I am trying to understand the advantages of multiprocessing over threading. I know that multiprocessing gets around the Global Interpreter Lock, but what other advantages are there, and can threading not do the same thing?

  • 9
    I think this can be useful in general: blogs.datalogics.com/2013/09/25/… Though there can be interesting thing depending on language. E.g. according to Andrew Sledge's link the python threads are slower. By java things are quite the opposite, java processes are much slower than threads, because you need a new jvm to start a new process.
    – inf3rno
    Commented Feb 3, 2016 at 9:17
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    neither of the top two answers(current top, second answer)covers the GIL in any significant way. here is an answer that does cover the GIL aspect: stackoverflow.com/a/18114882/52074 Commented Oct 19, 2016 at 15:35
  • @AndrasDeak can we close the other way around as per: meta.stackoverflow.com/questions/251938/… since this has much more upvotes/answers? Commented Feb 28, 2020 at 11:51
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    @CiroSantilli the reason I chose this direction is because the answers on this question are terrible. The accepted answer has little substance, in the context of python it's unacceptable. The top-voted answer is better, but still lacks proper explanation. The dupe's accepted answer has a detailed explanation from one of the best contributors (and teachers) in the tag, actually explaining what the "GIL limitations" are and why you'd want to use either. I'd much prefer to keep the dupe in this direction. I think we discussed this in python chat, but I can ask for opinions there if you'd like. Commented Feb 28, 2020 at 12:01
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    @CiroSantilli ah, I missed that you had an answer here! When I said "the answers [...] are terrible" I of course excluded present company ;) I think it'd be a lot better to have your answer there! Commented Feb 28, 2020 at 12:05

12 Answers 12


Here are some pros/cons I came up with.



  • Separate memory space
  • Code is usually straightforward
  • Takes advantage of multiple CPUs & cores
  • Avoids GIL limitations for cPython
  • Eliminates most needs for synchronization primitives unless if you use shared memory (instead, it's more of a communication model for IPC)
  • Child processes are interruptible/killable
  • Python multiprocessing module includes useful abstractions with an interface much like threading.Thread
  • A must with cPython for CPU-bound processing


  • IPC a little more complicated with more overhead (communication model vs. shared memory/objects)
  • Larger memory footprint



  • Lightweight - low memory footprint
  • Shared memory - makes access to state from another context easier
  • Allows you to easily make responsive UIs
  • cPython C extension modules that properly release the GIL will run in parallel
  • Great option for I/O-bound applications


  • cPython - subject to the GIL
  • Not interruptible/killable
  • If not following a command queue/message pump model (using the Queue module), then manual use of synchronization primitives become a necessity (decisions are needed for the granularity of locking)
  • Code is usually harder to understand and to get right - the potential for race conditions increases dramatically
  • 62
    For multiprocess: "Takes advantage of multiple CPUs & cores". Does threading have this pro too?
    – Deqing
    Commented Aug 21, 2014 at 13:33
  • 120
    @Deqing no it does not. In Python, because of GIL (Global Interpreter Lock) a single python process cannot run threads in parallel (utilize multiple cores). It can however run them concurrently (context switch during I/O bound operations). Commented Sep 5, 2014 at 4:56
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    @AndrewGuenther straight from the multiprocessing docs (emphasis mine): "The multiprocessing package offers both local and remote concurrency, effectively side-stepping the Global Interpreter Lock by using subprocesses instead of threads. Due to this, the multiprocessing module allows the programmer to fully leverage multiple processors on a given machine."
    – camconn
    Commented Dec 13, 2014 at 2:19
  • 39
    @camconn "@AndrewGuenther straight from the multiprocessing docs" Yes, the multiprocessing package can do this, but not the multithreading package, which it what my comment was referring to. Commented Dec 14, 2014 at 20:46
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    @AndrewGuenther Mea copa. I'm an ID10T trying to act smart. My fault.
    – camconn
    Commented Dec 14, 2014 at 23:31

The threading module uses threads, the multiprocessing module uses processes. The difference is that threads run in the same memory space, while processes have separate memory. This makes it a bit harder to share objects between processes with multiprocessing. Since threads use the same memory, precautions have to be taken or two threads will write to the same memory at the same time. This is what the global interpreter lock is for.

Spawning processes is a bit slower than spawning threads.

