851 lines
25 KiB
Python
851 lines
25 KiB
Python
"""
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Various tests for synchronization primitives.
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"""
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import sys
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import time
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from _thread import start_new_thread, TIMEOUT_MAX
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import threading
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import unittest
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from test import support
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def _wait():
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# A crude wait/yield function not relying on synchronization primitives.
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time.sleep(0.01)
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class Bunch(object):
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"""
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A bunch of threads.
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"""
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def __init__(self, f, n, wait_before_exit=False):
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"""
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Construct a bunch of `n` threads running the same function `f`.
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If `wait_before_exit` is True, the threads won't terminate until
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do_finish() is called.
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"""
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self.f = f
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self.n = n
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self.started = []
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self.finished = []
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self._can_exit = not wait_before_exit
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def task():
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tid = threading.get_ident()
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self.started.append(tid)
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try:
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f()
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finally:
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self.finished.append(tid)
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while not self._can_exit:
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_wait()
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for i in range(n):
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start_new_thread(task, ())
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def wait_for_started(self):
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while len(self.started) < self.n:
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_wait()
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def wait_for_finished(self):
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while len(self.finished) < self.n:
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_wait()
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def do_finish(self):
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self._can_exit = True
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class BaseTestCase(unittest.TestCase):
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def setUp(self):
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self._threads = support.threading_setup()
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def tearDown(self):
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support.threading_cleanup(*self._threads)
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support.reap_children()
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def assertTimeout(self, actual, expected):
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# The waiting and/or time.time() can be imprecise, which
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# is why comparing to the expected value would sometimes fail
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# (especially under Windows).
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self.assertGreaterEqual(actual, expected * 0.6)
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# Test nothing insane happened
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self.assertLess(actual, expected * 10.0)
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class BaseLockTests(BaseTestCase):
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"""
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Tests for both recursive and non-recursive locks.
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"""
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def test_constructor(self):
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lock = self.locktype()
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del lock
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def test_acquire_destroy(self):
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lock = self.locktype()
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lock.acquire()
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del lock
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def test_acquire_release(self):
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lock = self.locktype()
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lock.acquire()
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lock.release()
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del lock
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def test_try_acquire(self):
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lock = self.locktype()
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self.assertTrue(lock.acquire(False))
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lock.release()
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def test_try_acquire_contended(self):
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lock = self.locktype()
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lock.acquire()
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result = []
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def f():
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result.append(lock.acquire(False))
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Bunch(f, 1).wait_for_finished()
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self.assertFalse(result[0])
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lock.release()
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def test_acquire_contended(self):
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lock = self.locktype()
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lock.acquire()
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N = 5
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def f():
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lock.acquire()
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lock.release()
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b = Bunch(f, N)
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b.wait_for_started()
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_wait()
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self.assertEqual(len(b.finished), 0)
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lock.release()
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b.wait_for_finished()
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self.assertEqual(len(b.finished), N)
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def test_with(self):
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lock = self.locktype()
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def f():
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lock.acquire()
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lock.release()
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def _with(err=None):
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with lock:
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if err is not None:
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raise err
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_with()
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# Check the lock is unacquired
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Bunch(f, 1).wait_for_finished()
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self.assertRaises(TypeError, _with, TypeError)
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# Check the lock is unacquired
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Bunch(f, 1).wait_for_finished()
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def test_thread_leak(self):
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# The lock shouldn't leak a Thread instance when used from a foreign
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# (non-threading) thread.
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lock = self.locktype()
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def f():
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lock.acquire()
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lock.release()
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n = len(threading.enumerate())
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# We run many threads in the hope that existing threads ids won't
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# be recycled.
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Bunch(f, 15).wait_for_finished()
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if len(threading.enumerate()) != n:
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# There is a small window during which a Thread instance's
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# target function has finished running, but the Thread is still
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# alive and registered. Avoid spurious failures by waiting a
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# bit more (seen on a buildbot).
