failed to chdir to %s", workingDir); } // this is a virtual call, and it base behavior is to do nothing. q->setupChildProcess(); // execute the process if (!envp) { qt_safe_execvp(argv[0], argv); } else { if (path) { char **arg = path; while (*arg) { argv[0] = *arg; #if defined (QPROCESS_DEBUG) fprintf(stderr, "QProcessPrivate::execChild() searching / starting %s\n", argv[0]); #endif qt_safe_execve(argv[0], argv, envp); ++arg; } } else { #if defined (QPROCESS_DEBUG) fprintf(stderr, "QProcessPrivate::execChild() starting %s\n", argv[0]); #endif qt_safe_execve(argv[0], argv, envp); } } // notify failure QString error = qt_error_string(errno); #if defined (QPROCESS_DEBUG) fprintf(stderr, "QProcessPrivate::execChild() failed (%s), notifying parent process\n", qPrintable(error)); #endif qt_safe_write(childStartedPipe[1], error.data(), error.length() * sizeof(QChar)); qt_safe_close(childStartedPipe[1]); childStartedPipe[1] = -1; } #endif bool QProcessPrivate::processStarted() { ushort buf[errorBufferMax]; int i = qt_safe_read(childStartedPipe[0], &buf, sizeof buf); if (startupSocketNotifier) { startupSocketNotifier->setEnabled(false); startupSocketNotifier->deleteLater(); startupSocketNotifier = 0; } qt_safe_close(childStartedPipe[0]); childStartedPipe[0] = -1; #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::processStarted() == %s", i <= 0 ? "true" : "false"); #endif // did we read an error message? if (i > 0) q_func()->setErrorString(QString((const QChar *)buf, i / sizeof(QChar))); return i <= 0; } qint64 QProcessPrivate::bytesAvailableFromStdout() const { int nbytes = 0; qint64 available = 0; if (::ioctl(stdoutChannel.pipe[0], FIONREAD, (char *) &nbytes) >= 0) available = (qint64) nbytes; #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::bytesAvailableFromStdout() == %lld", available); #endif return available; } qint64 QProcessPrivate::bytesAvailableFromStderr() const { int nbytes = 0; qint64 available = 0; if (::ioctl(stderrChannel.pipe[0], FIONREAD, (char *) &nbytes) >= 0) available = (qint64) nbytes; #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::bytesAvailableFromStderr() == %lld", available); #endif return available; } qint64 QProcessPrivate::readFromStdout(char *data, qint64 maxlen) { qint64 bytesRead = qt_safe_read(stdoutChannel.pipe[0], data, maxlen); #if defined QPROCESS_DEBUG qDebug("QProcessPrivate::readFromStdout(%p \"%s\", %lld) == %lld", data, qt_prettyDebug(data, bytesRead, 16).constData(), maxlen, bytesRead); #endif return bytesRead; } qint64 QProcessPrivate::readFromStderr(char *data, qint64 maxlen) { qint64 bytesRead = qt_safe_read(stderrChannel.pipe[0], data, maxlen); #if defined QPROCESS_DEBUG qDebug("QProcessPrivate::readFromStderr(%p \"%s\", %lld) == %lld", data, qt_prettyDebug(data, bytesRead, 16).constData(), maxlen, bytesRead); #endif return bytesRead; } qint64 QProcessPrivate::writeToStdin(const char *data, qint64 maxlen) { qint64 written = qt_safe_write_nosignal(stdinChannel.pipe[1], data, maxlen); #if defined QPROCESS_DEBUG qDebug("QProcessPrivate::writeToStdin(%p \"%s\", %lld) == %lld", data, qt_prettyDebug(data, maxlen, 16).constData(), maxlen, written); if (written == -1) qDebug("QProcessPrivate::writeToStdin(), failed to write (%s)", qPrintable(qt_error_string(errno))); #endif // If the O_NONBLOCK flag is set and If some data can be written without blocking // the process, write() will transfer what it can and return the number of bytes written. // Otherwise, it will return -1 and set errno to EAGAIN if (written == -1 && errno == EAGAIN) written = 0; return written; } void QProcessPrivate::terminateProcess() { #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::killProcess()"); #endif if (pid) ::kill(pid_t(pid), SIGTERM); } void QProcessPrivate::killProcess() { #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::killProcess()"); #endif