  • 224
    The GIL in cPython does not protect your program state. It protects the interpreter's state. Commented Jun 15, 2010 at 14:19
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    Also, the OS handles process scheduling. The threading library handles thread scheduling. And, threads share I/O scheduling -- which can be a bottleneck. Processes have independent I/O scheduling.
    – S.Lott
    Commented Jun 15, 2010 at 14:36
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    how about IPC performance of multiprocessing? FOr a program which requires frequent share of objects among processes (e.g., through multiprocessing.Queue), what's the performance comparison to the in-process queue?
    – KFL
    Commented Oct 21, 2012 at 23:48
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    There is actually a good deal of difference: eli.thegreenplace.net/2012/01/16/… Commented May 29, 2013 at 11:36
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    Is there a problem though if there are too many processes being spawned too often since the CPU might run out of processes/memory. But it can be the same in case of too many threads spawned too often but still lesser overhead than multiple processes. Right?
    – TommyT
    Commented Feb 23, 2015 at 20:13

Threading's job is to enable applications to be responsive. Suppose you have a database connection and you need to respond to user input. Without threading, if the database connection is busy the application will not be able to respond to the user. By splitting off the database connection into a separate thread you can make the application more responsive. Also because both threads are in the same process, they can access the same data structures - good performance, plus a flexible software design.

Note that due to the GIL the app isn't actually doing two things at once, but what we've done is put the resource lock on the database into a separate thread so that CPU time can be switched between it and the user interaction. CPU time gets rationed out between the threads.

Multiprocessing is for times when you really do want more than one thing to be done at any given time. Suppose your application needs to connect to 6 databases and perform a complex matrix transformation on each dataset. Putting each job in a separate thread might help a little because when one connection is idle another one could get some CPU time, but the processing would not be done in parallel because the GIL means that you're only ever using the resources of one CPU. By putting each job in a Multiprocessing process, each can run on its own CPU and run at full efficiency.

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    "but the processing would not be done in parallel because the GIL means that you're only ever using the resources of one CPU" GIL in multiprocessing how come .... ? Commented Oct 12, 2014 at 20:33
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    @NishantKashyap - Reread the sentence you took that quote from. Simon is talking about the processing of multiple threads - it's not about multiprocessing. Commented Jun 24, 2015 at 21:19
  • On memory differences these are in a capEx up-front cost sense. OpEx (running) threads can be just as hungry as processes. You have control of both. Treat them as costs.
    – MrMesees
    Commented Sep 7, 2017 at 12:24
  • @ArtOfWarfare can you explain why the accepted answer assumes multithreaded parallelism can be achieved if the GIL 'releases properly'? Commented Jun 21, 2019 at 17:21
  • @LoveenDyall - I'm not sure why you called me of all people out and are commenting on this answer instead of the one you're asking about, but that bullet point is talking about writing a Python extension in C. If you're dropping out of the Python Interpreter and into the land of native code, you can absolutely utilize multiple CPU cores without concern for the Global Interpreter Lock, because it is only going to lock the interpreter, not native code. Beyond that, I'm not sure what exactly they mean by releasing the GIL properly - I've never written Python extensions before. Commented Jun 21, 2019 at 18:01

Python documentation quotes

The canonical version of this answer is now at the dupliquee question: What are the differences between the threading and multiprocessing modules?

I've highlighted the key Python documentation quotes about Process vs Threads and the GIL at: What is the global interpreter lock (GIL) in CPython?

Process vs thread experiments

I did a bit of benchmarking in order to show the difference more concretely.

In the benchmark, I timed CPU and IO bound work for various numbers of threads on an 8 hyperthread CPU. The work supplied per thread is always the same, such that more threads means more total work supplied.

The results were:

enter image description here

Plot data.


  • for CPU bound work, multiprocessing is always faster, presumably due to the GIL

  • for IO bound work. both are exactly the same speed

  • threads only scale up to about 4x instead of the expected 8x since I'm on an 8 hyperthread machine.

    Contrast that with a C POSIX CPU-bound work which reaches the expected 8x speedup: What do 'real', 'user' and 'sys' mean in the output of time(1)?

    TODO: I don't know the reason for this, there must be other Python inefficiencies coming into play.

