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The QWaitCondition class provides a condition variable for synchronizing threads. More...
The QWaitCondition class provides a condition variable for synchronizing threads.
QWaitCondition allows a thread to tell other threads that some sort of condition has been met. One or many threads can block waiting for a QWaitCondition to set a condition with wakeOne() or wakeAll(). Use wakeOne() to wake one randomly selected condition or wakeAll() to wake them all.
For example, let's suppose that we have three tasks that should be performed whenever the user presses a key. Each task could be split into a thread, each of which would have a run() body like this:
forever { mutex.lock(); keyPressed.wait(&mutex); do_something(); mutex.unlock(); }
Here, the keyPressed variable is a global variable of type QWaitCondition.
A fourth thread would read key presses and wake the other three threads up every time it receives one, like this:
forever {
getchar();
keyPressed.wakeAll();
}
The order in which the three threads are woken up is undefined. Also, if some of the threads are still in do_something() when the key is pressed, they won't be woken up (since they're not waiting on the condition variable) and so the task will not be performed for that key press. This issue can be solved using a counter and a QMutex to guard it. For example, here's the new code for the worker threads:
forever { mutex.lock(); keyPressed.wait(&mutex); ++count; mutex.unlock(); do_something(); mutex.lock(); --count; mutex.unlock(); }
Here's the code for the fourth thread:
forever { getchar(); mutex.lock(); // Sleep until there are no busy worker threads while (count > 0) { mutex.unlock(); sleep(1); mutex.lock(); } keyPressed.wakeAll(); mutex.unlock(); }
The mutex is necessary because the results of two threads attempting to change the value of the same variable simultaneously are unpredictable.
Wait conditions are a powerful thread synchronization primitive. The Wait Conditions example shows how to use QWaitCondition as an alternative to QSemaphore for controlling access to a circular buffer shared by a producer thread and a consumer thread.
Constructs a new wait condition object.
Releases the locked mutex and waits on the wait condition. The mutex must be initially locked by the calling thread. If mutex is not in a locked state, this function returns immediately. If mutex is a recursive mutex, this function returns immediately. The mutex will be unlocked, and the calling thread will block until either of these conditions is met:
The mutex will be returned to the same locked state. This function is provided to allow the atomic transition from the locked state to the wait state.
See also wakeOne() and wakeAll().
Releases the locked readWriteLock and waits on the wait condition. The readWriteLock must be initially locked by the calling thread. If readWriteLock is not in a locked state, this function returns immediately. The readWriteLock must not be locked recursively, otherwise this function will not release the lock properly. The readWriteLock will be unlocked, and the calling thread will block until either of these conditions is met:
The readWriteLock will be returned to the same locked state. This function is provided to allow the atomic transition from the locked state to the wait state.
This function was introduced in Qt 4.4.
See also wakeOne() and wakeAll().
Wakes all threads waiting on the wait condition. The order in which the threads are woken up depends on the operating system's scheduling policies and cannot be controlled or predicted.
See also wakeOne().
Wakes one thread waiting on the wait condition. The thread that is woken up depends on the operating system's scheduling policies, and cannot be controlled or predicted.
If you want to wake up a specific thread, the solution is typically to use different wait conditions and have different threads wait on different conditions.
See also wakeAll().
PyQt 4.10.1 for MacOS | Copyright © Riverbank Computing Ltd and Nokia 2012 | Qt 4.8.4 |