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time.sleep(0.4)
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self.assertEqual(n, len(threading.enumerate()))
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def test_timeout(self):
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lock = self.locktype()
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# Can't set timeout if not blocking
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self.assertRaises(ValueError, lock.acquire, 0, 1)
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# Invalid timeout values
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self.assertRaises(ValueError, lock.acquire, timeout=-100)
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self.assertRaises(OverflowError, lock.acquire, timeout=1e100)
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self.assertRaises(OverflowError, lock.acquire, timeout=TIMEOUT_MAX + 1)
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# TIMEOUT_MAX is ok
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lock.acquire(timeout=TIMEOUT_MAX)
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lock.release()
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t1 = time.time()
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self.assertTrue(lock.acquire(timeout=5))
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t2 = time.time()
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# Just a sanity test that it didn't actually wait for the timeout.
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self.assertLess(t2 - t1, 5)
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results = []
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def f():
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t1 = time.time()
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results.append(lock.acquire(timeout=0.5))
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t2 = time.time()
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results.append(t2 - t1)
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Bunch(f, 1).wait_for_finished()
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self.assertFalse(results[0])
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self.assertTimeout(results[1], 0.5)
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class LockTests(BaseLockTests):
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"""
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Tests for non-recursive, weak locks
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(which can be acquired and released from different threads).
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"""
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def test_reacquire(self):
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# Lock needs to be released before re-acquiring.
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lock = self.locktype()
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phase = []
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def f():
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lock.acquire()
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phase.append(None)
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lock.acquire()
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phase.append(None)
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start_new_thread(f, ())
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while len(phase) == 0:
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_wait()
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_wait()
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self.assertEqual(len(phase), 1)
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lock.release()
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while len(phase) == 1:
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_wait()
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self.assertEqual(len(phase), 2)
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def test_different_thread(self):
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# Lock can be released from a different thread.
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lock = self.locktype()
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lock.acquire()
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def f():
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lock.release()
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b = Bunch(f, 1)
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b.wait_for_finished()
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lock.acquire()
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lock.release()
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def test_state_after_timeout(self):
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# Issue #11618: check that lock is in a proper state after a
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# (non-zero) timeout.
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lock = self.locktype()
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lock.acquire()
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self.assertFalse(lock.acquire(timeout=0.01))
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lock.release()
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self.assertFalse(lock.locked())
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self.assertTrue(lock.acquire(blocking=False))
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class RLockTests(BaseLockTests):
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"""
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Tests for recursive locks.
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"""
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def test_reacquire(self):
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lock = self.locktype()
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lock.acquire()
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lock.acquire()
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lock.release()
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lock.acquire()
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lock.release()
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lock.release()
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def test_release_unacquired(self):
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# Cannot release an unacquired lock
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lock = self.locktype()
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self.assertRaises(RuntimeError, lock.release)
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self.assertRaises(RuntimeError, lock._release_save)
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lock.acquire()
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lock.acquire()
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lock.release()
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lock.acquire()
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lock.release()
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lock.release()
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self.assertRaises(RuntimeError, lock.release)
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self.assertRaises(RuntimeError, lock._release_save)
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def test_different_thread(self):
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# Cannot release from a different thread
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lock = self.locktype()
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def f():
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lock.acquire()
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b = Bunch(f, 1, True)
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try:
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self.assertRaises(RuntimeError, lock.release)
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finally:
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b.do_finish()
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def test__is_owned(self):
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lock = self.locktype()
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self.assertFalse(lock._is_owned())
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lock.acquire()
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self.assertTrue(lock._is_owned())
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lock.acquire()
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self.assertTrue(lock._is_owned())
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result = []
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def f():
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result.append(lock._is_owned())
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Bunch(f, 1).wait_for_finished()
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self.assertFalse(result[0])
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lock.release()
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self.assertTrue(lock._is_owned())
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lock.release()
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self.assertFalse(lock._is_owned())
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class EventTests(BaseTestCase):
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"""
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Tests for Event objects.