Test code:

#!/usr/bin/env python3

import multiprocessing
import threading
import time
import sys

def cpu_func(result, niters):
    A useless CPU bound function.
    for i in range(niters):
        result = (result * result * i + 2 * result * i * i + 3) % 10000000
    return result

class CpuThread(threading.Thread):
    def __init__(self, niters):
        self.niters = niters
        self.result = 1
    def run(self):
        self.result = cpu_func(self.result, self.niters)

class CpuProcess(multiprocessing.Process):
    def __init__(self, niters):
        self.niters = niters
        self.result = 1
    def run(self):
        self.result = cpu_func(self.result, self.niters)

class IoThread(threading.Thread):
    def __init__(self, sleep):
        self.sleep = sleep
        self.result = self.sleep
    def run(self):

class IoProcess(multiprocessing.Process):
    def __init__(self, sleep):
        self.sleep = sleep
        self.result = self.sleep
    def run(self):

if __name__ == '__main__':
    cpu_n_iters = int(sys.argv[1])
    sleep = 1
    cpu_count = multiprocessing.cpu_count()
    input_params = [
        (CpuThread, cpu_n_iters),
        (CpuProcess, cpu_n_iters),
        (IoThread, sleep),
        (IoProcess, sleep),
    header = ['nthreads']
    for thread_class, _ in input_params:
    print(' '.join(header))
    for nthreads in range(1, 2 * cpu_count):
        results = [nthreads]
        for thread_class, work_size in input_params:
            start_time = time.time()
            threads = []
            for i in range(nthreads):
                thread = thread_class(work_size)
            for i, thread in enumerate(threads):
            results.append(time.time() - start_time)
        print(' '.join('{:.6e}'.format(result) for result in results))

GitHub upstream + plotting code on same directory.

Tested on Ubuntu 18.10, Python 3.6.7, in a Lenovo ThinkPad P51 laptop with CPU: Intel Core i7-7820HQ CPU (4 cores / 8 threads), RAM: 2x Samsung M471A2K43BB1-CRC (2x 16GiB), SSD: Samsung MZVLB512HAJQ-000L7 (3,000 MB/s).

Visualize which threads are running at a given time

This post https://rohanvarma.me/GIL/ taught me that you can run a callback whenever a thread is scheduled with the target= argument of threading.Thread and the same for multiprocessing.Process.

This allows us to view exactly which thread runs at each time. When this is done, we would see something like (I made this particular graph up):

            + Active threads / processes           +
|Thread   1 |********     ************             |
|         2 |        *****            *************|
|Process  1 |***  ************** ******  ****      |
|         2 |** **** ****** ** ********* **********|
            + Time -->                             +

which would show that:

  • threads are fully serialized by the GIL
  • processes can run in parallel
  • Re: "threads only scale up to about 4x instead of the expected 8x since I'm on an 8 hyperthread machine." For CPU bound tasks, it should be expected that a 4 core machine max out at 4x. Hyper-threading only helps CPU context switching. (In most cases it only the "hype" that is effective. /joke)
    – Blaine
    Commented Sep 16, 2019 at 18:14
  • SO doesn't like dupe answers though, so you should probably consider deleting this instance of the answer. Commented Feb 28, 2020 at 12:09
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    @AndrasDeak I will leave it here because this page will be less good otherwise and certain links would break and I would lose hard earned rep. Commented Feb 28, 2020 at 12:22

The key advantage is isolation. A crashing process won't bring down other processes, whereas a crashing thread will probably wreak havoc with other threads.

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    Pretty sure this is just wrong. If a standard thread in Python ends by raising an exception, nothing will happen when you join it. I wrote my own subclass of thread which catches the exception in a thread and re-raises it on the thread that joins it, because the fact it was just ignores was really bad (lead to other hard to find bugs.) A process would have the same behavior. Unless by crashing you meant Python actual crashing, not an exception being raised. If you ever find Python crashing, that is definitely a bug that you should report. Python should always raise exceptions and never crash. Commented Oct 16, 2015 at 19:07
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    @ArtOfWarfare Threads can do much more than raise an exception. A rogue thread can, via buggy native or ctypes code, trash memory structures anywhere in the process, including the python runtime itself, thus corrupting the entire process. Commented Oct 17, 2015 at 1:11
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    @jar from a generic point of view, Marcelo's answer is more complete. If the system is really critical, you should never rely in the fact that "things work as expected". With separate memory spaces, an overflow must happen in order to damage nearby processes, which is a more unlikely thing to happen than the situation exposed by marcelo.
    – DGoiko
    Commented Jan 17, 2019 at 0:41

As mentioned in the question, Multiprocessing in Python is the only real way to achieve true parallelism. Multithreading cannot achieve this because the GIL prevents threads from running in parallel.

