Python Multithreading/Multiprocessing Examples

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Revision as of 16:37, 25 January 2017 by Thiebaut (talk | contribs) (Example 1)
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--D. Thiebaut (talk) 15:27, 25 January 2017 (EST)


Multithreading in Python


Warning! The multithreading module in Python does not provide true parallelism. Read up on the Global Interactive Lock if you want to learn more about this problem.

Example 1


# PythonThreading_Example1.py
# D. Thiebaut
# Taken and adapted from
# https://pymotw.com/2/threading/
#
# Python program illustrating how threads can
# be created and started in Python

from __future__ import print_function
import threading
import time


def worker( Id ):
    """
    thread worker function.  It receives an Id,
    and prints a message indicating it's starting.
    waits 0.5 seconds, prints another message, and dies.
    """
    print( 'Worker %d started\n' % Id )
    time.sleep( 0.5 )
    print( 'Worker %d finished\n' % Id )
    return

def main():
    """
    Spawns 5 threads that will run the worker function.
    Waits for the threads to finish, then stops.
    """
    threads = []
    for i in range(5):
        t = threading.Thread( target=worker, args=(i,) )
        threads.append(t)
        t.start()
    print( "Main has spawn all the threads" )

    # wait for all the threads to finish
    for t in threads:
        t.join()
        
    print( "Done!" )
    
main()


Computing Pi, Serial Version


# ComputingPy.py
# D. Thiebaut
#
# Computes an approximation of Pi by summing up
# a series of terms.  The more terms, the closer
# the approximation.
#

def f( x ):
    """
    The function being integrated, and which returns
    an approximation of Pi when summed up over an interval
    of integers.
    """
    return 4.0 / ( 1 + x*x )


def main():
    """
    Gets a number of terms from the user, then sums
    up the series and prints the resulting sum, which
    should approximate Pi.
    """

    # get the number of terms
    N = int( input( "> " ) )

    sum = 0.0          # where we sum up the individual
                       # intervals
    deltaX = 1.0 / N   # the interval

    # sum over N terms
    for i in range( N ):
        sum += f( i * deltaX )

    # display results
    print( "sum = %1.9f" % ( sum * deltaX ) )

main()