"""Easy to use object-oriented thread pool framework. A thread pool is an object that maintains a pool of worker threads to perform time consuming operations in parallel. It assigns jobs to the threads by putting them in a work request queue, where they are picked up by the next available thread. This then performs the requested operation in the background and puts the results in a another queue. The thread pool object can then collect the results from all threads from this queue as soon as they become available or after all threads have finished their work. It's also possible, to define callbacks to handle each result as it comes in. The basic concept and some code was taken from the book "Python in a Nutshell" by Alex Martelli, copyright 2003, ISBN 0-596-00188-6, from section 14.5 "Threaded Program Architecture". I wrapped the main program logic in the ThreadPool class, added the WorkRequest class and the callback system and tweaked the code here and there. Kudos also to Florent Aide for the exception handling mechanism. Basic usage: >>> pool = TreadPool(poolsize) >>> requests = makeRequests(some_callable, list_of_args, callback) >>> [pool.putRequest(req) for req in requests] >>> pool.wait() See the end of the module code for a brief, annotated usage example. Website : http://chrisarndt.de/en/software/python/threadpool/ """ __all__ = [ 'makeRequests', 'NoResultsPending', 'NoWorkersAvailable', 'ThreadPool', 'WorkRequest', 'WorkerThread' ] __author__ = "Christopher Arndt" __version__ = "1.2.3" __revision__ = "$Revision: 1.5 $" __date__ = "$Date: 2006/06/23 12:32:25 $" __license__ = 'Python license' # standard library modules import sys import threading import Queue # exceptions class NoResultsPending(Exception): """All work requests have been processed.""" pass class NoWorkersAvailable(Exception): """No worker threads available to process remaining requests.""" pass # classes class WorkerThread(threading.Thread): """Background thread connected to the requests/results queues. A worker thread sits in the background and picks up work requests from one queue and puts the results in another until it is dismissed. """ def __init__(self, requestsQueue, resultsQueue, **kwds): """Set up thread in daemonic mode and start it immediatedly. requestsQueue and resultQueue are instances of Queue.Queue passed by the ThreadPool class when it creates a new worker thread. """ threading.Thread.__init__(self, **kwds) self.setDaemon(1) self.workRequestQueue = requestsQueue self.resultQueue = resultsQueue self._dismissed = threading.Event() self.start() def run(self): """Repeatedly process the job queue until told to exit.""" while not self._dismissed.isSet(): # thread blocks here, if queue empty request = self.workRequestQueue.get() if self._dismissed.isSet(): # if told to exit, return the work request we just picked up self.workRequestQueue.put(request) break # and exit try: self.resultQueue.put( (request, request.callable(*request.args, **request.kwds)) ) except: request.exception = True self.resultQueue.put((request, sys.exc_info())) def dismiss(self): """Sets a flag to tell the thread to exit when done with current job. """ self._dismissed.set() class WorkRequest: """A request to execute a callable for putting in the request queue later. See the module function makeRequests() for the common case where you want to build several WorkRequests for the same callable but with different arguments for each call. """ def __init__(self, callable, args=None, kwds=None, requestID=None, callback=None, exc_callback=None): """Create a work request for a callable and attach callbacks. A work request consists of the a callable to be executed by a worker thread, a list of positional arguments, a dictionary of keyword arguments. A callback function can be specified, that is called when the results of the request are picked up from the result queue. It must accept two arguments, the request object and the results of the callable, in that order. If you want to pass additional information to the callback, just stick it on the request object. You can also give a callback for when an exception occurs. It should also accept two arguments, the work request and a tuple with the exception details as returned by sys.exc_info(). requestID, if given, must be hashable since it is used by the ThreadPool object to store the results of that work request in a dictionary. It defaults to the return value of id(self). """ if requestID is None: self.requestID = id(self) else: try: hash(requestID) except TypeError: raise TypeError("requestID must be hashable.") self.requestID = requestID self.exception = False self.callback = callback self.exc_callback = exc_callback self.callable = callable self.args = args or [] self.kwds = kwds or {} class ThreadPool: """A thread pool, distributing work requests and collecting results. See the module doctring for more