/* * synergy -- mouse and keyboard sharing utility * Copyright (C) 2004 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. */ #include "CEventQueue.h" #include "IEventJob.h" #include "CArch.h" // interrupt handler. this just adds a quit event to the queue. static void interrupt(void*) { EVENTQUEUE->addEvent(CEvent(CEvent::kQuit)); } // // CEventQueue // CEventQueue::CEventQueue() { setInstance(this); m_mutex = ARCH->newMutex(); ARCH->setInterruptHandler(&interrupt, NULL); } CEventQueue::~CEventQueue() { ARCH->setInterruptHandler(NULL, NULL); ARCH->closeMutex(m_mutex); setInstance(NULL); } bool CEventQueue::getEvent(CEvent& event, double timeout) { // if no events are waiting then handle timers and then wait if (doIsEmpty()) { // handle timers first if (hasTimerExpired(event)) { return true; } // get time until next timer expires. if there is a timer // and it'll expire before the client's timeout then use // that duration for our timeout instead. double timerTimeout = getNextTimerTimeout(); if (timerTimeout >= 0.0 && timerTimeout < timeout) { timeout = timerTimeout; } // wait for an event waitForEvent(timeout); } // if no events are pending then do the timers if (doIsEmpty()) { return hasTimerExpired(event); } return doGetEvent(event); } bool CEventQueue::dispatchEvent(const CEvent& event) { void* target = event.getTarget(); IEventJob* job = getHandler(event.getType(), target); if (job != NULL) { job->run(event); return true; } return false; } void CEventQueue::addEvent(const CEvent& event) { // discard bogus event types switch (event.getType()) { case CEvent::kUnknown: case CEvent::kSystem: case CEvent::kTimer: return; default: break; } // store the event's data locally UInt32 eventID = saveEvent(event); // add it if (!doAddEvent(eventID)) { // failed to send event removeEvent(eventID); CEvent::deleteData(event); } } CEventQueueTimer* CEventQueue::newTimer(double duration, void* target) { assert(duration > 0.0); CEventQueueTimer* timer = doNewTimer(duration, false); CArchMutexLock lock(m_mutex); m_timers.insert(timer); m_timerQueue.push(CTimer(timer, duration, target, false)); return timer; } CEventQueueTimer* CEventQueue::newOneShotTimer(double duration, void* target) { assert(duration > 0.0); CEventQueueTimer* timer = doNewTimer(duration, true); CArchMutexLock lock(m_mutex); m_timers.insert(timer); m_timerQueue.push(CTimer(timer, duration, target, true)); return timer; } void CEventQueue::deleteTimer(CEventQueueTimer* timer) { { CArchMutexLock lock(m_mutex); for (CTimerQueue::iterator index = m_timerQueue.begin(); index != m_timerQueue.end(); ++index) { if (index->getTimer() == timer) { m_timerQueue.erase(index); break; } } CTimers::iterator index = m_timers.find(timer); if (index != m_timers.end()) { m_timers.erase(index); } } doDeleteTimer(timer); } void CEventQueue::adoptHandler(void* target, IEventJob* handler) { CArchMutexLock lock(m_mutex); doAdoptHandler(CEvent::kUnknown, target, handler); } void CEventQueue::adoptHandler(CEvent::Type type, void* target, IEventJob* handler) { assert(type != CEvent::kUnknown); CArchMutexLock lock(m_mutex); doAdoptHandler(type, target, handler); } IEventJob* CEventQueue::orphanHandler(void* target) { CArchMutexLock lock(m_mutex); return doOrphanHandler(CEvent::kUnknown, target); } IEventJob* CEventQueue::orphanHandler(CEvent::Type type, void* target) { assert(type != CEvent::kUnknown); CArchMutexLock lock(m_mutex); return doOrphanHandler(type, target); } void CEventQueue::removeHandler(void* target) { delete orphanHandler(target); } void CEventQueue::removeHandler(CEvent::Type type, void* target) { delete orphanHandler(type, target); } void CEventQueue::doAdoptHandler(CEvent::Type type, void* target, IEventJob* handler) { IEventJob*& job = m_handlers[CTypeTarget(type, target)]; delete job; job = handler; } IEventJob* CEventQueue::doOrphanHandler(CEvent::Type type, void* target) { CHandlerTable::iterator index = m_handlers.find(CTypeTarget(type, target)); if (index != m_handlers.end()) { IEventJob* handler = index->second; m_handlers.erase(index); return handler; } else { return NULL; } } bool CEventQueue::isEmpty() const { return (doIsEmpty() && getNextTimerTimeout() != 0.0); } IEventJob* CEventQueue::getHandler(CEvent::Type type, void* target) const { CArchMutexLock lock(m_mutex); CHandlerTable::const_iterator index = m_handlers.find(CTypeTarget(type, target)); if (index != m_handlers.end()) { return index->second; } index = m_handlers.find(CTypeTarget(CEvent::kUnknown, target)); if (index != m_handlers.end()) { return index->second; } return NULL; } UInt32 CEventQueue::saveEvent(const CEvent& event) { CArchMutexLock lock(m_mutex); // choose id UInt32 id; if (!m_oldEventIDs.empty()) { // reuse an id id = m_oldEventIDs.back(); m_oldEventIDs.pop_back(); } else { // make a new id id = static_cast(m_events.size()); } // save data m_events[id] = event; return id; } CEvent CEventQueue::removeEvent(UInt32 eventID) { CArchMutexLock lock(m_mutex); // look up id CEventTable::iterator index = m_events.find(eventID); if (index == m_events.end()) { return CEvent(); } // get data CEvent event = index->second; m_events.erase(index); // save old id for reuse m_oldEventIDs.push_back(eventID); return event; } bool CEventQueue::hasTimerExpired(CEvent& event) { CArchMutexLock lock(m_mutex); // return true if there's a timer in the timer priority queue that // has expired. if returning true then fill in event appropriately // and reset and reinsert the timer. if (m_timerQueue.empty()) { return false; } // get time elapsed since last check const double time = m_time.getTime(); m_time.reset(); // countdown elapsed time for (CTimerQueue::iterator index = m_timerQueue.begin(); index != m_timerQueue.end(); ++index) { (*index) -= time; } // done if no timers are expired if (m_timerQueue.top() > 0.0) { return false; } // remove timer from queue CTimer timer = m_timerQueue.top(); m_timerQueue.pop(); // prepare event and reset the timer's clock timer.fillEvent(m_timerEvent); event = CEvent(CEvent::kTimer, timer.getTarget(), &m_timerEvent); timer.reset(); // reinsert timer into queue if it's not a one-shot if (!timer.isOneShot()) { m_timerQueue.push(timer); } return true; } double CEventQueue::getNextTimerTimeout() const { CArchMutexLock lock(m_mutex); // return -1 if no timers, 0 if the top timer has expired, otherwise // the time until the top timer in the timer priority queue will // expire. if (m_timerQueue.empty()) { return -1.0; } if (m_timerQueue.top() <= 0.0) { return 0.0; } return m_timerQueue.top(); } // // CEventQueue::CTypeTarget // CEventQueue::CTypeTarget::CTypeTarget(CEvent::Type type, void* target) : m_type(type), m_target(target) { // do nothing } CEventQueue::CTypeTarget::~CTypeTarget() { // do nothing } bool CEventQueue::CTypeTarget::operator<(const CTypeTarget& tt) const { return (m_type < tt.m_type || (m_type == tt.m_type && m_target < tt.m_target)); } // // CEventQueue::CTimer // CEventQueue::CTimer::CTimer(CEventQueueTimer* timer, double timeout, void* target, bool oneShot) : m_timer(timer), m_timeout(timeout), m_target(target), m_oneShot(oneShot), m_time(timeout) { assert(m_timeout > 0.0); } CEventQueue::CTimer::~CTimer() { // do nothing } void CEventQueue::CTimer::reset() { m_time = m_timeout; } CEventQueue::CTimer::CTimer& CEventQueue::CTimer::operator-=(double dt) { m_time -= dt; return *this; } CEventQueue::CTimer::operator double() const { return m_time; } bool CEventQueue::CTimer::isOneShot() const { return m_oneShot; } CEventQueueTimer* CEventQueue::CTimer::getTimer() const { return m_timer; } void* CEventQueue::CTimer::getTarget() const { return m_target; } void CEventQueue::CTimer::fillEvent(CTimerEvent& event) const { event.m_timer = m_timer; event.m_count = 0; if (m_time <= 0.0) { event.m_count = static_cast((m_timeout - m_time) / m_timeout); } } bool CEventQueue::CTimer::operator<(const CTimer& t) const { return m_time < t.m_time; }