As a consequence, threading may not always be useful in Python, and in fact, may even result in worse performance depending on what you are trying to achieve. For example, if you are performing a CPU-bound task such as decompressing gzip files or 3D-rendering (anything CPU intensive) then threading may actually hinder your performance rather than help. In such a case, you would want to use Multiprocessing as only this method actually runs in parallel and will help distribute the weight of the task at hand. There could be some overhead to this since Multiprocessing involves copying the memory of a script into each subprocess which may cause issues for larger-sized applications.

However, Multithreading becomes useful when your task is IO-bound. For example, if most of your task involves waiting on API-calls, you would use Multithreading because why not start up another request in another thread while you wait, rather than have your CPU sit idly by.


  • Multithreading is concurrent and is used for IO-bound tasks
  • Multiprocessing achieves true parallelism and is used for CPU-bound tasks
  • 2
    Could you give an example of task that is IO-bound? Commented Oct 13, 2018 at 16:16
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    @YellowPillow Let's say you're making multiple API calls to request some data, in this case the majority of the time is spent waiting on the network. As it awaits this network I/O, the GIL can be released to be used by the next task. However, the task will need to re-acquire the GIL in order to go to execute the rest of any python code associated with each API request, but, as the task is waiting for the network, it does not need to hold on to the GIL.
    – buydadip
    Commented Oct 13, 2018 at 20:26

Another thing not mentioned is that it depends on what OS you are using where speed is concerned. In Windows processes are costly so threads would be better in windows but in unix processes are faster than their windows variants so using processes in unix is much safer plus quick to spawn.

  • 8
    Do you have actual numbers to back this up with? IE, comparing doing a task serially, then on multiple threads, then on multiple processes, on both Windows and Unix? Commented Jun 24, 2015 at 21:21
  • 3
    Agree with @ArtOfWarfare question. Numbers? Do you recommend using Threads for Windows?
    – m3nda
    Commented Oct 16, 2015 at 11:31
  • The OS doesn't matter much because pythons GIL doesn't allow it to run multiple threads on a single process. Multiprocessing will be faster in Windows and Linux.
    – Viliami
    Commented Mar 5, 2019 at 23:04

Other answers have focused more on the multithreading vs multiprocessing aspect, but in python Global Interpreter Lock (GIL) has to be taken into account. When more number (say k) of threads are created, generally they will not increase the performance by k times, as it will still be running as a single threaded application. GIL is a global lock which locks everything out and allows only single thread execution utilizing only a single core. The performance does increase in places where C extensions like numpy, Network, I/O are being used, where a lot of background work is done and GIL is released.
So when threading is used, there is only a single operating system level thread while python creates pseudo-threads which are completely managed by threading itself but are essentially running as a single process. Preemption takes place between these pseudo threads. If the CPU runs at maximum capacity, you may want to switch to multiprocessing.
Now in case of self-contained instances of execution, you can instead opt for pool. But in case of overlapping data, where you may want processes communicating you should use multiprocessing.Process.

  • "So when threading is used, there is only a single operating system level thread while python creates pseudo-threads which are completely managed by threading itself but are essentially running as a single process. " That is not true. Python threads are real OS-threads. What you are describing are green threads, Python does not use that. It's just that a thread needs to hold the GIL to execute Python-bytecode which makes thread-execution sequential.
    – Darkonaut
    Commented Feb 13, 2019 at 16:09
  • Now in case of self-contained instances of execution, you can instead opt for pool. But in case of overlapping data, where you may want processes communicating you should use multiprocessing.Process. What pool? The multiprocessing library has a Pool, so this doesn't make much sense.
    – AMC
    Commented Feb 9, 2020 at 16:22


  • Multiprocessing adds CPUs to increase computing power.
  • Multiple processes are executed concurrently.
  • Creation of a process is time-consuming and resource intensive.
  • Multiprocessing can be symmetric or asymmetric.
  • The multiprocessing library in Python uses separate memory space, multiple CPU cores, bypasses GIL limitations in CPython, child processes are killable (ex. function calls in program) and is much easier to use.
  • Some caveats of the module are a larger memory footprint and IPC’s a little more complicated with more overhead.


  • Multithreading creates multiple threads of a single process to increase computing power.
  • Multiple threads of a single process are executed concurrently.
  • Creation of a thread is economical in both sense time and resource.
  • The multithreading library is lightweight, shares memory, responsible for responsive UI and is used well for I/O bound applications.
  • The module isn’t killable and is subject to the GIL.
  • Multiple threads live in the same process in the same space, each thread will do a specific task, have its own code, own stack memory, instruction pointer, and share heap memory.
  • If a thread has a memory leak it can damage the other threads and parent process.

