/**************************************************************************** ** ** Implementation of TQProcess class for Unix ** ** Created : 20000905 ** ** Copyright (C) 1992-2008 Trolltech ASA. All rights reserved. ** ** This file is part of the kernel module of the TQt GUI Toolkit. ** ** This file may be used under the terms of the GNU General ** Public License versions 2.0 or 3.0 as published by the Free ** Software Foundation and appearing in the files LICENSE.GPL2 ** and LICENSE.GPL3 included in the packaging of this file. ** Alternatively you may (at your option) use any later version ** of the GNU General Public License if such license has been ** publicly approved by Trolltech ASA (or its successors, if any) ** and the KDE Free TQt Foundation. ** ** Please review the following information to ensure GNU General ** Public Licensing requirements will be met: ** http://trolltech.com/products/qt/licenses/licensing/opensource/. ** If you are unsure which license is appropriate for your use, please ** review the following information: ** http://trolltech.com/products/qt/licenses/licensing/licensingoverview ** or contact the sales department at sales@trolltech.com. ** ** This file may be used under the terms of the Q Public License as ** defined by Trolltech ASA and appearing in the file LICENSE.TQPL ** included in the packaging of this file. Licensees holding valid TQt ** Commercial licenses may use this file in accordance with the TQt ** Commercial License Agreement provided with the Software. ** ** This file is provided "AS IS" with NO WARRANTY OF ANY KIND, ** INCLUDING THE WARRANTIES OF DESIGN, MERCHANTABILITY AND FITNESS FOR ** A PARTICULAR PURPOSE. Trolltech reserves all rights not granted ** herein. ** **********************************************************************/ #include "qplatformdefs.h" // Solaris redefines connect -> __xnet_connect with _XOPEN_SOURCE_EXTENDED. #if defined(connect) #undef connect #endif #include "tqprocess.h" #ifndef TQT_NO_PROCESS #include "tqapplication.h" #include "tqptrqueue.h" #include "tqptrlist.h" #include "tqsocketnotifier.h" #include "tqtimer.h" #include "tqcleanuphandler.h" #include "tqregexp.h" #include "private/tqinternal_p.h" #include #include #include #ifdef __MIPSEL__ # ifndef SOCK_DGRAM # define SOCK_DGRAM 1 # endif # ifndef SOCK_STREAM # define SOCK_STREAM 2 # endif #endif //#define QT_QPROCESS_DEBUG #ifdef Q_C_CALLBACKS extern "C" { #endif // Q_C_CALLBACKS QT_SIGNAL_RETTYPE qt_C_sigchldHnd(QT_SIGNAL_ARGS); #ifdef Q_C_CALLBACKS } #endif // Q_C_CALLBACKS class TQProc; class TQProcessManager; class TQProcessPrivate { public: TQProcessPrivate(); ~TQProcessPrivate(); void closeOpenSocketsForChild(); void newProc( pid_t pid, TQProcess *process ); TQMembuf bufStdout; TQMembuf bufStderr; TQPtrQueue stdinBuf; TQSocketNotifier *notifierStdin; TQSocketNotifier *notifierStdout; TQSocketNotifier *notifierStderr; ssize_t stdinBufRead; TQProc *proc; bool exitValuesCalculated; bool socketReadCalled; static TQProcessManager *procManager; }; /*********************************************************************** * * TQProc * **********************************************************************/ /* The class TQProcess does not necessarily map exactly to the running child processes: if the process is finished, the TQProcess class may still be there; furthermore a user can use TQProcess to start more than one process. The helper-class TQProc has the semantics that one instance of this class maps directly to a running child process. */ class TQProc { public: TQProc( pid_t p, TQProcess *proc=0 ) : pid(p), process(proc) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProc: Constructor for pid %d and TQProcess %p", pid, process ); #endif socketStdin = 0; socketStdout = 0; socketStderr = 0; } ~TQProc() { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProc: Destructor for pid %d and TQProcess %p", pid, process ); #endif if ( process ) { if ( process->d->notifierStdin ) process->d->notifierStdin->setEnabled( FALSE ); if ( process->d->notifierStdout ) process->d->notifierStdout->setEnabled( FALSE ); if ( process->d->notifierStderr ) process->d->notifierStderr->setEnabled( FALSE ); process->d->proc = 0; } if( socketStdin ) ::close( socketStdin ); if( socketStdout ) ::close( socketStdout ); if( socketStderr ) ::close( socketStderr ); } pid_t pid; int socketStdin; int socketStdout; int socketStderr; TQProcess *process; }; /*********************************************************************** * * TQProcessManager * **********************************************************************/ class TQProcessManager : public TQObject { TQ_OBJECT public: TQProcessManager(); ~TQProcessManager(); void append( TQProc *p ); void remove( TQProc *p ); void cleanup(); public slots: void removeMe(); void sigchldHnd( int ); public: struct sigaction oldactChld; struct sigaction oldactPipe; TQPtrList *procList; int sigchldFd[2]; private: TQSocketNotifier *sn; }; static void tqprocess_cleanup() { delete TQProcessPrivate::procManager; TQProcessPrivate::procManager = 0; } #ifdef Q_OS_QNX6 #define BAILOUT close(tmpSocket);close(socketFD[1]);return -1; int qnx6SocketPairReplacement (int socketFD[2]) { int tmpSocket; tmpSocket = socket (AF_INET, SOCK_STREAM, 0); if (tmpSocket == -1) return -1; socketFD[1] = socket(AF_INET, SOCK_STREAM, 0); if (socketFD[1] == -1) { BAILOUT }; sockaddr_in ipAddr; memset(&ipAddr, 0, sizeof(ipAddr)); ipAddr.sin_family = AF_INET; ipAddr.sin_addr.s_addr = INADDR_ANY; int socketOptions = 1; setsockopt(tmpSocket, SOL_SOCKET, SO_REUSEADDR, &socketOptions, sizeof(int)); bool found = FALSE; for (int socketIP = 2000; (socketIP < 2500) && !(found); socketIP++) { ipAddr.sin_port = htons(socketIP); if (bind(tmpSocket, (struct sockaddr *)&ipAddr, sizeof(ipAddr))) found = TRUE; } if (listen(tmpSocket, 5)) { BAILOUT }; // Select non-blocking mode int originalFlags = fcntl(socketFD[1], F_GETFL, 0); fcntl(socketFD[1], F_SETFL, originalFlags | O_NONBLOCK); // Request connection if (connect(socketFD[1], (struct sockaddr*)&ipAddr, sizeof(ipAddr))) if (errno != EINPROGRESS) { BAILOUT }; // Accept connection socketFD[0] = accept(tmpSocket, (struct sockaddr *)NULL, (size_t *)NULL); if(socketFD[0] == -1) { BAILOUT }; // We're done close(tmpSocket); // Restore original flags , ie return to blocking fcntl(socketFD[1], F_SETFL, originalFlags); return 0; } #undef BAILOUT #endif TQProcessManager::TQProcessManager() : sn(0) { procList = new TQPtrList; procList->setAutoDelete( TRUE ); // The SIGCHLD handler writes to a socket to tell the manager that // something happened. This is done to get the processing in sync with the // event reporting. #ifndef Q_OS_QNX6 if ( ::socketpair( AF_UNIX, SOCK_STREAM, 0, sigchldFd ) ) { #else if ( qnx6SocketPairReplacement (sigchldFd) ) { #endif sigchldFd[0] = 0; sigchldFd[1] = 0; } else { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager: install socket notifier (%d)", sigchldFd[1] ); #endif sn = new TQSocketNotifier( sigchldFd[1], TQSocketNotifier::Read, this ); connect( sn, TQ_SIGNAL(activated(int)), this, TQ_SLOT(sigchldHnd(int)) ); sn->setEnabled( TRUE ); } // install a SIGCHLD handler and ignore SIGPIPE struct sigaction act; #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager: install a SIGCHLD handler" ); #endif act.sa_handler = qt_C_sigchldHnd; sigemptyset( &(act.sa_mask) ); sigaddset( &(act.sa_mask), SIGCHLD ); act.sa_flags = SA_NOCLDSTOP; #if defined(SA_RESTART) act.sa_flags |= SA_RESTART; #endif if ( sigaction( SIGCHLD, &act, &oldactChld ) != 0 ) tqWarning( "Error installing SIGCHLD handler" ); #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager: install a SIGPIPE handler (SIG_IGN)" ); #endif act.sa_handler = QT_SIGNAL_IGNORE; sigemptyset( &(act.sa_mask) ); sigaddset( &(act.sa_mask), SIGPIPE ); act.sa_flags = 0; if ( sigaction( SIGPIPE, &act, &oldactPipe ) != 0 ) tqWarning( "Error installing SIGPIPE handler" ); } TQProcessManager::~TQProcessManager() { delete procList; if ( sigchldFd[0] != 0 ) ::close( sigchldFd[0] ); if ( sigchldFd[1] != 0 ) ::close( sigchldFd[1] ); // restore SIGCHLD handler #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager: restore old sigchild handler" ); #endif if ( sigaction( SIGCHLD, &oldactChld, 0 ) != 0 ) tqWarning( "Error restoring SIGCHLD handler" ); #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager: restore old sigpipe handler" ); #endif if ( sigaction( SIGPIPE, &oldactPipe, 0 ) != 0 ) tqWarning( "Error restoring SIGPIPE handler" ); } void TQProcessManager::append( TQProc *p ) { procList->append( p ); #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager: append process (procList.count(): %d)", procList->count() ); #endif } void TQProcessManager::remove( TQProc *p ) { procList->remove( p ); #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager: remove process (procList.count(): %d)", procList->count() ); #endif cleanup(); } void TQProcessManager::cleanup() { if ( procList->count() == 0 ) { TQTimer::singleShot( 0, this, TQ_SLOT(removeMe()) ); } } void TQProcessManager::removeMe() { if ( procList->count() == 0 ) { tqRemovePostRoutine(tqprocess_cleanup); TQProcessPrivate::procManager = 0; delete this; } } void TQProcessManager::sigchldHnd( int fd ) { // Disable the socket notifier to make sure that this function is not // called recursively -- this can happen, if you enter the event loop in // the slot connected to the processExited() signal (e.g. by showing a // modal dialog) and there are more than one process which exited in the // meantime. if ( sn ) { if ( !sn->isEnabled() ) return; sn->setEnabled( FALSE ); } char tmp; if (::read( fd, &tmp, sizeof(tmp) ) < 0) { tqWarning( "Could not read from file descriptor" ); } #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager::sigchldHnd()" ); #endif TQProc *proc; TQProcess *process; bool removeProc; proc = procList->first(); while ( proc != 0 ) { removeProc = FALSE; process = proc->process; if ( process != 0 ) { if ( !process->isRunning() ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager::sigchldHnd() (PID: %d): process exited (TQProcess available)", proc->pid ); #endif /* Apparently, there is not consistency among different operating systems on how to use FIONREAD. FreeBSD, Linux and Solaris all expect the 3rd argument to ioctl() to be an int, which is normally 32-bit even on 64-bit machines. IRIX, on the other hand, expects a size_t, which is 64-bit on 64-bit machines. So, the solution is to use size_t initialized to zero to make sure all bits are set to zero, preventing underflow with the FreeBSD/Linux/Solaris ioctls. */ size_t nbytes = 0; // read pending data if ( proc->socketStdout && ::ioctl(proc->socketStdout, FIONREAD, (char*)&nbytes)==0 && nbytes>0 ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager::sigchldHnd() (PID: %d): reading %d bytes of pending data on stdout", proc->pid, nbytes ); #endif process->socketRead( proc->socketStdout ); } nbytes = 0; if ( proc->socketStderr && ::ioctl(proc->socketStderr, FIONREAD, (char*)&nbytes)==0 && nbytes>0 ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager::sigchldHnd() (PID: %d): reading %d bytes of pending data on stderr", proc->pid, nbytes ); #endif process->socketRead( proc->socketStderr ); } // close filedescriptors if open, and disable the // socket notifiers if ( proc->socketStdout ) { ::close( proc->socketStdout ); proc->socketStdout = 0; if (process->d->notifierStdout) process->d->notifierStdout->setEnabled(FALSE); } if ( proc->socketStderr ) { ::close( proc->socketStderr ); proc->socketStderr = 0; if (process->d->notifierStderr) process->d->notifierStderr->setEnabled(FALSE); } if ( process->notifyOnExit ) emit process->processExited(); removeProc = TRUE; } } else { int status; if ( ::waitpid( proc->pid, &status, WNOHANG ) == proc->pid ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessManager::sigchldHnd() (PID: %d): process exited (TQProcess not available)", proc->pid ); #endif removeProc = TRUE; } } if ( removeProc ) { TQProc *oldproc = proc; proc = procList->next(); remove( oldproc ); } else { proc = procList->next(); } } if ( sn ) sn->setEnabled( TRUE ); } #include "tqprocess_unix.moc" /*********************************************************************** * * TQProcessPrivate * **********************************************************************/ TQProcessManager *TQProcessPrivate::procManager = 0; TQProcessPrivate::TQProcessPrivate() { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessPrivate: Constructor" ); #endif stdinBufRead = 0; notifierStdin = 0; notifierStdout = 0; notifierStderr = 0; exitValuesCalculated = FALSE; socketReadCalled = FALSE; proc = 0; } TQProcessPrivate::~TQProcessPrivate() { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcessPrivate: Destructor" ); #endif if ( proc != 0 ) { if ( proc->socketStdin != 0 ) { ::close( proc->socketStdin ); proc->socketStdin = 0; } proc->process = 0; } while ( !stdinBuf.isEmpty() ) { delete stdinBuf.dequeue(); } delete notifierStdin; delete notifierStdout; delete notifierStderr; } /* Closes all open sockets in the child process that are not needed by the child process. Otherwise one child may have an open socket on standard input, etc. of another child. */ void TQProcessPrivate::closeOpenSocketsForChild() { if ( procManager != 0 ) { if ( procManager->sigchldFd[0] != 0 ) ::close( procManager->sigchldFd[0] ); if ( procManager->sigchldFd[1] != 0 ) ::close( procManager->sigchldFd[1] ); // close also the sockets from other TQProcess instances for ( TQProc *p=procManager->procList->first(); p!