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** This file is part of the test suite of the Qt Toolkit.
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** contained in the Technology Preview License Agreement accompanying
** this package.
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** General Public License version 2.1 as published by the Free Software
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#include <QtTest/QtTest>
#include <qdatetime.h>
#include <qthreadpool.h>
#include <qstring.h>
#include <qmutex.h>
typedef void (*FunctionPointer)();
class FunctionPointerTask : public QRunnable
{
public:
FunctionPointerTask(FunctionPointer function)
:function(function) {}
void run() { function(); }
private:
FunctionPointer function;
};
QRunnable *createTask(FunctionPointer pointer)
{
return new FunctionPointerTask(pointer);
}
class tst_QThreadPool : public QObject
{
Q_OBJECT
private slots:
void runFunction();
void createThreadRunFunction();
void runMultiple();
void waitcomplete();
void runTask();
void singleton();
void destruction();
void threadRecycling();
void expiryTimeout();
void exceptions();
void maxThreadCount();
void setMaxThreadCount_data();
void setMaxThreadCount();
void setMaxThreadCountStartsAndStopsThreads();
void activeThreadCount();
void reserveThread_data();
void reserveThread();
void releaseThread_data();
void releaseThread();
void start();
void tryStart();
void tryStartPeakThreadCount();
void tryStartCount();
void waitForDone();
void destroyingWaitsForTasksToFinish();
void stressTest();
};
int testFunctionCount;
void sleepTestFunction()
{
QTest::qSleep(1000);
++testFunctionCount;
}
void emptyFunct()
{
}
void noSleepTestFunction()
{
++testFunctionCount;
}
void sleepTestFunctionMutex()
{
static QMutex testMutex;
QTest::qSleep(1000);
testMutex.lock();
++testFunctionCount;
testMutex.unlock();
}
void noSleepTestFunctionMutex()
{
static QMutex testMutex;
testMutex.lock();
++testFunctionCount;
testMutex.unlock();
}
void tst_QThreadPool::runFunction()
{
{
QThreadPool manager;
testFunctionCount = 0;
manager.start(createTask(noSleepTestFunction));
}
QCOMPARE(testFunctionCount, 1);
}
void tst_QThreadPool::createThreadRunFunction()
{
{
QThreadPool manager;
testFunctionCount = 0;
manager.start(createTask(noSleepTestFunction));
}
QCOMPARE(testFunctionCount, 1);
}
void tst_QThreadPool::runMultiple()
{
const int runs = 10;
{
QThreadPool manager;
testFunctionCount = 0;
for (int i = 0; i < runs; ++i) {
manager.start(createTask(sleepTestFunctionMutex));
}
}
QCOMPARE(testFunctionCount, runs);
{
QThreadPool manager;
testFunctionCount = 0;
for (int i = 0; i < runs; ++i) {
manager.start(createTask(noSleepTestFunctionMutex));
}
}
QCOMPARE(testFunctionCount, runs);
{
QThreadPool manager;
for (int i = 0; i < 500; ++i)
manager.start(createTask(emptyFunct));
}
}
void tst_QThreadPool::waitcomplete()
{
testFunctionCount = 0;
const int runs = 500;
for (int i = 0; i < 500; ++i) {
QThreadPool pool;
pool.start(createTask(noSleepTestFunction));
}
QCOMPARE(testFunctionCount, runs);
}
volatile bool ran;
class TestTask : public QRunnable
{
public:
void run()
{
ran = true;
}
};
void tst_QThreadPool::runTask()
{
QThreadPool manager;
ran = false;
manager.start(new TestTask());
// Hang if task is not runned.
while (ran == false)
QTest::qSleep(100); // no busy loop - this doesn't work with FIFO schedulers
}
/*
Test running via QThreadPool::globalInstance()
*/
void tst_QThreadPool::singleton()
{
ran = false;
QThreadPool::globalInstance()->start(new TestTask());
while (ran == false)
QTest::qSleep(100); // no busy loop - this doesn't work with FIFO schedulers
}
int *value = 0;
class IntAccessor : public QRunnable
{
public:
void run()
{
for (int i = 0; i < 100; ++i) {
++(*value);
QTest::qSleep(1);
}
}
};
/*
Test that the ThreadManager destructor waits until
all threads have completed.