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"""
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def test_is_set(self):
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evt = self.eventtype()
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self.assertFalse(evt.is_set())
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evt.set()
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self.assertTrue(evt.is_set())
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evt.set()
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self.assertTrue(evt.is_set())
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evt.clear()
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self.assertFalse(evt.is_set())
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evt.clear()
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self.assertFalse(evt.is_set())
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def _check_notify(self, evt):
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# All threads get notified
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N = 5
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results1 = []
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results2 = []
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def f():
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results1.append(evt.wait())
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results2.append(evt.wait())
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b = Bunch(f, N)
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b.wait_for_started()
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_wait()
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self.assertEqual(len(results1), 0)
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evt.set()
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b.wait_for_finished()
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self.assertEqual(results1, [True] * N)
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self.assertEqual(results2, [True] * N)
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def test_notify(self):
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evt = self.eventtype()
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self._check_notify(evt)
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# Another time, after an explicit clear()
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evt.set()
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evt.clear()
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self._check_notify(evt)
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def test_timeout(self):
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evt = self.eventtype()
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results1 = []
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results2 = []
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N = 5
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def f():
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results1.append(evt.wait(0.0))
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t1 = time.time()
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r = evt.wait(0.5)
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t2 = time.time()
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results2.append((r, t2 - t1))
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Bunch(f, N).wait_for_finished()
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self.assertEqual(results1, [False] * N)
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for r, dt in results2:
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self.assertFalse(r)
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self.assertTimeout(dt, 0.5)
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# The event is set
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results1 = []
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results2 = []
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evt.set()
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Bunch(f, N).wait_for_finished()
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self.assertEqual(results1, [True] * N)
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for r, dt in results2:
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self.assertTrue(r)
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class ConditionTests(BaseTestCase):
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"""
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Tests for condition variables.
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"""
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def test_acquire(self):
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cond = self.condtype()
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# Be default we have an RLock: the condition can be acquired multiple
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# times.
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cond.acquire()
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cond.acquire()
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cond.release()
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cond.release()
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lock = threading.Lock()
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cond = self.condtype(lock)
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cond.acquire()
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self.assertFalse(lock.acquire(False))
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cond.release()
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self.assertTrue(lock.acquire(False))
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self.assertFalse(cond.acquire(False))
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lock.release()
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with cond:
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self.assertFalse(lock.acquire(False))
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def test_unacquired_wait(self):
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cond = self.condtype()
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self.assertRaises(RuntimeError, cond.wait)
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def test_unacquired_notify(self):
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cond = self.condtype()
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self.assertRaises(RuntimeError, cond.notify)
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def _check_notify(self, cond):
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N = 5
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results1 = []
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results2 = []
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phase_num = 0
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def f():
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cond.acquire()
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result = cond.wait()
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cond.release()
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results1.append((result, phase_num))
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cond.acquire()
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result = cond.wait()
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cond.release()
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results2.append((result, phase_num))
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b = Bunch(f, N)
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b.wait_for_started()
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_wait()
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self.assertEqual(results1, [])
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# Notify 3 threads at first
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cond.acquire()
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cond.notify(3)
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_wait()
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phase_num = 1
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cond.release()
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while len(results1) < 3:
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_wait()
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self.assertEqual(results1, [(True, 1)] * 3)
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self.assertEqual(results2, [])
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# Notify 5 threads: they might be in their first or second wait
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cond.acquire()
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cond.notify(5)
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_wait()
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phase_num = 2
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cond.release()
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while len(results1) + len(results2) < 8:
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_wait()
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self.assertEqual(results1, [(True, 1)] * 3 + [(True, 2)] * 2)
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self.assertEqual(results2, [(True, 2)] * 3)
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# Notify all threads: they are all in their second wait
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cond.acquire()
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cond.notify_all()
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_wait()
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phase_num = 3
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cond.release()
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while len(results2) < 5:
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_wait()
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self.assertEqual(results1, [(True, 1)] * 3 + [(True,2)] * 2)
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self.assertEqual(results2, [(True, 2)] * 3 + [(True, 3)] * 2)
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b.wait_for_finished()
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def test_notify(self):
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cond = self.condtype()
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self._check_notify(cond)
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# A second time, to check internal state is still ok.
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self._check_notify(cond)
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def test_timeout(self):
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cond = self.condtype()
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results = []
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N = 5
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def f():
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cond.acquire()
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t1 = time.time()
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result = cond.wait(0.5)
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t2 = time.time()
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cond.release()
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results.append((t2 - t1, result))
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Bunch(f, N).wait_for_finished()
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self.assertEqual(len(results), N)
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for dt, result in results:
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self.assertTimeout(dt, 0.5)
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# Note that conceptually (that"s the condition variable protocol)
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# a wait() may succeed even if no one notifies us and before any
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# timeout occurs. Spurious wakeups can occur.
