At the bottom is the code I have now. It seems to work fine. However, I don't completely understand it. I thought without .join(), I'd risking the code going onto the next for-loop before the pool finishes executing. Wouldn't we need those 3 commented-out lines?

On the other hand, if I were to go with the .close() and .join() way, is there any way to 'reopen' that closed pool instead of Pool(6) every time?

import multiprocessing as mp
import random as rdm
from statistics import stdev, mean
import time

def mesh_subset(population, n_chosen=5):
    chosen = rdm.choices(population, k=n_chosen)
    return mean(chosen)

if __name__ == '__main__':
    population = [x for x in range(20)]
    N_iteration = 10
    start_time = time.time()
    pool = mp.Pool(6)
    for i in range(N_iteration):
        print([round(x,2) for x in population])
        # pool = mp.Pool(6)
        population = pool.map(mesh_subset, [population]*len(population))
        # pool.close()
        # pool.join()
    print('run time:', time.time() - start_time)

1 Answer 1


A pool of workers is a relatively costly thing to set up, so it should be done (if possible) only once, usually at the beginning of the script.

The pool.map command blocks until all the tasks are completed. After all, it returns a list of the results. It couldn't do that unless mesh_subset has been called on all the inputs and has returned a result for each. In contrast, methods like pool.apply_async do not block. apply_async returns an ApplyResult object with a get method which blocks until it obtains a result from a worker process.

pool.close sets the worker handler's state to CLOSE. This causes the handler to signal the workers to terminate.

The pool.join blocks until all the worker processes have been terminated.

So you don't need to call -- in fact you shouldn't call -- pool.close and pool.join until you are finished with the pool. Once the workers have been sent the signal to terminate (by pool.close), there is no way to "reopen" them. You would need to start a new pool instead.

In your situation, since you do want the loop to wait until all the tasks are completed, there would be no advantage to using pool.apply_async instead of pool.map. But if you were to use pool.apply_async, you could obtain the same result as before by calling get instead of resorting to closing and restarting the pool:

# you could do this, but using pool.map is simpler
for i in range(N_iteration):
    apply_results = [pool.apply_async(mesh_subset, [population]) for i in range(len(population))]
    # the call to result.get() blocks until its worker process (running
    # mesh_subset) returns a value
    population = [result.get() for result in apply_results]

When the loops complete, len(population) is unchanged.

If you did NOT want each loop to block until all the tasks are completed, you could use apply_async's callback feature:

N_pop = len(population)
result = []
for i in range(N_iteration):
    for i in range(N_pop):
        pool.apply_async(mesh_subset, [population]),

Now, when any mesh_subset returns a return_value, result.append(return_value) is called. The calls to apply_async do not block, so N_iteration * N_pop tasks are pushed into the pools task queue all at once. But since the pool has 6 workers, at most 6 calls to mesh_subset are running at any given time. As the workers complete the tasks, whichever worker finishes first calls result.append(return_value). So the values in result are unordered. This is different than pool.map which returns a list whose return values are in the same order as its corresponding list of arguments.

Barring an exception, result will eventually contain N_iteration * N_pop return values once all the tasks complete. Above, pool.close() and pool.join() were used to wait for all the tasks to complete.

  • 1
    Thanks, @unutbu, Just try to test if I understand it: so, had I used pool.wait_async, but still didn't want the code to go beyond a certain line before all processes finish running, then I would need to do pool.close and pool.join, in which case, I do need to reconstruct the pool with pool = mp.Pool(6) in each loop?
    – Indominus
    Dec 25, 2018 at 4:49
  • I added some code an explanation showing how one might use pool.apply_async without calling pool.close() and pool.join() each time through the loop.
    – unutbu
    Dec 25, 2018 at 11:56
  • Why would population eventually contain N_iteration * len(population) values? In my code (and intention), the size of population wouldn't change after each iteration. What each iteration does is: draw a few (default to 5, see my edit) and take average to form one member of the new population, repeat this drawing until the new population has the same size as the current population.
    – Indominus
    Dec 25, 2018 at 12:11
  • 1
    I saw your suggested edit, but had to reject it because it would not have worked as intended. Since pool.apply_async does not block, calling population = result could assign population to a partial or empty list.
    – unutbu
    Dec 25, 2018 at 13:45
  • 1
    The moral of the story is: The key to speed with multiprocessing is to make the workers do a lot of work and as little interprocess communication as possible. If the workers do little work (that is, the function ends quickly) and there is a lot of interprocess communication, then your multiprocessing code may be slower than a single process serial version of the computation.
    – unutbu
    Dec 25, 2018 at 14:11

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