/**************************************************************************** ** ** 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. ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qfuturewatcher.h" #ifndef QT_NO_QFUTURE #include "qfuturewatcher_p.h" #include #include #include #include QT_BEGIN_NAMESPACE /*! \class QFutureWatcher \reentrant \since 4.4 \inmodule QtCore \ingroup thread \brief The QFutureWatcher class allows monitoring a QFuture using signals and slots. QFutureWatcher provides information and notifications about a QFuture. Use the setFuture() function to start watching a particular QFuture. The future() function returns the future set with setFuture(). For convenience, several of QFuture's functions are also available in QFutureWatcher: progressValue(), progressMinimum(), progressMaximum(), progressText(), isStarted(), isFinished(), isRunning(), isCanceled(), isPaused(), waitForFinished(), result(), and resultAt(). The cancel(), setPaused(), pause(), resume(), and togglePaused() functions are slots in QFutureWatcher. Status changes are reported via the started(), finished(), canceled(), paused(), resumed(), resultReadyAt(), and resultsReadyAt() signals. Progress information is provided from the progressRangeChanged(), void progressValueChanged(), and progressTextChanged() signals. Throttling control is provided by the setPendingResultsLimit() function. When the number of pending resultReadyAt() or resultsReadyAt() signals exceeds the limit, the computation represented by the future will be throttled automatically. The computation will resume once the number of pending signals drops below the limit. Example: Starting a computation and getting a slot callback when it's finished: \snippet code/src_corelib_thread_qfuturewatcher.cpp 0 Be aware that not all asynchronous computations can be canceled or paused. For example, the future returned by QtConcurrent::run() cannot be canceled; but the future returned by QtConcurrent::mappedReduced() can. QFutureWatcher is specialized to not contain any of the result fetching functions. Any QFuture can be watched by a QFutureWatcher as well. This is useful if only status or progress information is needed; not the actual result data. \sa QFuture, {Qt Concurrent} */ /*! \fn QFutureWatcher::QFutureWatcher(QObject *parent) Constructs a new QFutureWatcher with the given \a parent. */ QFutureWatcherBase::QFutureWatcherBase(QObject *parent) :QObject(*new QFutureWatcherBasePrivate, parent) { } /*! \fn QFutureWatcher::~QFutureWatcher() Destroys the QFutureWatcher. */ /*! \fn void QFutureWatcher::cancel() Cancels the asynchronous computation represented by the future(). Note that the cancelation is asynchronous. Use waitForFinished() after calling cancel() when you need synchronous cancelation. Currently available results may still be accessed on a canceled QFuture, but new results will \e not become available after calling this function. Also, this QFutureWatcher will not deliver progress and result ready signals once canceled. This includes the progressValueChanged(), progressRangeChanged(), progressTextChanged(), resultReadyAt(), and resultsReadyAt() signals. Be aware that not all asynchronous computations can be canceled. For example, the QFuture returned by QtConcurrent::run() cannot be canceled; but the QFuture returned by QtConcurrent::mappedReduced() can. */ void QFutureWatcherBase::cancel() { futureInterface().cancel(); } /*! \fn void QFutureWatcher::setPaused(bool paused) If \a paused is true, this function pauses the asynchronous computation represented by the future(). If the computation is already paused, this function does nothing. This QFutureWatcher will stop delivering progress and result ready signals while the future is paused. Signal delivery will continue once the computation is resumed. If \a paused is false, this function resumes the asynchronous computation. If the computation was not previously paused, this function does nothing. Be aware that not all computations can be paused. For example, the QFuture returned by QtConcurrent::run() cannot be paused; but the QFuture returned by QtConcurrent::mappedReduced() can. \sa pause(), resume(), togglePaused() */ void QFutureWatcherBase::setPaused(bool paused) { futureInterface().setPaused(paused); } /*! \fn void QFutureWatcher::pause() Pauses the asynchronous computation represented by the future(). This is a convenience method that simply calls setPaused(true). \sa resume() */ void QFutureWatcherBase::pause() { futureInterface().setPaused(true); } /*! \fn void QFutureWatcher::resume() Resumes the asynchronous computation represented by the future(). This is a convenience method that simply calls setPaused(false). \sa pause() */ void QFutureWatcherBase::resume() { futureInterface().setPaused(false); } /*! \fn void QFutureWatcher::togglePaused() Toggles the paused state of the asynchronous computation. In other words, if the computation is currently paused, calling this function resumes it; if the computation is running, it becomes paused. This is a convenience method for calling setPaused(!isPaused()). \sa setPaused(), pause(), resume() */ void QFutureWatcherBase::togglePaused() { futureInterface().togglePaused(); } /*! \fn int QFutureWatcher::progressValue() const Returns the