What are the fundamental differences between queues and pipes in Python's multiprocessing package?

In what scenarios should one choose one over the other? When is it advantageous to use Pipe()? When is it advantageous to use Queue()?

  • A Pipe() can only have two endpoints.

  • A Queue() can have multiple producers and consumers.

When to use them

If you need more than two points to communicate, use a Queue().

If you need absolute performance, a Pipe() is much faster because Queue() is built on top of Pipe().

Performance Benchmarking

Let's assume you want to spawn two processes and send messages between them as quickly as possible. These are the timing results of a drag race between similar tests using Pipe() and Queue()... This is on a ThinkpadT61 running Ubuntu 11.10, and Python 2.7.2.

FYI, I threw in results for JoinableQueue() as a bonus; JoinableQueue() accounts for tasks when queue.task_done() is called (it doesn't even know about the specific task, it just counts unfinished tasks in the queue), so that queue.join() knows the work is finished.

The code for each at bottom of this answer...

mpenning@mpenning-T61:~$ python multi_pipe.py 
Sending 10000 numbers to Pipe() took 0.0369849205017 seconds
Sending 100000 numbers to Pipe() took 0.328398942947 seconds
Sending 1000000 numbers to Pipe() took 3.17266988754 seconds
mpenning@mpenning-T61:~$ python multi_queue.py 
Sending 10000 numbers to Queue() took 0.105256080627 seconds
Sending 100000 numbers to Queue() took 0.980564117432 seconds
Sending 1000000 numbers to Queue() took 10.1611330509 seconds
mpnening@mpenning-T61:~$ python multi_joinablequeue.py 
Sending 10000 numbers to JoinableQueue() took 0.172781944275 seconds
Sending 100000 numbers to JoinableQueue() took 1.5714070797 seconds
Sending 1000000 numbers to JoinableQueue() took 15.8527247906 seconds

In summary Pipe() is about three times faster than a Queue(). Don't even think about the JoinableQueue() unless you really must have the benefits.


Multiprocessing introduces subtle changes in information flow that make debugging hard unless you know some shortcuts. For instance, you might have a script that works fine when indexing through a dictionary in under many conditions, but infrequently fails with certain inputs.

Normally we get clues to the failure when the entire python process crashes; however, you don't get unsolicited crash tracebacks printed to the console if the multiprocessing function crashes. Tracking down unknown multiprocessing crashes is hard without a clue to what crashed the process.

The simplest way I have found to track down multiprocessing crash informaiton is to wrap the entire multiprocessing function in a try / except and use traceback.print_exc():

import traceback
def run(self, args):
        # Insert stuff to be multiprocessed here
        return args[0]['that']
        print "FATAL: reader({0}) exited while multiprocessing".format(args) 

Now, when you find a crash you see something like:

FATAL: reader([{'crash': 'this'}]) exited while multiprocessing
Traceback (most recent call last):
  File "foo.py", line 19, in __init__
  File "foo.py", line 46, in run
    KeyError: 'that'

Source Code:

from multiprocessing import Process, Pipe
import time

def reader_proc(pipe):
    ## Read from the pipe; this will be spawned as a separate Process
    p_output, p_input = pipe
    p_input.close()    # We are only reading
    while True:
        msg = p_output.recv()    # Read from the output pipe and do nothing
        if msg=='DONE':

def writer(count, p_input):
    for ii in xrange(0, count):
        p_input.send(ii)             # Write 'count' numbers into the input pipe

if __name__=='__main__':
    for count in [10**4, 10**5, 10**6]:
        # Pipes are unidirectional with two endpoints:  p_input ------> p_output
        p_output, p_input = Pipe()  # writer() writes to p_input from _this_ process
        reader_p = Process(target=reader_proc, args=((p_output, p_input),))
        reader_p.daemon = True
        reader_p.start()     # Launch the reader process

        p_output.close()       # We no longer need this part of the Pipe()
        _start = time.time()
        writer(count, p_input) # Send a lot of stuff to reader_proc()
        print("Sending {0} numbers to Pipe() took {1} seconds".format(count,
            (time.time() - _start)))


from multiprocessing import Process, Queue
import time
import sys

def reader_proc(queue):
    ## Read from the queue; this will be spawned as a separate Process
    while True:
        msg = queue.get()         # Read from the queue and do nothing
        if (msg == 'DONE'):

def writer(count, queue):
    ## Write to the queue
    for ii in range(0, count):
        queue.put(ii)             # Write 'count' numbers into the queue

if __name__=='__main__':
    pqueue = Queue() # writer() writes to pqueue from _this_ process
    for count in [10**4, 10**5, 10**6]:             
        ### reader_proc() reads from pqueue as a separate process
        reader_p = Process(target=reader_proc, args=((pqueue),))
        reader_p.daemon = True
        reader_p.start()        # Launch reader_proc() as a separate python process

