/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /************************************************************************* * * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * Copyright 2000, 2010 Oracle and/or its affiliates. * * OpenOffice.org - a multi-platform office productivity suite * * This file is part of OpenOffice.org. * * OpenOffice.org is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License version 3 * only, as published by the Free Software Foundation. * * OpenOffice.org 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 Lesser General Public License version 3 for more details * (a copy is included in the LICENSE file that accompanied this code). * * You should have received a copy of the GNU Lesser General Public License * version 3 along with OpenOffice.org. If not, see * * for a copy of the LGPLv3 License. * ************************************************************************/ #include "PresenterTimer.hxx" #include #include #include #include #include #include using namespace ::com::sun::star; using namespace ::com::sun::star::uno; #define A2S(pString) (::rtl::OUString(RTL_CONSTASCII_USTRINGPARAM(pString))) namespace sdext { namespace presenter { namespace { class TimerTask { public: TimerTask ( const PresenterTimer::Task& rTask, const TimeValue& rDueTime, const sal_Int64 nRepeatIntervall, const sal_Int32 nTaskId); ~TimerTask (void) {} PresenterTimer::Task maTask; TimeValue maDueTime; const sal_Int64 mnRepeatIntervall; const sal_Int32 mnTaskId; bool mbIsCanceled; }; typedef ::boost::shared_ptr SharedTimerTask; class TimerTaskComparator { public: bool operator() (const SharedTimerTask& rpTask1, const SharedTimerTask& rpTask2) const { return rpTask1->maDueTime.Seconds < rpTask2->maDueTime.Seconds || (rpTask1->maDueTime.Seconds == rpTask2->maDueTime.Seconds && rpTask1->maDueTime.Nanosec < rpTask2->maDueTime.Nanosec); } }; /** Queue all scheduled tasks and process them when their time has come. */ class TimerScheduler : public ::boost::enable_shared_from_this, public ::osl::Thread { public: static ::boost::shared_ptr Instance (void); static SharedTimerTask CreateTimerTask ( const PresenterTimer::Task& rTask, const TimeValue& rDueTime, const sal_Int64 nRepeatIntervall); void ScheduleTask (const SharedTimerTask& rpTask); void CancelTask (const sal_Int32 nTaskId); static bool GetCurrentTime (TimeValue& rCurrentTime); static sal_Int64 GetTimeDifference ( const TimeValue& rTargetTime, const TimeValue& rCurrentTime); static void ConvertToTimeValue ( TimeValue& rTimeValue, const sal_Int64 nTimeDifference); static sal_Int64 ConvertFromTimeValue ( const TimeValue& rTimeValue); private: static ::boost::shared_ptr mpInstance; static ::osl::Mutex maInstanceMutex; ::boost::shared_ptr mpLateDestroy; // for clean exit static sal_Int32 mnTaskId; ::osl::Mutex maTaskContainerMutex; typedef ::std::set TaskContainer; TaskContainer maScheduledTasks; ::osl::Mutex maCurrentTaskMutex; SharedTimerTask mpCurrentTask; static void Release (void); TimerScheduler (void); virtual ~TimerScheduler (void); class Deleter {public: void operator () (TimerScheduler* pScheduler) { delete pScheduler; } }; friend class Deleter; virtual void SAL_CALL run (void); virtual void SAL_CALL onTerminated (void) { mpLateDestroy.reset(); } }; } // end of anonymous namespace //===== PresenterTimer ======================================================== sal_Int32 PresenterTimer::ScheduleRepeatedTask ( const Task& rTask, const sal_Int64 nDelay, const sal_Int64 nIntervall) { TimeValue aCurrentTime; if (TimerScheduler::GetCurrentTime(aCurrentTime)) { TimeValue aDueTime; TimerScheduler::ConvertToTimeValue( aDueTime, TimerScheduler::ConvertFromTimeValue (aCurrentTime) + nDelay); SharedTimerTask pTask (TimerScheduler::CreateTimerTask(rTask, aDueTime, nIntervall)); TimerScheduler::Instance()->ScheduleTask(pTask); return pTask->mnTaskId; } return NotAValidTaskId; } void PresenterTimer::CancelTask (const sal_Int32 nTaskId) { return TimerScheduler::Instance()->CancelTask(nTaskId); } //===== TimerScheduler ======================================================== ::boost::shared_ptr TimerScheduler::mpInstance; ::osl::Mutex TimerScheduler::maInstanceMutex; sal_Int32 TimerScheduler::mnTaskId = PresenterTimer::NotAValidTaskId; ::boost::shared_ptr