cpython/Lib/test/_test_multiprocessing.py

5044 lines
156 KiB
Python

#
# Unit tests for the multiprocessing package
#
import unittest
import queue as pyqueue
import contextlib
import time
import io
import itertools
import sys
import os
import gc
import errno
import signal
import array
import socket
import random
import logging
import struct
import operator
import weakref
import test.support
import test.support.script_helper
from test import support
# Skip tests if _multiprocessing wasn't built.
_multiprocessing = test.support.import_module('_multiprocessing')
# Skip tests if sem_open implementation is broken.
test.support.import_module('multiprocessing.synchronize')
# import threading after _multiprocessing to raise a more relevant error
# message: "No module named _multiprocessing". _multiprocessing is not compiled
# without thread support.
import threading
import multiprocessing.connection
import multiprocessing.dummy
import multiprocessing.heap
import multiprocessing.managers
import multiprocessing.pool
import multiprocessing.queues
from multiprocessing import util
try:
from multiprocessing import reduction
HAS_REDUCTION = reduction.HAVE_SEND_HANDLE
except ImportError:
HAS_REDUCTION = False
try:
from multiprocessing.sharedctypes import Value, copy
HAS_SHAREDCTYPES = True
except ImportError:
HAS_SHAREDCTYPES = False
try:
import msvcrt
except ImportError:
msvcrt = None
#
#
#
# Timeout to wait until a process completes
TIMEOUT = 60.0 # seconds
def latin(s):
return s.encode('latin')
def close_queue(queue):
if isinstance(queue, multiprocessing.queues.Queue):
queue.close()
queue.join_thread()
def join_process(process):
# Since multiprocessing.Process has the same API than threading.Thread
# (join() and is_alive(), the support function can be reused
support.join_thread(process, timeout=TIMEOUT)
#
# Constants
#
LOG_LEVEL = util.SUBWARNING
#LOG_LEVEL = logging.DEBUG
DELTA = 0.1
CHECK_TIMINGS = False # making true makes tests take a lot longer
# and can sometimes cause some non-serious
# failures because some calls block a bit
# longer than expected
if CHECK_TIMINGS:
TIMEOUT1, TIMEOUT2, TIMEOUT3 = 0.82, 0.35, 1.4
else:
TIMEOUT1, TIMEOUT2, TIMEOUT3 = 0.1, 0.1, 0.1
HAVE_GETVALUE = not getattr(_multiprocessing,
'HAVE_BROKEN_SEM_GETVALUE', False)
WIN32 = (sys.platform == "win32")
from multiprocessing.connection import wait
def wait_for_handle(handle, timeout):
if timeout is not None and timeout < 0.0:
timeout = None
return wait([handle], timeout)
try:
MAXFD = os.sysconf("SC_OPEN_MAX")
except:
MAXFD = 256
# To speed up tests when using the forkserver, we can preload these:
PRELOAD = ['__main__', 'test.test_multiprocessing_forkserver']
#
# Some tests require ctypes
#
try:
from ctypes import Structure, c_int, c_double, c_longlong
except ImportError:
Structure = object
c_int = c_double = c_longlong = None
def check_enough_semaphores():
"""Check that the system supports enough semaphores to run the test."""
# minimum number of semaphores available according to POSIX
nsems_min = 256
try:
nsems = os.sysconf("SC_SEM_NSEMS_MAX")
except (AttributeError, ValueError):
# sysconf not available or setting not available
return
if nsems == -1 or nsems >= nsems_min:
return
raise unittest.SkipTest("The OS doesn't support enough semaphores "
"to run the test (required: %d)." % nsems_min)
#
# Creates a wrapper for a function which records the time it takes to finish
#
class TimingWrapper(object):
def __init__(self, func):
self.func = func
self.elapsed = None
def __call__(self, *args, **kwds):
t = time.monotonic()
try:
return self.func(*args, **kwds)
finally:
self.elapsed = time.monotonic() - t
#
# Base class for test cases
#
class BaseTestCase(object):
ALLOWED_TYPES = ('processes', 'manager', 'threads')
def assertTimingAlmostEqual(self, a, b):
if CHECK_TIMINGS:
self.assertAlmostEqual(a, b, 1)
def assertReturnsIfImplemented(self, value, func, *args):
try:
res = func(*args)
except NotImplementedError:
pass
else:
return self.assertEqual(value, res)
# For the sanity of Windows users, rather than crashing or freezing in
# multiple ways.
def __reduce__(self, *args):
raise NotImplementedError("shouldn't try to pickle a test case")
__reduce_ex__ = __reduce__
#
# Return the value of a semaphore
#
def get_value(self):
try:
return self.get_value()
except AttributeError:
try:
return self._Semaphore__value
except AttributeError:
try:
return self._value
except AttributeError:
raise NotImplementedError
#
# Testcases
#
class DummyCallable:
def __call__(self, q, c):
assert isinstance(c, DummyCallable)
q.put(5)
class _TestProcess(BaseTestCase):
ALLOWED_TYPES = ('processes', 'threads')
def test_current(self):
if self.TYPE == 'threads':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
current = self.current_process()
authkey = current.authkey
self.assertTrue(current.is_alive())
self.assertTrue(not current.daemon)
self.assertIsInstance(authkey, bytes)
self.assertTrue(len(authkey) > 0)
self.assertEqual(current.ident, os.getpid())
self.assertEqual(current.exitcode, None)
def test_daemon_argument(self):
if self.TYPE == "threads":
self.skipTest('test not appropriate for {}'.format(self.TYPE))
# By default uses the current process's daemon flag.
proc0 = self.Process(target=self._test)
self.assertEqual(proc0.daemon, self.current_process().daemon)
proc1 = self.Process(target=self._test, daemon=True)
self.assertTrue(proc1.daemon)
proc2 = self.Process(target=self._test, daemon=False)
self.assertFalse(proc2.daemon)
@classmethod
def _test(cls, q, *args, **kwds):
current = cls.current_process()
q.put(args)
q.put(kwds)
q.put(current.name)
if cls.TYPE != 'threads':
q.put(bytes(current.authkey))
q.put(current.pid)
def test_process(self):
q = self.Queue(1)
e = self.Event()
args = (q, 1, 2)
kwargs = {'hello':23, 'bye':2.54}
name = 'SomeProcess'
p = self.Process(
target=self._test, args=args, kwargs=kwargs, name=name
)
p.daemon = True
current = self.current_process()
if self.TYPE != 'threads':
self.assertEqual(p.authkey, current.authkey)
self.assertEqual(p.is_alive(), False)
self.assertEqual(p.daemon, True)
self.assertNotIn(p, self.active_children())
self.assertTrue(type(self.active_children()) is list)
self.assertEqual(p.exitcode, None)
p.start()
self.assertEqual(p.exitcode, None)
self.assertEqual(p.is_alive(), True)
self.assertIn(p, self.active_children())
self.assertEqual(q.get(), args[1:])
self.assertEqual(q.get(), kwargs)
self.assertEqual(q.get(), p.name)
if self.TYPE != 'threads':
self.assertEqual(q.get(), current.authkey)
self.assertEqual(q.get(), p.pid)
p.join()
self.assertEqual(p.exitcode, 0)
self.assertEqual(p.is_alive(), False)
self.assertNotIn(p, self.active_children())
close_queue(q)
@classmethod
def _sleep_some(cls):
time.sleep(100)
@classmethod
def _test_sleep(cls, delay):
time.sleep(delay)
def _kill_process(self, meth):
if self.TYPE == 'threads':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
p = self.Process(target=self._sleep_some)
p.daemon = True
p.start()
self.assertEqual(p.is_alive(), True)
self.assertIn(p, self.active_children())
self.assertEqual(p.exitcode, None)
join = TimingWrapper(p.join)
self.assertEqual(join(0), None)
self.assertTimingAlmostEqual(join.elapsed, 0.0)
self.assertEqual(p.is_alive(), True)
self.assertEqual(join(-1), None)
self.assertTimingAlmostEqual(join.elapsed, 0.0)
self.assertEqual(p.is_alive(), True)
# XXX maybe terminating too soon causes the problems on Gentoo...
time.sleep(1)
meth(p)
if hasattr(signal, 'alarm'):
# On the Gentoo buildbot waitpid() often seems to block forever.
# We use alarm() to interrupt it if it blocks for too long.
def handler(*args):
raise RuntimeError('join took too long: %s' % p)
old_handler = signal.signal(signal.SIGALRM, handler)
try:
signal.alarm(10)
self.assertEqual(join(), None)
finally:
signal.alarm(0)
signal.signal(signal.SIGALRM, old_handler)
else:
self.assertEqual(join(), None)
self.assertTimingAlmostEqual(join.elapsed, 0.0)
self.assertEqual(p.is_alive(), False)
self.assertNotIn(p, self.active_children())
p.join()
return p.exitcode
def test_terminate(self):
exitcode = self._kill_process(multiprocessing.Process.terminate)
if os.name != 'nt':
self.assertEqual(exitcode, -signal.SIGTERM)
def test_kill(self):
exitcode = self._kill_process(multiprocessing.Process.kill)
if os.name != 'nt':
self.assertEqual(exitcode, -signal.SIGKILL)
def test_cpu_count(self):
try:
cpus = multiprocessing.cpu_count()
except NotImplementedError:
cpus = 1
self.assertTrue(type(cpus) is int)
self.assertTrue(cpus >= 1)
def test_active_children(self):
self.assertEqual(type(self.active_children()), list)
p = self.Process(target=time.sleep, args=(DELTA,))
self.assertNotIn(p, self.active_children())
p.daemon = True
p.start()
self.assertIn(p, self.active_children())
p.join()
self.assertNotIn(p, self.active_children())
@classmethod
def _test_recursion(cls, wconn, id):
wconn.send(id)
if len(id) < 2:
for i in range(2):
p = cls.Process(
target=cls._test_recursion, args=(wconn, id+[i])
)
p.start()
p.join()
def test_recursion(self):
rconn, wconn = self.Pipe(duplex=False)
self._test_recursion(wconn, [])
time.sleep(DELTA)
result = []
while rconn.poll():
result.append(rconn.recv())
expected = [
[],
[0],
[0, 0],
[0, 1],
[1],
[1, 0],
[1, 1]
]
self.assertEqual(result, expected)
@classmethod
def _test_sentinel(cls, event):
event.wait(10.0)
def test_sentinel(self):
if self.TYPE == "threads":
self.skipTest('test not appropriate for {}'.format(self.TYPE))
event = self.Event()
p = self.Process(target=self._test_sentinel, args=(event,))
with self.assertRaises(ValueError):
p.sentinel
p.start()
self.addCleanup(p.join)
sentinel = p.sentinel
self.assertIsInstance(sentinel, int)
self.assertFalse(wait_for_handle(sentinel, timeout=0.0))
event.set()
p.join()
self.assertTrue(wait_for_handle(sentinel, timeout=1))
@classmethod
def _test_close(cls, rc=0, q=None):
if q is not None:
q.get()
sys.exit(rc)
def test_close(self):
if self.TYPE == "threads":
self.skipTest('test not appropriate for {}'.format(self.TYPE))
q = self.Queue()
p = self.Process(target=self._test_close, kwargs={'q': q})
p.daemon = True
p.start()
self.assertEqual(p.is_alive(), True)
# Child is still alive, cannot close
with self.assertRaises(ValueError):
p.close()
q.put(None)
p.join()
self.assertEqual(p.is_alive(), False)
self.assertEqual(p.exitcode, 0)
p.close()
with self.assertRaises(ValueError):
p.is_alive()
with self.assertRaises(ValueError):
p.join()
with self.assertRaises(ValueError):
p.terminate()
p.close()
wr = weakref.ref(p)
del p
gc.collect()
self.assertIs(wr(), None)
close_queue(q)
def test_many_processes(self):
if self.TYPE == 'threads':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
sm = multiprocessing.get_start_method()
N = 5 if sm == 'spawn' else 100
# Try to overwhelm the forkserver loop with events
procs = [self.Process(target=self._test_sleep, args=(0.01,))
for i in range(N)]
for p in procs:
p.start()
for p in procs:
join_process(p)
for p in procs:
self.assertEqual(p.exitcode, 0)
procs = [self.Process(target=self._sleep_some)
for i in range(N)]
for p in procs:
p.start()
time.sleep(0.001) # let the children start...
for p in procs:
p.terminate()
for p in procs:
join_process(p)
if os.name != 'nt':
exitcodes = [-signal.SIGTERM]
if sys.platform == 'darwin':
# bpo-31510: On macOS, killing a freshly started process with
# SIGTERM sometimes kills the process with SIGKILL.
exitcodes.append(-signal.SIGKILL)
for p in procs:
self.assertIn(p.exitcode, exitcodes)
def test_lose_target_ref(self):
c = DummyCallable()
wr = weakref.ref(c)
q = self.Queue()
p = self.Process(target=c, args=(q, c))
del c
p.start()
p.join()
self.assertIs(wr(), None)
self.assertEqual(q.get(), 5)
close_queue(q)
@classmethod
def _test_child_fd_inflation(self, evt, q):
q.put(test.support.fd_count())
evt.wait()
def test_child_fd_inflation(self):
# Number of fds in child processes should not grow with the
# number of running children.
if self.TYPE == 'threads':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
sm = multiprocessing.get_start_method()
if sm == 'fork':
# The fork method by design inherits all fds from the parent,
# trying to go against it is a lost battle
self.skipTest('test not appropriate for {}'.format(sm))
N = 5
evt = self.Event()
q = self.Queue()
procs = [self.Process(target=self._test_child_fd_inflation, args=(evt, q))
for i in range(N)]
for p in procs:
p.start()
try:
fd_counts = [q.get() for i in range(N)]
self.assertEqual(len(set(fd_counts)), 1, fd_counts)
finally:
evt.set()
for p in procs:
p.join()
close_queue(q)
@classmethod
def _test_wait_for_threads(self, evt):
def func1():
time.sleep(0.5)
evt.set()
def func2():
time.sleep(20)
evt.clear()
threading.Thread(target=func1).start()
threading.Thread(target=func2, daemon=True).start()
def test_wait_for_threads(self):
# A child process should wait for non-daemonic threads to end
# before exiting
if self.TYPE == 'threads':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
evt = self.Event()
proc = self.Process(target=self._test_wait_for_threads, args=(evt,))
proc.start()
proc.join()
self.assertTrue(evt.is_set())
@classmethod
def _test_error_on_stdio_flush(self, evt, break_std_streams={}):
for stream_name, action in break_std_streams.items():
if action == 'close':
stream = io.StringIO()
stream.close()
else:
assert action == 'remove'
stream = None
setattr(sys, stream_name, None)
evt.set()
def test_error_on_stdio_flush_1(self):
# Check that Process works with broken standard streams
streams = [io.StringIO(), None]
streams[0].close()
for stream_name in ('stdout', 'stderr'):
for stream in streams:
old_stream = getattr(sys, stream_name)
setattr(sys, stream_name, stream)
try:
evt = self.Event()
proc = self.Process(target=self._test_error_on_stdio_flush,
args=(evt,))
proc.start()
proc.join()
self.assertTrue(evt.is_set())
self.assertEqual(proc.exitcode, 0)
finally:
setattr(sys, stream_name, old_stream)
def test_error_on_stdio_flush_2(self):
# Same as test_error_on_stdio_flush_1(), but standard streams are
# broken by the child process
for stream_name in ('stdout', 'stderr'):
for action in ('close', 'remove'):
old_stream = getattr(sys, stream_name)
try:
evt = self.Event()
proc = self.Process(target=self._test_error_on_stdio_flush,
args=(evt, {stream_name: action}))
proc.start()
proc.join()
self.assertTrue(evt.is_set())
self.assertEqual(proc.exitcode, 0)
finally:
setattr(sys, stream_name, old_stream)
@classmethod
def _sleep_and_set_event(self, evt, delay=0.0):
time.sleep(delay)
evt.set()
def check_forkserver_death(self, signum):