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# This makes it hard to verify the result value.
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# In practice, this implementation has no spurious wakeups.
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self.assertFalse(result)
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def test_waitfor(self):
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cond = self.condtype()
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state = 0
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def f():
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with cond:
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result = cond.wait_for(lambda : state==4)
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self.assertTrue(result)
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self.assertEqual(state, 4)
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b = Bunch(f, 1)
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b.wait_for_started()
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for i in range(4):
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time.sleep(0.01)
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with cond:
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state += 1
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cond.notify()
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b.wait_for_finished()
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def test_waitfor_timeout(self):
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cond = self.condtype()
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state = 0
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success = []
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def f():
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with cond:
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dt = time.time()
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result = cond.wait_for(lambda : state==4, timeout=0.1)
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dt = time.time() - dt
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self.assertFalse(result)
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self.assertTimeout(dt, 0.1)
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success.append(None)
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b = Bunch(f, 1)
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b.wait_for_started()
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# Only increment 3 times, so state == 4 is never reached.
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for i in range(3):
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time.sleep(0.01)
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with cond:
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state += 1
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cond.notify()
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b.wait_for_finished()
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self.assertEqual(len(success), 1)
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class BaseSemaphoreTests(BaseTestCase):
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"""
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Common tests for {bounded, unbounded} semaphore objects.
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"""
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def test_constructor(self):
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self.assertRaises(ValueError, self.semtype, value = -1)
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self.assertRaises(ValueError, self.semtype, value = -sys.maxsize)
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def test_acquire(self):
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sem = self.semtype(1)
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sem.acquire()
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sem.release()
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sem = self.semtype(2)
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sem.acquire()
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sem.acquire()
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sem.release()
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sem.release()
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def test_acquire_destroy(self):
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sem = self.semtype()
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sem.acquire()
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del sem
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def test_acquire_contended(self):
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sem = self.semtype(7)
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sem.acquire()
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N = 10
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results1 = []
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results2 = []
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phase_num = 0
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def f():
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sem.acquire()
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results1.append(phase_num)
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sem.acquire()
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results2.append(phase_num)
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b = Bunch(f, 10)
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b.wait_for_started()
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while len(results1) + len(results2) < 6:
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_wait()
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self.assertEqual(results1 + results2, [0] * 6)
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phase_num = 1
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for i in range(7):
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sem.release()
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while len(results1) + len(results2) < 13:
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_wait()
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self.assertEqual(sorted(results1 + results2), [0] * 6 + [1] * 7)
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phase_num = 2
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for i in range(6):
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sem.release()
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while len(results1) + len(results2) < 19:
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_wait()
|
|
self.assertEqual(sorted(results1 + results2), [0] * 6 + [1] * 7 + [2] * 6)
|
|
# The semaphore is still locked
|
|
self.assertFalse(sem.acquire(False))
|
|
# Final release, to let the last thread finish
|
|
sem.release()
|
|
b.wait_for_finished()
|
|
|
|
def test_try_acquire(self):
|
|
sem = self.semtype(2)
|
|
self.assertTrue(sem.acquire(False))
|
|
self.assertTrue(sem.acquire(False))
|
|
self.assertFalse(sem.acquire(False))
|
|
sem.release()
|
|
self.assertTrue(sem.acquire(False))
|
|
|
|
def test_try_acquire_contended(self):
|
|
sem = self.semtype(4)
|
|
sem.acquire()
|
|
results = []
|
|
def f():
|
|
results.append(sem.acquire(False))
|
|
results.append(sem.acquire(False))
|
|
Bunch(f, 5).wait_for_finished()
|
|
# There can be a thread switch between acquiring the semaphore and
|
|
# appending the result, therefore results will not necessarily be
|
|
# ordered.
|
|
self.assertEqual(sorted(results), [False] * 7 + [True] * 3 )
|
|
|
|
def test_acquire_timeout(self):
|
|
sem = self.semtype(2)
|
|
self.assertRaises(ValueError, sem.acquire, False, timeout=1.0)
|
|
self.assertTrue(sem.acquire(timeout=0.005))
|
|
self.assertTrue(sem.acquire(timeout=0.005))
|
|
self.assertFalse(sem.acquire(timeout=0.005))
|
|
sem.release()
|
|
self.assertTrue(sem.acquire(timeout=0.005))
|
|
t = time.time()
|
|
self.assertFalse(sem.acquire(timeout=0.5))
|
|
dt = time.time() - t
|
|
self.assertTimeout(dt, 0.5)
|
|
|
|
def test_default_value(self):
