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I am attempting to implement multiprocessing in Python (Windows Server 2012) and am having trouble achieving the degree of performance improvement that I expect. In particular, for a set of tasks which are almost entirely independent, I would expect a linear improvement with additional cores.


I understand that--especially on Windows--there is overhead involved in opening new processes [1], and that many quirks of the underlying code can get in the way of a clean trend. But in theory the trend should ultimately still be close to linear for a fully parallelized task [2]; or perhaps logistic if I were dealing with a partially serial task [3].

However, when I run multiprocessing.Pool on a prime-checking test function (code below), I get a nearly perfect square-root relationship up to N_cores=36 (the number of physical cores on my server) before the expected performance hit when I get into the additional logical cores.


Here is a plot of my performance test results : enter image description here
( "Normalized Performance" is [ a run time with 1 CPU-core ] divided by [ a run time with N CPU-cores ] ).

Is it normal to have this dramatic diminishing of returns with multiprocessing? Or am I missing something with my implementation?


import numpy as np
from multiprocessing import Pool, cpu_count, Manager
import math as m
from functools import partial
from time import time

def check_prime(num):

    #Assert positive integer value
    if num!=m.floor(num) or num<1:
        print("Input must be a positive integer")
        return None

    #Check divisibility for all possible factors
    prime = True
    for i in range(2,num):
        if num%i==0: prime=False
    return prime

def cp_worker(num, L):
    prime = check_prime(num)
    L.append((num, prime))


def mp_primes(omag, mp=cpu_count()):
    with Manager() as manager:
        np.random.seed(0)
        numlist = np.random.randint(10**omag, 10**(omag+1), 100)

        L = manager.list()
        cp_worker_ptl = partial(cp_worker, L=L)

        try:
            pool = Pool(processes=mp)   
            list(pool.imap(cp_worker_ptl, numlist))
        except Exception as e:
            print(e)
        finally:
            pool.close() # no more tasks
            pool.join()

        return L


if __name__ == '__main__':
    rt = []
    for i in range(cpu_count()):
        t0 = time()
        mp_result = mp_primes(6, mp=i+1)
        t1 = time()
        rt.append(t1-t0)
        print("Using %i core(s), run time is %.2fs" % (i+1, rt[-1]))

Note: I am aware that for this task it would likely be more efficient to implement multithreading, but the actual script for which this one is a simplified analog is incompatible with Python multithreading due to GIL.

  • What is tqdm? – MegaIng May 7 '18 at 20:09
  • 1
    The multiprocessing docs should explain what they are doing better. A Manager holds Python objects and allows other processes to manipulate them using proxies - meaning it is synching the list to all workers. You'd be much better off with a multiprocessing.Array and give each work item the index where the result should be placed. Also, map is better than list(imap) and likely chunksize=1 will help. – tdelaney May 7 '18 at 20:48
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    32-bit processes (native or WOW64) support up to 32 logical cores. 64-bit Windows uses processor groups that have up to 64 logical cores per group, and a 64-bit process executes in a single group by default (a thread can be moved to another group). multiprocessing has no support for Windows processor groups, and it certainly won't actively manage threads to distribute a workload evenly across all cores. One or more processor groups may be under-utilized if the processes that end up in that group aren't as CPU intensive. – eryksun May 8 '18 at 2:17
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    Also. os.cpu_count() may be incorrect. In Python 3 it's calling GetMaximumProcessorCount (equivalent to POSIX _SC_NPROCESSORS_CONF) instead of GetActiveProcessorCount (equivalent to POSIX _SC_NPROCESSORS_ONLN). For systems that support hot-plugging CPUs, this count could be much larger than the number of actually available cores. – eryksun May 8 '18 at 2:19
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    Note that my comments weren't directed toward the result for up to 36 cores. user3666197 addressed the primary issue there. My first comment was directed at the graph result for 36 to 72 cores. I wouldn't expect this result for a system with 36 physical CPUs and 72 logical cores, but my assumption about the system could be wrong. The second and third comment addresses the range from 72 to 128. This definitely looks like the known bug in os.cpu_count. If the system has 72 logical cores, the CPU count should be 72, not 128. – eryksun May 8 '18 at 13:51
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@KellanM deserved [+1] for quantitative performance monitoring

am I missing something with my implementation?