if (pid) ::kill(pid_t(pid), SIGKILL); } static int select_msecs(int nfds, fd_set *fdread, fd_set *fdwrite, int timeout) { if (timeout < 0) return qt_safe_select(nfds, fdread, fdwrite, 0, 0); struct timespec tv; tv.tv_sec = timeout / 1000; tv.tv_nsec = (timeout % 1000) * 1000 * 1000; return qt_safe_select(nfds, fdread, fdwrite, 0, &tv); } /* Returns the difference between msecs and elapsed. If msecs is -1, however, -1 is returned. */ static int qt_timeout_value(int msecs, int elapsed) { if (msecs == -1) return -1; int timeout = msecs - elapsed; return timeout < 0 ? 0 : timeout; } bool QProcessPrivate::waitForStarted(int msecs) { Q_Q(QProcess); #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::waitForStarted(%d) waiting for child to start (fd = %d)", msecs, childStartedPipe[0]); #endif fd_set fds; FD_ZERO(&fds); FD_SET(childStartedPipe[0], &fds); if (select_msecs(childStartedPipe[0] + 1, &fds, 0, msecs) == 0) { processError = QProcess::Timedout; q->setErrorString(QProcess::tr("Process operation timed out")); #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::waitForStarted(%d) == false (timed out)", msecs); #endif return false; } bool startedEmitted = _q_startupNotification(); #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::waitForStarted() == %s", startedEmitted ? "true" : "false"); #endif return startedEmitted; } bool QProcessPrivate::waitForReadyRead(int msecs) { Q_Q(QProcess); #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::waitForReadyRead(%d)", msecs); #endif QElapsedTimer stopWatch; stopWatch.start(); forever { fd_set fdread; fd_set fdwrite; FD_ZERO(&fdread); FD_ZERO(&fdwrite); int nfds = deathPipe[0]; FD_SET(deathPipe[0], &fdread); if (processState == QProcess::Starting) add_fd(nfds, childStartedPipe[0], &fdread); if (stdoutChannel.pipe[0] != -1) add_fd(nfds, stdoutChannel.pipe[0], &fdread); if (stderrChannel.pipe[0] != -1) add_fd(nfds, stderrChannel.pipe[0], &fdread); if (!writeBuffer.isEmpty() && stdinChannel.pipe[1] != -1) add_fd(nfds, stdinChannel.pipe[1], &fdwrite); int timeout = qt_timeout_value(msecs, stopWatch.elapsed()); int ret = select_msecs(nfds + 1, &fdread, &fdwrite, timeout); if (ret < 0) { break; } if (ret == 0) { processError = QProcess::Timedout; q->setErrorString(QProcess::tr("Process operation timed out")); return false; } if (childStartedPipe[0] != -1 && FD_ISSET(childStartedPipe[0], &fdread)) { if (!_q_startupNotification()) return false; } bool readyReadEmitted = false; if (stdoutChannel.pipe[0] != -1 && FD_ISSET(stdoutChannel.pipe[0], &fdread)) { bool canRead = _q_canReadStandardOutput(); if (processChannel == QProcess::StandardOutput && canRead) readyReadEmitted = true; } if (stderrChannel.pipe[0] != -1 && FD_ISSET(stderrChannel.pipe[0], &fdread)) { bool canRead = _q_canReadStandardError(); if (processChannel == QProcess::StandardError && canRead) readyReadEmitted = true; } if (readyReadEmitted) return true; if (stdinChannel.pipe[1] != -1 && FD_ISSET(stdinChannel.pipe[1], &fdwrite)) _q_canWrite(); if (deathPipe[0] == -1 || FD_ISSET(deathPipe[0], &fdread)) { if (_q_processDied()) return false; } } return false; } bool QProcessPrivate::waitForBytesWritten(int msecs) { Q_Q(QProcess); #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::waitForBytesWritten(%d)", msecs); #endif QElapsedTimer stopWatch; stopWatch.start(); while (!writeBuffer.isEmpty()) { fd_set fdread; fd_set fdwrite; FD_ZERO(&fdread); FD_ZERO(&fdwrite); int nfds = deathPipe[0]; FD_SET(deathPipe[0], &fdread); if (processState == QProcess::Starting) add_fd(nfds, childStartedPipe[0], &fdread); if (stdoutChannel.pipe[0] != -1) add_fd(nfds, stdoutChannel.pipe[0], &fdread); if (stderrChannel.pipe[0] != -1) add_fd(nfds, stderrChannel.pipe[0], &fdread); if (!writeBuffer.isEmpty() && stdinChannel.pipe[1] != -1) add_fd(nfds, stdinChannel.pipe[1], &fdwrite); int timeout = qt_timeout_value(msecs, stopWatch.elapsed()); int ret = select_msecs(nfds + 1, &fdread, &fdwrite, timeout); if (ret < 0) { break; } if (ret == 0) { processError = QProcess::Timedout; q->setErrorString(QProcess::tr("Process operation timed out")); return false; } if (childStartedPipe[0] != -1 && FD_ISSET(childStartedPipe[0], &fdread)) { if (!