=0; p=procManager->procList->next() ) { ::close( p->socketStdin ); ::close( p->socketStdout ); ::close( p->socketStderr ); } } } void TQProcessPrivate::newProc( pid_t pid, TQProcess *process ) { proc = new TQProc( pid, process ); if ( procManager == 0 ) { procManager = new TQProcessManager; tqAddPostRoutine(tqprocess_cleanup); } // the TQProcessManager takes care of deleting the TQProc instances procManager->append( proc ); } /*********************************************************************** * * sigchld handler callback * **********************************************************************/ QT_SIGNAL_RETTYPE qt_C_sigchldHnd( QT_SIGNAL_ARGS ) { if ( TQProcessPrivate::procManager == 0 ) return; if ( TQProcessPrivate::procManager->sigchldFd[0] == 0 ) return; char a = 1; if (::write( TQProcessPrivate::procManager->sigchldFd[0], &a, sizeof(a) ) < 0) { tqWarning( "Could not write to file descriptor" ); } } /*********************************************************************** * * TQProcess * **********************************************************************/ /* This private class does basic initialization. */ void TQProcess::init() { d = new TQProcessPrivate(); exitStat = 0; exitNormal = FALSE; } /* This private class resets the process variables, etc. so that it can be used for another process to start. */ void TQProcess::reset() { delete d; d = new TQProcessPrivate(); exitStat = 0; exitNormal = FALSE; d->bufStdout.clear(); d->bufStderr.clear(); } TQMembuf* TQProcess::membufStdout() { if ( d->proc && d->proc->socketStdout ) { /* Apparently, there is not consistency among different operating systems on how to use FIONREAD. FreeBSD, Linux and Solaris all expect the 3rd argument to ioctl() to be an int, which is normally 32-bit even on 64-bit machines. IRIX, on the other hand, expects a size_t, which is 64-bit on 64-bit machines. So, the solution is to use size_t initialized to zero to make sure all bits are set to zero, preventing underflow with the FreeBSD/Linux/Solaris ioctls. */ size_t nbytes = 0; if ( ::ioctl(d->proc->socketStdout, FIONREAD, (char*)&nbytes)==0 && nbytes>0 ) socketRead( d->proc->socketStdout ); } return &d->bufStdout; } TQMembuf* TQProcess::membufStderr() { if ( d->proc && d->proc->socketStderr ) { /* Apparently, there is not consistency among different operating systems on how to use FIONREAD. FreeBSD, Linux and Solaris all expect the 3rd argument to ioctl() to be an int, which is normally 32-bit even on 64-bit machines. IRIX, on the other hand, expects a size_t, which is 64-bit on 64-bit machines. So, the solution is to use size_t initialized to zero to make sure all bits are set to zero, preventing underflow with the FreeBSD/Linux/Solaris ioctls. */ size_t nbytes = 0; if ( ::ioctl(d->proc->socketStderr, FIONREAD, (char*)&nbytes)==0 && nbytes>0 ) socketRead( d->proc->socketStderr ); } return &d->bufStderr; } /*! Destroys the instance. If the process is running, it is not terminated! The standard input, standard output and standard error of the process are closed. You can connect the destroyed() signal to the kill() slot, if you want the process to be terminated automatically when the instance is destroyed. \sa tryTerminate() kill() */ TQProcess::~TQProcess() { delete d; } /*! Tries to run a process for the command and arguments that were specified with setArguments(), addArgument() or that were specified in the constructor. The command is searched for in the path for executable programs; you can also use an absolute path in the command itself. If \a env is null, then the process is started with the same environment as the starting process. If \a env is non-null, then the values in the stringlist are interpreted as environment setttings of the form \c {key=value} and the process is started in these environment settings. For convenience, there is a small exception to this rule: under Unix, if \a env does not contain any settings for the environment variable \c LD_LIBRARY_PATH, then this variable is inherited from the starting process; under Windows the same applies for the environment variable \c PATH. Returns TRUE if the process could be started; otherwise returns FALSE. You can write data to the process's standard input with writeToStdin(). You can close standard input with closeStdin() and you can terminate the process with tryTerminate(), or with kill(). You can call this function even if you've used this instance to create a another process which is still running. In such cases, TQProcess closes the old process's standard input and deletes pending data, i.e., you lose all control over the old