TimerScheduler::Instance (void) { ::osl::MutexGuard aGuard (maInstanceMutex); if (mpInstance.get() == NULL) { mpInstance.reset(new TimerScheduler(), TimerScheduler::Deleter()); mpInstance->create(); } return mpInstance; } TimerScheduler::TimerScheduler (void) : maTaskContainerMutex(), maScheduledTasks(), maCurrentTaskMutex(), mpCurrentTask() { } TimerScheduler::~TimerScheduler (void) { } SharedTimerTask TimerScheduler::CreateTimerTask ( const PresenterTimer::Task& rTask, const TimeValue& rDueTime, const sal_Int64 nRepeatIntervall) { return SharedTimerTask(new TimerTask(rTask, rDueTime, nRepeatIntervall, ++mnTaskId)); } void TimerScheduler::ScheduleTask (const SharedTimerTask& rpTask) { if (rpTask.get() == NULL) return; if (rpTask->mbIsCanceled) return; { osl::MutexGuard aTaskGuard (maTaskContainerMutex); maScheduledTasks.insert(rpTask); } } void TimerScheduler::CancelTask (const sal_Int32 nTaskId) { // Set of scheduled tasks is sorted after their due times, not their // task ids. Therefore we have to do a linear search for the task to // cancel. { ::osl::MutexGuard aGuard (maTaskContainerMutex); TaskContainer::iterator iTask (maScheduledTasks.begin()); TaskContainer::const_iterator iEnd (maScheduledTasks.end()); for ( ; iTask!=iEnd; ++iTask) { if ((*iTask)->mnTaskId == nTaskId) { maScheduledTasks.erase(iTask); break; } } } // The task that is to be canceled may be currently about to be // processed. Mark it with a flag that a) prevents a repeating task // from being scheduled again and b) tries to prevent its execution. { ::osl::MutexGuard aGuard (maCurrentTaskMutex); if (mpCurrentTask.get() != NULL && mpCurrentTask->mnTaskId == nTaskId) mpCurrentTask->mbIsCanceled = true; } // Let the main-loop cleanup in it's own time } void SAL_CALL TimerScheduler::run (void) { while (1) { // Get the current time. TimeValue aCurrentTime; if ( ! GetCurrentTime(aCurrentTime)) { // We can not get the current time and thus can not schedule anything. break; } // Restrict access to the maScheduledTasks member to one, mutext // guarded, block. SharedTimerTask pTask; sal_Int64 nDifference = 0; { ::osl::MutexGuard aGuard (maTaskContainerMutex); // There are no more scheduled task. Leave this loop, function and // live of the TimerScheduler. if (maScheduledTasks.empty()) break; nDifference = GetTimeDifference( (*maScheduledTasks.begin())->maDueTime, aCurrentTime); if (nDifference <= 0) { pTask = *maScheduledTasks.begin(); maScheduledTasks.erase(maScheduledTasks.begin()); } } // Acquire a reference to the current task. { ::osl::MutexGuard aGuard (maCurrentTaskMutex); mpCurrentTask = pTask; } if (pTask.get() == NULL) { // Wait until the first task becomes due. TimeValue aTimeValue; ConvertToTimeValue(aTimeValue, nDifference); wait(aTimeValue); } else { // Execute task. if ( ! pTask->maTask.empty() && ! pTask->mbIsCanceled) { pTask->maTask(aCurrentTime); // Re-schedule repeating tasks. if (pTask->mnRepeatIntervall > 0) { ConvertToTimeValue( pTask->maDueTime, ConvertFromTimeValue(pTask->maDueTime) + pTask->mnRepeatIntervall); ScheduleTask(pTask); } } } // Release reference to the current task. { ::osl::MutexGuard aGuard (maCurrentTaskMutex); mpCurrentTask.reset(); } } // While holding maInstanceMutex osl::Guard< osl::Mutex > aInstance( maInstanceMutex ); mpLateDestroy = mpInstance; mpInstance.reset(); } bool TimerScheduler::GetCurrentTime (TimeValue& rCurrentTime) { TimeValue aSystemTime; if (osl_getSystemTime(&aSystemTime)) return osl_getLocalTimeFromSystemTime(&aSystemTime, &rCurrentTime); return false; } sal_Int64 TimerScheduler::GetTimeDifference ( const TimeValue& rTargetTime, const TimeValue& rCurrentTime) { return ConvertFromTimeValue(rTargetTime) - ConvertFromTimeValue(rCurrentTime); } void TimerScheduler::ConvertToTimeValue ( TimeValue& rTimeValue, const sal_Int64 nTimeDifference) { rTimeValue.Seconds = sal::static_int_cast(nTimeDifference / 1000000000L); rTimeValue.Nanosec = sal::static_int_cast(nTimeDifference % 1000000000L); } sal_Int64 TimerScheduler::ConvertFromTimeValue ( const TimeValue& rTimeValue) { return sal_Int64(rTimeValue.Seconds) * 1000000000L + rTimeValue.Nanosec; } //===== TimerTask ============================================================= namespace { TimerTask::TimerTask ( const PresenterTimer::Task& rTask, const