Yes, you abstract from all add-on costs of the process-management.

While you have expressed an expectation of " a linear improvement with additional cores. ", this would hardly appear in practice for several reasons ( even the hype of communism failed to deliver anything for free ).

Gene AMDAHL has formulated the inital law of diminishing returns. enter image description here
A more recent, re-formulated version, took into account also the effects of process-management {setup|terminate}-add-on overhead costs and tried to cope with atomicity-of-processing ( given large workpackage payloads cannot get easily re-located / re-distributed over available pool of free CPU-cores in most common programming systems ( except some indeed specific micro-scheduling art, like the one demonstrated in Semantic Design's PARLANSE or LLNL's SISAL have shown so colourfully in past ).


A best next step?

If indeed interested in this domain, one may always experimentally measure and compare the real costs of process management ( plus data-flow costs, plus memory-allocation costs, ... up until the process-termination and results re-assembly in the main process ) so as to quantitatively fair record and evaluate the add-on costs / benefit ratio of using more CPU-cores ( that will get, in python, re-instated the whole python-interpreter state, including all its memory-state, before a first usefull operation will get carried out in a first spawned and setup process ).

Underperformance ( for the former case below )
if not disastrous effects ( from the latter case below ),
of either of ill-engineered resources-mapping policy, be it
an "under-booking"-resources from a pool of CPU-cores
or
an "over-booking"-resources from a pool of RAM-space
are discussed also here

The link to the re-formulated Amdahl's Law above will help you evaluate the point of diminishing returns, not to pay more than will ever receive.

Hoefinger et Haunschmid experiments may serve as a good practical evidence, how a growing number of processing-nodes ( be it a local O/S managed CPU-core, or a NUMA distributed architecture node ) will start decreasing the resulting performance,
where a Point of diminishing returns ( demonstrated in overhead agnostic Amdahl's Law )
will actually start to become a Point after which you pay more than receive. :

enter image description here Good luck on this interesting field! enter image description here


Last, but not least,

NUMA / non-locality issues get their voice heard, into the discussion of scaling for HPC-grade tuned ( in-Cache / in-RAM computing strategies ) and may - as a side-effect - help detect the flaws ( as reported by @eryksun above ). One may feel free to review one's platform actual NUMA-topology by using lstopo tool, to see the abstraction, that one's operating system is trying to work with, once scheduling the "just"-[CONCURRENT] task execution over such a NUMA-resources-topology:

enter image description here

  • I like your analysis, but ... In a forking system like linux, you don't have to re-instate the python interpreter.. and even if you did, that's only once per pool worker. – tdelaney May 7 '18 at 20:58
  • Yes, @tdelaney your notice is coorect, with a few exceptions : (1) O/P explicitly stated Windows O/S, where all forking is not supported ( so far, 2018/Q2 ) (2) Unix / Linux O/S forking-tricks seem as not supported in py2.7.x (3) using additional process-to-process communication methods ( as you have proposed to use .Array() will add immense add-on SER/DES overhead costs pickle.{dumps|loads}(). Sure, the above proposed algorithm was not polished for HPC-grade ultimate processing efficiency ( which was not merit of the post ), yet, no reason to add even more overheads – user3666197 May 8 '18 at 11:53
  • Boldly stated. You posted a general observation and I mentioned mitigating factors (forking system overhead and the one-time cost). Not sure what the problem here is. – tdelaney May 8 '18 at 14:57
  • The answer is abstract and theoretical but does not address the particular question. There is no practical evidence that suggests this particular code suffers from anything of what you describe - mainly because the question lacks essential information. I see typical run times for cp_worker from 600 ms to 3500 ms - just how much (de)serialization/communication overhead is there supposed to be for such an impact on performance? – Zulan May 11 '18 at 11:29
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    Please don't use block quotes for emphasis. They are for marking up quotations, not for hilighting arbitrary blocks of text or drawing attention to your titles. We've had this discussion before, there are objectively right and wrong ways to use some of the formatting tools this site provides, such as block quotes. You are generally pretty free to format your posts as you like, but if somebody fixes a problem where you've incorrectly marked up your post, you are expected to leave their edits alone. – meagar May 11 '18 at 12:46

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