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I have a function that accepts a large array of x,y pairs as an input which does some elaborate curve fitting using numpy and scipy and then returns a single value. To try and speed things up I am trying to have two threads that I feed the data to using Queue.Queue . Once the data is done. I am trying to have the threads terminate and then end the calling process and return control to the shell.

I am trying to understand why I have to resort to a private method in threading.Thread to stop my threads and return control to the commandline.

The self.join() does not end the program. The only way to get back control was to use the private stop method.

        def stop(self):
            print "STOP CALLED"
            self.finished.set()
            print "SET DONE"
            # self.join(timeout=None) does not work
            self._Thread__stop()

Here is an approximation of my code:

    class CalcThread(threading.Thread):
        def __init__(self,in_queue,out_queue,function):
            threading.Thread.__init__(self)
            self.in_queue = in_queue
            self.out_queue = out_queue
            self.function = function
            self.finished = threading.Event()

        def stop(self):
            print "STOP CALLED"
            self.finished.set()
            print "SET DONE"
            self._Thread__stop()

        def run(self):
            while not self.finished.isSet():
                params_for_function = self.in_queue.get()
                try:
                    tm = self.function(paramsforfunction)
                    self.in_queue.task_done()
                    self.out_queue.put(tm)
                except ValueError as v:
                    #modify params and reinsert into queue
                    window = params_for_function["window"]
                    params_for_function["window"] = window + 1
                    self.in_queue.put(params_for_function)

    def big_calculation(well_id,window,data_arrays):
            # do some analysis to calculate tm
            return tm

    if __name__ == "__main__":
        NUM_THREADS = 2
        workers = []
        in_queue = Queue()
        out_queue = Queue()

        for i in range(NUM_THREADS):
            w = CalcThread(in_queue,out_queue,big_calculation)
            w.start()
            workers.append(w)

        if options.analyze_all:
              for i in well_ids:
                  in_queue.put(dict(well_id=i,window=10,data_arrays=my_data_dict))

        in_queue.join()
        print "ALL THREADS SEEM TO BE DONE"
        # gather data and report it from out_queue
        for i in well_ids:
            p = out_queue.get()
            print p
            out_queue.task_done()
            # I had to do this to get the out_queue to proceed
            if out_queue.qsize() == 0:
                out_queue.join()
                break
# Calling this stop method does not seem to return control to the command line unless I use threading.Thread private method

        for aworker in workers:
            aworker.stop()
share|improve this question
    
self.daemon = True – g.d.d.c Oct 6 '11 at 21:24
    
sys.exit() (kills the thread only) – Chris Morgan Oct 6 '11 at 23:10
    
self.daemon = True works only if set before start() is called, otherwise RuntimeError is raised – Dmitry Trofimov Oct 23 '12 at 14:31
    
sys.exit() doesn't kill the thread but raises SystemExit exception in current thread. – Dmitry Trofimov Oct 23 '12 at 14:32
up vote 5 down vote accepted

In general it is a bad idea to kill a thread that modifies shared resource.

CPU intensive tasks in multiple threads are worse than useless in Python unless you release GIL while performing computations. Many numpy functions do release GIL.

ThreadPoolExecutor example from the docs

import concurrent.futures # on Python 2.x: pip install futures 

calc_args = []
if options.analyze_all:
    calc_args.extend(dict(well_id=i,...) for i in well_ids)

with concurrent.futures.ThreadPoolExecutor(max_workers=NUM_THREADS) as executor:
    future_to_args = dict((executor.submit(big_calculation, args), args)
                           for args in calc_args)

    while future_to_args:
        for future in concurrent.futures.as_completed(dict(**future_to_args)):
            args = future_to_args.pop(future)
            if future.exception() is not None:
                print('%r generated an exception: %s' % (args,
                                                         future.exception()))
                if isinstance(future.exception(), ValueError):
                    #modify params and resubmit
                    args["window"] += 1
                    future_to_args[executor.submit(big_calculation, args)] = args

            else:
                print('f%r returned %r' % (args, future.result()))

print("ALL work SEEMs TO BE DONE")