Example of Multi-threading and Multiprocessing using Python

Python 3 has the facility of Launching parallel tasks. This makes our work easier.

It has for thread pooling and Process pooling.

The following gives an insight:

ThreadPoolExecutor Example

import concurrent.futures
import urllib.request

URLS = ['http://www.foxnews.com/',

# Retrieve a single page and report the URL and contents
def load_url(url, timeout):
    with urllib.request.urlopen(url, timeout=timeout) as conn:
        return conn.read()

# We can use a with statement to ensure threads are cleaned up promptly
with concurrent.futures.ThreadPoolExecutor(max_workers=5) as executor:
    # Start the load operations and mark each future with its URL
    future_to_url = {executor.submit(load_url, url, 60): url for url in URLS}
    for future in concurrent.futures.as_completed(future_to_url):
        url = future_to_url[future]
            data = future.result()
        except Exception as exc:
            print('%r generated an exception: %s' % (url, exc))
            print('%r page is %d bytes' % (url, len(data)))


import concurrent.futures
import math


def is_prime(n):
    if n % 2 == 0:
        return False

    sqrt_n = int(math.floor(math.sqrt(n)))
    for i in range(3, sqrt_n + 1, 2):
        if n % i == 0:
            return False
    return True

def main():
    with concurrent.futures.ProcessPoolExecutor() as executor:
        for number, prime in zip(PRIMES, executor.map(is_prime, PRIMES)):
            print('%d is prime: %s' % (number, prime))

if __name__ == '__main__':
  • Would have been better if you could have shown both ThreadPoolExecutor and ProcessPoolExecutor on the same example
    – Chandan
    Commented Oct 7, 2023 at 15:00
  • like multiplication of huge matrices
    – Chandan
    Commented Oct 7, 2023 at 15:41
  • 1
    @Chandan you can use the same example of ProcessPoolExecutor and change with concurrent.futures.ProcessPoolExecutor() as executor: to with concurrent.futures.ThreadPoolExecutor(max_workers=5) as executor:
    – Jeril
    Commented Oct 9, 2023 at 2:03

Threads share the same memory space to guarantee that two threads don't share the same memory location so special precautions must be taken the CPython interpreter handles this using a mechanism called GIL, or the Global Interpreter Lock

what is GIL(Just I want to Clarify GIL it's repeated above)?

In CPython, the global interpreter lock, or GIL, is a mutex that protects access to Python objects, preventing multiple threads from executing Python bytecodes at once. This lock is necessary mainly because CPython's memory management is not thread-safe.

For the main question, we can compare using Use Cases, How?

1-Use Cases for Threading: in case of GUI programs threading can be used to make the application responsive For example, in a text editing program, one thread can take care of recording the user inputs, another can be responsible for displaying the text, a third can do spell-checking, and so on. Here, the program has to wait for user interaction. which is the biggest bottleneck. Another use case for threading is programs that are IO bound or network bound, such as web-scrapers.

2-Use Cases for Multiprocessing: Multiprocessing outshines threading in cases where the program is CPU intensive and doesn’t have to do any IO or user interaction.

For More Details visit this link and link or you need in-depth knowledge for threading visit here for Multiprocessing visit here


Process may have multiple threads. These threads may share memory and are the units of execution within a process.

Processes run on the CPU, so threads are residing under each process. Processes are individual entities which run independently. If you want to share data or state between each process, you may use a memory-storage tool such as Cache(redis, memcache), Files, or a Database.

  • Processes run on the CPU, so threads are residing under each process. How does the first part of that sentence lead to the second part? Threads run on the CPU too.
    – AMC
    Commented Feb 9, 2020 at 16:24

As I learnd in university most of the answers above are right. In PRACTISE on different platforms (always using python) spawning multiple threads ends up like spawning one process. The difference is the multiple cores share the load instead of only 1 core processing everything at 100%. So if you spawn for example 10 threads on a 4 core pc, you will end up getting only the 25% of the cpus power!! And if u spawn 10 processes u will end up with the cpu processing at 100% (if u dont have other limitations). Im not a expert in all the new technologies. Im answering with own real experience background

  • 1
    In PRACTISE on different platforms (always using python) spawning multiple threads ends up like spawning one process. They don't have the same use cases at all though, so I'm not sure I agree with that.
    – AMC
    Commented Feb 9, 2020 at 16:28

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