cpython/Doc/includes/mp_pool.py

#
# A test of `multiprocessing.Pool` class
#
# Copyright (c) 2006-2008, R Oudkerk
# All rights reserved.
#

import multiprocessing
import time
import random
import sys

#
# Functions used by test code
#

def calculate(func, args):
    result = func(*args)
    return '%s says that %s%s = %s' % (
        multiprocessing.current_process().name,
        func.__name__, args, result
        )

def calculatestar(args):
    return calculate(*args)

def mul(a, b):
    time.sleep(0.5*random.random())
    return a * b

def plus(a, b):
    time.sleep(0.5*random.random())
    return a + b

def f(x):
    return 1.0 / (x-5.0)

def pow3(x):
    return x**3

def noop(x):
    pass

#
# Test code
#

def test():
    print 'cpu_count() = %d\n' % multiprocessing.cpu_count()

    #
    # Create pool
    #

    PROCESSES = 4
    print 'Creating pool with %d processes\n' % PROCESSES
    pool = multiprocessing.Pool(PROCESSES)
    print 'pool = %s' % pool
    print

    #
    # Tests
    #

    TASKS = [(mul, (i, 7)) for i in range(10)] + \
            [(plus, (i, 8)) for i in range(10)]

    results = [pool.apply_async(calculate, t) for t in TASKS]
    imap_it = pool.imap(calculatestar, TASKS)
    imap_unordered_it = pool.imap_unordered(calculatestar, TASKS)

    print 'Ordered results using pool.apply_async():'
    for r in results:
        print '\t', r.get()
    print

    print 'Ordered results using pool.imap():'
    for x in imap_it:
        print '\t', x
    print

    print 'Unordered results using pool.imap_unordered():'
    for x in imap_unordered_it:
        print '\t', x
    print

    print 'Ordered results using pool.map() --- will block till complete:'
    for x in pool.map(calculatestar, TASKS):
        print '\t', x
    print

    #
    # Simple benchmarks
    #

    N = 100000
    print 'def pow3(x): return x**3'

    t = time.time()
    A = map(pow3, xrange(N))
    print '\tmap(pow3, xrange(%d)):\n\t\t%s seconds' % \
          (N, time.time() - t)

    t = time.time()
    B = pool.map(pow3, xrange(N))
    print '\tpool.map(pow3, xrange(%d)):\n\t\t%s seconds' % \
          (N, time.time() - t)

    t = time.time()
    C = list(pool.imap(pow3, xrange(N), chunksize=N//8))
    print '\tlist(pool.imap(pow3, xrange(%d), chunksize=%d)):\n\t\t%s' \
          ' seconds' % (N, N//8, time.time() - t)

    assert A == B == C, (len(A), len(B), len(C))
    print

    L = [None] * 1000000
    print 'def noop(x): pass'
    print 'L = [None] * 1000000'

    t = time.time()
    A = map(noop, L)
    print '\tmap(noop, L):\n\t\t%s seconds' % \
          (time.time() - t)

    t = time.time()
    B = pool.map(noop, L)
    print '\tpool.map(noop, L):\n\t\t%s seconds' % \
          (time.time() - t)

    t = time.time()
    C = list(pool.imap(noop, L, chunksize=len(L)//8))
    print '\tlist(pool.imap(noop, L, chunksize=%d)):\n\t\t%s seconds' % \
          (len(L)//8, time.time() - t)

    assert A == B == C, (len(A), len(B), len(C))
    print

    del A, B, C, L

    #
    # Test error handling
    #

    print 'Testing error handling:'

    try:
        print pool.apply(f, (5,))
    except ZeroDivisionError:
        print '\tGot ZeroDivisionError as expected from pool.apply()'
    else:
        raise AssertionError, 'expected ZeroDivisionError'

    try:
        print pool.map(f, range(10))
    except ZeroDivisionError:
        print '\tGot ZeroDivisionError as expected from pool.map()'
    else:
        raise AssertionError, 'expected ZeroDivisionError'

    try:
        print list(pool.imap(f, range(10)))
    except ZeroDivisionError:
        print '\tGot ZeroDivisionError as expected from list(pool.imap())'
    else:
        raise AssertionError, 'expected ZeroDivisionError'

    it = pool.imap(f, range(10))
    for i in range(10):
        try:
            x = it.next()
        except ZeroDivisionError:
            if i == 5:
                pass
        except StopIteration:
            break
        else:
            if i == 5:
                raise AssertionError, 'expected ZeroDivisionError'

    assert i == 9
    print '\tGot ZeroDivisionError as expected from IMapIterator.next()'
    print