TimeValue& rDueTime, const sal_Int64 nRepeatIntervall, const sal_Int32 nTaskId) : maTask(rTask), maDueTime(rDueTime), mnRepeatIntervall(nRepeatIntervall), mnTaskId(nTaskId), mbIsCanceled(false) { } } // end of anonymous namespace //===== PresenterTimer ======================================================== ::rtl::Reference PresenterClockTimer::mpInstance; ::rtl::Reference PresenterClockTimer::Instance ( const css::uno::Reference& rxContext) { ::osl::MutexGuard aSolarGuard (::osl::Mutex::getGlobalMutex()); ::rtl::Reference pTimer; if (mpInstance.is()) { pTimer = mpInstance; } if ( ! pTimer.is()) { pTimer = ::rtl::Reference(new PresenterClockTimer(rxContext)); mpInstance = pTimer; } return pTimer; } PresenterClockTimer::PresenterClockTimer (const Reference& rxContext) : PresenterClockTimerInterfaceBase(m_aMutex), maListeners(), maDateTime(), mnTimerTaskId(PresenterTimer::NotAValidTaskId), mbIsCallbackPending(false), mxRequestCallback() { Reference xFactory ( rxContext->getServiceManager(), UNO_QUERY); if (xFactory.is()) mxRequestCallback = Reference( xFactory->createInstanceWithContext( A2S("com.sun.star.awt.AsyncCallback"), rxContext), UNO_QUERY_THROW); } PresenterClockTimer::~PresenterClockTimer (void) { if (mnTimerTaskId != PresenterTimer::NotAValidTaskId) { PresenterTimer::CancelTask(mnTimerTaskId); mnTimerTaskId = PresenterTimer::NotAValidTaskId; } Reference xComponent (mxRequestCallback, UNO_QUERY); if (xComponent.is()) xComponent->dispose(); mxRequestCallback = NULL; } void PresenterClockTimer::AddListener (const SharedListener& rListener) { osl::MutexGuard aGuard (maMutex); maListeners.push_back(rListener); // Create a timer task when the first listener is added. if (mnTimerTaskId==PresenterTimer::NotAValidTaskId) { mnTimerTaskId = PresenterTimer::ScheduleRepeatedTask( ::boost::bind(&PresenterClockTimer::CheckCurrentTime, this, _1), 0, 250000000 /*ns*/); } } void PresenterClockTimer::RemoveListener (const SharedListener& rListener) { osl::MutexGuard aGuard (maMutex); ListenerContainer::iterator iListener (::std::find( maListeners.begin(), maListeners.end(), rListener)); if (iListener != maListeners.end()) maListeners.erase(iListener); if (maListeners.empty()) { // We have no more clients and therefore are not interested in time changes. if (mnTimerTaskId != PresenterTimer::NotAValidTaskId) { PresenterTimer::CancelTask(mnTimerTaskId); mnTimerTaskId = PresenterTimer::NotAValidTaskId; } mpInstance = NULL; } } oslDateTime PresenterClockTimer::GetCurrentTime (void) { TimeValue aCurrentTime; TimerScheduler::GetCurrentTime(aCurrentTime); oslDateTime aDateTime; osl_getDateTimeFromTimeValue(&aCurrentTime, &aDateTime); return aDateTime; } void PresenterClockTimer::CheckCurrentTime (const TimeValue& rCurrentTime) { css::uno::Reference xRequestCallback; css::uno::Reference xCallback; { osl::MutexGuard aGuard (maMutex); TimeValue aCurrentTime (rCurrentTime); oslDateTime aDateTime; if (osl_getDateTimeFromTimeValue(&aCurrentTime, &aDateTime)) { if (aDateTime.Seconds != maDateTime.Seconds || aDateTime.Minutes != maDateTime.Minutes || aDateTime.Hours != maDateTime.Hours) { // The displayed part of the current time has changed. // Prepare to call the listeners. maDateTime = aDateTime; // Schedule notification of listeners. if (mxRequestCallback.is() && ! mbIsCallbackPending) { mbIsCallbackPending = true; xRequestCallback = mxRequestCallback; xCallback = this; } } } } if (mxRequestCallback.is() && xCallback.is()) xRequestCallback->addCallback(xCallback, Any()); } //----- XCallback ------------------------------------------------------------- void SAL_CALL PresenterClockTimer::notify (const css::uno::Any& rUserData) throw (css::uno::RuntimeException) { (void)rUserData; ListenerContainer aListenerCopy (maListeners); { osl::MutexGuard aGuard (maMutex); mbIsCallbackPending = false; ::std::copy( maListeners.begin(), maListeners.end(), ::std::back_inserter(aListenerCopy)); } if (aListenerCopy.size() > 0) { ListenerContainer::const_iterator iListener; ListenerContainer::const_iterator iEnd (aListenerCopy.end()); for (iListener=aListenerCopy.begin(); iListener!=iEnd; ++iListener) { (*iListener)->TimeHasChanged(maDateTime); } } } } } // end of namespace ::sdext::presenter /* vim:set shiftwidth=4 softtabstop=4 expandtab: */