# bpo-31308: if the forkserver process has died, we should still
# be able to create and run new Process instances (the forkserver
# is implicitly restarted).
if self.TYPE == 'threads':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
sm = multiprocessing.get_start_method()
if sm != 'forkserver':
# The fork method by design inherits all fds from the parent,
# trying to go against it is a lost battle
self.skipTest('test not appropriate for {}'.format(sm))
from multiprocessing.forkserver import _forkserver
_forkserver.ensure_running()
# First process sleeps 500 ms
delay = 0.5
evt = self.Event()
proc = self.Process(target=self._sleep_and_set_event, args=(evt, delay))
proc.start()
pid = _forkserver._forkserver_pid
os.kill(pid, signum)
# give time to the fork server to die and time to proc to complete
time.sleep(delay * 2.0)
evt2 = self.Event()
proc2 = self.Process(target=self._sleep_and_set_event, args=(evt2,))
proc2.start()
proc2.join()
self.assertTrue(evt2.is_set())
self.assertEqual(proc2.exitcode, 0)
proc.join()
self.assertTrue(evt.is_set())
self.assertIn(proc.exitcode, (0, 255))
def test_forkserver_sigint(self):
# Catchable signal
self.check_forkserver_death(signal.SIGINT)
def test_forkserver_sigkill(self):
# Uncatchable signal
if os.name != 'nt':
self.check_forkserver_death(signal.SIGKILL)
#
#
#
class _UpperCaser(multiprocessing.Process):
def __init__(self):
multiprocessing.Process.__init__(self)
self.child_conn, self.parent_conn = multiprocessing.Pipe()
def run(self):
self.parent_conn.close()
for s in iter(self.child_conn.recv, None):
self.child_conn.send(s.upper())
self.child_conn.close()
def submit(self, s):
assert type(s) is str
self.parent_conn.send(s)
return self.parent_conn.recv()
def stop(self):
self.parent_conn.send(None)
self.parent_conn.close()
self.child_conn.close()
class _TestSubclassingProcess(BaseTestCase):
ALLOWED_TYPES = ('processes',)
def test_subclassing(self):
uppercaser = _UpperCaser()
uppercaser.daemon = True
uppercaser.start()
self.assertEqual(uppercaser.submit('hello'), 'HELLO')
self.assertEqual(uppercaser.submit('world'), 'WORLD')
uppercaser.stop()
uppercaser.join()
def test_stderr_flush(self):
# sys.stderr is flushed at process shutdown (issue #13812)
if self.TYPE == "threads":
self.skipTest('test not appropriate for {}'.format(self.TYPE))
testfn = test.support.TESTFN
self.addCleanup(test.support.unlink, testfn)
proc = self.Process(target=self._test_stderr_flush, args=(testfn,))
proc.start()
proc.join()
with open(testfn, 'r') as f:
err = f.read()
# The whole traceback was printed
self.assertIn("ZeroDivisionError", err)
self.assertIn("test_multiprocessing.py", err)
self.assertIn("1/0 # MARKER", err)
@classmethod
def _test_stderr_flush(cls, testfn):
fd = os.open(testfn, os.O_WRONLY | os.O_CREAT | os.O_EXCL)
sys.stderr = open(fd, 'w', closefd=False)
1/0 # MARKER
@classmethod
def _test_sys_exit(cls, reason, testfn):
fd = os.open(testfn, os.O_WRONLY | os.O_CREAT | os.O_EXCL)
sys.stderr = open(fd, 'w', closefd=False)
sys.exit(reason)
def test_sys_exit(self):
# See Issue 13854
if self.TYPE == 'threads':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
testfn = test.support.TESTFN
self.addCleanup(test.support.unlink, testfn)
for reason in (
[1, 2, 3],
'ignore this',
):
p = self.Process(target=self._test_sys_exit, args=(reason, testfn))
p.daemon = True
p.start()
join_process(p)
self.assertEqual(p.exitcode, 1)
with open(testfn, 'r') as f:
content = f.read()
self.assertEqual(content.rstrip(), str(reason))
os.unlink(testfn)
for reason in (True, False, 8):
p = self.Process(target=sys.exit, args=(reason,))
p.daemon = True
p.start()
join_process(p)
self.assertEqual(p.exitcode, reason)
#
#
#
def queue_empty(q):
if hasattr(q, 'empty'):
return q.empty()
else:
return q.qsize() == 0
def queue_full(q, maxsize):
if hasattr(q, 'full'):
return q.full()
else:
return q.qsize() == maxsize
class _TestQueue(BaseTestCase):
@classmethod
def _test_put(cls, queue, child_can_start, parent_can_continue):
child_can_start.wait()
for i in range(6):
queue.get()
parent_can_continue.set()
def test_put(self):
MAXSIZE = 6
queue = self.Queue(maxsize=MAXSIZE)
child_can_start = self.Event()
parent_can_continue = self.Event()
proc = self.Process(
target=self._test_put,
args=(queue, child_can_start, parent_can_continue)
)
proc.daemon = True
proc.start()
self.assertEqual(queue_empty(queue), True)
self.assertEqual(queue_full(queue, MAXSIZE), False)
queue.put(1)
queue.put(2, True)
queue.put(3, True, None)
queue.put(4, False)
queue.put(5, False, None)
queue.put_nowait(6)
# the values may be in buffer but not yet in pipe so sleep a bit
time.sleep(DELTA)
self.assertEqual(queue_empty(queue), False)
self.assertEqual(queue_full(queue, MAXSIZE), True)
put = TimingWrapper(queue.put)
put_nowait = TimingWrapper(queue.put_nowait)
self.assertRaises(pyqueue.Full, put, 7, False)
self.assertTimingAlmostEqual(put.elapsed, 0)
self.assertRaises(pyqueue.Full, put, 7, False, None)
self.assertTimingAlmostEqual(put.elapsed, 0)
self.assertRaises(pyqueue.Full, put_nowait, 7)
self.assertTimingAlmostEqual(put_nowait.elapsed, 0)
self.assertRaises(pyqueue.Full, put, 7, True, TIMEOUT1)
self.assertTimingAlmostEqual(put.elapsed, TIMEOUT1)
self.assertRaises(pyqueue.Full, put, 7, False, TIMEOUT2)
self.assertTimingAlmostEqual(put.elapsed, 0)
self.assertRaises(pyqueue.Full, put, 7, True, timeout=TIMEOUT3)
self.assertTimingAlmostEqual(put.elapsed, TIMEOUT3)
child_can_start.set()
parent_can_continue.wait()
self.assertEqual(queue_empty(queue), True)
self.assertEqual(queue_full(queue, MAXSIZE), False)
proc.join()
close_queue(queue)
@classmethod
def _test_get(cls, queue, child_can_start, parent_can_continue):
child_can_start.wait()
#queue.put(1)
queue.put(2)
queue.put(3)
queue.put(4)
queue.put(5)
parent_can_continue.set()
def test_get(self):
queue = self.Queue()
child_can_start = self.Event()
parent_can_continue = self.Event()
proc = self.Process(
target=self._test_get,
args=(queue, child_can_start, parent_can_continue)
)
proc.daemon = True
proc.start()
self.assertEqual(queue_empty(queue), True)
child_can_start.set()
parent_can_continue.wait()
time.sleep(DELTA)
self.assertEqual(queue_empty(queue), False)
# Hangs unexpectedly, remove for now
#self.assertEqual(queue.get(), 1)
self.assertEqual(queue.get(True, None), 2)
self.assertEqual(queue.get(True), 3)
self.assertEqual(queue.get(timeout=1), 4)
self.assertEqual(queue.get_nowait(), 5)
self.assertEqual(queue_empty(queue), True)
get = TimingWrapper(queue.get)
get_nowait = TimingWrapper(queue.get_nowait)
self.assertRaises(pyqueue.Empty, get, False)
self.assertTimingAlmostEqual(get.elapsed, 0)
self.assertRaises(pyqueue.Empty, get, False, None)
self.assertTimingAlmostEqual(get.elapsed, 0)
self.assertRaises(pyqueue.Empty, get_nowait)
self.assertTimingAlmostEqual(get_nowait.elapsed, 0)
self.assertRaises(pyqueue.Empty, get, True, TIMEOUT1)
self.assertTimingAlmostEqual(get.elapsed, TIMEOUT1)
self.assertRaises(pyqueue.Empty, get, False, TIMEOUT2)
self.assertTimingAlmostEqual(get.elapsed, 0)
self.assertRaises(pyqueue.Empty, get, timeout=TIMEOUT3)
self.assertTimingAlmostEqual(get.elapsed, TIMEOUT3)
proc.join()
close_queue(queue)
@classmethod
def _test_fork(cls, queue):
for i in range(10, 20):
queue.put(i)
# note that at this point the items may only be buffered, so the
# process cannot shutdown until the feeder thread has finished
# pushing items onto the pipe.
def test_fork(self):
# Old versions of Queue would fail to create a new feeder
# thread for a forked process if the original process had its
# own feeder thread. This test checks that this no longer
# happens.
queue = self.Queue()
# put items on queue so that main process starts a feeder thread
for i in range(10):
queue.put(i)
# wait to make sure thread starts before we fork a new process
time.sleep(DELTA)
# fork process
p = self.Process(target=self._test_fork, args=(queue,))
p.daemon = True
p.start()
# check that all expected items are in the queue
for i in range(20):
self.assertEqual(queue.get(), i)
self.assertRaises(pyqueue.Empty, queue.get, False)
p.join()
close_queue(queue)
def test_qsize(self):
q = self.Queue()
try:
self.assertEqual(q.qsize(), 0)
except NotImplementedError:
self.skipTest('qsize method not implemented')
q.put(1)
self.assertEqual(q.qsize(), 1)
q.put(5)
self.assertEqual(q.qsize(), 2)
q.get()
self.assertEqual(q.qsize(), 1)
q.get()
self.assertEqual(q.qsize(), 0)
close_queue(q)
@classmethod
def _test_task_done(cls, q):
for obj in iter(q.get, None):
time.sleep(DELTA)
q.task_done()
def test_task_done(self):
queue = self.JoinableQueue()
workers = [self.Process(target=self._test_task_done, args=(queue,))
for i in range(4)]
for p in workers:
p.daemon = True
p.start()
for i in range(10):
queue.put(i)
queue.join()
for p in workers:
queue.put(None)
for p in workers:
p.join()
close_queue(queue)
def test_no_import_lock_contention(self):
with test.support.temp_cwd():
module_name = 'imported_by_an_imported_module'
with open(module_name + '.py', 'w') as f:
f.write("""if 1:
import multiprocessing
q = multiprocessing.Queue()
q.put('knock knock')
q.get(timeout=3)
q.close()
del q
""")
with test.support.DirsOnSysPath(os.getcwd()):
try:
__import__(module_name)
except pyqueue.Empty:
self.fail("Probable regression on import lock contention;"
" see Issue #22853")
def test_timeout(self):
q = multiprocessing.Queue()
start = time.monotonic()
self.assertRaises(pyqueue.Empty, q.get, True, 0.200)
delta = time.monotonic() - start
# bpo-30317: Tolerate a delta of 100 ms because of the bad clock
# resolution on Windows (usually 15.6 ms). x86 Windows7 3.x once
# failed because the delta was only 135.8 ms.
self.assertGreaterEqual(delta, 0.100)
close_queue(q)
def test_queue_feeder_donot_stop_onexc(self):
# bpo-30414: verify feeder handles exceptions correctly
if self.TYPE != 'processes':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
class NotSerializable(object):
def __reduce__(self):
raise AttributeError
with test.support.captured_stderr():
q = self.Queue()
q.put(NotSerializable())
q.put(True)
self.assertTrue(q.get(timeout=TIMEOUT))
close_queue(q)
with test.support.captured_stderr():
# bpo-33078: verify that the queue size is correctly handled
# on errors.
q = self.Queue(maxsize=1)
q.put(NotSerializable())
q.put(True)
try:
self.assertEqual(q.qsize(), 1)
except NotImplementedError:
# qsize is not available on all platform as it
# relies on sem_getvalue
pass
# bpo-30595: use a timeout of 1 second for slow buildbots
self.assertTrue(q.get(timeout=1.0))
# Check that the size of the queue is correct
self.assertTrue(q.empty())
close_queue(q)
def test_queue_feeder_on_queue_feeder_error(self):
# bpo-30006: verify feeder handles exceptions using the
# _on_queue_feeder_error hook.
if self.TYPE != 'processes':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
class NotSerializable(object):
"""Mock unserializable object"""
def __init__(self):
self.reduce_was_called = False
self.on_queue_feeder_error_was_called = False
def __reduce__(self):
self.reduce_was_called = True
raise AttributeError
class SafeQueue(multiprocessing.queues.Queue):
"""Queue with overloaded _on_queue_feeder_error hook"""
@staticmethod
def _on_queue_feeder_error(e, obj):
if (isinstance(e, AttributeError) and
isinstance(obj, NotSerializable)):
obj.on_queue_feeder_error_was_called = True
not_serializable_obj = NotSerializable()
# The captured_stderr reduces the noise in the test report
with test.support.captured_stderr():
q = SafeQueue(ctx=multiprocessing.get_context())
q.put(not_serializable_obj)
# Verify that q is still functioning correctly
q.put(True)
self.assertTrue(q.get(timeout=1.0))
# Assert that the serialization and the hook have been called correctly
self.assertTrue(not_serializable_obj.reduce_was_called)
self.assertTrue(not_serializable_obj.on_queue_feeder_error_was_called)
#
#
#
class _TestLock(BaseTestCase):
def test_lock(self):
lock = self.Lock()
self.assertEqual(lock.acquire(), True)
self.assertEqual(lock.acquire(False), False)
self.assertEqual(lock.release(), None)
self.assertRaises((ValueError, threading.ThreadError), lock.release)
def test_rlock(self):
lock = self.RLock()
self.assertEqual(lock.acquire(), True)
self.assertEqual(lock.acquire(), True)
self.assertEqual(lock.acquire(), True)
self.assertEqual(lock.release(), None)
self.assertEqual(lock.release(), None)
self.assertEqual(lock.release(), None)
self.assertRaises((AssertionError, RuntimeError), lock.release)
def test_lock_context(self):
with self.Lock():
pass
class _TestSemaphore(BaseTestCase):
def _test_semaphore(self, sem):
self.assertReturnsIfImplemented(2, get_value, sem)
self.assertEqual(sem.acquire(), True)
self.assertReturnsIfImplemented(1, get_value, sem)
self.assertEqual(sem.acquire(), True)
self.assertReturnsIfImplemented(0, get_value, sem)
self.assertEqual(sem.acquire(False), False)
self.assertReturnsIfImplemented(0, get_value, sem)
self.assertEqual(sem.release(), None)
self.assertReturnsIfImplemented(1, get_value, sem)
self.assertEqual(sem.release(), None)
self.assertReturnsIfImplemented(2, get_value, sem)
def test_semaphore(self):
sem = self.Semaphore(2)
self._test_semaphore(sem)
self.assertEqual(sem.release(), None)
self.assertReturnsIfImplemented(3, get_value, sem)
self.assertEqual(sem.release(), None)
self.assertReturnsIfImplemented(4, get_value, sem)
def test_bounded_semaphore(self):
sem = self.BoundedSemaphore(2)
self._test_semaphore(sem)
# Currently fails on OS/X
#if HAVE_GETVALUE:
# self.assertRaises(ValueError, sem.release)
# self.assertReturnsIfImplemented(2, get_value, sem)
def test_timeout(self):
if self.TYPE != 'processes':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
sem = self.Semaphore(0)
acquire = TimingWrapper(sem.acquire)
self.assertEqual(acquire(False), False)
self.assertTimingAlmostEqual(acquire.elapsed, 0.0)
self.assertEqual(acquire(False, None), False)
self.assertTimingAlmostEqual(acquire.elapsed, 0.0)
self.assertEqual(acquire(False, TIMEOUT1), False)
self.assertTimingAlmostEqual(acquire.elapsed, 0)
self.assertEqual(acquire(True, TIMEOUT2), False)
self.assertTimingAlmostEqual(acquire.elapsed, TIMEOUT2)
self.assertEqual(acquire(timeout=TIMEOUT3), False)
self.assertTimingAlmostEqual(acquire.elapsed, TIMEOUT3)
class _TestCondition(BaseTestCase):
@classmethod
def f(cls, cond, sleeping, woken, timeout=None):
cond.acquire()
sleeping.release()
cond.wait(timeout)
woken.release()
cond.release()
def assertReachesEventually(self, func, value):
for i in range(10):
try:
if func() == value:
break
except NotImplementedError:
break
time.sleep(DELTA)
time.sleep(DELTA)
self.assertReturnsIfImplemented(value, func)
def check_invariant(self, cond):
# this is only supposed to succeed when there are no sleepers
if self.TYPE == 'processes':
try:
sleepers = (cond._sleeping_count.get_value() -
cond._woken_count.get_value())
self.assertEqual(sleepers, 0)
self.assertEqual(cond._wait_semaphore.get_value(), 0)
except NotImplementedError:
pass
def test_notify(self):
cond = self.Condition()
sleeping = self.Semaphore(0)
woken = self.Semaphore(0)
p = self.Process(target=self.f, args=(cond, sleeping, woken))
p.daemon = True
p.start()
self.addCleanup(p.join)
p = threading.Thread(target=self.f, args=(cond, sleeping, woken))
p.daemon = True
p.start()
self.addCleanup(p.join)
# wait for both children to start sleeping
sleeping.acquire()
sleeping.acquire()
# check no process/thread has woken up
time.sleep(DELTA)
self.assertReturnsIfImplemented(0, get_value, woken)
# wake up one process/thread
cond.acquire()
cond.notify()
cond.release()
# check one process/thread has woken up
time.sleep(DELTA)
self.assertReturnsIfImplemented(1, get_value, woken)
# wake up another
cond.acquire()
cond.notify()
cond.release()
# check other has woken up
time.sleep(DELTA)
self.assertReturnsIfImplemented(2, get_value, woken)
# check state is not mucked up
self.check_invariant(cond)
p.join()
def test_notify_all(self):
cond = self.Condition()
sleeping = self.Semaphore(0)
woken = self.Semaphore(0)
# start some threads/processes which will timeout
for i in range(3):
p = self.Process(target=self.f,
args=(cond, sleeping, woken, TIMEOUT1))
p.daemon = True
p.start()
self.addCleanup(p.join)
t = threading.Thread(target=self.f,
args=(cond, sleeping, woken, TIMEOUT1))
t.daemon = True
t.start()
self.addCleanup(t.join)
# wait for them all to sleep
for i in range(6):
sleeping.acquire()
# check they have all timed out
for i in range(6):
woken.acquire()
self.assertReturnsIfImplemented(0, get_value, woken)
# check state is not mucked up
self.check_invariant(cond)
# start some more threads/processes
for i in range(3):
p = self.Process(target=self.f, args=(cond, sleeping, woken))
p.daemon = True
p.start()
self.addCleanup(p.join)
t = threading.Thread(target=self.f, args=(cond, sleeping, woken))
t.daemon = True
t.start()
self.addCleanup(t.join)
# wait for them to all sleep
for i in range(6):
sleeping.acquire()
# check no process/thread has woken up
time.sleep(DELTA)
self.assertReturnsIfImplemented(0, get_value, woken)
# wake them all up
cond.acquire()
cond.notify_all()
cond.release()
# check they have all woken
self.assertReachesEventually(lambda: get_value(woken), 6)
# check state is not mucked up
self.check_invariant(cond)
def test_notify_n(self):
cond = self.Condition()
sleeping = self.Semaphore(0)
woken = self.Semaphore(0)
# start some threads/processes
for i in range(3):
p = self.Process(target=self.f, args=(cond, sleeping, woken))
p.daemon = True
p.start()
self.addCleanup(p.join)
t = threading.Thread(target=self.f, args=(cond, sleeping, woken))
t.daemon = True
t.start()
self.addCleanup(t.join)
# wait for them to all sleep
for i in range(6):
sleeping.acquire()
# check no process/thread has woken up
time.sleep(DELTA)
self.assertReturnsIfImplemented(0, get_value, woken)
# wake some of them up
cond.acquire()
cond.notify(n=2)
cond.release()
# check 2 have woken
self.assertReachesEventually(lambda: get_value(woken), 2)
# wake the rest of them
cond.acquire()
cond.notify(n=4)
cond.release()
self.assertReachesEventually(lambda: get_value(woken), 6)
# doesn't do anything more
cond.acquire()
cond.notify(n=3)
cond.release()
self.assertReturnsIfImplemented(6, get_value, woken)
# check state is not mucked up
self.check_invariant(cond)
def test_timeout(self):
cond = self.Condition()
wait = TimingWrapper(cond.wait)
cond.acquire()
res = wait(TIMEOUT1)
cond.release()
self.assertEqual(res, False)
self.assertTimingAlmostEqual(wait.elapsed, TIMEOUT1)
@classmethod
def _test_waitfor_f(cls, cond, state):
with cond:
state.value = 0
cond.notify()
result = cond.wait_for(lambda : state.value==4)
if not result or state.value != 4:
sys.exit(1)
@unittest.skipUnless(HAS_SHAREDCTYPES, 'needs sharedctypes')
def test_waitfor(self):
# based on test in test/lock_tests.py
cond = self.Condition()
state = self.Value('i', -1)
p = self.Process(target=self._test_waitfor_f, args=(cond, state))
p.daemon = True
p.start()
with cond:
result = cond.wait_for(lambda : state.value==0)
self.assertTrue(result)
self.assertEqual(state.value, 0)
for i in range(4):
time.sleep(0.01)
with cond:
state.value += 1
cond.notify()
join_process(p)
self.assertEqual(p.exitcode, 0)
@classmethod
def _test_waitfor_timeout_f(cls, cond, state, success, sem):
sem.release()
with cond:
expected = 0.1
dt = time.monotonic()
result = cond.wait_for(lambda : state.value==4, timeout=expected)
dt = time.monotonic() - dt
# borrow logic in assertTimeout() from test/lock_tests.py
if not result and expected * 0.6 < dt < expected * 10.0:
success.value = True
@unittest.skipUnless(HAS_SHAREDCTYPES, 'needs sharedctypes')
def test_waitfor_timeout(self):
# based on test in test/lock_tests.py
cond = self.Condition()
state = self.Value('i', 0)
success = self.Value('i', False)
sem = self.Semaphore(0)
p = self.Process(target=self._test_waitfor_timeout_f,
args=(cond, state, success, sem))
p.daemon = True
p.start()
self.assertTrue(sem.acquire(timeout=TIMEOUT))