process, but the old process is not terminated. This applies also if the process could not be started. (On operating systems that have zombie processes, TQt will also wait() on the old process.) \sa launch() closeStdin() */ bool TQProcess::start( TQStringList *env ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::start()" ); #endif reset(); int sStdin[2]; int sStdout[2]; int sStderr[2]; // open sockets for piping #ifndef Q_OS_QNX6 if ( (comms & Stdin) && ::socketpair( AF_UNIX, SOCK_STREAM, 0, sStdin ) == -1 ) { #else if ( (comms & Stdin) && qnx6SocketPairReplacement(sStdin) == -1 ) { #endif return FALSE; } #ifndef Q_OS_QNX6 if ( (comms & Stderr) && ::socketpair( AF_UNIX, SOCK_STREAM, 0, sStderr ) == -1 ) { #else if ( (comms & Stderr) && qnx6SocketPairReplacement(sStderr) == -1 ) { #endif if ( comms & Stdin ) { ::close( sStdin[0] ); ::close( sStdin[1] ); } return FALSE; } #ifndef Q_OS_QNX6 if ( (comms & Stdout) && ::socketpair( AF_UNIX, SOCK_STREAM, 0, sStdout ) == -1 ) { #else if ( (comms & Stdout) && qnx6SocketPairReplacement(sStdout) == -1 ) { #endif if ( comms & Stdin ) { ::close( sStdin[0] ); ::close( sStdin[1] ); } if ( comms & Stderr ) { ::close( sStderr[0] ); ::close( sStderr[1] ); } return FALSE; } // the following pipe is only used to determine if the process could be // started int fd[2]; if ( pipe( fd ) < 0 ) { // non critical error, go on fd[0] = 0; fd[1] = 0; } // construct the arguments for exec TQCString *arglistQ = new TQCString[ _arguments.count() + 1 ]; const char** arglist = new const char*[ _arguments.count() + 1 ]; int i = 0; for ( TQStringList::Iterator it = _arguments.begin(); it != _arguments.end(); ++it ) { arglistQ[i] = (*it).local8Bit(); arglist[i] = arglistQ[i]; #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::start(): arg %d = %s", i, arglist[i] ); #endif i++; } #ifdef Q_OS_MACX if(i) { TQCString arg_bundle = arglistQ[0]; TQFileInfo fi(arg_bundle); if(fi.exists() && fi.isDir() && arg_bundle.right(4) == ".app") { TQCString exe = arg_bundle; int lslash = exe.findRev('/'); if(lslash != -1) exe = exe.mid(lslash+1); exe = TQCString(arg_bundle + "/Contents/MacOS/" + exe); exe = exe.left(exe.length() - 4); //chop off the .app if(TQFile::exists(exe)) { arglistQ[0] = exe; arglist[0] = arglistQ[0]; } } } #endif arglist[i] = 0; // Must make sure signal handlers are installed before exec'ing // in case the process exits quickly. if ( d->procManager == 0 ) { d->procManager = new TQProcessManager; tqAddPostRoutine(tqprocess_cleanup); } // fork and exec TQApplication::flushX(); pid_t pid = fork(); if ( pid == 0 ) { // child d->closeOpenSocketsForChild(); if ( comms & Stdin ) { ::close( sStdin[1] ); ::dup2( sStdin[0], STDIN_FILENO ); } if ( comms & Stdout ) { ::close( sStdout[0] ); ::dup2( sStdout[1], STDOUT_FILENO ); } if ( comms & Stderr ) { ::close( sStderr[0] ); ::dup2( sStderr[1], STDERR_FILENO ); } if ( comms & DupStderr ) { ::dup2( STDOUT_FILENO, STDERR_FILENO ); } #ifndef TQT_NO_DIR if (::chdir( workingDir.absPath().latin1() ) < 0) { tqWarning( "Could not chdir" ); } #endif if ( fd[0] ) ::close( fd[0] ); if ( fd[1] ) ::fcntl( fd[1], F_SETFD, FD_CLOEXEC ); // close on exec shows sucess if ( env == 0 ) { // inherit environment and start process #ifndef Q_OS_QNX4 ::execvp( arglist[0], (char*const*)arglist ); // ### cast not nice #else ::execvp( arglist[0], (char const*const*)arglist ); // ### cast not nice #endif } else { // start process with environment settins as specified in env // construct the environment for exec int numEntries = env->count(); #if defined(Q_OS_MACX) TQString ld_library_path("DYLD_LIBRARY_PATH"); #else TQString ld_library_path("LD_LIBRARY_PATH"); #endif bool setLibraryPath = env->grep( TQRegExp( "^" + ld_library_path + "=" ) ).empty() && getenv( ld_library_path ) != 0; if ( setLibraryPath ) numEntries++; TQCString *envlistQ = new TQCString[ numEntries + 1 ]; const char** envlist = new const char*[ numEntries + 1 ]; int i = 0; if ( setLibraryPath ) { envlistQ[i] = TQString( ld_library_path + "=%1" ).arg( getenv( ld_library_path ) ).local8Bit(); envlist[i] = envlistQ[i]; i++; } for ( TQStringList::Iterator it = env->begin(); it != env->end(); ++it ) { envlistQ[i] = (*it).local8Bit(); envlist[i] = envlistQ[i]; i++; } envlist[i] = 0; // look for the executable in the search path if ( _arguments.count()>0 && getenv("PATH")!