/* * synergy -- mouse and keyboard sharing utility * Copyright (C) 2012 Bolton Software Ltd. * Copyright (C) 2002 Chris Schoeneman * * This package is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * found in the file COPYING that should have accompanied this file. * * This package 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 "CArchMultithreadPosix.h" #include "CArch.h" #include "XArch.h" #include #if TIME_WITH_SYS_TIME # include # include #else # if HAVE_SYS_TIME_H # include # else # include # endif #endif #include #define SIGWAKEUP SIGUSR1 #if !HAVE_PTHREAD_SIGNAL // boy, is this platform broken. forget about pthread signal // handling and let signals through to every process. synergy // will not terminate cleanly when it gets SIGTERM or SIGINT. # define pthread_sigmask sigprocmask # define pthread_kill(tid_, sig_) kill(0, (sig_)) # define sigwait(set_, sig_) # undef HAVE_POSIX_SIGWAIT # define HAVE_POSIX_SIGWAIT 1 #endif static void setSignalSet(sigset_t* sigset) { sigemptyset(sigset); sigaddset(sigset, SIGHUP); sigaddset(sigset, SIGINT); sigaddset(sigset, SIGTERM); sigaddset(sigset, SIGUSR2); } // // CArchThreadImpl // class CArchThreadImpl { public: CArchThreadImpl(); public: int m_refCount; IArchMultithread::ThreadID m_id; pthread_t m_thread; IArchMultithread::ThreadFunc m_func; void* m_userData; bool m_cancel; bool m_cancelling; bool m_exited; void* m_result; void* m_networkData; }; CArchThreadImpl::CArchThreadImpl() : m_refCount(1), m_id(0), m_func(NULL), m_userData(NULL), m_cancel(false), m_cancelling(false), m_exited(false), m_result(NULL), m_networkData(NULL) { // do nothing } // // CArchMultithreadPosix // CArchMultithreadPosix* CArchMultithreadPosix::s_instance = NULL; CArchMultithreadPosix::CArchMultithreadPosix() : m_newThreadCalled(false), m_nextID(0) { assert(s_instance == NULL); s_instance = this; // no signal handlers for (size_t i = 0; i < kNUM_SIGNALS; ++i) { m_signalFunc[i] = NULL; m_signalUserData[i] = NULL; } // create mutex for thread list m_threadMutex = newMutex(); // create thread for calling (main) thread and add it to our // list. no need to lock the mutex since we're the only thread. m_mainThread = new CArchThreadImpl; m_mainThread->m_thread = pthread_self(); insert(m_mainThread); // install SIGWAKEUP handler. this causes SIGWAKEUP to interrupt // system calls. we use that when cancelling a thread to force it // to wake up immediately if it's blocked in a system call. we // won't need this until another thread is created but it's fine // to install it now. struct sigaction act; sigemptyset(&act.sa_mask); # if defined(SA_INTERRUPT) act.sa_flags = SA_INTERRUPT; # else act.sa_flags = 0; # endif act.sa_handler = &threadCancel; sigaction(SIGWAKEUP, &act, NULL); // set desired signal dispositions. let SIGWAKEUP through but // ignore SIGPIPE (we'll handle EPIPE). sigset_t sigset; sigemptyset(&sigset); sigaddset(&sigset, SIGWAKEUP); pthread_sigmask(SIG_UNBLOCK, &sigset, NULL); sigemptyset(&sigset); sigaddset(&sigset, SIGPIPE); pthread_sigmask(SIG_BLOCK, &sigset, NULL); } CArchMultithreadPosix::~CArchMultithreadPosix() { assert(s_instance != NULL); closeMutex(m_threadMutex); s_instance = NULL; } void CArchMultithreadPosix::setNetworkDataForCurrentThread(void* data) { lockMutex(m_threadMutex); CArchThreadImpl* thread = find(pthread_self()); thread->m_networkData = data; unlockMutex(m_threadMutex); } void* CArchMultithreadPosix::getNetworkDataForThread(CArchThread thread) { lockMutex(m_threadMutex); void* data = thread->m_networkData; unlockMutex(m_threadMutex); return data; } CArchMultithreadPosix* CArchMultithreadPosix::getInstance() { return s_instance; } CArchCond CArchMultithreadPosix::newCondVar() { CArchCondImpl* cond = new CArchCondImpl; int status = pthread_cond_init(&cond->m_cond, NULL); (void)status; assert(status == 0); return cond; } void CArchMultithreadPosix::closeCondVar(CArchCond cond) { int status = pthread_cond_destroy(&cond->m_cond); (void)status; assert(status == 0); delete cond; } void CArchMultithreadPosix::signalCondVar(CArchCond cond) { int status = pthread_cond_signal(&cond->m_cond); (void)status; assert(status == 0); } void