# Only increment 3 times, so state == 4 is never reached.
for i in range(3):
time.sleep(0.01)
with cond:
state.value += 1
cond.notify()
join_process(p)
self.assertTrue(success.value)
@classmethod
def _test_wait_result(cls, c, pid):
with c:
c.notify()
time.sleep(1)
if pid is not None:
os.kill(pid, signal.SIGINT)
def test_wait_result(self):
if isinstance(self, ProcessesMixin) and sys.platform != 'win32':
pid = os.getpid()
else:
pid = None
c = self.Condition()
with c:
self.assertFalse(c.wait(0))
self.assertFalse(c.wait(0.1))
p = self.Process(target=self._test_wait_result, args=(c, pid))
p.start()
self.assertTrue(c.wait(60))
if pid is not None:
self.assertRaises(KeyboardInterrupt, c.wait, 60)
p.join()
class _TestEvent(BaseTestCase):
@classmethod
def _test_event(cls, event):
time.sleep(TIMEOUT2)
event.set()
def test_event(self):
event = self.Event()
wait = TimingWrapper(event.wait)
# Removed temporarily, due to API shear, this does not
# work with threading._Event objects. is_set == isSet
self.assertEqual(event.is_set(), False)
# Removed, threading.Event.wait() will return the value of the __flag
# instead of None. API Shear with the semaphore backed mp.Event
self.assertEqual(wait(0.0), False)
self.assertTimingAlmostEqual(wait.elapsed, 0.0)
self.assertEqual(wait(TIMEOUT1), False)
self.assertTimingAlmostEqual(wait.elapsed, TIMEOUT1)
event.set()
# See note above on the API differences
self.assertEqual(event.is_set(), True)
self.assertEqual(wait(), True)
self.assertTimingAlmostEqual(wait.elapsed, 0.0)
self.assertEqual(wait(TIMEOUT1), True)
self.assertTimingAlmostEqual(wait.elapsed, 0.0)
# self.assertEqual(event.is_set(), True)
event.clear()
#self.assertEqual(event.is_set(), False)
p = self.Process(target=self._test_event, args=(event,))
p.daemon = True
p.start()
self.assertEqual(wait(), True)
p.join()
#
# Tests for Barrier - adapted from tests in test/lock_tests.py
#
# Many of the tests for threading.Barrier use a list as an atomic
# counter: a value is appended to increment the counter, and the
# length of the list gives the value. We use the class DummyList
# for the same purpose.
class _DummyList(object):
def __init__(self):
wrapper = multiprocessing.heap.BufferWrapper(struct.calcsize('i'))
lock = multiprocessing.Lock()
self.__setstate__((wrapper, lock))
self._lengthbuf[0] = 0
def __setstate__(self, state):
(self._wrapper, self._lock) = state
self._lengthbuf = self._wrapper.create_memoryview().cast('i')
def __getstate__(self):
return (self._wrapper, self._lock)
def append(self, _):
with self._lock:
self._lengthbuf[0] += 1
def __len__(self):
with self._lock:
return self._lengthbuf[0]
def _wait():
# A crude wait/yield function not relying on synchronization primitives.
time.sleep(0.01)
class Bunch(object):
"""
A bunch of threads.
"""
def __init__(self, namespace, f, args, n, wait_before_exit=False):
"""
Construct a bunch of `n` threads running the same function `f`.
If `wait_before_exit` is True, the threads won't terminate until
do_finish() is called.
"""
self.f = f
self.args = args
self.n = n
self.started = namespace.DummyList()
self.finished = namespace.DummyList()
self._can_exit = namespace.Event()
if not wait_before_exit:
self._can_exit.set()
threads = []
for i in range(n):
p = namespace.Process(target=self.task)
p.daemon = True
p.start()
threads.append(p)
def finalize(threads):
for p in threads:
p.join()
self._finalizer = weakref.finalize(self, finalize, threads)
def task(self):
pid = os.getpid()
self.started.append(pid)
try:
self.f(*self.args)
finally:
self.finished.append(pid)
self._can_exit.wait(30)
assert self._can_exit.is_set()
def wait_for_started(self):
while len(self.started) < self.n:
_wait()
def wait_for_finished(self):
while len(self.finished) < self.n:
_wait()
def do_finish(self):
self._can_exit.set()
def close(self):
self._finalizer()
class AppendTrue(object):
def __init__(self, obj):
self.obj = obj
def __call__(self):
self.obj.append(True)
class _TestBarrier(BaseTestCase):
"""
Tests for Barrier objects.
"""
N = 5
defaultTimeout = 30.0 # XXX Slow Windows buildbots need generous timeout
def setUp(self):
self.barrier = self.Barrier(self.N, timeout=self.defaultTimeout)
def tearDown(self):
self.barrier.abort()
self.barrier = None
def DummyList(self):
if self.TYPE == 'threads':
return []
elif self.TYPE == 'manager':
return self.manager.list()
else:
return _DummyList()
def run_threads(self, f, args):
b = Bunch(self, f, args, self.N-1)
try:
f(*args)
b.wait_for_finished()
finally:
b.close()
@classmethod
def multipass(cls, barrier, results, n):
m = barrier.parties
assert m == cls.N
for i in range(n):
results[0].append(True)
assert len(results[1]) == i * m
barrier.wait()
results[1].append(True)
assert len(results[0]) == (i + 1) * m
barrier.wait()
try:
assert barrier.n_waiting == 0
except NotImplementedError:
pass
assert not barrier.broken
def test_barrier(self, passes=1):
"""
Test that a barrier is passed in lockstep
"""
results = [self.DummyList(), self.DummyList()]
self.run_threads(self.multipass, (self.barrier, results, passes))
def test_barrier_10(self):
"""
Test that a barrier works for 10 consecutive runs
"""
return self.test_barrier(10)
@classmethod
def _test_wait_return_f(cls, barrier, queue):
res = barrier.wait()
queue.put(res)
def test_wait_return(self):
"""
test the return value from barrier.wait
"""
queue = self.Queue()
self.run_threads(self._test_wait_return_f, (self.barrier, queue))
results = [queue.get() for i in range(self.N)]
self.assertEqual(results.count(0), 1)
close_queue(queue)
@classmethod
def _test_action_f(cls, barrier, results):
barrier.wait()
if len(results) != 1:
raise RuntimeError
def test_action(self):
"""
Test the 'action' callback
"""
results = self.DummyList()
barrier = self.Barrier(self.N, action=AppendTrue(results))
self.run_threads(self._test_action_f, (barrier, results))
self.assertEqual(len(results), 1)
@classmethod
def _test_abort_f(cls, barrier, results1, results2):
try:
i = barrier.wait()
if i == cls.N//2:
raise RuntimeError
barrier.wait()
results1.append(True)
except threading.BrokenBarrierError:
results2.append(True)
except RuntimeError:
barrier.abort()
def test_abort(self):
"""
Test that an abort will put the barrier in a broken state
"""
results1 = self.DummyList()
results2 = self.DummyList()
self.run_threads(self._test_abort_f,
(self.barrier, results1, results2))
self.assertEqual(len(results1), 0)
self.assertEqual(len(results2), self.N-1)
self.assertTrue(self.barrier.broken)
@classmethod
def _test_reset_f(cls, barrier, results1, results2, results3):
i = barrier.wait()
if i == cls.N//2:
# Wait until the other threads are all in the barrier.
while barrier.n_waiting < cls.N-1:
time.sleep(0.001)
barrier.reset()
else:
try:
barrier.wait()
results1.append(True)
except threading.BrokenBarrierError:
results2.append(True)
# Now, pass the barrier again
barrier.wait()
results3.append(True)
def test_reset(self):
"""
Test that a 'reset' on a barrier frees the waiting threads
"""
results1 = self.DummyList()
results2 = self.DummyList()
results3 = self.DummyList()
self.run_threads(self._test_reset_f,
(self.barrier, results1, results2, results3))
self.assertEqual(len(results1), 0)
self.assertEqual(len(results2), self.N-1)
self.assertEqual(len(results3), self.N)
@classmethod
def _test_abort_and_reset_f(cls, barrier, barrier2,
results1, results2, results3):
try:
i = barrier.wait()
if i == cls.N//2:
raise RuntimeError
barrier.wait()
results1.append(True)
except threading.BrokenBarrierError:
results2.append(True)
except RuntimeError:
barrier.abort()
# Synchronize and reset the barrier. Must synchronize first so
# that everyone has left it when we reset, and after so that no
# one enters it before the reset.
if barrier2.wait() == cls.N//2:
barrier.reset()
barrier2.wait()
barrier.wait()
results3.append(True)
def test_abort_and_reset(self):
"""
Test that a barrier can be reset after being broken.
"""
results1 = self.DummyList()
results2 = self.DummyList()
results3 = self.DummyList()
barrier2 = self.Barrier(self.N)
self.run_threads(self._test_abort_and_reset_f,
(self.barrier, barrier2, results1, results2, results3))
self.assertEqual(len(results1), 0)
self.assertEqual(len(results2), self.N-1)
self.assertEqual(len(results3), self.N)
@classmethod
def _test_timeout_f(cls, barrier, results):
i = barrier.wait()
if i == cls.N//2:
# One thread is late!
time.sleep(1.0)
try:
barrier.wait(0.5)
except threading.BrokenBarrierError:
results.append(True)
def test_timeout(self):
"""
Test wait(timeout)
"""
results = self.DummyList()
self.run_threads(self._test_timeout_f, (self.barrier, results))
self.assertEqual(len(results), self.barrier.parties)
@classmethod
def _test_default_timeout_f(cls, barrier, results):
i = barrier.wait(cls.defaultTimeout)
if i == cls.N//2:
# One thread is later than the default timeout
time.sleep(1.0)
try:
barrier.wait()
except threading.BrokenBarrierError:
results.append(True)
def test_default_timeout(self):
"""
Test the barrier's default timeout
"""
barrier = self.Barrier(self.N, timeout=0.5)
results = self.DummyList()
self.run_threads(self._test_default_timeout_f, (barrier, results))
self.assertEqual(len(results), barrier.parties)
def test_single_thread(self):
b = self.Barrier(1)
b.wait()
b.wait()
@classmethod
def _test_thousand_f(cls, barrier, passes, conn, lock):
for i in range(passes):
barrier.wait()
with lock:
conn.send(i)
def test_thousand(self):
if self.TYPE == 'manager':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
passes = 1000
lock = self.Lock()
conn, child_conn = self.Pipe(False)
for j in range(self.N):
p = self.Process(target=self._test_thousand_f,
args=(self.barrier, passes, child_conn, lock))
p.start()
self.addCleanup(p.join)
for i in range(passes):
for j in range(self.N):
self.assertEqual(conn.recv(), i)
#
#
#
class _TestValue(BaseTestCase):
ALLOWED_TYPES = ('processes',)
codes_values = [
('i', 4343, 24234),
('d', 3.625, -4.25),
('h', -232, 234),
('q', 2 ** 33, 2 ** 34),
('c', latin('x'), latin('y'))
]
def setUp(self):
if not HAS_SHAREDCTYPES:
self.skipTest("requires multiprocessing.sharedctypes")
@classmethod
def _test(cls, values):
for sv, cv in zip(values, cls.codes_values):
sv.value = cv[2]
def test_value(self, raw=False):
if raw:
values = [self.RawValue(code, value)
for code, value, _ in self.codes_values]
else:
values = [self.Value(code, value)
for code, value, _ in self.codes_values]
for sv, cv in zip(values, self.codes_values):
self.assertEqual(sv.value, cv[1])
proc = self.Process(target=self._test, args=(values,))
proc.daemon = True
proc.start()
proc.join()
for sv, cv in zip(values, self.codes_values):
self.assertEqual(sv.value, cv[2])
def test_rawvalue(self):
self.test_value(raw=True)
def test_getobj_getlock(self):
val1 = self.Value('i', 5)
lock1 = val1.get_lock()
obj1 = val1.get_obj()
val2 = self.Value('i', 5, lock=None)
lock2 = val2.get_lock()
obj2 = val2.get_obj()
lock = self.Lock()
val3 = self.Value('i', 5, lock=lock)
lock3 = val3.get_lock()
obj3 = val3.get_obj()
self.assertEqual(lock, lock3)
arr4 = self.Value('i', 5, lock=False)
self.assertFalse(hasattr(arr4, 'get_lock'))
self.assertFalse(hasattr(arr4, 'get_obj'))
self.assertRaises(AttributeError, self.Value, 'i', 5, lock='navalue')
arr5 = self.RawValue('i', 5)
self.assertFalse(hasattr(arr5, 'get_lock'))
self.assertFalse(hasattr(arr5, 'get_obj'))
class _TestArray(BaseTestCase):
ALLOWED_TYPES = ('processes',)
@classmethod
def f(cls, seq):
for i in range(1, len(seq)):
seq[i] += seq[i-1]
@unittest.skipIf(c_int is None, "requires _ctypes")
def test_array(self, raw=False):
seq = [680, 626, 934, 821, 150, 233, 548, 982, 714, 831]
if raw:
arr = self.RawArray('i', seq)
else:
arr = self.Array('i', seq)
self.assertEqual(len(arr), len(seq))
self.assertEqual(arr[3], seq[3])
self.assertEqual(list(arr[2:7]), list(seq[2:7]))
arr[4:8] = seq[4:8] = array.array('i', [1, 2, 3, 4])
self.assertEqual(list(arr[:]), seq)
self.f(seq)
p = self.Process(target=self.f, args=(arr,))
p.daemon = True
p.start()
p.join()
self.assertEqual(list(arr[:]), seq)
@unittest.skipIf(c_int is None, "requires _ctypes")
def test_array_from_size(self):