information. """ def __init__(self, num_workers, q_size=0): """Set up the thread pool and start num_workers worker threads. num_workers is the number of worker threads to start initialy. If q_size > 0 the size of the work request queue is limited and the thread pool blocks when the queue is full and it tries to put more work requests in it (see putRequest method). """ self.requestsQueue = Queue.Queue(q_size) self.resultsQueue = Queue.Queue() self.workers = [] self.workRequests = {} self.createWorkers(num_workers) def createWorkers(self, num_workers): """Add num_workers worker threads to the pool.""" for i in range(num_workers): self.workers.append(WorkerThread(self.requestsQueue, self.resultsQueue)) def dismissWorkers(self, num_workers): """Tell num_workers worker threads to quit after their current task. """ for i in range(min(num_workers, len(self.workers))): worker = self.workers.pop() worker.dismiss() def putRequest(self, request, block=True, timeout=0): """Put work request into work queue and save its id for later.""" assert isinstance(request, WorkRequest) self.requestsQueue.put(request, block, timeout) self.workRequests[request.requestID] = request def poll(self, block=False): """Process any new results in the queue.""" while True: # still results pending? if not self.workRequests: raise NoResultsPending # are there still workers to process remaining requests? elif block and not self.workers: raise NoWorkersAvailable try: # get back next results request, result = self.resultsQueue.get(block=block) # has an exception occured? if request.exception and request.exc_callback: request.exc_callback(request, result) # hand results to callback, if any if request.callback and not \ (request.exception and request.exc_callback): request.callback(request, result) del self.workRequests[request.requestID] except Queue.Empty: break def wait(self): """Wait for results, blocking until all have arrived.""" while 1: try: self.poll(True) except NoResultsPending: break # helper functions def makeRequests(callable, args_list, callback=None, exc_callback=None): """Create several work requests for same callable with different arguments. Convenience function for creating several work requests for the same callable where each invocation of the callable receives different values for its arguments. args_list contains the parameters for each invocation of callable. Each item in 'args_list' should be either a 2-item tuple of the list of positional arguments and a dictionary of keyword arguments or a single, non-tuple argument. See docstring for WorkRequest for info on callback and exc_callback. """ requests = [] for item in args_list: if isinstance(item, tuple): requests.append( WorkRequest(callable, item[0], item[1], callback=callback, exc_callback=exc_callback) ) else: requests.append( WorkRequest(callable, [item], None, callback=callback, exc_callback=exc_callback) ) return requests ################ # USAGE EXAMPLE ################ if __name__ == '__main__': import random import time # the work the threads will have to do (rather trivial in our example) def do_something(data): time.sleep(random.randint(1,5)) result = round(random.random() * data, 5) # just to show off, we throw an exception once in a while if result > 3: raise RuntimeError("Something extraordinary happened!") return result # this will be called each time a result is available def print_result(request, result): print "**Result: %s from request #%s" % (result, request.requestID) # this will be called when an exception occurs within a thread def handle_exception(request, exc_info): print "Exception occured in request #%s: %s" % \ (request.requestID, exc_info[1]) # assemble the arguments for each job to a list... data = [random.randint(1,10) for i in range(20)] # ... and build a WorkRequest object for each item in data requests = makeRequests(do_something, data, print_result, handle_exception) # or the other form of args_lists accepted by makeRequests: ((,), {}) data = [((random.randint(1,10),), {}) for i in range(20)] requests.extend( makeRequests(do_something, data, print_result, handle_exception) ) # we create a pool of 3 worker threads main = ThreadPool(3) # then we put the work requests in the queue... for req in requests: main.putRequest(req) print "Work request #%s added." % req.requestID # or shorter: # [main.putRequest(req) for req in requests] # ...and wait for the results to arrive in the result queue # by using ThreadPool.wait(). This would block until results for # all work requests have arrived: # main.wait() # instead we can poll for results while doing something else: i = 0 while 1: try: main.poll() print "Main thread working..." time.sleep(0.5) if i == 10: print "Adding 3 more worker threads..." main.createWorkers(3) i += 1 except KeyboardInterrupt: print "Interrupted!" break except NoResultsPending: print "All results collected." break