CArchMultithreadPosix::broadcastCondVar(CArchCond cond) { int status = pthread_cond_broadcast(&cond->m_cond); (void)status; assert(status == 0); } bool CArchMultithreadPosix::waitCondVar(CArchCond cond, CArchMutex mutex, double timeout) { // we can't wait on a condition variable and also wake it up for // cancellation since we don't use posix cancellation. so we // must wake up periodically to check for cancellation. we // can't simply go back to waiting after the check since the // condition may have changed and we'll have lost the signal. // so we have to return to the caller. since the caller will // always check for spurious wakeups the only drawback here is // performance: we're waking up a lot more than desired. static const double maxCancellationLatency = 0.1; if (timeout < 0.0 || timeout > maxCancellationLatency) { timeout = maxCancellationLatency; } // see if we should cancel this thread testCancelThread(); // get final time struct timeval now; gettimeofday(&now, NULL); struct timespec finalTime; finalTime.tv_sec = now.tv_sec; finalTime.tv_nsec = now.tv_usec * 1000; long timeout_sec = (long)timeout; long timeout_nsec = (long)(1.0e+9 * (timeout - timeout_sec)); finalTime.tv_sec += timeout_sec; finalTime.tv_nsec += timeout_nsec; if (finalTime.tv_nsec >= 1000000000) { finalTime.tv_nsec -= 1000000000; finalTime.tv_sec += 1; } // wait int status = pthread_cond_timedwait(&cond->m_cond, &mutex->m_mutex, &finalTime); // check for cancel again testCancelThread(); switch (status) { case 0: // success return true; case ETIMEDOUT: return false; default: assert(0 && "condition variable wait error"); return false; } } CArchMutex CArchMultithreadPosix::newMutex() { pthread_mutexattr_t attr; int status = pthread_mutexattr_init(&attr); assert(status == 0); CArchMutexImpl* mutex = new CArchMutexImpl; status = pthread_mutex_init(&mutex->m_mutex, &attr); assert(status == 0); return mutex; } void CArchMultithreadPosix::closeMutex(CArchMutex mutex) { int status = pthread_mutex_destroy(&mutex->m_mutex); (void)status; assert(status == 0); delete mutex; } void CArchMultithreadPosix::lockMutex(CArchMutex mutex) { int status = pthread_mutex_lock(&mutex->m_mutex); switch (status) { case 0: // success return; case EDEADLK: assert(0 && "lock already owned"); break; case EAGAIN: assert(0 && "too many recursive locks"); break; default: assert(0 && "unexpected error"); break; } } void CArchMultithreadPosix::unlockMutex(CArchMutex mutex) { int status = pthread_mutex_unlock(&mutex->m_mutex); switch (status) { case 0: // success return; case EPERM: assert(0 && "thread doesn't own a lock"); break; default: assert(0 && "unexpected error"); break; } } CArchThread CArchMultithreadPosix::newThread(ThreadFunc func, void* data) { assert(func != NULL); // initialize signal handler. we do this here instead of the // constructor so we can avoid daemonizing (using fork()) // when there are multiple threads. clients can safely // use condition variables and mutexes before creating a // new thread and they can safely use the only thread // they have access to, the main thread, so they really // can't tell the difference. if (!m_newThreadCalled) { m_newThreadCalled = true; #if HAVE_PTHREAD_SIGNAL startSignalHandler(); #endif } lockMutex(m_threadMutex); // create thread impl for new thread CArchThreadImpl* thread = new CArchThreadImpl; thread->m_func = func; thread->m_userData = data; // create the thread. pthread_create() on RedHat 7.2 smp fails // if passed a NULL attr so use a default attr. pthread_attr_t attr; int status = pthread_attr_init(&attr); if (status == 0) { status = pthread_create(&thread->m_thread, &attr, &CArchMultithreadPosix::threadFunc, thread); pthread_attr_destroy(&attr); } // check if thread was started if (status != 0) { // failed to start thread so clean up delete thread; thread = NULL; } else { // add thread to list insert(thread); // increment ref count to account for the thread itself refThread(thread); } // note that the child thread will wait until we release this mutex unlockMutex(m_threadMutex); return thread; } CArchThread CArchMultithreadPosix::newCurrentThread() { lockMutex(m_threadMutex); CArchThreadImpl* thread = find(pthread_self()); unlockMutex(m_threadMutex); assert(thread != NULL); return thread; } void CArchMultithreadPosix::closeThread(CArchThread thread) { assert(thread != NULL); // decrement ref count and clean up thread if no more references if (--thread->m_refCount == 0) { // detach from thread (unless it's the main thread) if (thread->m_func != NULL) { pthread_detach(thread->m_thread); } // remove thread from list lockMutex(m_threadMutex); assert(findNoRef(thread->m_thread) == thread); erase(thread); unlockMutex(m_threadMutex); // done with thread delete thread; } } CArchThread CArchMultithreadPosix::copyThread(CArchThread thread) { refThread(thread); return thread; } void CArchMultithreadPosix::cancelThread(CArchThread thread) { assert(thread != NULL); // set cancel and wakeup flags if thread can be cancelled bool wakeup = false; lockMutex(m_threadMutex); if (!thread->m_exited && !thread->m_cancelling) { thread->m_cancel = true; wakeup = true; } unlockMutex(m_threadMutex); // force thread to exit system calls if wakeup is true if (wakeup) { pthread_kill(thread->m_thread, SIGWAKEUP); } } void CArchMultithreadPosix::setPriorityOfThread(CArchThread thread, int /*n*/) { assert(thread != NULL); // FIXME } void CArchMultithreadPosix::testCancelThread() { // find current thread lockMutex(m_threadMutex); CArchThreadImpl* thread = findNoRef(pthread_self()); unlockMutex(m_threadMutex); // test cancel on thread testCancelThreadImpl(thread); } bool CArchMultithreadPosix::wait(CArchThread target, double timeout) { assert(target != NULL); lockMutex(m_threadMutex); // find current thread CArchThreadImpl* self = findNoRef(pthread_self()); // ignore wait if trying to wait on ourself if (target == self) { unlockMutex(m_threadMutex); return false; } // ref the target so it can't go away while we're watching it refThread(target); unlockMutex(m_threadMutex); try { // do first test regardless of timeout testCancelThreadImpl(self); if (isExitedThread(target)) { closeThread(target); return true; } // wait and repeat test if there's a timeout if (timeout != 0.0) { const double start = ARCH->time(); do { // wait a little ARCH->sleep(0.05); // repeat test testCancelThreadImpl(self); if (isExitedThread(target)) { closeThread(target); return true; } // repeat wait and test until timed out } while (timeout < 0.0 || (ARCH->time() - start) <= timeout); } closeThread(target); return false; } catch (...) { closeThread(target); throw; } } bool CArchMultithreadPosix::isSameThread(CArchThread thread1, CArchThread thread2) { return (thread1 == thread2); } bool CArchMultithreadPosix::isExitedThread(CArchThread thread) { lockMutex(m_threadMutex); bool exited = thread->m_exited; unlockMutex(m_threadMutex); return exited; } void* CArchMultithreadPosix::getResultOfThread(CArchThread thread) { lockMutex(m_threadMutex); void* result = thread->m_result; unlockMutex(m_threadMutex); return result; } IArchMultithread::ThreadID CArchMultithreadPosix::getIDOfThread(CArchThread thread) { return thread->m_id; } void CArchMultithreadPosix::setSignalHandler( ESignal signal, SignalFunc func, void* userData) { lockMutex(m_threadMutex); m_signalFunc[signal] = func; m_signalUserData[signal] = userData; unlockMutex(m_threadMutex); } void CArchMultithreadPosix::raiseSignal(ESignal signal) { lockMutex(m_threadMutex); if (m_signalFunc[signal] != NULL) { m_signalFunc[signal](signal, m_signalUserData[signal]); pthread_kill(m_mainThread->m_thread, SIGWAKEUP); } else if (signal == kINTERRUPT || signal == kTERMINATE) { ARCH->cancelThread(m_mainThread); } unlockMutex(m_threadMutex); } void CArchMultithreadPosix::startSignalHandler() { // set signal mask. the main thread blocks these signals and // the signal handler thread will listen for them. sigset_t sigset, oldsigset; setSignalSet(&sigset); pthread_sigmask(SIG_BLOCK, &sigset, &oldsigset); // fire up the INT and TERM signal handler thread. we could // instead arrange to catch and handle these signals but // we'd be unable to cancel the main thread since no pthread // calls are allowed in a signal handler. pthread_attr_t attr; int status = pthread_attr_init(&attr); if (status == 0) { status = pthread_create(&m_signalThread, &attr, &CArchMultithreadPosix::threadSignalHandler, NULL); pthread_attr_destroy(&attr); } if (status != 0) { // can't create thread to wait for signal so don't block // the signals. pthread_sigmask(SIG_UNBLOCK, &oldsigset, NULL); } } CArchThreadImpl* CArchMultithreadPosix::find(pthread_t thread) { CArchThreadImpl* impl = findNoRef(thread); if (impl != NULL) { refThread(impl); } return impl; } CArchThreadImpl* CArchMultithreadPosix::findNoRef(pthread_t thread) { // linear search for (CThreadList::const_iterator index = m_threadList.begin(); index != m_threadList.end(); ++index) { if ((*index)->m_thread == thread) { return *index; } } return NULL; } void CArchMultithreadPosix::insert(CArchThreadImpl* thread) { assert(thread != NULL); // thread shouldn't already be on the list assert(findNoRef(thread->m_thread) == NULL); // set thread id. note that we don't worry about m_nextID // wrapping back to 0 and duplicating thread ID's since the // likelihood of synergy running that long is vanishingly // small. thread->m_id = ++m_nextID; // append to list m_threadList.push_back(thread); } void CArchMultithreadPosix::erase(CArchThreadImpl* thread) { for (CThreadList::iterator index = m_threadList.begin(); index != m_threadList.end(); ++index) { if (*index == thread) { m_threadList.erase(index); break; } } } void CArchMultithreadPosix::refThread(CArchThreadImpl* thread) { assert(thread != NULL); assert(findNoRef(thread->m_thread) != NULL); ++thread->m_refCount; } void CArchMultithreadPosix::testCancelThreadImpl(CArchThreadImpl* thread) { assert(thread != NULL); // update cancel state lockMutex(m_threadMutex); bool cancel = false; if (thread->m_cancel && !thread->m_cancelling) { thread->m_cancelling = true; thread->m_cancel = false; cancel = true; } unlockMutex(m_threadMutex); // unwind thread's stack if cancelling if (cancel) { throw XThreadCancel(); } } void* CArchMultithreadPosix::threadFunc(void* vrep) { // get the thread CArchThreadImpl* thread = reinterpret_cast(vrep); // setup pthreads pthread_setcancelstate(PTHREAD_CANCEL_DISABLE, NULL); pthread_setcanceltype(PTHREAD_CANCEL_DEFERRED, NULL); // run thread s_instance->doThreadFunc(thread); // terminate the thread return NULL; } void CArchMultithreadPosix::doThreadFunc(CArchThread thread) { // default priority is slightly below normal setPriorityOfThread(thread, 1); // wait for parent to initialize this object lockMutex(m_threadMutex); unlockMutex(m_threadMutex); void* result = NULL; try { // go result = (*thread->m_func)(thread->m_userData); } catch (XThreadCancel&) { // client called cancel() } catch (...) { // note -- don't catch (...) to avoid masking bugs lockMutex(m_threadMutex); thread->m_exited = true; unlockMutex(m_threadMutex); closeThread(thread); throw; } // thread has exited lockMutex(m_threadMutex); thread->m_result = result; thread->m_exited = true; unlockMutex(m_threadMutex); // done with thread closeThread(thread); } void CArchMultithreadPosix::threadCancel(int) { // do nothing } void* CArchMultithreadPosix::threadSignalHandler(void*) { // detach pthread_detach(pthread_self()); // add signal to mask sigset_t sigset; setSignalSet(&sigset); // also wait on SIGABRT. on linux (others?) this thread (process) // will persist after all the other threads evaporate due to an // assert unless we wait on SIGABRT. that means our resources (like // the socket we're listening on) are not released and never will be // until the lingering thread is killed. i don't know why sigwait() // should protect the thread from being killed. note that sigwait() // doesn't actually return if we receive SIGABRT and, for some // reason, we don't have to block SIGABRT. sigaddset(&sigset, SIGABRT); // we exit the loop via thread cancellation in sigwait() for (;;) { // wait #if HAVE_POSIX_SIGWAIT int signal = 0; sigwait(&sigset, &signal); #else sigwait(&sigset); #endif // if we get here then the signal was raised switch (signal) { case SIGINT: ARCH->raiseSignal(kINTERRUPT); break; case SIGTERM: ARCH->raiseSignal(kTERMINATE); break; case SIGHUP: ARCH->raiseSignal(kHANGUP); break; case SIGUSR2: ARCH->raiseSignal(kUSER); break; default: // ignore break; } } return NULL; }