size = 10
# Test for zeroing (see issue #11675).
# The repetition below strengthens the test by increasing the chances
# of previously allocated non-zero memory being used for the new array
# on the 2nd and 3rd loops.
for _ in range(3):
arr = self.Array('i', size)
self.assertEqual(len(arr), size)
self.assertEqual(list(arr), [0] * size)
arr[:] = range(10)
self.assertEqual(list(arr), list(range(10)))
del arr
@unittest.skipIf(c_int is None, "requires _ctypes")
def test_rawarray(self):
self.test_array(raw=True)
@unittest.skipIf(c_int is None, "requires _ctypes")
def test_getobj_getlock_obj(self):
arr1 = self.Array('i', list(range(10)))
lock1 = arr1.get_lock()
obj1 = arr1.get_obj()
arr2 = self.Array('i', list(range(10)), lock=None)
lock2 = arr2.get_lock()
obj2 = arr2.get_obj()
lock = self.Lock()
arr3 = self.Array('i', list(range(10)), lock=lock)
lock3 = arr3.get_lock()
obj3 = arr3.get_obj()
self.assertEqual(lock, lock3)
arr4 = self.Array('i', range(10), lock=False)
self.assertFalse(hasattr(arr4, 'get_lock'))
self.assertFalse(hasattr(arr4, 'get_obj'))
self.assertRaises(AttributeError,
self.Array, 'i', range(10), lock='notalock')
arr5 = self.RawArray('i', range(10))
self.assertFalse(hasattr(arr5, 'get_lock'))
self.assertFalse(hasattr(arr5, 'get_obj'))
#
#
#
class _TestContainers(BaseTestCase):
ALLOWED_TYPES = ('manager',)
def test_list(self):
a = self.list(list(range(10)))
self.assertEqual(a[:], list(range(10)))
b = self.list()
self.assertEqual(b[:], [])
b.extend(list(range(5)))
self.assertEqual(b[:], list(range(5)))
self.assertEqual(b[2], 2)
self.assertEqual(b[2:10], [2,3,4])
b *= 2
self.assertEqual(b[:], [0, 1, 2, 3, 4, 0, 1, 2, 3, 4])
self.assertEqual(b + [5, 6], [0, 1, 2, 3, 4, 0, 1, 2, 3, 4, 5, 6])
self.assertEqual(a[:], list(range(10)))
d = [a, b]
e = self.list(d)
self.assertEqual(
[element[:] for element in e],
[[0, 1, 2, 3, 4, 5, 6, 7, 8, 9], [0, 1, 2, 3, 4, 0, 1, 2, 3, 4]]
)
f = self.list([a])
a.append('hello')
self.assertEqual(f[0][:], [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 'hello'])
def test_list_iter(self):
a = self.list(list(range(10)))
it = iter(a)
self.assertEqual(list(it), list(range(10)))
self.assertEqual(list(it), []) # exhausted
# list modified during iteration
it = iter(a)
a[0] = 100
self.assertEqual(next(it), 100)
def test_list_proxy_in_list(self):
a = self.list([self.list(range(3)) for _i in range(3)])
self.assertEqual([inner[:] for inner in a], [[0, 1, 2]] * 3)
a[0][-1] = 55
self.assertEqual(a[0][:], [0, 1, 55])
for i in range(1, 3):
self.assertEqual(a[i][:], [0, 1, 2])
self.assertEqual(a[1].pop(), 2)
self.assertEqual(len(a[1]), 2)
for i in range(0, 3, 2):
self.assertEqual(len(a[i]), 3)
del a
b = self.list()
b.append(b)
del b
def test_dict(self):
d = self.dict()
indices = list(range(65, 70))
for i in indices:
d[i] = chr(i)
self.assertEqual(d.copy(), dict((i, chr(i)) for i in indices))
self.assertEqual(sorted(d.keys()), indices)
self.assertEqual(sorted(d.values()), [chr(i) for i in indices])
self.assertEqual(sorted(d.items()), [(i, chr(i)) for i in indices])
def test_dict_iter(self):
d = self.dict()
indices = list(range(65, 70))
for i in indices:
d[i] = chr(i)
it = iter(d)
self.assertEqual(list(it), indices)
self.assertEqual(list(it), []) # exhausted
# dictionary changed size during iteration
it = iter(d)
d.clear()
self.assertRaises(RuntimeError, next, it)
def test_dict_proxy_nested(self):
pets = self.dict(ferrets=2, hamsters=4)
supplies = self.dict(water=10, feed=3)
d = self.dict(pets=pets, supplies=supplies)
self.assertEqual(supplies['water'], 10)
self.assertEqual(d['supplies']['water'], 10)
d['supplies']['blankets'] = 5
self.assertEqual(supplies['blankets'], 5)
self.assertEqual(d['supplies']['blankets'], 5)
d['supplies']['water'] = 7
self.assertEqual(supplies['water'], 7)
self.assertEqual(d['supplies']['water'], 7)
del pets
del supplies
self.assertEqual(d['pets']['ferrets'], 2)
d['supplies']['blankets'] = 11
self.assertEqual(d['supplies']['blankets'], 11)
pets = d['pets']
supplies = d['supplies']
supplies['water'] = 7
self.assertEqual(supplies['water'], 7)
self.assertEqual(d['supplies']['water'], 7)
d.clear()
self.assertEqual(len(d), 0)
self.assertEqual(supplies['water'], 7)
self.assertEqual(pets['hamsters'], 4)
l = self.list([pets, supplies])
l[0]['marmots'] = 1
self.assertEqual(pets['marmots'], 1)
self.assertEqual(l[0]['marmots'], 1)
del pets
del supplies
self.assertEqual(l[0]['marmots'], 1)
outer = self.list([[88, 99], l])
self.assertIsInstance(outer[0], list) # Not a ListProxy
self.assertEqual(outer[-1][-1]['feed'], 3)
def test_namespace(self):
n = self.Namespace()
n.name = 'Bob'
n.job = 'Builder'
n._hidden = 'hidden'
self.assertEqual((n.name, n.job), ('Bob', 'Builder'))
del n.job
self.assertEqual(str(n), "Namespace(name='Bob')")
self.assertTrue(hasattr(n, 'name'))
self.assertTrue(not hasattr(n, 'job'))
#
#
#
def sqr(x, wait=0.0):
time.sleep(wait)
return x*x
def mul(x, y):
return x*y
def raise_large_valuerror(wait):
time.sleep(wait)
raise ValueError("x" * 1024**2)
def identity(x):
return x
class CountedObject(object):
n_instances = 0
def __new__(cls):
cls.n_instances += 1
return object.__new__(cls)
def __del__(self):
type(self).n_instances -= 1
class SayWhenError(ValueError): pass
def exception_throwing_generator(total, when):
if when == -1:
raise SayWhenError("Somebody said when")
for i in range(total):
if i == when:
raise SayWhenError("Somebody said when")
yield i
class _TestPool(BaseTestCase):
@classmethod
def setUpClass(cls):
super().setUpClass()
cls.pool = cls.Pool(4)
@classmethod
def tearDownClass(cls):
cls.pool.terminate()
cls.pool.join()
cls.pool = None
super().tearDownClass()
def test_apply(self):
papply = self.pool.apply
self.assertEqual(papply(sqr, (5,)), sqr(5))
self.assertEqual(papply(sqr, (), {'x':3}), sqr(x=3))
def test_map(self):
pmap = self.pool.map
self.assertEqual(pmap(sqr, list(range(10))), list(map(sqr, list(range(10)))))
self.assertEqual(pmap(sqr, list(range(100)), chunksize=20),
list(map(sqr, list(range(100)))))
def test_starmap(self):
psmap = self.pool.starmap
tuples = list(zip(range(10), range(9,-1, -1)))
self.assertEqual(psmap(mul, tuples),
list(itertools.starmap(mul, tuples)))
tuples = list(zip(range(100), range(99,-1, -1)))
self.assertEqual(psmap(mul, tuples, chunksize=20),
list(itertools.starmap(mul, tuples)))
def test_starmap_async(self):
tuples = list(zip(range(100), range(99,-1, -1)))
self.assertEqual(self.pool.starmap_async(mul, tuples).get(),
list(itertools.starmap(mul, tuples)))
def test_map_async(self):
self.assertEqual(self.pool.map_async(sqr, list(range(10))).get(),
list(map(sqr, list(range(10)))))
def test_map_async_callbacks(self):
call_args = self.manager.list() if self.TYPE == 'manager' else []
self.pool.map_async(int, ['1'],
callback=call_args.append,
error_callback=call_args.append).wait()
self.assertEqual(1, len(call_args))
self.assertEqual([1], call_args[0])
self.pool.map_async(int, ['a'],
callback=call_args.append,
error_callback=call_args.append).wait()
self.assertEqual(2, len(call_args))
self.assertIsInstance(call_args[1], ValueError)
def test_map_unplicklable(self):
# Issue #19425 -- failure to pickle should not cause a hang
if self.TYPE == 'threads':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
class A(object):
def __reduce__(self):
raise RuntimeError('cannot pickle')
with self.assertRaises(RuntimeError):
self.pool.map(sqr, [A()]*10)
def test_map_chunksize(self):
try:
self.pool.map_async(sqr, [], chunksize=1).get(timeout=TIMEOUT1)
except multiprocessing.TimeoutError:
self.fail("pool.map_async with chunksize stalled on null list")
def test_map_handle_iterable_exception(self):
if self.TYPE == 'manager':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
# SayWhenError seen at the very first of the iterable
with self.assertRaises(SayWhenError):
self.pool.map(sqr, exception_throwing_generator(1, -1), 1)
# again, make sure it's reentrant
with self.assertRaises(SayWhenError):
self.pool.map(sqr, exception_throwing_generator(1, -1), 1)
with self.assertRaises(SayWhenError):
self.pool.map(sqr, exception_throwing_generator(10, 3), 1)
class SpecialIterable:
def __iter__(self):
return self
def __next__(self):
raise SayWhenError
def __len__(self):
return 1
with self.assertRaises(SayWhenError):
self.pool.map(sqr, SpecialIterable(), 1)
with self.assertRaises(SayWhenError):
self.pool.map(sqr, SpecialIterable(), 1)
def test_async(self):
res = self.pool.apply_async(sqr, (7, TIMEOUT1,))
get = TimingWrapper(res.get)
self.assertEqual(get(), 49)
self.assertTimingAlmostEqual(get.elapsed, TIMEOUT1)
def test_async_timeout(self):
res = self.pool.apply_async(sqr, (6, TIMEOUT2 + 1.0))
get = TimingWrapper(res.get)
self.assertRaises(multiprocessing.TimeoutError, get, timeout=TIMEOUT2)
self.assertTimingAlmostEqual(get.elapsed, TIMEOUT2)
def test_imap(self):
it = self.pool.imap(sqr, list(range(10)))
self.assertEqual(list(it), list(map(sqr, list(range(10)))))
it = self.pool.imap(sqr, list(range(10)))
for i in range(10):
self.assertEqual(next(it), i*i)
self.assertRaises(StopIteration, it.__next__)
it = self.pool.imap(sqr, list(range(1000)), chunksize=100)
for i in range(1000):
self.assertEqual(next(it), i*i)
self.assertRaises(StopIteration, it.__next__)
def test_imap_handle_iterable_exception(self):
if self.TYPE == 'manager':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
# SayWhenError seen at the very first of the iterable
it = self.pool.imap(sqr, exception_throwing_generator(1, -1), 1)
self.assertRaises(SayWhenError, it.__next__)
# again, make sure it's reentrant
it = self.pool.imap(sqr, exception_throwing_generator(1, -1), 1)
self.assertRaises(SayWhenError, it.__next__)
it = self.pool.imap(sqr, exception_throwing_generator(10, 3), 1)
for i in range(3):
self.assertEqual(next(it), i*i)
self.assertRaises(SayWhenError, it.__next__)
# SayWhenError seen at start of problematic chunk's results
it = self.pool.imap(sqr, exception_throwing_generator(20, 7), 2)
for i in range(6):
self.assertEqual(next(it), i*i)
self.assertRaises(SayWhenError, it.__next__)
it = self.pool.imap(sqr, exception_throwing_generator(20, 7), 4)
for i in range(4):
self.assertEqual(next(it), i*i)
self.assertRaises(SayWhenError, it.__next__)
def test_imap_unordered(self):
it = self.pool.imap_unordered(sqr, list(range(10)))
self.assertEqual(sorted(it), list(map(sqr, list(range(10)))))
it = self.pool.imap_unordered(sqr, list(range(1000)), chunksize=100)
self.assertEqual(sorted(it), list(map(sqr, list(range(1000)))))
def test_imap_unordered_handle_iterable_exception(self):
if self.TYPE == 'manager':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
# SayWhenError seen at the very first of the iterable
it = self.pool.imap_unordered(sqr,
exception_throwing_generator(1, -1),
1)
self.assertRaises(SayWhenError, it.__next__)
# again, make sure it's reentrant
it = self.pool.imap_unordered(sqr,
exception_throwing_generator(1, -1),
1)
self.assertRaises(SayWhenError, it.__next__)
it = self.pool.imap_unordered(sqr,
exception_throwing_generator(10, 3),
1)
expected_values = list(map(sqr, list(range(10))))
with self.assertRaises(SayWhenError):
# imap_unordered makes it difficult to anticipate the SayWhenError
for i in range(10):
value = next(it)
self.assertIn(value, expected_values)
expected_values.remove(value)
it = self.pool.imap_unordered(sqr,
exception_throwing_generator(20, 7),
2)
expected_values = list(map(sqr, list(range(20))))
with self.assertRaises(SayWhenError):
for i in range(20):
value = next(it)
self.assertIn(value, expected_values)
expected_values.remove(value)
def test_make_pool(self):
expected_error = (RemoteError if self.TYPE == 'manager'
else ValueError)
self.assertRaises(expected_error, self.Pool, -1)
self.assertRaises(expected_error, self.Pool, 0)
if self.TYPE != 'manager':
p = self.Pool(3)
try:
self.assertEqual(3, len(p._pool))
finally:
p.close()
p.join()
def test_terminate(self):
result = self.pool.map_async(
time.sleep, [0.1 for i in range(10000)], chunksize=1
)
self.pool.terminate()
join = TimingWrapper(self.pool.join)
join()
# Sanity check the pool didn't wait for all tasks to finish
self.assertLess(join.elapsed, 2.0)
def test_empty_iterable(self):
# See Issue 12157
p = self.Pool(1)
self.assertEqual(p.map(sqr, []), [])
self.assertEqual(list(p.imap(sqr, [])), [])
self.assertEqual(list(p.imap_unordered(sqr, [])), [])
self.assertEqual(p.map_async(sqr, []).get(), [])
p.close()
p.join()
def test_context(self):
if self.TYPE == 'processes':
L = list(range(10))
expected = [sqr(i) for i in L]
with self.Pool(2) as p:
r = p.map_async(sqr, L)
self.assertEqual(r.get(), expected)
p.join()
self.assertRaises(ValueError, p.map_async, sqr, L)
@classmethod
def _test_traceback(cls):
raise RuntimeError(123) # some comment
def test_traceback(self):
# We want ensure that the traceback from the child process is
# contained in the traceback raised in the main process.
if self.TYPE == 'processes':
with self.Pool(1) as p:
try:
p.apply(self._test_traceback)
except Exception as e:
exc = e
else:
self.fail('expected RuntimeError')
p.join()
self.assertIs(type(exc), RuntimeError)
self.assertEqual(exc.args, (123,))
cause = exc.__cause__
self.assertIs(type(cause), multiprocessing.pool.RemoteTraceback)
self.assertIn('raise RuntimeError(123) # some comment', cause.tb)
with test.support.captured_stderr() as f1:
try:
raise exc
except RuntimeError:
sys.excepthook(*sys.exc_info())
self.assertIn('raise RuntimeError(123) # some comment',
f1.getvalue())
# _helper_reraises_exception should not make the error
# a remote exception
with self.Pool(1) as p:
try:
p.map(sqr, exception_throwing_generator(1, -1), 1)
except Exception as e:
exc = e
else:
self.fail('expected SayWhenError')
self.assertIs(type(exc), SayWhenError)
self.assertIs(exc.__cause__, None)
p.join()
@classmethod
def _test_wrapped_exception(cls):
raise RuntimeError('foo')
def test_wrapped_exception(self):
# Issue #20980: Should not wrap exception when using thread pool
with self.Pool(1) as p:
with self.assertRaises(RuntimeError):
p.apply(self._test_wrapped_exception)
p.join()
def test_map_no_failfast(self):
# Issue #23992: the fail-fast behaviour when an exception is raised
# during map() would make Pool.join() deadlock, because a worker
# process would fill the result queue (after the result handler thread
# terminated, hence not draining it anymore).
t_start = time.monotonic()
with self.assertRaises(ValueError):
with self.Pool(2) as p:
try:
p.map(raise_large_valuerror, [0, 1])
finally:
time.sleep(0.5)
p.close()
p.join()
# check that we indeed waited for all jobs
self.assertGreater(time.monotonic() - t_start, 0.9)
def test_release_task_refs(self):
# Issue #29861: task arguments and results should not be kept
# alive after we are done with them.
objs = [CountedObject() for i in range(10)]
refs = [weakref.ref(o) for o in objs]
self.pool.map(identity, objs)
del objs
time.sleep(DELTA) # let threaded cleanup code run
self.assertEqual(set(wr() for wr in refs), {None})
# With a process pool, copies of the objects are returned, check
# they were released too.
self.assertEqual(CountedObject.n_instances, 0)
def raising():
raise KeyError("key")
def unpickleable_result():
return lambda: 42
class _TestPoolWorkerErrors(BaseTestCase):
ALLOWED_TYPES = ('processes', )
def test_async_error_callback(self):
p = multiprocessing.Pool(2)
scratchpad = [None]
def errback(exc):
scratchpad[0] = exc
res = p.apply_async(raising, error_callback=errback)
self.assertRaises(KeyError, res.get)
self.assertTrue(scratchpad[0])
self.assertIsInstance(scratchpad[0], KeyError)
p.close()
p.join()
def test_unpickleable_result(self):
from multiprocessing.pool import MaybeEncodingError
p = multiprocessing.Pool(2)