*/
void tst_QThreadPool::destruction()
{
value = new int;
QThreadPool *threadManager = new QThreadPool();
threadManager->start(new IntAccessor());
threadManager->start(new IntAccessor());
delete threadManager;
delete value;
value = 0;
}
QSemaphore threadRecyclingSemaphore;
QThread *recycledThread = 0;
class ThreadRecorderTask : public QRunnable
{
public:
void run()
{
recycledThread = QThread::currentThread();
threadRecyclingSemaphore.release();
}
};
/*
Test that the thread pool really reuses threads.
*/
void tst_QThreadPool::threadRecycling()
{
QThreadPool threadPool;
threadPool.start(new ThreadRecorderTask());
threadRecyclingSemaphore.acquire();
QThread *thread1 = recycledThread;
QTest::qSleep(100);
threadPool.start(new ThreadRecorderTask());
threadRecyclingSemaphore.acquire();
QThread *thread2 = recycledThread;
QCOMPARE(thread1, thread2);
QTest::qSleep(100);
threadPool.start(new ThreadRecorderTask());
threadRecyclingSemaphore.acquire();
QThread *thread3 = recycledThread;
QCOMPARE(thread2, thread3);
}
class ExpiryTimeoutTask : public QRunnable
{
public:
QThread *thread;
int runCount;
QSemaphore semaphore;
ExpiryTimeoutTask()
: thread(0), runCount(0)
{
setAutoDelete(false);
}
void run()
{
thread = QThread::currentThread();
++runCount;
semaphore.release();
}
};
void tst_QThreadPool::expiryTimeout()
{
ExpiryTimeoutTask task;
QThreadPool threadPool;
threadPool.setMaxThreadCount(1);
int expiryTimeout = threadPool.expiryTimeout();
threadPool.setExpiryTimeout(1000);
QCOMPARE(threadPool.expiryTimeout(), 1000);
// run the task
threadPool.start(&task);
QVERIFY(task.semaphore.tryAcquire(1, 10000));
QCOMPARE(task.runCount, 1);
QVERIFY(!task.thread->wait(100));
// thread should expire
QThread *firstThread = task.thread;
QVERIFY(task.thread->wait(10000));
// run task again, thread should be restarted
threadPool.start(&task);
QVERIFY(task.semaphore.tryAcquire(1, 10000));
QCOMPARE(task.runCount, 2);
QVERIFY(!task.thread->wait(100));
// thread should expire again
QVERIFY(task.thread->wait(10000));
// thread pool should have reused the expired thread (instead of
// starting a new one)
QCOMPARE(firstThread, task.thread);
threadPool.setExpiryTimeout(expiryTimeout);
QCOMPARE(threadPool.expiryTimeout(), expiryTimeout);
}
#ifndef QT_NO_EXCEPTIONS
class ExceptionTask : public QRunnable
{
public:
void run()
{
throw new int;
}
};
#endif
void tst_QThreadPool::exceptions()
{
#ifndef QT_NO_EXCEPTIONS
ExceptionTask task;
{
QThreadPool threadPool;
// Uncomment this for a nice crash.