    #
    # Testing timeouts
    #

    print 'Testing ApplyResult.get() with timeout:',
    res = pool.apply_async(calculate, TASKS[0])
    while 1:
        sys.stdout.flush()
        try:
            sys.stdout.write('\n\t%s' % res.get(0.02))
            break
        except multiprocessing.TimeoutError:
            sys.stdout.write('.')
    print
    print

    print 'Testing IMapIterator.next() with timeout:',
    it = pool.imap(calculatestar, TASKS)
    while 1:
        sys.stdout.flush()
        try:
            sys.stdout.write('\n\t%s' % it.next(0.02))
        except StopIteration:
            break
        except multiprocessing.TimeoutError:
            sys.stdout.write('.')
    print
    print

    #
    # Testing callback
    #

    print 'Testing callback:'

    A = []
    B = [56, 0, 1, 8, 27, 64, 125, 216, 343, 512, 729]

    r = pool.apply_async(mul, (7, 8), callback=A.append)
    r.wait()

    r = pool.map_async(pow3, range(10), callback=A.extend)
    r.wait()

    if A == B:
        print '\tcallbacks succeeded\n'
    else:
        print '\t*** callbacks failed\n\t\t%s != %s\n' % (A, B)

    #
    # Check there are no outstanding tasks
    #

    assert not pool._cache, 'cache = %r' % pool._cache

    #
    # Check close() methods
    #

    print 'Testing close():'

    for worker in pool._pool:
        assert worker.is_alive()

    result = pool.apply_async(time.sleep, [0.5])
    pool.close()
    pool.join()

    assert result.get() is None

    for worker in pool._pool:
        assert not worker.is_alive()

    print '\tclose() succeeded\n'

    #
    # Check terminate() method
    #

    print 'Testing terminate():'

    pool = multiprocessing.Pool(2)
    DELTA = 0.1
    ignore = pool.apply(pow3, [2])
    results = [pool.apply_async(time.sleep, [DELTA]) for i in range(100)]
    pool.terminate()
    pool.join()

    for worker in pool._pool:
        assert not worker.is_alive()

    print '\tterminate() succeeded\n'

    #
    # Check garbage collection
    #

    print 'Testing garbage collection:'

    pool = multiprocessing.Pool(2)
    DELTA = 0.1
    processes = pool._pool
    ignore = pool.apply(pow3, [2])
    results = [pool.apply_async(time.sleep, [DELTA]) for i in range(100)]

    results = pool = None

    time.sleep(DELTA * 2)

    for worker in processes:
        assert not worker.is_alive()

    print '\tgarbage collection succeeded\n'


if __name__ == '__main__':
    multiprocessing.freeze_support()

    assert len(sys.argv) in (1, 2)

    if len(sys.argv) == 1 or sys.argv[1] == 'processes':
        print ' Using processes '.center(79, '-')
    elif sys.argv[1] == 'threads':
        print ' Using threads '.center(79, '-')
        import multiprocessing.dummy as multiprocessing
    else:
        print 'Usage:\n\t%s [processes | threads]' % sys.argv[0]
        raise SystemExit(2)

    test()
add the multiprocessing package to fulfill PEP 371 2008-06-10 23:40:25 -03:00			`#`
			# A test of `multiprocessing.Pool` class
			`#`
Retain copyright of processing examples. This was requested by a Debian maintainer during packaging of the multiprocessing package for 2.4/2.5 2008-11-28 15:33:33 -04:00			`# Copyright (c) 2006-2008, R Oudkerk`
			`# All rights reserved.`
			`#`
add the multiprocessing package to fulfill PEP 371 2008-06-10 23:40:25 -03:00
			`import multiprocessing`
			`import time`
			`import random`
			`import sys`

			`#`
			`# Functions used by test code`
			`#`

			`def calculate(func, args):`
			`result = func(*args)`
			`return '%s says that %s%s = %s' % (`
issue3352: clean up the multiprocessing API to remove many get_/set_ methods and convert them to properties. Update the docs and the examples included. 2008-08-19 16:06:19 -03:00			`multiprocessing.current_process().name,`
add the multiprocessing package to fulfill PEP 371 2008-06-10 23:40:25 -03:00			`func.__name__, args, result`
			`)`