# Make sure we don't lose pool processes because of encoding errors.
for iteration in range(20):
scratchpad = [None]
def errback(exc):
scratchpad[0] = exc
res = p.apply_async(unpickleable_result, error_callback=errback)
self.assertRaises(MaybeEncodingError, res.get)
wrapped = scratchpad[0]
self.assertTrue(wrapped)
self.assertIsInstance(scratchpad[0], MaybeEncodingError)
self.assertIsNotNone(wrapped.exc)
self.assertIsNotNone(wrapped.value)
p.close()
p.join()
class _TestPoolWorkerLifetime(BaseTestCase):
ALLOWED_TYPES = ('processes', )
def test_pool_worker_lifetime(self):
p = multiprocessing.Pool(3, maxtasksperchild=10)
self.assertEqual(3, len(p._pool))
origworkerpids = [w.pid for w in p._pool]
# Run many tasks so each worker gets replaced (hopefully)
results = []
for i in range(100):
results.append(p.apply_async(sqr, (i, )))
# Fetch the results and verify we got the right answers,
# also ensuring all the tasks have completed.
for (j, res) in enumerate(results):
self.assertEqual(res.get(), sqr(j))
# Refill the pool
p._repopulate_pool()
# Wait until all workers are alive
# (countdown * DELTA = 5 seconds max startup process time)
countdown = 50
while countdown and not all(w.is_alive() for w in p._pool):
countdown -= 1
time.sleep(DELTA)
finalworkerpids = [w.pid for w in p._pool]
# All pids should be assigned. See issue #7805.
self.assertNotIn(None, origworkerpids)
self.assertNotIn(None, finalworkerpids)
# Finally, check that the worker pids have changed
self.assertNotEqual(sorted(origworkerpids), sorted(finalworkerpids))
p.close()
p.join()
def test_pool_worker_lifetime_early_close(self):
# Issue #10332: closing a pool whose workers have limited lifetimes
# before all the tasks completed would make join() hang.
p = multiprocessing.Pool(3, maxtasksperchild=1)
results = []
for i in range(6):
results.append(p.apply_async(sqr, (i, 0.3)))
p.close()
p.join()
# check the results
for (j, res) in enumerate(results):
self.assertEqual(res.get(), sqr(j))
#
# Test of creating a customized manager class
#
from multiprocessing.managers import BaseManager, BaseProxy, RemoteError
class FooBar(object):
def f(self):
return 'f()'
def g(self):
raise ValueError
def _h(self):
return '_h()'
def baz():
for i in range(10):
yield i*i
class IteratorProxy(BaseProxy):
_exposed_ = ('__next__',)
def __iter__(self):
return self
def __next__(self):
return self._callmethod('__next__')
class MyManager(BaseManager):
pass
MyManager.register('Foo', callable=FooBar)
MyManager.register('Bar', callable=FooBar, exposed=('f', '_h'))
MyManager.register('baz', callable=baz, proxytype=IteratorProxy)
class _TestMyManager(BaseTestCase):
ALLOWED_TYPES = ('manager',)
def test_mymanager(self):
manager = MyManager()
manager.start()
self.common(manager)
manager.shutdown()
# bpo-30356: BaseManager._finalize_manager() sends SIGTERM
# to the manager process if it takes longer than 1 second to stop,
# which happens on slow buildbots.
self.assertIn(manager._process.exitcode, (0, -signal.SIGTERM))
def test_mymanager_context(self):
with MyManager() as manager:
self.common(manager)
# bpo-30356: BaseManager._finalize_manager() sends SIGTERM
# to the manager process if it takes longer than 1 second to stop,
# which happens on slow buildbots.
self.assertIn(manager._process.exitcode, (0, -signal.SIGTERM))
def test_mymanager_context_prestarted(self):
manager = MyManager()
manager.start()
with manager:
self.common(manager)
self.assertEqual(manager._process.exitcode, 0)
def common(self, manager):
foo = manager.Foo()
bar = manager.Bar()
baz = manager.baz()
foo_methods = [name for name in ('f', 'g', '_h') if hasattr(foo, name)]
bar_methods = [name for name in ('f', 'g', '_h') if hasattr(bar, name)]
self.assertEqual(foo_methods, ['f', 'g'])
self.assertEqual(bar_methods, ['f', '_h'])
self.assertEqual(foo.f(), 'f()')
self.assertRaises(ValueError, foo.g)
self.assertEqual(foo._callmethod('f'), 'f()')
self.assertRaises(RemoteError, foo._callmethod, '_h')
self.assertEqual(bar.f(), 'f()')
self.assertEqual(bar._h(), '_h()')
self.assertEqual(bar._callmethod('f'), 'f()')
self.assertEqual(bar._callmethod('_h'), '_h()')
self.assertEqual(list(baz), [i*i for i in range(10)])
#
# Test of connecting to a remote server and using xmlrpclib for serialization
#
_queue = pyqueue.Queue()
def get_queue():
return _queue
class QueueManager(BaseManager):
'''manager class used by server process'''
QueueManager.register('get_queue', callable=get_queue)
class QueueManager2(BaseManager):
'''manager class which specifies the same interface as QueueManager'''
QueueManager2.register('get_queue')
SERIALIZER = 'xmlrpclib'
class _TestRemoteManager(BaseTestCase):
ALLOWED_TYPES = ('manager',)
values = ['hello world', None, True, 2.25,
'hall\xe5 v\xe4rlden',
'\u043f\u0440\u0438\u0432\u0456\u0442 \u0441\u0432\u0456\u0442',
b'hall\xe5 v\xe4rlden',
]
result = values[:]
@classmethod
def _putter(cls, address, authkey):
manager = QueueManager2(
address=address, authkey=authkey, serializer=SERIALIZER
)
manager.connect()
queue = manager.get_queue()
# Note that xmlrpclib will deserialize object as a list not a tuple
queue.put(tuple(cls.values))
def test_remote(self):
authkey = os.urandom(32)
manager = QueueManager(
address=(test.support.HOST, 0), authkey=authkey, serializer=SERIALIZER
)
manager.start()
self.addCleanup(manager.shutdown)
p = self.Process(target=self._putter, args=(manager.address, authkey))
p.daemon = True
p.start()
manager2 = QueueManager2(
address=manager.address, authkey=authkey, serializer=SERIALIZER
)
manager2.connect()
queue = manager2.get_queue()
self.assertEqual(queue.get(), self.result)
# Because we are using xmlrpclib for serialization instead of
# pickle this will cause a serialization error.
self.assertRaises(Exception, queue.put, time.sleep)
# Make queue finalizer run before the server is stopped
del queue
class _TestManagerRestart(BaseTestCase):
@classmethod
def _putter(cls, address, authkey):
manager = QueueManager(
address=address, authkey=authkey, serializer=SERIALIZER)
manager.connect()
queue = manager.get_queue()
queue.put('hello world')
def test_rapid_restart(self):
authkey = os.urandom(32)
manager = QueueManager(
address=(test.support.HOST, 0), authkey=authkey, serializer=SERIALIZER)
try:
srvr = manager.get_server()
addr = srvr.address
# Close the connection.Listener socket which gets opened as a part
# of manager.get_server(). It's not needed for the test.
srvr.listener.close()
manager.start()
p = self.Process(target=self._putter, args=(manager.address, authkey))
p.start()
p.join()
queue = manager.get_queue()
self.assertEqual(queue.get(), 'hello world')
del queue
finally:
if hasattr(manager, "shutdown"):
manager.shutdown()
manager = QueueManager(
address=addr, authkey=authkey, serializer=SERIALIZER)
try:
manager.start()
self.addCleanup(manager.shutdown)
except OSError as e:
if e.errno != errno.EADDRINUSE:
raise
# Retry after some time, in case the old socket was lingering
# (sporadic failure on buildbots)
time.sleep(1.0)
manager = QueueManager(
address=addr, authkey=authkey, serializer=SERIALIZER)
if hasattr(manager, "shutdown"):
self.addCleanup(manager.shutdown)
#
#
#
SENTINEL = latin('')
class _TestConnection(BaseTestCase):
ALLOWED_TYPES = ('processes', 'threads')
@classmethod
def _echo(cls, conn):
for msg in iter(conn.recv_bytes, SENTINEL):
conn.send_bytes(msg)
conn.close()
def test_connection(self):
conn, child_conn = self.Pipe()
p = self.Process(target=self._echo, args=(child_conn,))
p.daemon = True
p.start()
seq = [1, 2.25, None]
msg = latin('hello world')
longmsg = msg * 10
arr = array.array('i', list(range(4)))
if self.TYPE == 'processes':
self.assertEqual(type(conn.fileno()), int)
self.assertEqual(conn.send(seq), None)
self.assertEqual(conn.recv(), seq)
self.assertEqual(conn.send_bytes(msg), None)
self.assertEqual(conn.recv_bytes(), msg)
if self.TYPE == 'processes':
buffer = array.array('i', [0]*10)
expected = list(arr) + [0] * (10 - len(arr))
self.assertEqual(conn.send_bytes(arr), None)
self.assertEqual(conn.recv_bytes_into(buffer),
len(arr) * buffer.itemsize)
self.assertEqual(list(buffer), expected)
buffer = array.array('i', [0]*10)
expected = [0] * 3 + list(arr) + [0] * (10 - 3 - len(arr))
self.assertEqual(conn.send_bytes(arr), None)
self.assertEqual(conn.recv_bytes_into(buffer, 3 * buffer.itemsize),
len(arr) * buffer.itemsize)
self.assertEqual(list(buffer), expected)
buffer = bytearray(latin(' ' * 40))
self.assertEqual(conn.send_bytes(longmsg), None)
try:
res = conn.recv_bytes_into(buffer)
except multiprocessing.BufferTooShort as e:
self.assertEqual(e.args, (longmsg,))
else:
self.fail('expected BufferTooShort, got %s' % res)
poll = TimingWrapper(conn.poll)
self.assertEqual(poll(), False)
self.assertTimingAlmostEqual(poll.elapsed, 0)
self.assertEqual(poll(-1), False)
self.assertTimingAlmostEqual(poll.elapsed, 0)
self.assertEqual(poll(TIMEOUT1), False)
self.assertTimingAlmostEqual(poll.elapsed, TIMEOUT1)
conn.send(None)
time.sleep(.1)
self.assertEqual(poll(TIMEOUT1), True)
self.assertTimingAlmostEqual(poll.elapsed, 0)
self.assertEqual(conn.recv(), None)
really_big_msg = latin('X') * (1024 * 1024 * 16) # 16Mb
conn.send_bytes(really_big_msg)
self.assertEqual(conn.recv_bytes(), really_big_msg)
conn.send_bytes(SENTINEL) # tell child to quit
child_conn.close()
if self.TYPE == 'processes':
self.assertEqual(conn.readable, True)
self.assertEqual(conn.writable, True)
self.assertRaises(EOFError, conn.recv)
self.assertRaises(EOFError, conn.recv_bytes)
p.join()
def test_duplex_false(self):
reader, writer = self.Pipe(duplex=False)
self.assertEqual(writer.send(1), None)
self.assertEqual(reader.recv(), 1)
if self.TYPE == 'processes':
self.assertEqual(reader.readable, True)
self.assertEqual(reader.writable, False)
self.assertEqual(writer.readable, False)
self.assertEqual(writer.writable, True)
self.assertRaises(OSError, reader.send, 2)
self.assertRaises(OSError, writer.recv)
self.assertRaises(OSError, writer.poll)
def test_spawn_close(self):
# We test that a pipe connection can be closed by parent
# process immediately after child is spawned. On Windows this
# would have sometimes failed on old versions because
# child_conn would be closed before the child got a chance to
# duplicate it.
conn, child_conn = self.Pipe()
p = self.Process(target=self._echo, args=(child_conn,))
p.daemon = True
p.start()
child_conn.close() # this might complete before child initializes
msg = latin('hello')
conn.send_bytes(msg)
self.assertEqual(conn.recv_bytes(), msg)
conn.send_bytes(SENTINEL)
conn.close()
p.join()
def test_sendbytes(self):
if self.TYPE != 'processes':
self.skipTest('test not appropriate for {}'.format(self.TYPE))
msg = latin('abcdefghijklmnopqrstuvwxyz')
a, b = self.Pipe()
a.send_bytes(msg)
self.assertEqual(b.recv_bytes(), msg)
a.send_bytes(msg, 5)
self.assertEqual(b.recv_bytes(), msg[5:])
a.send_bytes(msg, 7, 8)
self.assertEqual(b.recv_bytes(), msg[7:7+8])
a.send_bytes(msg, 26)
self.assertEqual(b.recv_bytes(), latin(''))
a.send_bytes(msg, 26, 0)
self.assertEqual(b.recv_bytes(), latin(''))
self.assertRaises(ValueError, a.send_bytes, msg, 27)
self.assertRaises(ValueError, a.send_bytes, msg, 22, 5)
self.assertRaises(ValueError, a.send_bytes, msg, 26, 1)
self.assertRaises(ValueError, a.send_bytes, msg, -1)
self.assertRaises(ValueError, a.send_bytes, msg, 4, -1)
@classmethod
def _is_fd_assigned(cls, fd):
try:
os.fstat(fd)
except OSError as e:
if e.errno == errno.EBADF:
return False
raise
else:
return True
@classmethod
def _writefd(cls, conn, data, create_dummy_fds=False):
if create_dummy_fds:
for i in range(0, 256):
if not cls._is_fd_assigned(i):
os.dup2(conn.fileno(), i)
fd = reduction.recv_handle(conn)
if msvcrt:
fd = msvcrt.open_osfhandle(fd, os.O_WRONLY)
os.write(fd, data)
os.close(fd)
@unittest.skipUnless(HAS_REDUCTION, "test needs multiprocessing.reduction")
def test_fd_transfer(self):
if self.TYPE != 'processes':
self.skipTest("only makes sense with processes")
conn, child_conn = self.Pipe(duplex=True)
p = self.Process(target=self._writefd, args=(child_conn, b"foo"))
p.daemon = True
p.start()
self.addCleanup(test.support.unlink, test.support.TESTFN)
with open(test.support.TESTFN, "wb") as f:
fd = f.fileno()
if msvcrt:
fd = msvcrt.get_osfhandle(fd)
reduction.send_handle(conn, fd, p.pid)
p.join()
with open(test.support.TESTFN, "rb") as f:
self.assertEqual(f.read(), b"foo")
@unittest.skipUnless(HAS_REDUCTION, "test needs multiprocessing.reduction")
@unittest.skipIf(sys.platform == "win32",
"test semantics don't make sense on Windows")
@unittest.skipIf(MAXFD <= 256,
"largest assignable fd number is too small")
@unittest.skipUnless(hasattr(os, "dup2"),
"test needs os.dup2()")
def test_large_fd_transfer(self):
# With fd > 256 (issue #11657)
if self.TYPE != 'processes':
self.skipTest("only makes sense with processes")
conn, child_conn = self.Pipe(duplex=True)
p = self.Process(target=self._writefd, args=(child_conn, b"bar", True))
p.daemon = True
p.start()
self.addCleanup(test.support.unlink, test.support.TESTFN)
with open(test.support.TESTFN, "wb") as f:
fd = f.fileno()
for newfd in range(256, MAXFD):
if not self._is_fd_assigned(newfd):
break
else:
self.fail("could not find an unassigned large file descriptor")
os.dup2(fd, newfd)
try:
reduction.send_handle(conn, newfd, p.pid)
finally:
os.close(newfd)
p.join()
with open(test.support.TESTFN, "rb") as f:
self.assertEqual(f.read(), b"bar")
@classmethod
def _send_data_without_fd(self, conn):
os.write(conn.fileno(), b"\0")
@unittest.skipUnless(HAS_REDUCTION, "test needs multiprocessing.reduction")
@unittest.skipIf(sys.platform == "win32", "doesn't make sense on Windows")
def test_missing_fd_transfer(self):
# Check that exception is raised when received data is not
# accompanied by a file descriptor in ancillary data.
if self.TYPE != 'processes':
self.skipTest("only makes sense with processes")
conn, child_conn = self.Pipe(duplex=True)
p = self.Process(target=self._send_data_without_fd, args=(child_conn,))
p.daemon = True
p.start()
self.assertRaises(RuntimeError, reduction.recv_handle, conn)
p.join()
def test_context(self):
a, b = self.Pipe()
with a, b:
a.send(1729)
self.assertEqual(b.recv(), 1729)
if self.TYPE == 'processes':
self.assertFalse(a.closed)
self.assertFalse(b.closed)
if self.TYPE == 'processes':
self.assertTrue(a.closed)
self.assertTrue(b.closed)
self.assertRaises(OSError, a.recv)
self.assertRaises(OSError, b.recv)
class _TestListener(BaseTestCase):
ALLOWED_TYPES = ('processes',)
def test_multiple_bind(self):
for family in self.connection.families:
l = self.connection.Listener(family=family)
self.addCleanup(l.close)
self.assertRaises(OSError, self.connection.Listener,
l.address, family)
def test_context(self):
with self.connection.Listener() as l:
with self.connection.Client(l.address) as c:
with l.accept() as d:
c.send(1729)
self.assertEqual(d.recv(), 1729)
if self.TYPE == 'processes':
self.assertRaises(OSError, l.accept)
class _TestListenerClient(BaseTestCase):
ALLOWED_TYPES = ('processes', 'threads')
@classmethod
def _test(cls, address):
conn = cls.connection.Client(address)
conn.send('hello')
conn.close()
def test_listener_client(self):
for family in self.connection.families:
l = self.connection.Listener(family=family)
p = self.Process(target=self._test, args=(l.address,))
p.daemon = True
p.start()
conn = l.accept()
self.assertEqual(conn.recv(), 'hello')
p.join()
l.close()
def test_issue14725(self):
l = self.connection.Listener()
p = self.Process(target=self._test, args=(l.address,))
p.daemon = True
p.start()
time.sleep(1)