_q_startupNotification()) return false; } if (stdinChannel.pipe[1] != -1 && FD_ISSET(stdinChannel.pipe[1], &fdwrite)) return _q_canWrite(); if (stdoutChannel.pipe[0] != -1 && FD_ISSET(stdoutChannel.pipe[0], &fdread)) _q_canReadStandardOutput(); if (stderrChannel.pipe[0] != -1 && FD_ISSET(stderrChannel.pipe[0], &fdread)) _q_canReadStandardError(); if (deathPipe[0] == -1 || FD_ISSET(deathPipe[0], &fdread)) { if (_q_processDied()) return false; } } return false; } bool QProcessPrivate::waitForFinished(int msecs) { Q_Q(QProcess); #if defined (QPROCESS_DEBUG) qDebug("QProcessPrivate::waitForFinished(%d)", msecs); #endif QElapsedTimer stopWatch; stopWatch.start(); forever { fd_set fdread; fd_set fdwrite; int nfds = -1; FD_ZERO(&fdread); FD_ZERO(&fdwrite); if (processState == QProcess::Starting) add_fd(nfds, childStartedPipe[0], &fdread); if (stdoutChannel.pipe[0] != -1) add_fd(nfds, stdoutChannel.pipe[0], &fdread); if (stderrChannel.pipe[0] != -1) add_fd(nfds, stderrChannel.pipe[0], &fdread); if (processState == QProcess::Running) add_fd(nfds, deathPipe[0], &fdread); if (!writeBuffer.isEmpty() && stdinChannel.pipe[1] != -1) add_fd(nfds, stdinChannel.pipe[1], &fdwrite); int timeout = qt_timeout_value(msecs, stopWatch.elapsed()); int ret = select_msecs(nfds + 1, &fdread, &fdwrite, timeout); if (ret < 0) { break; } if (ret == 0) { processError = QProcess::Timedout; q->setErrorString(QProcess::tr("Process operation timed out")); return false; } if (childStartedPipe[0] != -1 && FD_ISSET(childStartedPipe[0], &fdread)) { if (!_q_startupNotification()) return false; } if (stdinChannel.pipe[1] != -1 && FD_ISSET(stdinChannel.pipe[1], &fdwrite)) _q_canWrite(); if (stdoutChannel.pipe[0] != -1 && FD_ISSET(stdoutChannel.pipe[0], &fdread)) _q_canReadStandardOutput(); if (stderrChannel.pipe[0] != -1 && FD_ISSET(stderrChannel.pipe[0], &fdread)) _q_canReadStandardError(); if (deathPipe[0] == -1 || FD_ISSET(deathPipe[0], &fdread)) { if (_q_processDied()) return true; } } return false; } bool QProcessPrivate::waitForWrite(int msecs) { fd_set fdwrite; FD_ZERO(&fdwrite); FD_SET(stdinChannel.pipe[1], &fdwrite); return select_msecs(stdinChannel.pipe[1] + 1, 0, &fdwrite, msecs < 0 ? 0 : msecs) == 1; } void QProcessPrivate::findExitCode() { Q_Q(QProcess); processManager()->remove(q); } bool QProcessPrivate::waitForDeadChild() { Q_Q(QProcess); // read a byte from the death pipe char c; qt_safe_read(deathPipe[0], &c, 1); // check if our process is dead int exitStatus; if (qt_safe_waitpid(pid_t(pid), &exitStatus, WNOHANG) > 0) { processManager()->remove(q); crashed = !WIFEXITED(exitStatus); exitCode = WEXITSTATUS(exitStatus); #if defined QPROCESS_DEBUG qDebug() << "QProcessPrivate::waitForDeadChild() dead with exitCode" << exitCode << ", crashed?" << crashed; #endif return true; } #if defined QPROCESS_DEBUG qDebug() << "QProcessPrivate::waitForDeadChild() not dead!"; #endif return false; } void QProcessPrivate::_q_notified() { } #if defined(Q_OS_QNX) bool QProcessPrivate::startDetached(const QString &program, const QStringList &arguments, const QString &workingDirectory, qint64 *pid) { const int fd_count = 3; int fd_map[fd_count] = { QT_FILENO(stdin), QT_FILENO(stdout), QT_FILENO(stderr) }; QList enc_args; enc_args.append(QFile::encodeName(program)); for (int i = 0; i < arguments.size(); ++i) enc_args.append(arguments.at(i).toLocal8Bit()); const int argc = enc_args.size(); QScopedArrayPointer raw_argv(new