			`def calculatestar(args):`
			`return calculate(*args)`

			`def mul(a, b):`
			`time.sleep(0.5*random.random())`
			`return a * b`

			`def plus(a, b):`
			`time.sleep(0.5*random.random())`
			`return a + b`

			`def f(x):`
			`return 1.0 / (x-5.0)`

			`def pow3(x):`
			`return x**3`

			`def noop(x):`
			`pass`

			`#`
			`# Test code`
			`#`

			`def test():`
			`print 'cpu_count() = %d\n' % multiprocessing.cpu_count()`

			`#`
			`# Create pool`
			`#`

			`PROCESSES = 4`
			`print 'Creating pool with %d processes\n' % PROCESSES`
			`pool = multiprocessing.Pool(PROCESSES)`
			`print 'pool = %s' % pool`
			`print`

			`#`
			`# Tests`
			`#`

			`TASKS = [(mul, (i, 7)) for i in range(10)] + \`
			`[(plus, (i, 8)) for i in range(10)]`

			`results = [pool.apply_async(calculate, t) for t in TASKS]`
			`imap_it = pool.imap(calculatestar, TASKS)`
			`imap_unordered_it = pool.imap_unordered(calculatestar, TASKS)`

			`print 'Ordered results using pool.apply_async():'`
			`for r in results:`
			`print '\t', r.get()`
			`print`

			`print 'Ordered results using pool.imap():'`
			`for x in imap_it:`
			`print '\t', x`
			`print`

			`print 'Unordered results using pool.imap_unordered():'`
			`for x in imap_unordered_it:`
			`print '\t', x`
			`print`

			`print 'Ordered results using pool.map() --- will block till complete:'`
			`for x in pool.map(calculatestar, TASKS):`
			`print '\t', x`
			`print`

			`#`
			`# Simple benchmarks`
			`#`

			`N = 100000`
			`print 'def pow3(x): return x**3'`

			`t = time.time()`
			`A = map(pow3, xrange(N))`
			`print '\tmap(pow3, xrange(%d)):\n\t\t%s seconds' % \`
			`(N, time.time() - t)`

			`t = time.time()`
			`B = pool.map(pow3, xrange(N))`
			`print '\tpool.map(pow3, xrange(%d)):\n\t\t%s seconds' % \`
			`(N, time.time() - t)`

			`t = time.time()`
			`C = list(pool.imap(pow3, xrange(N), chunksize=N//8))`
			`print '\tlist(pool.imap(pow3, xrange(%d), chunksize=%d)):\n\t\t%s' \`
			`' seconds' % (N, N//8, time.time() - t)`

			`assert A == B == C, (len(A), len(B), len(C))`
			`print`

			`L = [None] * 1000000`
			`print 'def noop(x): pass'`
			`print 'L = [None] * 1000000'`

			`t = time.time()`
			`A = map(noop, L)`
			`print '\tmap(noop, L):\n\t\t%s seconds' % \`
			`(time.time() - t)`

			`t = time.time()`
			`B = pool.map(noop, L)`
			`print '\tpool.map(noop, L):\n\t\t%s seconds' % \`
			`(time.time() - t)`

			`t = time.time()`
			`C = list(pool.imap(noop, L, chunksize=len(L)//8))`
			`print '\tlist(pool.imap(noop, L, chunksize=%d)):\n\t\t%s seconds' % \`
			`(len(L)//8, time.time() - t)`

			`assert A == B == C, (len(A), len(B), len(C))`
			`print`

			`del A, B, C, L`

			`#`
			`# Test error handling`
			`#`

			`print 'Testing error handling:'`

			`try:`
			`print pool.apply(f, (5,))`
			`except ZeroDivisionError:`
			`print '\tGot ZeroDivisionError as expected from pool.apply()'`
			`else:`
			`raise AssertionError, 'expected ZeroDivisionError'`

			`try:`
			`print pool.map(f, range(10))`
			`except ZeroDivisionError:`
			`print '\tGot ZeroDivisionError as expected from pool.map()'`
			`else:`
			`raise AssertionError, 'expected ZeroDivisionError'`