# On Windows the client process should by now have connected,
# written data and closed the pipe handle by now. This causes
# ConnectNamdedPipe() to fail with ERROR_NO_DATA. See Issue
# 14725.
conn = l.accept()
self.assertEqual(conn.recv(), 'hello')
conn.close()
p.join()
l.close()
def test_issue16955(self):
for fam in self.connection.families:
l = self.connection.Listener(family=fam)
c = self.connection.Client(l.address)
a = l.accept()
a.send_bytes(b"hello")
self.assertTrue(c.poll(1))
a.close()
c.close()
l.close()
class _TestPoll(BaseTestCase):
ALLOWED_TYPES = ('processes', 'threads')
def test_empty_string(self):
a, b = self.Pipe()
self.assertEqual(a.poll(), False)
b.send_bytes(b'')
self.assertEqual(a.poll(), True)
self.assertEqual(a.poll(), True)
@classmethod
def _child_strings(cls, conn, strings):
for s in strings:
time.sleep(0.1)
conn.send_bytes(s)
conn.close()
def test_strings(self):
strings = (b'hello', b'', b'a', b'b', b'', b'bye', b'', b'lop')
a, b = self.Pipe()
p = self.Process(target=self._child_strings, args=(b, strings))
p.start()
for s in strings:
for i in range(200):
if a.poll(0.01):
break
x = a.recv_bytes()
self.assertEqual(s, x)
p.join()
@classmethod
def _child_boundaries(cls, r):
# Polling may "pull" a message in to the child process, but we
# don't want it to pull only part of a message, as that would
# corrupt the pipe for any other processes which might later
# read from it.
r.poll(5)
def test_boundaries(self):
r, w = self.Pipe(False)
p = self.Process(target=self._child_boundaries, args=(r,))
p.start()
time.sleep(2)
L = [b"first", b"second"]
for obj in L:
w.send_bytes(obj)
w.close()
p.join()
self.assertIn(r.recv_bytes(), L)
@classmethod
def _child_dont_merge(cls, b):
b.send_bytes(b'a')
b.send_bytes(b'b')
b.send_bytes(b'cd')
def test_dont_merge(self):
a, b = self.Pipe()
self.assertEqual(a.poll(0.0), False)
self.assertEqual(a.poll(0.1), False)
p = self.Process(target=self._child_dont_merge, args=(b,))
p.start()
self.assertEqual(a.recv_bytes(), b'a')
self.assertEqual(a.poll(1.0), True)
self.assertEqual(a.poll(1.0), True)
self.assertEqual(a.recv_bytes(), b'b')
self.assertEqual(a.poll(1.0), True)
self.assertEqual(a.poll(1.0), True)
self.assertEqual(a.poll(0.0), True)
self.assertEqual(a.recv_bytes(), b'cd')
p.join()
#
# Test of sending connection and socket objects between processes
#
@unittest.skipUnless(HAS_REDUCTION, "test needs multiprocessing.reduction")
class _TestPicklingConnections(BaseTestCase):
ALLOWED_TYPES = ('processes',)
@classmethod
def tearDownClass(cls):
from multiprocessing import resource_sharer
resource_sharer.stop(timeout=TIMEOUT)
@classmethod
def _listener(cls, conn, families):
for fam in families:
l = cls.connection.Listener(family=fam)
conn.send(l.address)
new_conn = l.accept()
conn.send(new_conn)
new_conn.close()
l.close()
l = socket.socket()
l.bind((test.support.HOST, 0))
l.listen()
conn.send(l.getsockname())
new_conn, addr = l.accept()
conn.send(new_conn)
new_conn.close()
l.close()
conn.recv()
@classmethod
def _remote(cls, conn):
for (address, msg) in iter(conn.recv, None):
client = cls.connection.Client(address)
client.send(msg.upper())
client.close()
address, msg = conn.recv()
client = socket.socket()
client.connect(address)
client.sendall(msg.upper())
client.close()
conn.close()
def test_pickling(self):
families = self.connection.families
lconn, lconn0 = self.Pipe()
lp = self.Process(target=self._listener, args=(lconn0, families))
lp.daemon = True
lp.start()
lconn0.close()
rconn, rconn0 = self.Pipe()
rp = self.Process(target=self._remote, args=(rconn0,))
rp.daemon = True
rp.start()
rconn0.close()
for fam in families:
msg = ('This connection uses family %s' % fam).encode('ascii')
address = lconn.recv()
rconn.send((address, msg))
new_conn = lconn.recv()
self.assertEqual(new_conn.recv(), msg.upper())
rconn.send(None)
msg = latin('This connection uses a normal socket')
address = lconn.recv()
rconn.send((address, msg))
new_conn = lconn.recv()
buf = []
while True:
s = new_conn.recv(100)
if not s:
break
buf.append(s)
buf = b''.join(buf)
self.assertEqual(buf, msg.upper())
new_conn.close()
lconn.send(None)
rconn.close()
lconn.close()
lp.join()
rp.join()
@classmethod
def child_access(cls, conn):
w = conn.recv()
w.send('all is well')
w.close()
r = conn.recv()
msg = r.recv()
conn.send(msg*2)
conn.close()
def test_access(self):
# On Windows, if we do not specify a destination pid when
# using DupHandle then we need to be careful to use the
# correct access flags for DuplicateHandle(), or else
# DupHandle.detach() will raise PermissionError. For example,
# for a read only pipe handle we should use
# access=FILE_GENERIC_READ. (Unfortunately
# DUPLICATE_SAME_ACCESS does not work.)
conn, child_conn = self.Pipe()
p = self.Process(target=self.child_access, args=(child_conn,))
p.daemon = True
p.start()
child_conn.close()
r, w = self.Pipe(duplex=False)
conn.send(w)
w.close()
self.assertEqual(r.recv(), 'all is well')
r.close()
r, w = self.Pipe(duplex=False)
conn.send(r)
r.close()
w.send('foobar')
w.close()
self.assertEqual(conn.recv(), 'foobar'*2)
p.join()
#
#
#
class _TestHeap(BaseTestCase):
ALLOWED_TYPES = ('processes',)
def test_heap(self):
iterations = 5000
maxblocks = 50
blocks = []
# create and destroy lots of blocks of different sizes
for i in range(iterations):
size = int(random.lognormvariate(0, 1) * 1000)
b = multiprocessing.heap.BufferWrapper(size)
blocks.append(b)
if len(blocks) > maxblocks:
i = random.randrange(maxblocks)
del blocks[i]
# get the heap object
heap = multiprocessing.heap.BufferWrapper._heap
# verify the state of the heap
all = []
occupied = 0
heap._lock.acquire()
self.addCleanup(heap._lock.release)
for L in list(heap._len_to_seq.values()):
for arena, start, stop in L:
all.append((heap._arenas.index(arena), start, stop,
stop-start, 'free'))
for arena, start, stop in heap._allocated_blocks:
all.append((heap._arenas.index(arena), start, stop,
stop-start, 'occupied'))
occupied += (stop-start)
all.sort()
for i in range(len(all)-1):
(arena, start, stop) = all[i][:3]
(narena, nstart, nstop) = all[i+1][:3]
self.assertTrue((arena != narena and nstart == 0) or
(stop == nstart))
def test_free_from_gc(self):
# Check that freeing of blocks by the garbage collector doesn't deadlock
# (issue #12352).
# Make sure the GC is enabled, and set lower collection thresholds to
# make collections more frequent (and increase the probability of
# deadlock).
if not gc.isenabled():
gc.enable()
self.addCleanup(gc.disable)
thresholds = gc.get_threshold()
self.addCleanup(gc.set_threshold, *thresholds)
gc.set_threshold(10)
# perform numerous block allocations, with cyclic references to make
# sure objects are collected asynchronously by the gc
for i in range(5000):
a = multiprocessing.heap.BufferWrapper(1)
b = multiprocessing.heap.BufferWrapper(1)
# circular references
a.buddy = b
b.buddy = a
#
#
#
class _Foo(Structure):
_fields_ = [
('x', c_int),
('y', c_double),
('z', c_longlong,)
]
class _TestSharedCTypes(BaseTestCase):
ALLOWED_TYPES = ('processes',)
def setUp(self):
if not HAS_SHAREDCTYPES:
self.skipTest("requires multiprocessing.sharedctypes")
@classmethod
def _double(cls, x, y, z, foo, arr, string):
x.value *= 2
y.value *= 2
z.value *= 2
foo.x *= 2
foo.y *= 2
string.value *= 2
for i in range(len(arr)):
arr[i] *= 2
def test_sharedctypes(self, lock=False):
x = Value('i', 7, lock=lock)
y = Value(c_double, 1.0/3.0, lock=lock)
z = Value(c_longlong, 2 ** 33, lock=lock)
foo = Value(_Foo, 3, 2, lock=lock)
arr = self.Array('d', list(range(10)), lock=lock)
string = self.Array('c', 20, lock=lock)
string.value = latin('hello')
p = self.Process(target=self._double, args=(x, y, z, foo, arr, string))
p.daemon = True
p.start()
p.join()
self.assertEqual(x.value, 14)
self.assertAlmostEqual(y.value, 2.0/3.0)
self.assertEqual(z.value, 2 ** 34)
self.assertEqual(foo.x, 6)
self.assertAlmostEqual(foo.y, 4.0)
for i in range(10):
self.assertAlmostEqual(arr[i], i*2)
self.assertEqual(string.value, latin('hellohello'))
def test_synchronize(self):
self.test_sharedctypes(lock=True)
def test_copy(self):
foo = _Foo(2, 5.0, 2 ** 33)
bar = copy(foo)
foo.x = 0
foo.y = 0
foo.z = 0
self.assertEqual(bar.x, 2)
self.assertAlmostEqual(bar.y, 5.0)
self.assertEqual(bar.z, 2 ** 33)
#
#
#
class _TestFinalize(BaseTestCase):
ALLOWED_TYPES = ('processes',)
def setUp(self):
self.registry_backup = util._finalizer_registry.copy()
util._finalizer_registry.clear()
def tearDown(self):
self.assertFalse(util._finalizer_registry)
util._finalizer_registry.update(self.registry_backup)
@classmethod
def _test_finalize(cls, conn):
class Foo(object):
pass
a = Foo()
util.Finalize(a, conn.send, args=('a',))
del a # triggers callback for a
b = Foo()
close_b = util.Finalize(b, conn.send, args=('b',))
close_b() # triggers callback for b
close_b() # does nothing because callback has already been called
del b # does nothing because callback has already been called
c = Foo()
util.Finalize(c, conn.send, args=('c',))
d10 = Foo()
util.Finalize(d10, conn.send, args=('d10',), exitpriority=1)
d01 = Foo()
util.Finalize(d01, conn.send, args=('d01',), exitpriority=0)
d02 = Foo()
util.Finalize(d02, conn.send, args=('d02',), exitpriority=0)
d03 = Foo()
util.Finalize(d03, conn.send, args=('d03',), exitpriority=0)
util.Finalize(None, conn.send, args=('e',), exitpriority=-10)
util.Finalize(None, conn.send, args=('STOP',), exitpriority=-100)
# call multiprocessing's cleanup function then exit process without
# garbage collecting locals
util._exit_function()
conn.close()
os._exit(0)
def test_finalize(self):
conn, child_conn = self.Pipe()
p = self.Process(target=self._test_finalize, args=(child_conn,))
p.daemon = True
p.start()
p.join()
result = [obj for obj in iter(conn.recv, 'STOP')]
self.assertEqual(result, ['a', 'b', 'd10', 'd03', 'd02', 'd01', 'e'])
def test_thread_safety(self):
# bpo-24484: _run_finalizers() should be thread-safe
def cb():
pass
class Foo(object):
def __init__(self):
self.ref = self # create reference cycle
# insert finalizer at random key
util.Finalize(self, cb, exitpriority=random.randint(1, 100))
finish = False
exc = None
def run_finalizers():
nonlocal exc
while not finish:
time.sleep(random.random() * 1e-1)
try:
# A GC run will eventually happen during this,
# collecting stale Foo's and mutating the registry
util._run_finalizers()
except Exception as e:
exc = e
def make_finalizers():
nonlocal exc
d = {}
while not finish:
try:
# Old Foo's get gradually replaced and later
# collected by the GC (because of the cyclic ref)
d[random.getrandbits(5)] = {Foo() for i in range(10)}
except Exception as e:
exc = e
d.clear()
old_interval = sys.getswitchinterval()
old_threshold = gc.get_threshold()
try:
sys.setswitchinterval(1e-6)
gc.set_threshold(5, 5, 5)
threads = [threading.Thread(target=run_finalizers),
threading.Thread(target=make_finalizers)]
with test.support.start_threads(threads):
time.sleep(4.0) # Wait a bit to trigger race condition
finish = True
if exc is not None:
raise exc
finally:
sys.setswitchinterval(old_interval)
gc.set_threshold(*old_threshold)
gc.collect() # Collect remaining Foo's
#
# Test that from ... import * works for each module
#
class _TestImportStar(unittest.TestCase):
def get_module_names(self):
import glob
folder = os.path.dirname(multiprocessing.__file__)
pattern = os.path.join(folder, '*.py')
files = glob.glob(pattern)
modules = [os.path.splitext(os.path.split(f)[1])[0] for f in files]
modules = ['multiprocessing.' + m for m in modules]
modules.remove('multiprocessing.__init__')
modules.append('multiprocessing')
return modules
def test_import(self):
modules = self.get_module_names()
if sys.platform == 'win32':
modules.remove('multiprocessing.popen_fork')
modules.remove('multiprocessing.popen_forkserver')
modules.remove('multiprocessing.popen_spawn_posix')
else:
modules.remove('multiprocessing.popen_spawn_win32')
if not HAS_REDUCTION:
modules.remove('multiprocessing.popen_forkserver')
if c_int is None:
# This module requires _ctypes
modules.remove('multiprocessing.sharedctypes')
for name in modules:
__import__(name)
mod = sys.modules[name]
self.assertTrue(hasattr(mod, '__all__'), name)
for attr in mod.__all__:
self.assertTrue(
hasattr(mod, attr),
'%r does not have attribute %r' % (mod, attr)
)
#
# Quick test that logging works -- does not test logging output
#
class _TestLogging(BaseTestCase):
ALLOWED_TYPES = ('processes',)
def test_enable_logging(self):
logger = multiprocessing.get_logger()
logger.setLevel(util.SUBWARNING)
self.assertTrue(logger is not None)
logger.debug('this will not be printed')
logger.info('nor will this')
logger.setLevel(LOG_LEVEL)
@classmethod
def _test_level(cls, conn):
logger = multiprocessing.get_logger()
conn.send(logger.getEffectiveLevel())
def test_level(self):
LEVEL1 = 32
LEVEL2 = 37
logger = multiprocessing.get_logger()
root_logger = logging.getLogger()
root_level = root_logger.level
reader, writer = multiprocessing.Pipe(duplex=False)
logger.setLevel(LEVEL1)
p = self.Process(target=self._test_level, args=(writer,))
p.start()
self.assertEqual(LEVEL1, reader.recv())
p.join()
p.close()
logger.setLevel(logging.NOTSET)
root_logger.setLevel(LEVEL2)
p = self.Process(target=self._test_level, args=(writer,))
p.start()
self.assertEqual(LEVEL2, reader.recv())
p.join()
p.close()
root_logger.setLevel(root_level)
logger.setLevel(level=LOG_LEVEL)
# class _TestLoggingProcessName(BaseTestCase):
#
# def handle(self, record):
# assert record.processName == multiprocessing.current_process().name
# self.__handled = True
#
# def test_logging(self):
# handler = logging.Handler()
# handler.handle = self.handle
# self.__handled = False
# # Bypass getLogger() and side-effects
# logger = logging.getLoggerClass()(
# 'multiprocessing.test.TestLoggingProcessName')
# logger.addHandler(handler)
# logger.propagate = False
#
# logger.warn('foo')
# assert self.__handled
#
# Check that Process.join() retries if os.waitpid() fails with EINTR
#
class _TestPollEintr(BaseTestCase):
ALLOWED_TYPES = ('processes',)
@classmethod
def _killer(cls, pid):
time.sleep(0.1)
os.kill(pid, signal.SIGUSR1)
@unittest.skipUnless(hasattr(signal, 'SIGUSR1'), 'requires SIGUSR1')
def test_poll_eintr(self):
got_signal = [False]
def record(*args):
got_signal[0] = True
pid = os.getpid()
oldhandler = signal.signal(signal.SIGUSR1, record)
try:
killer = self.Process(target=self._killer, args=(pid,))
killer.start()
try:
p = self.Process(target=time.sleep, args=(2,))
p.start()
p.join()
finally:
killer.join()
self.assertTrue(got_signal[0])
self.assertEqual(p.exitcode, 0)
finally:
signal.signal(signal.SIGUSR1, oldhandler)
#
# Test to verify handle verification, see issue 3321
#
class TestInvalidHandle(unittest.TestCase):
@unittest.skipIf(WIN32, "skipped on Windows")
def test_invalid_handles(self):
conn = multiprocessing.connection.Connection(44977608)
# check that poll() doesn't crash
try:
conn.poll()
except (ValueError, OSError):
pass
finally:
# Hack private attribute _handle to avoid printing an error
# in conn.__del__
conn._handle = None
self.assertRaises((ValueError, OSError),
multiprocessing.connection.Connection, -1)
class OtherTest(unittest.TestCase):