|
|
# The default initial value is 1.
|
|
sem = self.semtype()
|
|
sem.acquire()
|
|
def f():
|
|
sem.acquire()
|
|
sem.release()
|
|
b = Bunch(f, 1)
|
|
b.wait_for_started()
|
|
_wait()
|
|
self.assertFalse(b.finished)
|
|
sem.release()
|
|
b.wait_for_finished()
|
|
|
|
def test_with(self):
|
|
sem = self.semtype(2)
|
|
def _with(err=None):
|
|
with sem:
|
|
self.assertTrue(sem.acquire(False))
|
|
sem.release()
|
|
with sem:
|
|
self.assertFalse(sem.acquire(False))
|
|
if err:
|
|
raise err
|
|
_with()
|
|
self.assertTrue(sem.acquire(False))
|
|
sem.release()
|
|
self.assertRaises(TypeError, _with, TypeError)
|
|
self.assertTrue(sem.acquire(False))
|
|
sem.release()
|
|
|
|
class SemaphoreTests(BaseSemaphoreTests):
|
|
"""
|
|
Tests for unbounded semaphores.
|
|
"""
|
|
|
|
def test_release_unacquired(self):
|
|
# Unbounded releases are allowed and increment the semaphore's value
|
|
sem = self.semtype(1)
|
|
sem.release()
|
|
sem.acquire()
|
|
sem.acquire()
|
|
sem.release()
|
|
|
|
|
|
class BoundedSemaphoreTests(BaseSemaphoreTests):
|
|
"""
|
|
Tests for bounded semaphores.
|
|
"""
|
|
|
|
def test_release_unacquired(self):
|
|
# Cannot go past the initial value
|
|
sem = self.semtype()
|
|
self.assertRaises(ValueError, sem.release)
|
|
sem.acquire()
|
|
sem.release()
|
|
self.assertRaises(ValueError, sem.release)
|
|
|
|
|
|
class BarrierTests(BaseTestCase):
|
|
"""
|
|
Tests for Barrier objects.
|
|
"""
|
|
N = 5
|
|
defaultTimeout = 2.0
|
|
|
|
def setUp(self):
|
|
self.barrier = self.barriertype(self.N, timeout=self.defaultTimeout)
|
|
def tearDown(self):
|
|
self.barrier.abort()
|
|
|
|
def run_threads(self, f):
|
|
b = Bunch(f, self.N-1)
|
|
f()
|
|
b.wait_for_finished()
|
|
|
|
def multipass(self, results, n):
|
|
m = self.barrier.parties
|
|
self.assertEqual(m, self.N)
|
|
for i in range(n):
|
|
results[0].append(True)
|
|
self.assertEqual(len(results[1]), i * m)
|
|
self.barrier.wait()
|
|
results[1].append(True)
|
|
self.assertEqual(len(results[0]), (i + 1) * m)
|
|
self.barrier.wait()
|
|
self.assertEqual(self.barrier.n_waiting, 0)
|
|
self.assertFalse(self.barrier.broken)
|
|
|
|
def test_barrier(self, passes=1):
|
|
"""
|
|
Test that a barrier is passed in lockstep
|
|
"""
|
|
results = [[],[]]
|
|
def f():
|
|
self.multipass(results, passes)
|
|
self.run_threads(f)
|
|
|
|
def test_barrier_10(self):
|
|
"""
|
|
Test that a barrier works for 10 consecutive runs
|
|
"""
|
|
return self.test_barrier(10)
|
|
|
|
def test_wait_return(self):
|
|
"""
|
|
test the return value from barrier.wait
|
|
"""
|
|
results = []
|
|
def f():
|
|
r = self.barrier.wait()
|
|
results.append(r)
|
|
|
|
self.run_threads(f)
|
|
self.assertEqual(sum(results), sum(range(self.N)))
|
|
|
|
def test_action(self):
|
|
"""
|
|
Test the 'action' callback
|
|
"""
|
|
results = []
|
|
def action():
|
|
results.append(True)
|
|
barrier = self.barriertype(self.N, action)
|
|
def f():
|
|
barrier.wait()
|
|
self.assertEqual(len(results), 1)
|
|
|
|
self.run_threads(f)