// threadPool.start(&task);
}
#else
QSKIP("No exception support", SkipAll);
#endif
}
void tst_QThreadPool::maxThreadCount()
{
DEPENDS_ON("setMaxThreadCount()");
}
void tst_QThreadPool::setMaxThreadCount_data()
{
QTest::addColumn<int>("limit");
QTest::newRow("") << 1;
QTest::newRow("") << -1;
QTest::newRow("") << 2;
QTest::newRow("") << -2;
QTest::newRow("") << 4;
QTest::newRow("") << -4;
QTest::newRow("") << 0;
QTest::newRow("") << 12345;
QTest::newRow("") << -6789;
QTest::newRow("") << 42;
QTest::newRow("") << -666;
}
void tst_QThreadPool::setMaxThreadCount()
{
QFETCH(int, limit);
QThreadPool *threadPool = QThreadPool::globalInstance();
int savedLimit = threadPool->maxThreadCount();
// maxThreadCount() should always return the previous argument to
// setMaxThreadCount(), regardless of input
threadPool->setMaxThreadCount(limit);
QCOMPARE(threadPool->maxThreadCount(), limit);
// the value returned from maxThreadCount() should always be valid input for setMaxThreadCount()
threadPool->setMaxThreadCount(savedLimit);
QCOMPARE(threadPool->maxThreadCount(), savedLimit);
// setting the limit on children should have no effect on the parent
{
QThreadPool threadPool2(threadPool);
savedLimit = threadPool2.maxThreadCount();
// maxThreadCount() should always return the previous argument to
// setMaxThreadCount(), regardless of input
threadPool2.setMaxThreadCount(limit);
QCOMPARE(threadPool2.maxThreadCount(), limit);
// the value returned from maxThreadCount() should always be valid input for setMaxThreadCount()
threadPool2.setMaxThreadCount(savedLimit);
QCOMPARE(threadPool2.maxThreadCount(), savedLimit);
}
}
void tst_QThreadPool::setMaxThreadCountStartsAndStopsThreads()
{
class WaitingTask : public QRunnable
{
public:
QSemaphore waitForStarted, waitToFinish;
WaitingTask() { setAutoDelete(false); }
void run()
{
waitForStarted.release();
waitToFinish.acquire();
}
};
QThreadPool threadPool;
threadPool.setMaxThreadCount(1);
WaitingTask *task = new WaitingTask;
threadPool.start(task);
QVERIFY(task->waitForStarted.tryAcquire(1, 1000));
// thread limit is 1, cannot start more tasks
threadPool.start(task);
QVERIFY(!task->waitForStarted.tryAcquire(1, 1000));
// increasing the limit by 1 should start the task immediately
threadPool.setMaxThreadCount(2);
QVERIFY(task->waitForStarted.tryAcquire(1, 1000));
// ... but we still cannot start more tasks
threadPool.start(task);
QVERIFY(!task->waitForStarted.tryAcquire(1, 1000));
// increasing the limit should be able to start more than one at a time
threadPool.start(task);
threadPool.setMaxThreadCount(4);
QVERIFY(task->waitForStarted.tryAcquire(2, 1000));
// ... but we still cannot start more tasks
threadPool.start(task);
threadPool.start(task);
QVERIFY(!task->waitForStarted.tryAcquire(2, 1000));
// decreasing the thread limit should cause the active thread count to go down
threadPool.setMaxThreadCount(2);
QCOMPARE(threadPool.activeThreadCount(), 4);
task->waitToFinish.release(2);
QTest::qWait(1000);
QCOMPARE(threadPool.activeThreadCount(), 2);
// ... and we still cannot start more tasks
threadPool.start(task);
threadPool.start(task);
QVERIFY(!task->waitForStarted.tryAcquire(2, 1000));
// start all remaining tasks
threadPool.start(task);
threadPool.start(task);
threadPool.start(task);
threadPool.start(task);
threadPool.setMaxThreadCount(8);
QVERIFY(task->waitForStarted.tryAcquire(6, 1000));
task->waitToFinish.release(10);
// delete task;
}
void tst_QThreadPool::activeThreadCount()
{
DEPENDS_ON("tryReserveThread()");
DEPENDS_ON("reserveThread()");