You could replace ThreadPoolExecutor by ProcessPoolExecutor if there is no shared state. Put the code in your main() function.

share|improve this answer
    
WOW this is a HUGE eye-opener. Thanks a lot for introducing me to concurrent.futures. And it works very well with python 2.7 and numpy and scipy. None of the hastles of thread.Threading and all the concurrent execution benefits – harijay Oct 9 '11 at 12:20

To elaborate on my comment - if the sole purpose of your threads is to consume values from a Queue and perform a function on them you're decidedly better off to do something like this IMHO:

q = Queue()
results = []

def worker():
  while True:
    x, y = q.get()
    results.append(x ** y)
    q.task_done()

for _ in range(workerCount):
  t = Thread(target = worker)
  t.daemon = True
  t.start()

for tup in listOfXYs:
  q.put(tup)

q.join()

# Some more code here with the results list.

q.join() will block until it is empty again. The worker threads will continue to attempt to retrieve values, but won't find any, so they'll wait indefinitely once the queue is empty. When your script finishes its execution later the worker threads will die because they're marked as daemon threads.

share|improve this answer
2  
Instead of using daemons for this stuff (imo not a nice design for that situation, YMMV), you could use sentinel values. I.e. after all jobs are finished, put nrThreads sentinel values into the queue and then join the queue or the threads again. The threads just check if get() returned the sentinel (None is a good choice usually) and stop in that case. Makes it also easier to include the code in a larger design. – Voo Oct 6 '11 at 22:03
    
@Voo: The worker threads themselves are putting new values in in_queue. If the main thread puts sentinels in in_queue, they may signal termination prematurely. How would you handle this situation? – unutbu Oct 6 '11 at 22:12
    
@unutbu - I don't personally see the advantage to the sentinel values, but you could (theoretically) address that concern by using a LifoQueue in place of a standard queue and pre-populate it with a sentinel value for each worker thread. This does carry the potential (in the op's case at least) that some of your workers die off early, but that a final worker that re-adds to the in_queue several times ends up running significantly longer. A daemon thread in a blocked queue.get() consumes little to no resources and isn't a performance drain in my experience. – g.d.d.c Oct 6 '11 at 22:18
    
@g.d.d.c: I like your idea of using a LifoQueue. I think that could be workable. But there is still one other the problem: how to know when out_queue is empty. I don't think testing qsize is safe -- a thread may be about to put a new item in out_queue while the main thread is testing qsize when it is temporarily zero. – unutbu Oct 6 '11 at 22:27
1  
I obviously didn't explain the concept good enough, but yep, g.d.d.c got it right. wait, put sentinels in queue, wait again (though you could wait on the threads/processes/threadpool/whatever the second time as well; not exactly the same semantics but close enough). It's quite a useful pattern for this kind of problem - can get more complicated with several input queues, output queues, etc. but that's the nature of the beast and we can generalize the solution to that as well. – Voo Oct 6 '11 at 22:56

I tried g.d.d.c's method and it produced an interesting result. I could get his exact x**y calculation to work just fine spread between the threads .

When I called my function inside the worker while True loop. I could perform the calculations among multiple threads only if I put a time.sleep(1) in the for loop that calls the threads start() method.

So In my code. Without the time.sleep(1) the program gave me either a clean exit with no output or in some cases

"Exception in thread Thread-2 (most likely raised during interpreter shutdown):Exception in thread Thread-1 (most likely raised during interpreter shutdown):"

Once I added the time.sleep() everything ran fine.

for aworker in range(5):
    t = Thread(target = worker)
    t.daemon = True
    t.start()
    # This sleep was essential or results for my specific function were None
    time.sleep(1)
    print "Started"
share|improve this answer

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