I just wrote a task queue in Python whose job is to limit the number of tasks that are run at one time. This is a little different than
Queue.Queue because instead of limiting how many items can be in the queue, it limits how many can be taken out at one time. It still uses an unbounded
Queue.Queue to do its job, but it relies on a
Semaphore to limit the number of threads:
from Queue import Queue from threading import BoundedSemaphore, Lock, Thread class TaskQueue(object): """ Queues tasks to be run in separate threads and limits the number concurrently running tasks. """ def __init__(self, limit): """Initializes a new instance of a TaskQueue.""" self.__semaphore = BoundedSemaphore(limit) self.__queue = Queue() self.__cancelled = False self.__lock = Lock() def enqueue(self, callback): """Indicates that the given callback should be ran.""" self.__queue.put(callback) def start(self): """Tells the task queue to start running the queued tasks.""" thread = Thread(target=self.__process_items) thread.start() def stop(self): self.__cancel() # prevent blocking on a semaphore.acquire self.__semaphore.release() # prevent blocking on a Queue.get self.__queue.put(lambda: None) def __cancel(self): print 'canceling' with self.__lock: self.__cancelled = True def __process_items(self): while True: # see if the queue has been stopped before blocking on acquire if self.__is_canceled(): break self.__semaphore.acquire() # see if the queue has been stopped before blocking on get if self.__is_canceled(): break callback = self.__queue.get() # see if the queue has been stopped before running the task if self.__is_canceled(): break def runTask(): try: callback() finally: self.__semaphore.release() thread = Thread(target=runTask) thread.start() self.__queue.task_done() def __is_canceled(self): with self.__lock: return self.__cancelled
The Python interpreter runs forever unless I explicitly stop the task queue. This is a lot more tricky than I thought it would be. If you look at the
stop method, you'll see that I set a
release the semaphore and
put a no-op callback on the queue. The last two parts are necessary because the code could be blocking on the
Semaphore or on the
Queue. I basically have to force these to go through so that the loop has a chance to break out.
This code works. This class is useful when running a service that is trying to run thousands of tasks in parallel. In order to keep the machine running smoothly and to prevent the OS from screaming about too many active threads, this code will limit the number of threads living at any one time.
I have written a similar chunk of code in C# before. What made that code particular cut 'n' dry was that .NET has something called a
CancellationToken that just about every threading class uses. Any time there is a blocking operation, that operation takes an optional token. If the parent task is ever canceled, any child tasks blocking with that token will be immediately canceled, as well. This seems like a much cleaner way to exit than to "fake it" by releasing semaphores or putting values in a queue.
I was wondering if there was an equivalent way of doing this in Python? I definitely want to be using threads instead of something like asynchronous events. I am wondering if there is a way to achieve the same thing using two
Queue.Queues where one is has a max size and the other doesn't - but I'm still not sure how to handle cancellation.