DEPENDS_ON("releaseThread()");
}
void tst_QThreadPool::reserveThread_data()
{
setMaxThreadCount_data();
}
void tst_QThreadPool::reserveThread()
{
QFETCH(int, limit);
QThreadPool *threadpool = QThreadPool::globalInstance();
int savedLimit = threadpool->maxThreadCount();
threadpool->setMaxThreadCount(limit);
// reserve up to the limit
for (int i = 0; i < limit; ++i)
threadpool->reserveThread();
// reserveThread() should always reserve a thread, regardless of
// how many have been previously reserved
threadpool->reserveThread();
QCOMPARE(threadpool->activeThreadCount(), (limit > 0 ? limit : 0) + 1);
threadpool->reserveThread();
QCOMPARE(threadpool->activeThreadCount(), (limit > 0 ? limit : 0) + 2);
// cleanup
threadpool->releaseThread();
threadpool->releaseThread();
for (int i = 0; i < limit; ++i)
threadpool->releaseThread();
// reserving threads in children should not effect the parent
{
QThreadPool threadpool2(threadpool);
threadpool2.setMaxThreadCount(limit);
// reserve up to the limit
for (int i = 0; i < limit; ++i)
threadpool2.reserveThread();
// reserveThread() should always reserve a thread, regardless
// of how many have been previously reserved
threadpool2.reserveThread();
QCOMPARE(threadpool2.activeThreadCount(), (limit > 0 ? limit : 0) + 1);
threadpool2.reserveThread();
QCOMPARE(threadpool2.activeThreadCount(), (limit > 0 ? limit : 0) + 2);
threadpool->reserveThread();
QCOMPARE(threadpool->activeThreadCount(), 1);
threadpool->reserveThread();
QCOMPARE(threadpool->activeThreadCount(), 2);
// cleanup
threadpool2.releaseThread();
threadpool2.releaseThread();
threadpool->releaseThread();
threadpool->releaseThread();
while (threadpool2.activeThreadCount() > 0)
threadpool2.releaseThread();
}
// reset limit on global QThreadPool
threadpool->setMaxThreadCount(savedLimit);
}
void tst_QThreadPool::releaseThread_data()
{
setMaxThreadCount_data();
}
void tst_QThreadPool::releaseThread()
{
QFETCH(int, limit);
QThreadPool *threadpool = QThreadPool::globalInstance();
int savedLimit = threadpool->maxThreadCount();
threadpool->setMaxThreadCount(limit);
// reserve up to the limit
for (int i = 0; i < limit; ++i)
threadpool->reserveThread();
// release should decrease the number of reserved threads
int reserved = threadpool->activeThreadCount();
while (reserved-- > 0) {
threadpool->releaseThread();
QCOMPARE(threadpool->activeThreadCount(), reserved);
}
QCOMPARE(threadpool->activeThreadCount(), 0);
// releaseThread() can release more than have been reserved
threadpool->releaseThread();
QCOMPARE(threadpool->activeThreadCount(), -1);
threadpool->reserveThread();
QCOMPARE(threadpool->activeThreadCount(), 0);
// releasing threads in children should not effect the parent
{
QThreadPool threadpool2(threadpool);
threadpool2.setMaxThreadCount(limit);
// reserve up to the limit
for (int i = 0; i < limit; ++i)
threadpool2.reserveThread();
// release should decrease the number of reserved threads
int reserved = threadpool2.activeThreadCount();
while (reserved-- > 0) {
threadpool2.releaseThread();
QCOMPARE(threadpool2.activeThreadCount(), reserved);
QCOMPARE(threadpool->activeThreadCount(), 0);
}
QCOMPARE(threadpool2.activeThreadCount(), 0);
QCOMPARE(threadpool->activeThreadCount(), 0);
// releaseThread() can release more than have been reserved
threadpool2.releaseThread();
QCOMPARE(threadpool2.activeThreadCount(), -1);
QCOMPARE(threadpool->activeThreadCount(), 0);
threadpool2.reserveThread();
QCOMPARE(threadpool2.activeThreadCount(), 0);
QCOMPARE(threadpool->activeThreadCount(), 0);
}