			`try:`
			`print list(pool.imap(f, range(10)))`
			`except ZeroDivisionError:`
			`print '\tGot ZeroDivisionError as expected from list(pool.imap())'`
			`else:`
			`raise AssertionError, 'expected ZeroDivisionError'`

			`it = pool.imap(f, range(10))`
			`for i in range(10):`
			`try:`
			`x = it.next()`
			`except ZeroDivisionError:`
			`if i == 5:`
			`pass`
			`except StopIteration:`
			`break`
			`else:`
			`if i == 5:`
			`raise AssertionError, 'expected ZeroDivisionError'`

			`assert i == 9`
			`print '\tGot ZeroDivisionError as expected from IMapIterator.next()'`
			`print`

			`#`
			`# Testing timeouts`
			`#`

			`print 'Testing ApplyResult.get() with timeout:',`
			`res = pool.apply_async(calculate, TASKS[0])`
			`while 1:`
			`sys.stdout.flush()`
			`try:`
			`sys.stdout.write('\n\t%s' % res.get(0.02))`
			`break`
			`except multiprocessing.TimeoutError:`
			`sys.stdout.write('.')`
			`print`
			`print`

			`print 'Testing IMapIterator.next() with timeout:',`
			`it = pool.imap(calculatestar, TASKS)`
			`while 1:`
			`sys.stdout.flush()`
			`try:`
			`sys.stdout.write('\n\t%s' % it.next(0.02))`
			`except StopIteration:`
			`break`
			`except multiprocessing.TimeoutError:`
			`sys.stdout.write('.')`
			`print`
			`print`

			`#`
			`# Testing callback`
			`#`

			`print 'Testing callback:'`

			`A = []`
			`B = [56, 0, 1, 8, 27, 64, 125, 216, 343, 512, 729]`

			`r = pool.apply_async(mul, (7, 8), callback=A.append)`
			`r.wait()`

			`r = pool.map_async(pow3, range(10), callback=A.extend)`
			`r.wait()`

			`if A == B:`
			`print '\tcallbacks succeeded\n'`
			`else:`
			`print '\t*** callbacks failed\n\t\t%s != %s\n' % (A, B)`

			`#`
			`# Check there are no outstanding tasks`
			`#`

			`assert not pool._cache, 'cache = %r' % pool._cache`

			`#`
			`# Check close() methods`
			`#`

			`print 'Testing close():'`

			`for worker in pool._pool:`
			`assert worker.is_alive()`

			`result = pool.apply_async(time.sleep, [0.5])`
			`pool.close()`
			`pool.join()`

			`assert result.get() is None`

			`for worker in pool._pool:`
			`assert not worker.is_alive()`

			`print '\tclose() succeeded\n'`

			`#`
			`# Check terminate() method`
			`#`

			`print 'Testing terminate():'`

			`pool = multiprocessing.Pool(2)`
			`DELTA = 0.1`
			`ignore = pool.apply(pow3, [2])`
			`results = [pool.apply_async(time.sleep, [DELTA]) for i in range(100)]`
			`pool.terminate()`
			`pool.join()`

			`for worker in pool._pool:`
			`assert not worker.is_alive()`

			`print '\tterminate() succeeded\n'`

			`#`
			`# Check garbage collection`
			`#`

			`print 'Testing garbage collection:'`

			`pool = multiprocessing.Pool(2)`
			`DELTA = 0.1`
			`processes = pool._pool`
			`ignore = pool.apply(pow3, [2])`
			`results = [pool.apply_async(time.sleep, [DELTA]) for i in range(100)]`

			`results = pool = None`

			`time.sleep(DELTA * 2)`

			`for worker in processes:`
			`assert not worker.is_alive()`

			`print '\tgarbage collection succeeded\n'`


			`if __name__ == '__main__':`
			`multiprocessing.freeze_support()`

			`assert len(sys.argv) in (1, 2)`

			`if len(sys.argv) == 1 or sys.argv[1] == 'processes':`
			`print ' Using processes '.center(79, '-')`
			`elif sys.argv[1] == 'threads':`
			`print ' Using threads '.center(79, '-')`
			`import multiprocessing.dummy as multiprocessing`
			`else:`
			`print 'Usage:\n\t%s [processes \| threads]' % sys.argv[0]`
			`raise SystemExit(2)`

			`test()`