/**************************************************************************** ** ** Copyright (C) 2011 Nokia Corporation and/or its subsidiary(-ies). ** All rights reserved. ** Contact: Nokia Corporation (qt-info@nokia.com) ** ** This file is part of the QtCore module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage ** This file contains pre-release code and may not be distributed. ** You may use this file in accordance with the terms and conditions ** contained in the Technology Preview License Agreement accompanying ** this package. ** ** 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, Nokia gives you certain additional ** rights. These rights are described in the Nokia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** If you have questions regarding the use of this file, please contact ** Nokia at qt-info@nokia.com. ** ** ** ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #ifndef QTCONCURRENT_ITERATEKERNEL_H #define QTCONCURRENT_ITERATEKERNEL_H #include #ifndef QT_NO_CONCURRENT #include #include #include #ifndef QT_NO_STL # include #endif QT_BEGIN_HEADER QT_BEGIN_NAMESPACE QT_MODULE(Core) #ifndef qdoc namespace QtConcurrent { #ifndef QT_NO_STL using std::advance; #else template void advance(It &it, T value) { it+=value; } #endif /* The BlockSizeManager class manages how many iterations a thread should reserve and process at a time. This is done by measuring the time spent in the user code versus the control part code, and then increasing the block size if the ratio between them is to small. The block size management is done on the basis of the median of several timing measuremens, and it is done induvidualy for each thread. */ class Q_CORE_EXPORT BlockSizeManager { public: BlockSizeManager(int iterationCount); void timeBeforeUser(); void timeAfterUser(); int blockSize(); private: inline bool blockSizeMaxed() { return (m_blockSize >= maxBlockSize); } const int maxBlockSize; qint64 beforeUser; qint64 afterUser; Median controlPartElapsed; Median userPartElapsed; int m_blockSize; }; template class ResultReporter { public: ResultReporter(ThreadEngine *_threadEngine) :threadEngine(_threadEngine) { } void reserveSpace(int resultCount) { currentResultCount = resultCount; vector.resize(qMax(resultCount, vector.count())); } void reportResults(int begin) { const int useVectorThreshold = 4; // Tunable parameter. if (currentResultCount > useVectorThreshold) { vector.resize(currentResultCount); threadEngine->reportResults(vector, begin); } else { for (int i = 0; i < currentResultCount; ++i) threadEngine->reportResult(&vector.at(i), begin + i); } } inline T * getPointer() { return vector.data(); } int currentResultCount; ThreadEngine *threadEngine; QVector vector; }; template <> class ResultReporter { public: inline ResultReporter(ThreadEngine *) { } inline void reserveSpace(int) { }; inline void reportResults(int) { }; inline void * getPointer() { return 0; } }; #ifndef QT_NO_STL inline bool selectIteration(std::bidirectional_iterator_tag) { return false; // while } inline bool selectIteration(std::forward_iterator_tag) { return false; // while } inline bool selectIteration(std::random_access_iterator_tag) { return true; // for } #else // no stl support, always use while iteration template inline bool selectIteration(T) { return false; // while } #endif template class IterateKernel : public ThreadEngine { public: typedef T ResultType; IterateKernel(Iterator _begin, Iterator _end) #if defined (QT_NO_STL) : begin(_begin), end(_end), current(_begin), currentIndex(0), forIteration(false), progressReportingEnabled(true) #elif !defined(QT_NO_PARTIAL_TEMPLATE_SPECIALIZATION) : begin(_begin), end(_end), current(_begin), currentIndex(0), forIteration(selectIteration(typename std::iterator_traits::iterator_category())), progressReportingEnabled(true) #else : begin(_begin), end(_end), currentIndex(0), forIteration(selectIteration(std::iterator_category(_begin))), progressReportingEnabled(true) #endif { #if defined (QT_NO_STL) iterationCount = 0; #else iterationCount = forIteration ? std::distance(_begin, _end) : 0; #endif } virtual ~IterateKernel() { } virtual bool runIteration(Iterator it, int index , T *result) { Q_UNUSED(it); Q_UNUSED(index); Q_UNUSED(result); return false; } virtual bool runIterations(Iterator _begin, int beginIndex, int endIndex, T *results) { Q_UNUSED(_begin); Q_UNUSED(beginIndex); Q_UNUSED(endIndex); Q_UNUSED(results); return false; } void start() { progressReportingEnabled = this->isProgressReportingEnabled(); if (progressReportingEnabled && iterationCount > 0) this->setProgressRange(0, iterationCount); } bool shouldStartThread() { if (forIteration) return (currentIndex < iterationCount) && !this->shouldThrottleThread(); else // whileIteration return (iteratorThreads == 0); } ThreadFunctionResult threadFunction() { if (forIteration) return this->forThreadFunction(); else // whileIteration return this->whileThreadFunction(); } ThreadFunctionResult forThreadFunction() { BlockSizeManager blockSizeManager(iterationCount); ResultReporter resultReporter(this); for(;;) { if (this->isCanceled()) break; const int currentBlockSize = blockSizeManager.blockSize(); if (currentIndex >= iterationCount) break; // Atomically reserve a block of iterationCount for this thread. const int beginIndex = currentIndex.fetchAndAddRelease(currentBlockSize); const int endIndex = qMin(beginIndex + currentBlockSize, iterationCount); if (beginIndex >= endIndex) { // No more work break; } this->waitForResume(); // (only waits if the qfuture is paused.) if (shouldStartThread()) this->startThread(); const int finalBlockSize = endIndex - beginIndex; // block size adjusted for possible end-of-range resultReporter.reserveSpace(finalBlockSize); // Call user code with the current iteration range. blockSizeManager.timeBeforeUser(); const bool resultsAvailable = this->runIterations(begin, beginIndex, endIndex, resultReporter.getPointer()); blockSizeManager.timeAfterUser(); if (resultsAvailable) resultReporter.reportResults(beginIndex); // Report progress if progress reporting enabled. if (progressReportingEnabled) { completed.fetchAndAddAcquire(finalBlockSize); this->setProgressValue(this->completed); } if (this->shouldThrottleThread()) return ThrottleThread; } return ThreadFinished; } ThreadFunctionResult whileThreadFunction() { if (iteratorThreads.testAndSetAcquire(0, 1) == false) return ThreadFinished; ResultReporter resultReporter(this); resultReporter.reserveSpace(1); while (current != end) { // The following two lines breaks support for input iterators according to // the sgi docs: dereferencing prev after calling ++current is not allowed // on input iterators. (prev is dereferenced inside user.runIteration()) Iterator prev = current; ++current; int index = currentIndex.fetchAndAddRelaxed(1); iteratorThreads.testAndSetRelease(1, 0); this->waitForResume(); // (only waits if the qfuture is paused.) if (shouldStartThread()) this->startThread(); const bool resultAavailable = this->runIteration(prev, index, resultReporter.getPointer()); if (resultAavailable) resultReporter.reportResults(index); if (this->shouldThrottleThread()) return ThrottleThread; if (iteratorThreads.testAndSetAcquire(0, 1) == false) return ThreadFinished; } return ThreadFinished; } public: const Iterator begin; const Iterator end; Iterator current; QAtomicInt currentIndex; bool forIteration; QAtomicInt iteratorThreads; int iterationCount; bool progressReportingEnabled; QAtomicInt completed; }; } // namespace QtConcurrent #endif //qdoc QT_END_NAMESPACE QT_END_HEADER #endif // QT_NO_CONCURRENT #endif