=0 ) { TQString command = _arguments[0]; if ( !command.contains( '/' ) ) { TQStringList pathList = TQStringList::split( ':', getenv( "PATH" ) ); for (TQStringList::Iterator it = pathList.begin(); it != pathList.end(); ++it ) { TQString dir = *it; #if defined(Q_OS_MACX) //look in a bundle if(!TQFile::exists(dir + "/" + command) && TQFile::exists(dir + "/" + command + ".app")) dir += "/" + command + ".app/Contents/MacOS"; #endif #ifndef TQT_NO_DIR TQFileInfo fileInfo( dir, command ); #else TQFileInfo fileInfo( dir + "/" + command ); #endif if ( fileInfo.isExecutable() ) { #if defined(Q_OS_MACX) arglistQ[0] = fileInfo.absFilePath().local8Bit(); #else arglistQ[0] = fileInfo.filePath().local8Bit(); #endif arglist[0] = arglistQ[0]; break; } } } } #ifndef Q_OS_QNX4 ::execve( arglist[0], (char*const*)arglist, (char*const*)envlist ); // ### casts not nice #else ::execve( arglist[0], (char const*const*)arglist,(char const*const*)envlist ); // ### casts not nice #endif } if ( fd[1] ) { char buf = 0; if (::write( fd[1], &buf, 1 ) < 0) { tqWarning( "Could not write to file descriptor" ); } ::close( fd[1] ); } ::_exit( -1 ); } else if ( pid == -1 ) { // error forking goto error; } // test if exec was successful if ( fd[1] ) ::close( fd[1] ); if ( fd[0] ) { char buf; for ( ;; ) { int n = ::read( fd[0], &buf, 1 ); if ( n==1 ) { // socket was not closed => error if ( ::waitpid( pid, 0, WNOHANG ) != pid ) { // The wait did not succeed yet, so try again when we get // the sigchild (to avoid zombies). d->newProc( pid, 0 ); } d->proc = 0; goto error; } else if ( n==-1 ) { if ( errno==EAGAIN || errno==EINTR ) // try it again continue; } break; } ::close( fd[0] ); } d->newProc( pid, this ); if ( comms & Stdin ) { ::close( sStdin[0] ); d->proc->socketStdin = sStdin[1]; // Select non-blocking mode int originalFlags = fcntl(d->proc->socketStdin, F_GETFL, 0); fcntl(d->proc->socketStdin, F_SETFL, originalFlags | O_NONBLOCK); d->notifierStdin = new TQSocketNotifier( sStdin[1], TQSocketNotifier::Write ); connect( d->notifierStdin, TQ_SIGNAL(activated(int)), this, TQ_SLOT(socketWrite(int)) ); // setup notifiers for the sockets if ( !d->stdinBuf.isEmpty() ) { d->notifierStdin->setEnabled( TRUE ); } } if ( comms & Stdout ) { ::close( sStdout[1] ); d->proc->socketStdout = sStdout[0]; d->notifierStdout = new TQSocketNotifier( sStdout[0], TQSocketNotifier::Read ); connect( d->notifierStdout, TQ_SIGNAL(activated(int)), this, TQ_SLOT(socketRead(int)) ); if ( ioRedirection ) d->notifierStdout->setEnabled( TRUE ); } if ( comms & Stderr ) { ::close( sStderr[1] ); d->proc->socketStderr = sStderr[0]; d->notifierStderr = new TQSocketNotifier( sStderr[0], TQSocketNotifier::Read ); connect( d->notifierStderr, TQ_SIGNAL(activated(int)), this, TQ_SLOT(socketRead(int)) ); if ( ioRedirection ) d->notifierStderr->setEnabled( TRUE ); } // cleanup and return delete[] arglistQ; delete[] arglist; return TRUE; error: #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::start(): error starting process" ); #endif if ( d->procManager ) d->procManager->cleanup(); if ( comms & Stdin ) { ::close( sStdin[1] ); ::close( sStdin[0] ); } if ( comms & Stdout ) { ::close( sStdout[0] ); ::close( sStdout[1] ); } if ( comms & Stderr ) { ::close( sStderr[0] ); ::close( sStderr[1] ); } ::close( fd[0] ); ::close( fd[1] ); delete[] arglistQ; delete[] arglist; return FALSE; } /*! Asks the process to terminate. Processes can ignore this if they wish. If you want to be certain that the process really terminates, you can use kill() instead. The slot returns immediately: it does not wait until the process has finished. When the process terminates, the processExited() signal is emitted. \sa kill() processExited() */ void TQProcess::tryTerminate() const { if ( d->proc != 0 ) ::kill( d->proc->pid, SIGTERM ); } /*! Terminates the process. This is not a safe way to end a process since the process will not be able to do any cleanup. tryTerminate() is safer, but processes can ignore a tryTerminate(). The nice way to end a process and to be sure that it is finished, is to do something like this: \code process->tryTerminate(); TQTimer::singleShot( 5000, process, TQ_SLOT( kill() ) ); \endcode This tries to terminate the process the nice way. If the process is still running after 5 seconds, it terminates the process the hard way. The timeout should be chosen depending on the time the process needs to do all its cleanup: use a higher value if the process is likely to do a lot of computation or I/O on cleanup. The slot returns immediately: it does not wait until the process has finished. When the process terminates, the processExited() signal is emitted. \sa tryTerminate() processExited() */ void TQProcess::kill() const { if ( d->proc != 0 ) ::kill( d->proc->pid, SIGKILL ); } /*! Returns TRUE if the process is running; otherwise returns FALSE. \sa normalExit() exitStatus() processExited() */ bool TQProcess::isRunning() const { if ( d->exitValuesCalculated ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::isRunning(): FALSE (already computed)" ); #endif return FALSE; } if ( d->proc == 0 ) return FALSE; int status; if ( ::waitpid( d->proc->pid, &status, WNOHANG ) == d->proc->pid ) { // compute the exit values TQProcess *that = (TQProcess*)this; // mutable that->exitNormal = WIFEXITED( status ) != 0; if ( exitNormal ) { that->exitStat = (char)WEXITSTATUS( status ); } d->exitValuesCalculated = TRUE; // On heavy processing, the socket notifier for the sigchild might not // have found time to fire yet. if ( d->procManager && d->procManager->sigchldFd[1] < FD_SETSIZE ) { fd_set fds; struct timeval tv; FD_ZERO( &fds ); FD_SET( d->procManager->sigchldFd[1], &fds ); tv.tv_sec = 0; tv.tv_usec = 0; if ( ::select( d->procManager->sigchldFd[1]+1, &fds, 0, 0, &tv ) > 0 ) d->procManager->sigchldHnd( d->procManager->sigchldFd[1] ); } #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::isRunning() (PID: %d): FALSE", d->proc->pid ); #endif return FALSE; } #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::isRunning() (PID: %d): TRUE", d->proc->pid ); #endif return TRUE; } /*! Returns TRUE if it's possible to read an entire line of text from standard output at this time; otherwise returns FALSE. \sa readLineStdout() canReadLineStderr() */ bool TQProcess::canReadLineStdout() const { if ( !d->proc || !d->proc->socketStdout ) return d->bufStdout.size() != 0; TQProcess *that = (TQProcess*)this; return that->membufStdout()->scanNewline( 0 ); } /*! Returns TRUE if it's possible to read an entire line of text from standard error at this time; otherwise returns FALSE. \sa readLineStderr() canReadLineStdout() */ bool TQProcess::canReadLineStderr() const { if ( !d->proc || !d->proc->socketStderr ) return d->bufStderr.size() != 0; TQProcess *that = (TQProcess*)this; return that->membufStderr()->scanNewline( 0 ); } /*! Writes the data \a buf to the process's standard input. The process may or may not read this data. This function always returns immediately. The data you pass to writeToStdin() is copied into an internal memory buffer in TQProcess, and when control goes back to the event loop, TQProcess will starting transferring data from this buffer to the running process.   Sometimes the data will be transferred in several payloads, depending on how much data is read at a time by the process itself. When TQProcess has transferred all the data from its memory buffer to the running process, it emits wroteToStdin(). Note that some operating systems use a buffer to transfer the data. As a result, wroteToStdin() may be emitted before the running process has actually read all the data. \sa wroteToStdin() closeStdin() readStdout() readStderr() */ void TQProcess::writeToStdin( const TQByteArray& buf ) { #if defined(QT_QPROCESS_DEBUG) // tqDebug( "TQProcess::writeToStdin(): write to stdin (%d)", d->socketStdin ); #endif d->stdinBuf.enqueue( new TQByteArray(buf) ); if ( d->notifierStdin != 0 ) d->notifierStdin->setEnabled( TRUE ); } /*! Closes the process's standard input. This function also deletes any pending data that has not been written to standard input. \sa wroteToStdin() */ void TQProcess::closeStdin() { if ( d->proc == 0 ) return; if ( d->proc->socketStdin !=0 ) { while ( !d->stdinBuf.isEmpty() ) { delete d->stdinBuf.dequeue(); } delete d->notifierStdin; d->notifierStdin = 0; if ( ::close( d->proc->socketStdin ) != 0 ) { tqWarning( "Could not close stdin of child process" ); } #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::closeStdin(): stdin (%d) closed", d->proc->socketStdin ); #endif d->proc->socketStdin = 0; } } /* This private slot is called when the process has outputted data to either standard output or standard error. */ void TQProcess::socketRead( int fd ) { if ( d->socketReadCalled ) { // the slots that are connected to the readyRead...