// reset limit on global QThreadPool
threadpool->setMaxThreadCount(savedLimit);
}
QAtomicInt count;
class CountingRunnable : public QRunnable
{
public: void run()
{
count.ref();
}
};
void tst_QThreadPool::start()
{
const int runs = 1000;
count = 0;
{
QThreadPool threadPool;
for (int i = 0; i< runs; ++i) {
threadPool.start(new CountingRunnable());
}
}
QCOMPARE(int(count), runs);
}
void tst_QThreadPool::tryStart()
{
class WaitingTask : public QRunnable
{
public:
QSemaphore semaphore;
WaitingTask() { setAutoDelete(false); }
void run()
{
semaphore.acquire();
count.ref();
}
};
count = 0;
WaitingTask task;
QThreadPool threadPool;
for (int i = 0; i < threadPool.maxThreadCount(); ++i) {
threadPool.start(&task);
}
QVERIFY(!threadPool.tryStart(&task));
task.semaphore.release(threadPool.maxThreadCount());
threadPool.waitForDone();
QCOMPARE(int(count), threadPool.maxThreadCount());
}
QMutex mutex;
int activeThreads = 0;
int peakActiveThreads = 0;
void tst_QThreadPool::tryStartPeakThreadCount()
{
class CounterTask : public QRunnable
{
public:
CounterTask() { setAutoDelete(false); }
void run()
{
{
QMutexLocker lock(&mutex);
++activeThreads;
peakActiveThreads = qMax(peakActiveThreads, activeThreads);
}
QTest::qWait(100);
{
QMutexLocker lock(&mutex);
--activeThreads;
}
}
};
CounterTask task;
QThreadPool threadPool;
for (int i = 0; i < 20; ++i) {
if (threadPool.tryStart(&task) == false)
QTest::qWait(10);
}
QCOMPARE(peakActiveThreads, QThread::idealThreadCount());
for (int i = 0; i < 20; ++i) {
if (threadPool.tryStart(&task) == false)
QTest::qWait(10);
}
QCOMPARE(peakActiveThreads, QThread::idealThreadCount());
}
void tst_QThreadPool::tryStartCount()
{
class SleeperTask : public QRunnable
{
public:
SleeperTask() { setAutoDelete(false); }
void run()
{
QTest::qWait(50);
}
};
SleeperTask task;
QThreadPool threadPool;
const int runs = 5;
for (int i = 0; i < runs; ++i) {
// qDebug() << "iteration" << i;
int count = 0;
while (threadPool.tryStart(&task))
++count;
QCOMPARE(count, QThread::idealThreadCount());
QTest::qWait(100);
}
}
void tst_QThreadPool::waitForDone()
{
QTime total, pass;
total.start();
QThreadPool threadPool;
while (total.elapsed() < 10000) {
int runs;
runs = count = 0;
pass.restart();
while (pass.elapsed() < 100) {
threadPool.start(new CountingRunnable());
++runs;
}
threadPool.waitForDone();
QCOMPARE(int(count), runs);
runs = count = 0;
pass.restart();
while (pass.elapsed() < 100) {
threadPool.start(new CountingRunnable());
threadPool.start(new CountingRunnable());
runs += 2;
}
threadPool.waitForDone();
QCOMPARE(int(count), runs);
}
}
void tst_QThreadPool::destroyingWaitsForTasksToFinish()
{
QTime total, pass;
total.start();
while (total.elapsed() < 10000) {
int runs;
runs = count = 0;
{
QThreadPool threadPool;
pass.restart();
while (pass.elapsed() < 100) {
threadPool.start(new CountingRunnable());
++runs;
}
}
QCOMPARE(int(count), runs);
runs = count = 0;
{
QThreadPool threadPool;
pass.restart();
while (pass.elapsed() < 100) {
threadPool.start(new CountingRunnable());
threadPool.start(new CountingRunnable());
runs += 2;
}
}
QCOMPARE(int(count), runs);
}
}
void tst_QThreadPool::stressTest()
{
class Task : public QRunnable
{
QSemaphore semaphore;
public:
Task() { setAutoDelete(false); }
void start()
{
QThreadPool::globalInstance()->start(this);
}
void wait()
{
semaphore.acquire();
}
void run()
{
semaphore.release();
}
};
QTime total;
total.start();
while (total.elapsed() < 30000) {
Task t;
t.start();
t.wait();
}
}
QTEST_MAIN(tst_QThreadPool);
#include "tst_qthreadpool.moc"