        _start = time.time()
        writer(count, pqueue)    # Send a lot of stuff to reader()
        reader_p.join()         # Wait for the reader to finish
        print("Sending {0} numbers to Queue() took {1} seconds".format(count, 
            (time.time() - _start)))

from multiprocessing import Process, JoinableQueue
import time

def reader_proc(queue):
    ## Read from the queue; this will be spawned as a separate Process
    while True:
        msg = queue.get()         # Read from the queue and do nothing

def writer(count, queue):
    for ii in xrange(0, count):
        queue.put(ii)             # Write 'count' numbers into the queue

if __name__=='__main__':
    for count in [10**4, 10**5, 10**6]:
        jqueue = JoinableQueue() # writer() writes to jqueue from _this_ process
        # reader_proc() reads from jqueue as a different process...
        reader_p = Process(target=reader_proc, args=((jqueue),))
        reader_p.daemon = True
        reader_p.start()     # Launch the reader process
        _start = time.time()
        writer(count, jqueue) # Send a lot of stuff to reader_proc() (in different process)
        jqueue.join()         # Wait for the reader to finish
        print("Sending {0} numbers to JoinableQueue() took {1} seconds".format(count, 
            (time.time() - _start)))
  • 2
    @Jonathan "In summary Pipe() is about three times faster than a Queue()" – James Brady Dec 12 '11 at 14:01
  • 16
    Excellent! Good answer and nice that you provided benchmarks! I only have two tiny quibbles: (1) "orders of magnitude faster" is a bit of an overstatement. The difference is x3, which is about a third of one order of magnitude. Just saying. ;-); and (2) a more fair comparison would be running N workers, each communicating with main thread via point-to-point pipe compared to performance of running N workers all pulling from a single point-to-multipoint queue. – JJC Mar 31 '12 at 9:28
  • 3
    To your "Bonus Material"... Yeah. If you're subclassing Process, put the bulk of the 'run' method in a try block. That is also a useful way to do logging of exceptions. To replicate the normal exception output: sys.stderr.write(''.join(traceback.format_exception(*(sys.exc_info())))) – travc Feb 28 '13 at 7:33
  • 2
    @alexpinho98 - but you're going to need some out-of-band data, and associated signalling mode, to indicate that what you're sending is not regular data but error data. seeing as the originating process is already in an unpredictable state this may be too much to ask. – scytale Jun 27 '13 at 23:52
  • 11
    @JJC To quibble with your quibble, 3x is about half an order of magnitude, not a third -- sqrt(10) =~ 3. – jab Aug 3 '13 at 2:59

One additional feature of Queue() that is worth noting is the feeder thread. This section notes "When a process first puts an item on the queue a feeder thread is started which transfers objects from a buffer into the pipe." An infinite number of (or maxsize) items can be inserted into Queue() without any calls to queue.put() blocking. This allows you to store multiple items in a Queue(), until your program is ready to process them.

Pipe(), on the other hand, has a finite amount of storage for items that have been sent to one connection, but have not been received from the other connection. After this storage is used up, calls to connection.send() will block until there is space to write the entire item. This will stall the thread doing the writing until some other thread reads from the pipe. Connection objects give you access to the underlying file descriptor. On *nix systems, you can prevent connection.send() calls from blocking using the os.set_blocking() function. However, this will cause problems if you try to send a single item that does not fit in the pipe's file. Recent versions of Linux allow you to increase the size of a file, but the maximum size allowed varies based on system configurations. You should therefore never rely on Pipe() to buffer data. Calls to connection.send could block until data gets read from the pipe somehwere else.

In conclusion, Queue is a better choice than pipe when you need to buffer data. Even when you only need to communicate between two points.

  • The section you link makes a note about a feeder thread, but the documentation of the put method still declares it a blocking or failing method: "If the optional argument block is True (the default) and timeout is None (the default), block if necessary until a free slot is available. If timeout is a positive number, it blocks at most timeout seconds and raises the queue.Full exception if no free slot was available within that time." Are you sure about your answer? – Anab Sep 5 '20 at 20:52
  • I am sure about my answer. The put method will block if the maxsize parameter to the constructor of Queue is specified. But this will be because of the number of items in the queue, not the size of individual items. – Roger Iyengar Sep 6 '20 at 20:59
  • Thanks for the clarification, I had missed that part. – Anab Sep 6 '20 at 21:03

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