char*[argc + 1]); for (int i = 0; i < argc; ++i) raw_argv[i] = const_cast(enc_args.at(i).data()); raw_argv[argc] = 0; char **envp = 0; // inherit environment // Encode the working directory if it's non-empty, otherwise just pass 0. const char *workingDirPtr = 0; QByteArray encodedWorkingDirectory; if (!workingDirectory.isEmpty()) { encodedWorkingDirectory = QFile::encodeName(workingDirectory); workingDirPtr = encodedWorkingDirectory.constData(); } pid_t childPid = doSpawn(fd_count, fd_map, raw_argv.data(), envp, workingDirPtr, true); if (pid && childPid != -1) *pid = childPid; return childPid != -1; } #else bool QProcessPrivate::startDetached(const QString &program, const QStringList &arguments, const QString &workingDirectory, qint64 *pid) { processManager()->start(); QByteArray encodedWorkingDirectory = QFile::encodeName(workingDirectory); // To catch the startup of the child int startedPipe[2]; if (qt_safe_pipe(startedPipe) != 0) return false; // To communicate the pid of the child int pidPipe[2]; if (qt_safe_pipe(pidPipe) != 0) { qt_safe_close(startedPipe[0]); qt_safe_close(startedPipe[1]); return false; } pid_t childPid = fork(); if (childPid == 0) { struct sigaction noaction; memset(&noaction, 0, sizeof(noaction)); noaction.sa_handler = SIG_IGN; ::sigaction(SIGPIPE, &noaction, 0); ::setsid(); qt_safe_close(startedPipe[0]); qt_safe_close(pidPipe[0]); pid_t doubleForkPid = fork(); if (doubleForkPid == 0) { qt_safe_close(pidPipe[1]); if (!encodedWorkingDirectory.isEmpty()) { if (QT_CHDIR(encodedWorkingDirectory.constData()) == -1) qWarning("QProcessPrivate::startDetached: failed to chdir to %s", encodedWorkingDirectory.constData()); } char **argv = new char *[arguments.size() + 2]; for (int i = 0; i < arguments.size(); ++i) argv[i + 1] = ::strdup(QFile::encodeName(arguments.at(i)).constData()); argv[arguments.size() + 1] = 0; if (!program.contains(QLatin1Char('/'))) { const QString path = QString::fromLocal8Bit(::getenv("PATH")); if (!path.isEmpty()) { QStringList pathEntries = path.split(QLatin1Char(':')); for (int k = 0; k < pathEntries.size(); ++k) { QByteArray tmp = QFile::encodeName(pathEntries.at(k)); if (!tmp.endsWith('/')) tmp += '/'; tmp += QFile::encodeName(program); argv[0] = tmp.data(); qt_safe_execv(argv[0], argv); } } } else { QByteArray tmp = QFile::encodeName(program); argv[0] = tmp.data(); qt_safe_execv(argv[0], argv); } struct sigaction noaction; memset(&noaction, 0, sizeof(noaction)); noaction.sa_handler = SIG_IGN; ::sigaction(SIGPIPE, &noaction, 0); // '\1' means execv failed char c = '\1'; qt_safe_write(startedPipe[1], &c, 1); qt_safe_close(startedPipe[1]); ::_exit(1); } else if (doubleForkPid == -1) { struct sigaction noaction; memset(&noaction, 0, sizeof(noaction)); noaction.sa_handler = SIG_IGN; ::sigaction(SIGPIPE, &noaction, 0); // '\2' means internal error char c = '\2'; qt_safe_write(startedPipe[1], &c, 1); } qt_safe_close(startedPipe[1]); qt_safe_write(pidPipe[1], (const char *)&doubleForkPid, sizeof(pid_t)); if (QT_CHDIR("/") == -1) qWarning("QProcessPrivate::startDetached: failed to chdir to /"); ::_exit(1); } qt_safe_close(startedPipe[1]); qt_safe_close(pidPipe[1]); if (childPid == -1) { qt_safe_close(startedPipe[0]); qt_safe_close(pidPipe[0]); return false; } char reply = '\0'; int startResult = qt_safe_read(startedPipe[0], &reply, 1); int result; qt_safe_close(startedPipe[0]); qt_safe_waitpid(childPid, &result, 0); bool success = (startResult != -1 && reply == '\0'); if (success && pid) { pid_t actualPid = 0; if (qt_safe_read(pidPipe[0], (char *)&actualPid, sizeof(pid_t)) == sizeof(pid_t)) { *pid = actualPid; } else { *pid = 0; } } qt_safe_close(pidPipe[0]); return success; } #endif void QProcessPrivate::initializeProcessManager() { (void) processManager(); } QT_END_NAMESPACE #include "qprocess_unix.moc" #endif // QT_NO_PROCESS