() signals might // trigger a recursive call of socketRead(). Avoid this since you get a // blocking read otherwise. return; } #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::socketRead(): %d", fd ); #endif if ( fd == 0 ) return; if ( !d->proc ) return; TQMembuf *buffer = 0; int n; if ( fd == d->proc->socketStdout ) { buffer = &d->bufStdout; } else if ( fd == d->proc->socketStderr ) { buffer = &d->bufStderr; } else { // this case should never happen, but just to be safe return; } #if defined(QT_QPROCESS_DEBUG) uint oldSize = buffer->size(); #endif // try to read data first (if it fails, the filedescriptor was closed) const int basize = 4096; TQByteArray *ba = new TQByteArray( basize ); n = ::read( fd, ba->data(), basize ); if ( n > 0 ) { ba->resize( n ); buffer->append( ba ); ba = 0; } else { delete ba; ba = 0; } // eof or error? if ( n == 0 || n == -1 ) { if ( fd == d->proc->socketStdout ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::socketRead(): stdout (%d) closed", fd ); #endif d->notifierStdout->setEnabled( FALSE ); delete d->notifierStdout; d->notifierStdout = 0; ::close( d->proc->socketStdout ); d->proc->socketStdout = 0; return; } else if ( fd == d->proc->socketStderr ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::socketRead(): stderr (%d) closed", fd ); #endif d->notifierStderr->setEnabled( FALSE ); delete d->notifierStderr; d->notifierStderr = 0; ::close( d->proc->socketStderr ); d->proc->socketStderr = 0; return; } } if ( fd < FD_SETSIZE ) { fd_set fds; struct timeval tv; FD_ZERO( &fds ); FD_SET( fd, &fds ); tv.tv_sec = 0; tv.tv_usec = 0; while ( ::select( fd+1, &fds, 0, 0, &tv ) > 0 ) { // prepare for the next round FD_ZERO( &fds ); FD_SET( fd, &fds ); // read data ba = new TQByteArray( basize ); n = ::read( fd, ba->data(), basize ); if ( n > 0 ) { ba->resize( n ); buffer->append( ba ); ba = 0; } else { delete ba; ba = 0; break; } } } d->socketReadCalled = TRUE; if ( fd == d->proc->socketStdout ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::socketRead(): %d bytes read from stdout (%d)", buffer->size()-oldSize, fd ); #endif emit readyReadStdout(); } else if ( fd == d->proc->socketStderr ) { #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::socketRead(): %d bytes read from stderr (%d)", buffer->size()-oldSize, fd ); #endif emit readyReadStderr(); } d->socketReadCalled = FALSE; } /* This private slot is called when the process tries to read data from standard input. */ void TQProcess::socketWrite( int fd ) { while ( fd == d->proc->socketStdin && d->proc->socketStdin != 0 ) { if ( d->stdinBuf.isEmpty() ) { d->notifierStdin->setEnabled( FALSE ); return; } ssize_t ret = ::write( fd, d->stdinBuf.head()->data() + d->stdinBufRead, d->stdinBuf.head()->size() - d->stdinBufRead ); #if defined(QT_QPROCESS_DEBUG) tqDebug( "TQProcess::socketWrite(): wrote %d bytes to stdin (%d)", ret, fd ); #endif if ( ret == -1 ) return; d->stdinBufRead += ret; if ( d->stdinBufRead == (ssize_t)d->stdinBuf.head()->size() ) { d->stdinBufRead = 0; delete d->stdinBuf.dequeue(); if ( wroteToStdinConnected && d->stdinBuf.isEmpty() ) emit wroteToStdin(); } } } /*! \internal Flushes standard input. This is useful if you want to use TQProcess in a synchronous manner. This function should probably go into the public API. */ void TQProcess::flushStdin() { if (d->proc) socketWrite(d->proc->socketStdin); } /* This private slot is only used under Windows (but tqmoc does not know about #if defined()). */ void TQProcess::timeout() { } /* This private function is used by connectNotify() and disconnectNotify() to change the value of ioRedirection (and related behaviour) */ void TQProcess::setIoRedirection( bool value ) { ioRedirection = value; if ( ioRedirection ) { if ( d->notifierStdout ) d->notifierStdout->setEnabled( TRUE ); if ( d->notifierStderr ) d->notifierStderr->setEnabled( TRUE ); } else { if ( d->notifierStdout ) d->notifierStdout->setEnabled( FALSE ); if ( d->notifierStderr ) d->notifierStderr->setEnabled( FALSE ); } } /* This private function is used by connectNotify() and disconnectNotify() to change the value of notifyOnExit (and related behaviour) */ void TQProcess::setNotifyOnExit( bool value ) { notifyOnExit = value; } /* This private function is used by connectNotify() and disconnectNotify() to change the value of wroteToStdinConnected (and related behaviour) */ void TQProcess::setWroteStdinConnected( bool value ) { wroteToStdinConnected = value; } /*! \enum TQProcess::PID \internal */ /*! Returns platform dependent information about the process. This can be used together with platform specific system calls. Under Unix the return value is the PID of the process, or -1 if no process belongs to this object. Under Windows it is a pointer to the \c PROCESS_INFORMATION struct, or 0 if no process is belongs to this object. Use of this function's return value is likely to be non-portable. */ TQProcess::PID TQProcess::processIdentifier() { if ( d->proc == 0 ) return -1; return d->proc->pid; } #endif // TQT_NO_PROCESS