current progress value, which is between the progressMinimum() and progressMaximum(). \sa progressMinimum(), progressMaximum() */ int QFutureWatcherBase::progressValue() const { return futureInterface().progressValue(); } /*! \fn int QFutureWatcher::progressMinimum() const Returns the minimum progressValue(). \sa progressValue(), progressMaximum() */ int QFutureWatcherBase::progressMinimum() const { return futureInterface().progressMinimum(); } /*! \fn int QFutureWatcher::progressMaximum() const Returns the maximum progressValue(). \sa progressValue(), progressMinimum() */ int QFutureWatcherBase::progressMaximum() const { return futureInterface().progressMaximum(); } /*! \fn QString QFutureWatcher::progressText() const Returns the (optional) textual representation of the progress as reported by the asynchronous computation. Be aware that not all computations provide a textual representation of the progress, and as such, this function may return an empty string. */ QString QFutureWatcherBase::progressText() const { return futureInterface().progressText(); } /*! \fn bool QFutureWatcher::isStarted() const Returns \c true if the asynchronous computation represented by the future() has been started; otherwise returns \c false. */ bool QFutureWatcherBase::isStarted() const { return futureInterface().queryState(QFutureInterfaceBase::Started); } /*! \fn bool QFutureWatcher::isFinished() const Returns \c true if the asynchronous computation represented by the future() has finished; otherwise returns \c false. */ bool QFutureWatcherBase::isFinished() const { Q_D(const QFutureWatcherBase); return d->finished; } /*! \fn bool QFutureWatcher::isRunning() const Returns \c true if the asynchronous computation represented by the future() is currently running; otherwise returns \c false. */ bool QFutureWatcherBase::isRunning() const { return futureInterface().queryState(QFutureInterfaceBase::Running); } /*! \fn bool QFutureWatcher::isCanceled() const Returns \c true if the asynchronous computation has been canceled with the cancel() function; otherwise returns \c false. Be aware that the computation may still be running even though this function returns \c true. See cancel() for more details. */ bool QFutureWatcherBase::isCanceled() const { return futureInterface().queryState(QFutureInterfaceBase::Canceled); } /*! \fn bool QFutureWatcher::isPaused() const Returns \c true if the asynchronous computation has been paused with the pause() function; otherwise returns \c false. Be aware that the computation may still be running even though this function returns \c true. See setPaused() for more details. \sa setPaused(), togglePaused() */ bool QFutureWatcherBase::isPaused() const { return futureInterface().queryState(QFutureInterfaceBase::Paused); } /*! \fn void QFutureWatcher::waitForFinished() Waits for the asynchronous computation to finish (including cancel()ed computations). */ void QFutureWatcherBase::waitForFinished() { futureInterface().waitForFinished(); } /*! \fn void QFutureWatcher::setPendingResultsLimit(int limit) The setPendingResultsLimit() provides throttling control. When the number of pending resultReadyAt() or resultsReadyAt() signals exceeds the \a limit, the computation represented by the future will be throttled automatically. The computation will resume once the number of pending signals drops below the \a limit. */ bool QFutureWatcherBase::event(QEvent *event) { Q_D(QFutureWatcherBase); if (event->type() == QEvent::FutureCallOut) { QFutureCallOutEvent *callOutEvent = static_cast(event); if (futureInterface().isPaused()) { d->pendingCallOutEvents.append(callOutEvent->clone()); return true; } if (callOutEvent->callOutType == QFutureCallOutEvent::Resumed && !d->pendingCallOutEvents.isEmpty()) { // send the resume d->sendCallOutEvent(callOutEvent); // next send all pending call outs for (int i = 0; i < d->pendingCallOutEvents.count(); ++i) d->sendCallOutEvent(d->pendingCallOutEvents.at(i)); qDeleteAll(d->pendingCallOutEvents); d->pendingCallOutEvents.clear(); } else { d->sendCallOutEvent(callOutEvent); } return true; } return QObject::event(event); } void QFutureWatcherBase::setPendingResultsLimit(int limit) { Q_D(QFutureWatcherBase); d->maximumPendingResultsReady = limit; } void QFutureWatcherBase::connectNotify(const QMetaMethod &signal) { Q_D(QFutureWatcherBase); static const QMetaMethod resultReadyAtSignal = QMetaMethod::fromSignal(&QFutureWatcherBase::resultReadyAt); if (signal == resultReadyAtSignal) d->resultAtConnected.ref(); #ifndef QT_NO_DEBUG static const QMetaMethod finishedSignal = QMetaMethod::fromSignal(&QFutureWatcherBase::finished); if (signal == finishedSignal) { if (futureInterface().isRunning()) { //connections should be established before calling stFuture to avoid race. // (The future could finish before the connection is made.) qWarning("QFutureWatcher::connect: connecting after calling setFuture() is likely to produce race"); } } #endif } void QFutureWatcherBase::disconnectNotify(const QMetaMethod &signal) { Q_D(QFutureWatcherBase); static const QMetaMethod resultReadyAtSignal = QMetaMethod::fromSignal(&QFutureWatcherBase::resultReadyAt); if (signal == resultReadyAtSignal) d->resultAtConnected.deref(); } /*! \internal */ QFutureWatcherBasePrivate::QFutureWatcherBasePrivate() : maximumPendingResultsReady(QThread::idealThreadCount() * 