# TODO: add more tests for deliver/answer challenge.
def test_deliver_challenge_auth_failure(self):
class _FakeConnection(object):
def recv_bytes(self, size):
return b'something bogus'
def send_bytes(self, data):
pass
self.assertRaises(multiprocessing.AuthenticationError,
multiprocessing.connection.deliver_challenge,
_FakeConnection(), b'abc')
def test_answer_challenge_auth_failure(self):
class _FakeConnection(object):
def __init__(self):
self.count = 0
def recv_bytes(self, size):
self.count += 1
if self.count == 1:
return multiprocessing.connection.CHALLENGE
elif self.count == 2:
return b'something bogus'
return b''
def send_bytes(self, data):
pass
self.assertRaises(multiprocessing.AuthenticationError,
multiprocessing.connection.answer_challenge,
_FakeConnection(), b'abc')
#
# Test Manager.start()/Pool.__init__() initializer feature - see issue 5585
#
def initializer(ns):
ns.test += 1
class TestInitializers(unittest.TestCase):
def setUp(self):
self.mgr = multiprocessing.Manager()
self.ns = self.mgr.Namespace()
self.ns.test = 0
def tearDown(self):
self.mgr.shutdown()
self.mgr.join()
def test_manager_initializer(self):
m = multiprocessing.managers.SyncManager()
self.assertRaises(TypeError, m.start, 1)
m.start(initializer, (self.ns,))
self.assertEqual(self.ns.test, 1)
m.shutdown()
m.join()
def test_pool_initializer(self):
self.assertRaises(TypeError, multiprocessing.Pool, initializer=1)
p = multiprocessing.Pool(1, initializer, (self.ns,))
p.close()
p.join()
self.assertEqual(self.ns.test, 1)
#
# Issue 5155, 5313, 5331: Test process in processes
# Verifies os.close(sys.stdin.fileno) vs. sys.stdin.close() behavior
#
def _this_sub_process(q):
try:
item = q.get(block=False)
except pyqueue.Empty:
pass
def _test_process():
queue = multiprocessing.Queue()
subProc = multiprocessing.Process(target=_this_sub_process, args=(queue,))
subProc.daemon = True
subProc.start()
subProc.join()
def _afunc(x):
return x*x
def pool_in_process():
pool = multiprocessing.Pool(processes=4)
x = pool.map(_afunc, [1, 2, 3, 4, 5, 6, 7])
pool.close()
pool.join()
class _file_like(object):
def __init__(self, delegate):
self._delegate = delegate
self._pid = None
@property
def cache(self):
pid = os.getpid()
# There are no race conditions since fork keeps only the running thread
if pid != self._pid:
self._pid = pid
self._cache = []
return self._cache
def write(self, data):
self.cache.append(data)
def flush(self):
self._delegate.write(''.join(self.cache))
self._cache = []
class TestStdinBadfiledescriptor(unittest.TestCase):
def test_queue_in_process(self):
proc = multiprocessing.Process(target=_test_process)
proc.start()
proc.join()
def test_pool_in_process(self):
p = multiprocessing.Process(target=pool_in_process)
p.start()
p.join()
def test_flushing(self):
sio = io.StringIO()
flike = _file_like(sio)
flike.write('foo')
proc = multiprocessing.Process(target=lambda: flike.flush())
flike.flush()
assert sio.getvalue() == 'foo'
class TestWait(unittest.TestCase):
@classmethod
def _child_test_wait(cls, w, slow):
for i in range(10):
if slow:
time.sleep(random.random()*0.1)
w.send((i, os.getpid()))
w.close()
def test_wait(self, slow=False):
from multiprocessing.connection import wait
readers = []
procs = []
messages = []
for i in range(4):
r, w = multiprocessing.Pipe(duplex=False)
p = multiprocessing.Process(target=self._child_test_wait, args=(w, slow))
p.daemon = True
p.start()
w.close()
readers.append(r)
procs.append(p)
self.addCleanup(p.join)
while readers:
for r in wait(readers):
try:
msg = r.recv()
except EOFError:
readers.remove(r)
r.close()
else:
messages.append(msg)
messages.sort()
expected = sorted((i, p.pid) for i in range(10) for p in procs)
self.assertEqual(messages, expected)
@classmethod
def _child_test_wait_socket(cls, address, slow):
s = socket.socket()
s.connect(address)
for i in range(10):
if slow:
time.sleep(random.random()*0.1)
s.sendall(('%s\n' % i).encode('ascii'))
s.close()
def test_wait_socket(self, slow=False):
from multiprocessing.connection import wait
l = socket.socket()
l.bind((test.support.HOST, 0))
l.listen()
addr = l.getsockname()
readers = []
procs = []
dic = {}
for i in range(4):
p = multiprocessing.Process(target=self._child_test_wait_socket,
args=(addr, slow))
p.daemon = True
p.start()
procs.append(p)
self.addCleanup(p.join)
for i in range(4):
r, _ = l.accept()
readers.append(r)
dic[r] = []
l.close()
while readers:
for r in wait(readers):
msg = r.recv(32)
if not msg:
readers.remove(r)
r.close()
else:
dic[r].append(msg)
expected = ''.join('%s\n' % i for i in range(10)).encode('ascii')
for v in dic.values():
self.assertEqual(b''.join(v), expected)
def test_wait_slow(self):
self.test_wait(True)
def test_wait_socket_slow(self):
self.test_wait_socket(True)
def test_wait_timeout(self):
from multiprocessing.connection import wait
expected = 5
a, b = multiprocessing.Pipe()
start = time.monotonic()
res = wait([a, b], expected)
delta = time.monotonic() - start
self.assertEqual(res, [])
self.assertLess(delta, expected * 2)
self.assertGreater(delta, expected * 0.5)
b.send(None)
start = time.monotonic()
res = wait([a, b], 20)
delta = time.monotonic() - start
self.assertEqual(res, [a])
self.assertLess(delta, 0.4)
@classmethod
def signal_and_sleep(cls, sem, period):
sem.release()
time.sleep(period)
def test_wait_integer(self):
from multiprocessing.connection import wait
expected = 3
sorted_ = lambda l: sorted(l, key=lambda x: id(x))
sem = multiprocessing.Semaphore(0)
a, b = multiprocessing.Pipe()
p = multiprocessing.Process(target=self.signal_and_sleep,
args=(sem, expected))
p.start()
self.assertIsInstance(p.sentinel, int)
self.assertTrue(sem.acquire(timeout=20))
start = time.monotonic()
res = wait([a, p.sentinel, b], expected + 20)
delta = time.monotonic() - start
self.assertEqual(res, [p.sentinel])
self.assertLess(delta, expected + 2)
self.assertGreater(delta, expected - 2)
a.send(None)
start = time.monotonic()
res = wait([a, p.sentinel, b], 20)
delta = time.monotonic() - start
self.assertEqual(sorted_(res), sorted_([p.sentinel, b]))
self.assertLess(delta, 0.4)
b.send(None)
start = time.monotonic()
res = wait([a, p.sentinel, b], 20)
delta = time.monotonic() - start
self.assertEqual(sorted_(res), sorted_([a, p.sentinel, b]))
self.assertLess(delta, 0.4)
p.terminate()
p.join()
def test_neg_timeout(self):
from multiprocessing.connection import wait
a, b = multiprocessing.Pipe()
t = time.monotonic()
res = wait([a], timeout=-1)
t = time.monotonic() - t
self.assertEqual(res, [])
self.assertLess(t, 1)
a.close()
b.close()
#
# Issue 14151: Test invalid family on invalid environment
#
class TestInvalidFamily(unittest.TestCase):
@unittest.skipIf(WIN32, "skipped on Windows")
def test_invalid_family(self):
with self.assertRaises(ValueError):
multiprocessing.connection.Listener(r'\\.\test')
@unittest.skipUnless(WIN32, "skipped on non-Windows platforms")
def test_invalid_family_win32(self):
with self.assertRaises(ValueError):
multiprocessing.connection.Listener('/var/test.pipe')
#
# Issue 12098: check sys.flags of child matches that for parent
#
class TestFlags(unittest.TestCase):
@classmethod
def run_in_grandchild(cls, conn):
conn.send(tuple(sys.flags))
@classmethod
def run_in_child(cls):
import json
r, w = multiprocessing.Pipe(duplex=False)
p = multiprocessing.Process(target=cls.run_in_grandchild, args=(w,))
p.start()
grandchild_flags = r.recv()
p.join()
r.close()
w.close()
flags = (tuple(sys.flags), grandchild_flags)
print(json.dumps(flags))
def test_flags(self):
import json, subprocess
# start child process using unusual flags
prog = ('from test._test_multiprocessing import TestFlags; ' +
'TestFlags.run_in_child()')
data = subprocess.check_output(
[sys.executable, '-E', '-S', '-O', '-c', prog])
child_flags, grandchild_flags = json.loads(data.decode('ascii'))
self.assertEqual(child_flags, grandchild_flags)
#
# Test interaction with socket timeouts - see Issue #6056
#
class TestTimeouts(unittest.TestCase):
@classmethod
def _test_timeout(cls, child, address):
time.sleep(1)
child.send(123)
child.close()
conn = multiprocessing.connection.Client(address)
conn.send(456)
conn.close()
def test_timeout(self):
old_timeout = socket.getdefaulttimeout()
try:
socket.setdefaulttimeout(0.1)
parent, child = multiprocessing.Pipe(duplex=True)
l = multiprocessing.connection.Listener(family='AF_INET')
p = multiprocessing.Process(target=self._test_timeout,
args=(child, l.address))
p.start()
child.close()
self.assertEqual(parent.recv(), 123)
parent.close()
conn = l.accept()
self.assertEqual(conn.recv(), 456)
conn.close()
l.close()
join_process(p)
finally:
socket.setdefaulttimeout(old_timeout)
#
# Test what happens with no "if __name__ == '__main__'"
#
class TestNoForkBomb(unittest.TestCase):
def test_noforkbomb(self):
sm = multiprocessing.get_start_method()
name = os.path.join(os.path.dirname(__file__), 'mp_fork_bomb.py')
if sm != 'fork':
rc, out, err = test.support.script_helper.assert_python_failure(name, sm)
self.assertEqual(out, b'')
self.assertIn(b'RuntimeError', err)
else:
rc, out, err = test.support.script_helper.assert_python_ok(name, sm)
self.assertEqual(out.rstrip(), b'123')
self.assertEqual(err, b'')
#
# Issue #17555: ForkAwareThreadLock
#
class TestForkAwareThreadLock(unittest.TestCase):
# We recursively start processes. Issue #17555 meant that the
# after fork registry would get duplicate entries for the same
# lock. The size of the registry at generation n was ~2**n.
@classmethod
def child(cls, n, conn):
if n > 1:
p = multiprocessing.Process(target=cls.child, args=(n-1, conn))
p.start()
conn.close()
join_process(p)
else:
conn.send(len(util._afterfork_registry))
conn.close()
def test_lock(self):
r, w = multiprocessing.Pipe(False)
l = util.ForkAwareThreadLock()
old_size = len(util._afterfork_registry)
p = multiprocessing.Process(target=self.child, args=(5, w))
p.start()
w.close()
new_size = r.recv()
join_process(p)
self.assertLessEqual(new_size, old_size)
#
# Check that non-forked child processes do not inherit unneeded fds/handles
#
class TestCloseFds(unittest.TestCase):
def get_high_socket_fd(self):
if WIN32:
# The child process will not have any socket handles, so
# calling socket.fromfd() should produce WSAENOTSOCK even
# if there is a handle of the same number.
return socket.socket().detach()
else:
# We want to produce a socket with an fd high enough that a
# freshly created child process will not have any fds as high.
fd = socket.socket().detach()
to_close = []
while fd < 50:
to_close.append(fd)
fd = os.dup(fd)
for x in to_close:
os.close(x)
return fd
def close(self, fd):
if WIN32:
socket.socket(socket.AF_INET, socket.SOCK_STREAM, fileno=fd).close()
else:
os.close(fd)
@classmethod
def _test_closefds(cls, conn, fd):
try:
s = socket.fromfd(fd, socket.AF_INET, socket.SOCK_STREAM)
except Exception as e:
conn.send(e)
else:
s.close()
conn.send(None)
def test_closefd(self):
if not HAS_REDUCTION:
raise unittest.SkipTest('requires fd pickling')
reader, writer = multiprocessing.Pipe()
fd = self.get_high_socket_fd()
try:
p = multiprocessing.Process(target=self._test_closefds,
args=(writer, fd))
p.start()
writer.close()
e = reader.recv()
join_process(p)
finally:
self.close(fd)
writer.close()
reader.close()
if multiprocessing.get_start_method() == 'fork':
self.assertIs(e, None)
else:
WSAENOTSOCK = 10038
self.assertIsInstance(e, OSError)
self.assertTrue(e.errno == errno.EBADF or
e.winerror == WSAENOTSOCK, e)
#
# Issue #17097: EINTR should be ignored by recv(), send(), accept() etc
#
class TestIgnoreEINTR(unittest.TestCase):
# Sending CONN_MAX_SIZE bytes into a multiprocessing pipe must block
CONN_MAX_SIZE = max(support.PIPE_MAX_SIZE, support.SOCK_MAX_SIZE)
@classmethod
def _test_ignore(cls, conn):
def handler(signum, frame):
pass
signal.signal(signal.SIGUSR1, handler)
conn.send('ready')
x = conn.recv()
conn.send(x)
conn.send_bytes(b'x' * cls.CONN_MAX_SIZE)
@unittest.skipUnless(hasattr(signal, 'SIGUSR1'), 'requires SIGUSR1')
def test_ignore(self):
conn, child_conn = multiprocessing.Pipe()
try:
p = multiprocessing.Process(target=self._test_ignore,
args=(child_conn,))
p.daemon = True
p.start()
child_conn.close()
self.assertEqual(conn.recv(), 'ready')
time.sleep(0.1)
os.kill(p.pid, signal.SIGUSR1)
time.sleep(0.1)
conn.send(1234)
self.assertEqual(conn.recv(), 1234)
time.sleep(0.1)
os.kill(p.pid, signal.SIGUSR1)
self.assertEqual(conn.recv_bytes(), b'x' * self.CONN_MAX_SIZE)
time.sleep(0.1)
p.join()
finally:
conn.close()
@classmethod
def _test_ignore_listener(cls, conn):
def handler(signum, frame):
pass
signal.signal(signal.SIGUSR1, handler)
with multiprocessing.connection.Listener() as l:
conn.send(l.address)
a = l.accept()
a.send('welcome')
@unittest.skipUnless(hasattr(signal, 'SIGUSR1'), 'requires SIGUSR1')
def test_ignore_listener(self):
conn, child_conn = multiprocessing.Pipe()
try:
p = multiprocessing.Process(target=self._test_ignore_listener,
args=(child_conn,))
p.daemon = True
p.start()
child_conn.close()
address = conn.recv()
time.sleep(0.1)
os.kill(p.pid, signal.SIGUSR1)
time.sleep(0.1)
client = multiprocessing.connection.Client(address)
self.assertEqual(client.recv(), 'welcome')
p.join()
finally:
conn.close()
class TestStartMethod(unittest.TestCase):
@classmethod
def _check_context(cls, conn):
conn.send(multiprocessing.get_start_method())
def check_context(self, ctx):
r, w = ctx.Pipe(duplex=False)
p = ctx.Process(target=self._check_context, args=(w,))
p.start()
w.close()
child_method = r.recv()
r.close()
p.join()
self.assertEqual(child_method, ctx.get_start_method())
def test_context(self):
for method in ('fork', 'spawn', 'forkserver'):
try:
ctx = multiprocessing.get_context(method)
except ValueError:
continue
self.assertEqual(ctx.get_start_method(), method)
self.assertIs(ctx.get_context(), ctx)
self.assertRaises(ValueError, ctx.set_start_method, 'spawn')
self.assertRaises(ValueError, ctx.set_start_method, None)
self.check_context(ctx)
def test_set_get(self):
multiprocessing.set_forkserver_preload(PRELOAD)
count = 0
old_method = multiprocessing.get_start_method()
try:
for method in ('fork', 'spawn', 'forkserver'):
try:
multiprocessing.set_start_method(method, force=True)
except ValueError:
continue
self.assertEqual(multiprocessing.get_start_method(), method)
ctx = multiprocessing.get_context()
self.assertEqual(ctx.get_start_method(), method)
self.assertTrue(type(ctx).__name__.lower().startswith(method))
self.assertTrue(
ctx.Process.__name__.lower().startswith(method))
self.check_context(multiprocessing)
count += 1
finally:
multiprocessing.set_start_method(old_method, force=True)
self.assertGreaterEqual(count, 1)
def test_get_all(self):
methods = multiprocessing.get_all_start_methods()
if sys.platform == 'win32':
self.assertEqual(methods, ['spawn'])
else:
self.assertTrue(methods == ['fork', 'spawn'] or
methods == ['fork', 'spawn', 'forkserver'])
def test_preload_resources(self):
if multiprocessing.get_start_method() != 'forkserver':
self.skipTest("test only relevant for 'forkserver' method")
name = os.path.join(os.path.dirname(__file__), 'mp_preload.py')
rc, out, err = test.support.script_helper.assert_python_ok(name)
out = out.decode()
err = err.decode()
if out.rstrip() != 'ok' or err != '':
print(out)
print(err)
self.fail("failed spawning forkserver or grandchild")
@unittest.skipIf(sys.platform == "win32",
"test semantics don't make sense on Windows")
class TestSemaphoreTracker(unittest.TestCase):
def test_semaphore_tracker(self):
#
# Check that killing process does not leak named semaphores
#
import subprocess
cmd = '''if 1:
import multiprocessing as mp, time, os
mp.set_start_method("spawn")
lock1 = mp.Lock()
lock2 = mp.Lock()
os.write(%d, lock1._semlock.name.encode("ascii") + b"\\n")
os.write(%d, lock2._semlock.name.encode("ascii") + b"\\n")
time.sleep(10)
'''
r, w = os.pipe()
p = subprocess.Popen([sys.executable,
'-E', '-c', cmd % (w, w)],
pass_fds=[w],
stderr=subprocess.PIPE)
os.close(w)
with open(r, 'rb', closefd=True) as f:
name1 = f.readline().rstrip().decode('ascii')
name2 = f.readline().rstrip().decode('ascii')
_multiprocessing.sem_unlink(name1)
p.terminate()
p.wait()
time.sleep(2.0)
with self.assertRaises(OSError) as ctx:
_multiprocessing.sem_unlink(name2)
# docs say it should be ENOENT, but OSX seems to give EINVAL
self.assertIn(ctx.exception.errno, (errno.ENOENT, errno.EINVAL))
err = p.stderr.read().decode('utf-8')
p.stderr.close()
expected = 'semaphore_tracker: There appear to be 2 leaked semaphores'
self.assertRegex(err, expected)
self.assertRegex(err, r'semaphore_tracker: %r: \[Errno' % name1)
def check_semaphore_tracker_death(self, signum, should_die):