|
|
|
|
def test_abort(self):
|
|
"""
|
|
Test that an abort will put the barrier in a broken state
|
|
"""
|
|
results1 = []
|
|
results2 = []
|
|
def f():
|
|
try:
|
|
i = self.barrier.wait()
|
|
if i == self.N//2:
|
|
raise RuntimeError
|
|
self.barrier.wait()
|
|
results1.append(True)
|
|
except threading.BrokenBarrierError:
|
|
results2.append(True)
|
|
except RuntimeError:
|
|
self.barrier.abort()
|
|
pass
|
|
|
|
self.run_threads(f)
|
|
self.assertEqual(len(results1), 0)
|
|
self.assertEqual(len(results2), self.N-1)
|
|
self.assertTrue(self.barrier.broken)
|
|
|
|
def test_reset(self):
|
|
"""
|
|
Test that a 'reset' on a barrier frees the waiting threads
|
|
"""
|
|
results1 = []
|
|
results2 = []
|
|
results3 = []
|
|
def f():
|
|
i = self.barrier.wait()
|
|
if i == self.N//2:
|
|
# Wait until the other threads are all in the barrier.
|
|
while self.barrier.n_waiting < self.N-1:
|
|
time.sleep(0.001)
|
|
self.barrier.reset()
|
|
else:
|
|
try:
|
|
self.barrier.wait()
|
|
results1.append(True)
|
|
except threading.BrokenBarrierError:
|
|
results2.append(True)
|
|
# Now, pass the barrier again
|
|
self.barrier.wait()
|
|
results3.append(True)
|
|
|
|
self.run_threads(f)
|
|
self.assertEqual(len(results1), 0)
|
|
self.assertEqual(len(results2), self.N-1)
|
|
self.assertEqual(len(results3), self.N)
|
|
|
|
|
|
def test_abort_and_reset(self):
|
|
"""
|
|
Test that a barrier can be reset after being broken.
|
|
"""
|
|
results1 = []
|
|
results2 = []
|
|
results3 = []
|
|
barrier2 = self.barriertype(self.N)
|
|
def f():
|
|
try:
|
|
i = self.barrier.wait()
|
|
if i == self.N//2:
|
|
raise RuntimeError
|
|
self.barrier.wait()
|
|
results1.append(True)
|
|
except threading.BrokenBarrierError:
|
|
results2.append(True)
|
|
except RuntimeError:
|
|
self.barrier.abort()
|
|
pass
|
|
# 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() == self.N//2:
|
|
self.barrier.reset()
|
|
barrier2.wait()
|
|
self.barrier.wait()
|
|
results3.append(True)
|
|
|
|
self.run_threads(f)
|
|
self.assertEqual(len(results1), 0)
|
|
self.assertEqual(len(results2), self.N-1)
|
|
self.assertEqual(len(results3), self.N)
|
|
|
|
def test_timeout(self):
|
|
"""
|
|
Test wait(timeout)
|
|
"""
|
|
def f():
|
|
i = self.barrier.wait()
|
|
if i == self.N // 2:
|
|
# One thread is late!
|
|
time.sleep(1.0)
|
|
# Default timeout is 2.0, so this is shorter.
|
|
self.assertRaises(threading.BrokenBarrierError,
|
|
self.barrier.wait, 0.5)
|
|
self.run_threads(f)
|
|
|
|
def test_default_timeout(self):
|
|
"""
|
|
Test the barrier's default timeout
|
|
"""
|
|
# create a barrier with a low default timeout
|
|
barrier = self.barriertype(self.N, timeout=0.3)
|
|
def f():
|
|
i = barrier.wait()
|
|
if i == self.N // 2:
|
|
# One thread is later than the default timeout of 0.3s.
|
|
time.sleep(1.0)
|
|
self.assertRaises(threading.BrokenBarrierError, barrier.wait)
|
|
self.run_threads(f)
|
|
|
|
def test_single_thread(self):
|
|
b = self.barriertype(1)
|
|
b.wait()
|
|
b.wait()
|