2), resultAtConnected(0) { } /*! \internal */ void QFutureWatcherBase::connectOutputInterface() { futureInterface().d->connectOutputInterface(d_func()); } /*! \internal */ void QFutureWatcherBase::disconnectOutputInterface(bool pendingAssignment) { if (pendingAssignment) { Q_D(QFutureWatcherBase); d->pendingResultsReady.store(0); qDeleteAll(d->pendingCallOutEvents); d->pendingCallOutEvents.clear(); d->finished = false; } futureInterface().d->disconnectOutputInterface(d_func()); } void QFutureWatcherBasePrivate::postCallOutEvent(const QFutureCallOutEvent &callOutEvent) { Q_Q(QFutureWatcherBase); if (callOutEvent.callOutType == QFutureCallOutEvent::ResultsReady) { if (pendingResultsReady.fetchAndAddRelaxed(1) >= maximumPendingResultsReady) q->futureInterface().d->internal_setThrottled(true); } QCoreApplication::postEvent(q, callOutEvent.clone()); } void QFutureWatcherBasePrivate::callOutInterfaceDisconnected() { QCoreApplication::removePostedEvents(q_func(), QEvent::FutureCallOut); } void QFutureWatcherBasePrivate::sendCallOutEvent(QFutureCallOutEvent *event) { Q_Q(QFutureWatcherBase); switch (event->callOutType) { case QFutureCallOutEvent::Started: emit q->started(); break; case QFutureCallOutEvent::Finished: finished = true; emit q->finished(); break; case QFutureCallOutEvent::Canceled: pendingResultsReady.store(0); emit q->canceled(); break; case QFutureCallOutEvent::Paused: if (q->futureInterface().isCanceled()) break; emit q->paused(); break; case QFutureCallOutEvent::Resumed: if (q->futureInterface().isCanceled()) break; emit q->resumed(); break; case QFutureCallOutEvent::ResultsReady: { if (q->futureInterface().isCanceled()) break; if (pendingResultsReady.fetchAndAddRelaxed(-1) <= maximumPendingResultsReady) q->futureInterface().setThrottled(false); const int beginIndex = event->index1; const int endIndex = event->index2; emit q->resultsReadyAt(beginIndex, endIndex); if (resultAtConnected.load() <= 0) break; for (int i = beginIndex; i < endIndex; ++i) emit q->resultReadyAt(i); } break; case QFutureCallOutEvent::Progress: if (q->futureInterface().isCanceled()) break; emit q->progressValueChanged(event->index1); if (!event->text.isNull()) // ### q->progressTextChanged(event->text); break; case QFutureCallOutEvent::ProgressRange: emit q->progressRangeChanged(event->index1, event->index2); break; default: break; } } /*! \fn const T &QFutureWatcher::result() const Returns the first result in the future(). If the result is not immediately available, this function will block and wait for the result to become available. This is a convenience method for calling resultAt(0). \sa resultAt() */ /*! \fn const T &QFutureWatcher::resultAt(int index) const Returns the result at \a index in the future(). If the result is not immediately available, this function will block and wait for the result to become available. \sa result() */ /*! \fn void QFutureWatcher::setFuture(const QFuture &future) Starts watching the given \a future. One of the signals might be emitted for the current state of the \a future. For example, if the future is already stopped, the finished signal will be emitted. To avoid a race condition, it is important to call this function \e after doing the connections. */ /*! \fn QFuture QFutureWatcher::future() const Returns the watched future. */ /*! \fn void QFutureWatcher::started() This signal is emitted when this QFutureWatcher starts watching the future set with setFuture(). */ /*! \fn void QFutureWatcher::finished() This signal is emitted when the watched future finishes. */ /*! \fn void QFutureWatcher::canceled() This signal is emitted if the watched future is canceled. */ /*! \fn void QFutureWatcher::paused() This signal is emitted when the watched future is paused. */ /*! \fn void QFutureWatcher::resumed() This signal is emitted when the watched future is resumed. */ /*! \fn void QFutureWatcher::progressRangeChanged(int minimum, int maximum) The progress range for the watched future has changed to \a minimum and \a maximum */ /*! \fn void QFutureWatcher::progressValueChanged(int progressValue) This signal is emitted when the watched future reports progress, \a progressValue gives the current progress. In order to avoid overloading the GUI event loop, QFutureWatcher limits the progress signal emission rate. This means that listeners connected to this slot might not get all progress reports the future makes. The last progress update (where \a progressValue equals the maximum value) will always be delivered. */ /*! \fn void QFutureWatcher::progressTextChanged(const QString &progressText) This signal is emitted when the watched future reports textual progress information, \a progressText. */ /*! \fn void QFutureWatcher::resultReadyAt(int index) This signal is emitted when the watched future reports a ready result at \a index. If the future reports multiple results, the index will indicate which one it is. Results can be reported out-of-order. To get the result, call future().result(index); */ /*! \fn void QFutureWatcher::resultsReadyAt(int beginIndex, int endIndex); This signal is emitted when the watched future reports ready results. The results are indexed from \a beginIndex to \a endIndex. */ QT_END_NAMESPACE #endif // QT_NO_QFUTURE