# bpo-31310: if the semaphore tracker process has died, it should
# be restarted implicitly.
from multiprocessing.semaphore_tracker import _semaphore_tracker
_semaphore_tracker.ensure_running()
pid = _semaphore_tracker._pid
os.kill(pid, signum)
time.sleep(1.0) # give it time to die
ctx = multiprocessing.get_context("spawn")
with contextlib.ExitStack() as stack:
if should_die:
stack.enter_context(self.assertWarnsRegex(
UserWarning,
"semaphore_tracker: process died"))
sem = ctx.Semaphore()
sem.acquire()
sem.release()
wr = weakref.ref(sem)
# ensure `sem` gets collected, which triggers communication with
# the semaphore tracker
del sem
gc.collect()
self.assertIsNone(wr())
def test_semaphore_tracker_sigint(self):
# Catchable signal (ignored by semaphore tracker)
self.check_semaphore_tracker_death(signal.SIGINT, False)
def test_semaphore_tracker_sigkill(self):
# Uncatchable signal.
self.check_semaphore_tracker_death(signal.SIGKILL, True)
class TestSimpleQueue(unittest.TestCase):
@classmethod
def _test_empty(cls, queue, child_can_start, parent_can_continue):
child_can_start.wait()
# issue 30301, could fail under spawn and forkserver
try:
queue.put(queue.empty())
queue.put(queue.empty())
finally:
parent_can_continue.set()
def test_empty(self):
queue = multiprocessing.SimpleQueue()
child_can_start = multiprocessing.Event()
parent_can_continue = multiprocessing.Event()
proc = multiprocessing.Process(
target=self._test_empty,
args=(queue, child_can_start, parent_can_continue)
)
proc.daemon = True
proc.start()
self.assertTrue(queue.empty())
child_can_start.set()
parent_can_continue.wait()
self.assertFalse(queue.empty())
self.assertEqual(queue.get(), True)
self.assertEqual(queue.get(), False)
self.assertTrue(queue.empty())
proc.join()
class TestSyncManagerTypes(unittest.TestCase):
"""Test all the types which can be shared between a parent and a
child process by using a manager which acts as an intermediary
between them.
In the following unit-tests the base type is created in the parent
process, the @classmethod represents the worker process and the
shared object is readable and editable between the two.
# The child.
@classmethod
def _test_list(cls, obj):
assert obj[0] == 5
assert obj.append(6)
# The parent.
def test_list(self):
o = self.manager.list()
o.append(5)
self.run_worker(self._test_list, o)
assert o[1] == 6
"""
manager_class = multiprocessing.managers.SyncManager
def setUp(self):
self.manager = self.manager_class()
self.manager.start()
self.proc = None
def tearDown(self):
if self.proc is not None and self.proc.is_alive():
self.proc.terminate()
self.proc.join()
self.manager.shutdown()
self.manager = None
self.proc = None
@classmethod
def setUpClass(cls):
support.reap_children()
tearDownClass = setUpClass
def wait_proc_exit(self):
# Only the manager process should be returned by active_children()
# but this can take a bit on slow machines, so wait a few seconds
# if there are other children too (see #17395).
join_process(self.proc)
start_time = time.monotonic()
t = 0.01
while len(multiprocessing.active_children()) > 1:
time.sleep(t)
t *= 2
dt = time.monotonic() - start_time
if dt >= 5.0:
test.support.environment_altered = True
print("Warning -- multiprocessing.Manager still has %s active "
"children after %s seconds"
% (multiprocessing.active_children(), dt),
file=sys.stderr)
break
def run_worker(self, worker, obj):
self.proc = multiprocessing.Process(target=worker, args=(obj, ))
self.proc.daemon = True
self.proc.start()
self.wait_proc_exit()
self.assertEqual(self.proc.exitcode, 0)
@classmethod
def _test_queue(cls, obj):
assert obj.qsize() == 2
assert obj.full()
assert not obj.empty()
assert obj.get() == 5
assert not obj.empty()
assert obj.get() == 6
assert obj.empty()
def test_queue(self, qname="Queue"):
o = getattr(self.manager, qname)(2)
o.put(5)
o.put(6)
self.run_worker(self._test_queue, o)
assert o.empty()
assert not o.full()
def test_joinable_queue(self):
self.test_queue("JoinableQueue")
@classmethod
def _test_event(cls, obj):
assert obj.is_set()
obj.wait()
obj.clear()
obj.wait(0.001)
def test_event(self):
o = self.manager.Event()
o.set()
self.run_worker(self._test_event, o)
assert not o.is_set()
o.wait(0.001)
@classmethod
def _test_lock(cls, obj):
obj.acquire()
def test_lock(self, lname="Lock"):
o = getattr(self.manager, lname)()
self.run_worker(self._test_lock, o)
o.release()
self.assertRaises(RuntimeError, o.release) # already released
@classmethod
def _test_rlock(cls, obj):
obj.acquire()
obj.release()
def test_rlock(self, lname="Lock"):
o = getattr(self.manager, lname)()
self.run_worker(self._test_rlock, o)
@classmethod
def _test_semaphore(cls, obj):
obj.acquire()
def test_semaphore(self, sname="Semaphore"):
o = getattr(self.manager, sname)()
self.run_worker(self._test_semaphore, o)
o.release()
def test_bounded_semaphore(self):
self.test_semaphore(sname="BoundedSemaphore")
@classmethod
def _test_condition(cls, obj):
obj.acquire()
obj.release()
def test_condition(self):
o = self.manager.Condition()
self.run_worker(self._test_condition, o)
@classmethod
def _test_barrier(cls, obj):
assert obj.parties == 5
obj.reset()
def test_barrier(self):
o = self.manager.Barrier(5)
self.run_worker(self._test_barrier, o)
@classmethod
def _test_pool(cls, obj):
# TODO: fix https://bugs.python.org/issue35919
with obj:
pass
def test_pool(self):
o = self.manager.Pool(processes=4)
self.run_worker(self._test_pool, o)
@classmethod
def _test_list(cls, obj):
assert obj[0] == 5
assert obj.count(5) == 1
assert obj.index(5) == 0
obj.sort()
obj.reverse()
for x in obj:
pass
assert len(obj) == 1
assert obj.pop(0) == 5
def test_list(self):
o = self.manager.list()
o.append(5)
self.run_worker(self._test_list, o)
assert not o
self.assertEqual(len(o), 0)
@classmethod
def _test_dict(cls, obj):
assert len(obj) == 1
assert obj['foo'] == 5
assert obj.get('foo') == 5
assert list(obj.items()) == [('foo', 5)]
assert list(obj.keys()) == ['foo']
assert list(obj.values()) == [5]
assert obj.copy() == {'foo': 5}
assert obj.popitem() == ('foo', 5)
def test_dict(self):
o = self.manager.dict()
o['foo'] = 5
self.run_worker(self._test_dict, o)
assert not o
self.assertEqual(len(o), 0)
@classmethod
def _test_value(cls, obj):
assert obj.value == 1
assert obj.get() == 1
obj.set(2)
def test_value(self):
o = self.manager.Value('i', 1)
self.run_worker(self._test_value, o)
self.assertEqual(o.value, 2)
self.assertEqual(o.get(), 2)
@classmethod
def _test_array(cls, obj):
assert obj[0] == 0
assert obj[1] == 1
assert len(obj) == 2
assert list(obj) == [0, 1]
def test_array(self):
o = self.manager.Array('i', [0, 1])
self.run_worker(self._test_array, o)
@classmethod
def _test_namespace(cls, obj):
assert obj.x == 0
assert obj.y == 1
def test_namespace(self):
o = self.manager.Namespace()
o.x = 0
o.y = 1
self.run_worker(self._test_namespace, o)
#
# Mixins
#
class BaseMixin(object):
@classmethod
def setUpClass(cls):
cls.dangling = (multiprocessing.process._dangling.copy(),
threading._dangling.copy())
@classmethod
def tearDownClass(cls):
# bpo-26762: Some multiprocessing objects like Pool create reference
# cycles. Trigger a garbage collection to break these cycles.
test.support.gc_collect()
processes = set(multiprocessing.process._dangling) - set(cls.dangling[0])
if processes:
test.support.environment_altered = True
print('Warning -- Dangling processes: %s' % processes,
file=sys.stderr)
processes = None
threads = set(threading._dangling) - set(cls.dangling[1])
if threads:
test.support.environment_altered = True
print('Warning -- Dangling threads: %s' % threads,
file=sys.stderr)
threads = None
class ProcessesMixin(BaseMixin):
TYPE = 'processes'
Process = multiprocessing.Process
connection = multiprocessing.connection
current_process = staticmethod(multiprocessing.current_process)
active_children = staticmethod(multiprocessing.active_children)
Pool = staticmethod(multiprocessing.Pool)
Pipe = staticmethod(multiprocessing.Pipe)
Queue = staticmethod(multiprocessing.Queue)
JoinableQueue = staticmethod(multiprocessing.JoinableQueue)
Lock = staticmethod(multiprocessing.Lock)
RLock = staticmethod(multiprocessing.RLock)
Semaphore = staticmethod(multiprocessing.Semaphore)
BoundedSemaphore = staticmethod(multiprocessing.BoundedSemaphore)
Condition = staticmethod(multiprocessing.Condition)
Event = staticmethod(multiprocessing.Event)
Barrier = staticmethod(multiprocessing.Barrier)
Value = staticmethod(multiprocessing.Value)
Array = staticmethod(multiprocessing.Array)
RawValue = staticmethod(multiprocessing.RawValue)
RawArray = staticmethod(multiprocessing.RawArray)
class ManagerMixin(BaseMixin):
TYPE = 'manager'
Process = multiprocessing.Process
Queue = property(operator.attrgetter('manager.Queue'))
JoinableQueue = property(operator.attrgetter('manager.JoinableQueue'))
Lock = property(operator.attrgetter('manager.Lock'))
RLock = property(operator.attrgetter('manager.RLock'))
Semaphore = property(operator.attrgetter('manager.Semaphore'))
BoundedSemaphore = property(operator.attrgetter('manager.BoundedSemaphore'))
Condition = property(operator.attrgetter('manager.Condition'))
Event = property(operator.attrgetter('manager.Event'))
Barrier = property(operator.attrgetter('manager.Barrier'))
Value = property(operator.attrgetter('manager.Value'))
Array = property(operator.attrgetter('manager.Array'))
list = property(operator.attrgetter('manager.list'))
dict = property(operator.attrgetter('manager.dict'))
Namespace = property(operator.attrgetter('manager.Namespace'))
@classmethod
def Pool(cls, *args, **kwds):
return cls.manager.Pool(*args, **kwds)
@classmethod
def setUpClass(cls):
super().setUpClass()
cls.manager = multiprocessing.Manager()
@classmethod
def tearDownClass(cls):
# only the manager process should be returned by active_children()
# but this can take a bit on slow machines, so wait a few seconds
# if there are other children too (see #17395)
start_time = time.monotonic()
t = 0.01
while len(multiprocessing.active_children()) > 1:
time.sleep(t)
t *= 2
dt = time.monotonic() - start_time
if dt >= 5.0:
test.support.environment_altered = True
print("Warning -- multiprocessing.Manager still has %s active "
"children after %s seconds"
% (multiprocessing.active_children(), dt),
file=sys.stderr)
break
gc.collect() # do garbage collection
if cls.manager._number_of_objects() != 0:
# This is not really an error since some tests do not
# ensure that all processes which hold a reference to a
# managed object have been joined.
test.support.environment_altered = True
print('Warning -- Shared objects which still exist at manager '
'shutdown:')
print(cls.manager._debug_info())
cls.manager.shutdown()
cls.manager.join()
cls.manager = None
super().tearDownClass()
class ThreadsMixin(BaseMixin):
TYPE = 'threads'
Process = multiprocessing.dummy.Process
connection = multiprocessing.dummy.connection
current_process = staticmethod(multiprocessing.dummy.current_process)
active_children = staticmethod(multiprocessing.dummy.active_children)
Pool = staticmethod(multiprocessing.dummy.Pool)
Pipe = staticmethod(multiprocessing.dummy.Pipe)
Queue = staticmethod(multiprocessing.dummy.Queue)
JoinableQueue = staticmethod(multiprocessing.dummy.JoinableQueue)
Lock = staticmethod(multiprocessing.dummy.Lock)
RLock = staticmethod(multiprocessing.dummy.RLock)
Semaphore = staticmethod(multiprocessing.dummy.Semaphore)
BoundedSemaphore = staticmethod(multiprocessing.dummy.BoundedSemaphore)
Condition = staticmethod(multiprocessing.dummy.Condition)
Event = staticmethod(multiprocessing.dummy.Event)
Barrier = staticmethod(multiprocessing.dummy.Barrier)
Value = staticmethod(multiprocessing.dummy.Value)
Array = staticmethod(multiprocessing.dummy.Array)
#
# Functions used to create test cases from the base ones in this module
#
def install_tests_in_module_dict(remote_globs, start_method):
__module__ = remote_globs['__name__']
local_globs = globals()
ALL_TYPES = {'processes', 'threads', 'manager'}
for name, base in local_globs.items():
if not isinstance(base, type):
continue
if issubclass(base, BaseTestCase):
if base is BaseTestCase:
continue
assert set(base.ALLOWED_TYPES) <= ALL_TYPES, base.ALLOWED_TYPES
for type_ in base.ALLOWED_TYPES:
newname = 'With' + type_.capitalize() + name[1:]
Mixin = local_globs[type_.capitalize() + 'Mixin']
class Temp(base, Mixin, unittest.TestCase):
pass
Temp.__name__ = Temp.__qualname__ = newname
Temp.__module__ = __module__
remote_globs[newname] = Temp
elif issubclass(base, unittest.TestCase):
class Temp(base, object):
pass
Temp.__name__ = Temp.__qualname__ = name
Temp.__module__ = __module__
remote_globs[name] = Temp
dangling = [None, None]
old_start_method = [None]
def setUpModule():
multiprocessing.set_forkserver_preload(PRELOAD)
multiprocessing.process._cleanup()
dangling[0] = multiprocessing.process._dangling.copy()
dangling[1] = threading._dangling.copy()
old_start_method[0] = multiprocessing.get_start_method(allow_none=True)
try:
multiprocessing.set_start_method(start_method, force=True)
except ValueError:
raise unittest.SkipTest(start_method +
' start method not supported')
if sys.platform.startswith("linux"):
try:
lock = multiprocessing.RLock()
except OSError:
raise unittest.SkipTest("OSError raises on RLock creation, "
"see issue 3111!")
check_enough_semaphores()
util.get_temp_dir() # creates temp directory
multiprocessing.get_logger().setLevel(LOG_LEVEL)
def tearDownModule():
need_sleep = False
# bpo-26762: Some multiprocessing objects like Pool create reference
# cycles. Trigger a garbage collection to break these cycles.
test.support.gc_collect()
multiprocessing.set_start_method(old_start_method[0], force=True)
# pause a bit so we don't get warning about dangling threads/processes
processes = set(multiprocessing.process._dangling) - set(dangling[0])
if processes:
need_sleep = True
test.support.environment_altered = True
print('Warning -- Dangling processes: %s' % processes,
file=sys.stderr)
processes = None
threads = set(threading._dangling) - set(dangling[1])
if threads:
need_sleep = True
test.support.environment_altered = True
print('Warning -- Dangling threads: %s' % threads,
file=sys.stderr)
threads = None
# Sleep 500 ms to give time to child processes to complete.
if need_sleep:
time.sleep(0.5)
multiprocessing.process._cleanup()
test.support.gc_collect()
remote_globs['setUpModule'] = setUpModule
remote_globs['tearDownModule'] = tearDownModule