Lib/test/test_threading.py - platform/external/python/cpython2 - Gitiles

 # Very rudimentary test of threading module

 import test.test_support
 from test.test_support import verbose
 import random
 import sys
 import threading
 import thread
 import time
 import unittest

 # A trivial mutable counter.
 class Counter(object):
     def __init__(self):
         self.value = 0
     def inc(self):
         self.value += 1
     def dec(self):
         self.value -= 1
     def get(self):
         return self.value

 class TestThread(threading.Thread):
     def __init__(self, name, testcase, sema, mutex, nrunning):
         threading.Thread.__init__(self, name=name)
         self.testcase = testcase
         self.sema = sema
         self.mutex = mutex
         self.nrunning = nrunning

     def run(self):
         delay = random.random() * 2
         if verbose:
             print 'task', self.getName(), 'will run for', delay, 'sec'

         self.sema.acquire()

         self.mutex.acquire()
         self.nrunning.inc()
         if verbose:
             print self.nrunning.get(), 'tasks are running'
         self.testcase.assert_(self.nrunning.get() <= 3)
         self.mutex.release()

         time.sleep(delay)
         if verbose:
             print 'task', self.getName(), 'done'

         self.mutex.acquire()
         self.nrunning.dec()
         self.testcase.assert_(self.nrunning.get() >= 0)
         if verbose:
             print self.getName(), 'is finished.', self.nrunning.get(), \
                   'tasks are running'
         self.mutex.release()

         self.sema.release()

 class ThreadTests(unittest.TestCase):

     # Create a bunch of threads, let each do some work, wait until all are
     # done.
     def test_various_ops(self):
         # This takes about n/3 seconds to run (about n/3 clumps of tasks,
         # times about 1 second per clump).
         NUMTASKS = 10

         # no more than 3 of the 10 can run at once
         sema = threading.BoundedSemaphore(value=3)
         mutex = threading.RLock()
         numrunning = Counter()

         threads = []

         for i in range(NUMTASKS):
             t = TestThread("<thread %d>"%i, self, sema, mutex, numrunning)
             threads.append(t)
             t.start()

         if verbose:
             print 'waiting for all tasks to complete'
         for t in threads:
             t.join(NUMTASKS)
             self.assert_(not t.isAlive())
         if verbose:
             print 'all tasks done'
         self.assertEqual(numrunning.get(), 0)

     # run with a small(ish) thread stack size (256kB)
     def test_various_ops_small_stack(self):
         if verbose:
             print 'with 256kB thread stack size...'
         try:
             threading.stack_size(262144)
         except thread.error:
             if verbose:
                 print 'platform does not support changing thread stack size'
             return
         self.test_various_ops()
         threading.stack_size(0)

     # run with a large thread stack size (1MB)
     def test_various_ops_large_stack(self):
         if verbose:
             print 'with 1MB thread stack size...'
         try:
             threading.stack_size(0x100000)
         except thread.error:
             if verbose:
                 print 'platform does not support changing thread stack size'
             return
         self.test_various_ops()
         threading.stack_size(0)

     def test_foreign_thread(self):
         # Check that a "foreign" thread can use the threading module.
         def f(mutex):
             # Acquiring an RLock forces an entry for the foreign
             # thread to get made in the threading._active map.
             r = threading.RLock()
             r.acquire()
             r.release()
             mutex.release()

         mutex = threading.Lock()
         mutex.acquire()
         tid = thread.start_new_thread(f, (mutex,))
         # Wait for the thread to finish.
         mutex.acquire()
         self.assert_(tid in threading._active)
         self.assert_(isinstance(threading._active[tid],
                                 threading._DummyThread))
         del threading._active[tid]

     # PyThreadState_SetAsyncExc() is a CPython-only gimmick, not (currently)
     # exposed at the Python level.  This test relies on ctypes to get at it.
     def test_PyThreadState_SetAsyncExc(self):
         try:
             import ctypes
         except ImportError:
             if verbose:
                 print "test_PyThreadState_SetAsyncExc can't import ctypes"
             return  # can't do anything

         set_async_exc = ctypes.pythonapi.PyThreadState_SetAsyncExc

         class AsyncExc(Exception):
             pass

         exception = ctypes.py_object(AsyncExc)

         # `worker_started` is set by the thread when it's inside a try/except
         # block waiting to catch the asynchronously set AsyncExc exception.
         # `worker_saw_exception` is set by the thread upon catching that
         # exception.
         worker_started = threading.Event()
         worker_saw_exception = threading.Event()

         class Worker(threading.Thread):
             def run(self):
                 self.id = thread.get_ident()
                 self.finished = False

                 try:
                     while True:
                         worker_started.set()
                         time.sleep(0.1)
                 except AsyncExc:
                     self.finished = True
                     worker_saw_exception.set()

         t = Worker()
         t.setDaemon(True) # so if this fails, we don't hang Python at shutdown
         t.start()
         if verbose:
             print "    started worker thread"

         # Try a thread id that doesn't make sense.
         if verbose:
             print "    trying nonsensical thread id"
         result = set_async_exc(ctypes.c_long(-1), exception)
         self.assertEqual(result, 0)  # no thread states modified

         # Now raise an exception in the worker thread.
         if verbose:
             print "    waiting for worker thread to get started"
         worker_started.wait()
         if verbose:
             print "    verifying worker hasn't exited"
         self.assert_(not t.finished)
         if verbose:
             print "    attempting to raise asynch exception in worker"
         result = set_async_exc(ctypes.c_long(t.id), exception)
         self.assertEqual(result, 1) # one thread state modified
         if verbose:
             print "    waiting for worker to say it caught the exception"
         worker_saw_exception.wait(timeout=10)
         self.assert_(t.finished)
         if verbose:
             print "    all OK -- joining worker"
         if t.finished:
             t.join()
         # else the thread is still running, and we have no way to kill it

     def test_enumerate_after_join(self):
         # Try hard to trigger #1703448: a thread is still returned in
         # threading.enumerate() after it has been join()ed.
         enum = threading.enumerate
         old_interval = sys.getcheckinterval()
         sys.setcheckinterval(1)
         try:
             for i in xrange(1, 1000):
                 t = threading.Thread(target=lambda: None)
                 t.start()
                 t.join()
                 l = enum()
                 self.assertFalse(t in l,
                     "#1703448 triggered after %d trials: %s" % (i, l))
         finally:
             sys.setcheckinterval(old_interval)


 def test_main():
     test.test_support.run_unittest(ThreadTests)

 if __name__ == "__main__":
     test_main()
	# Very rudimentary test of threading module

	import test.test_support
	from test.test_support import verbose
	import random
	import sys
	import threading
	import thread
	import time
	import unittest

	# A trivial mutable counter.
	class Counter(object):
	def __init__(self):
	self.value = 0
	def inc(self):
	self.value += 1
	def dec(self):
	self.value -= 1
	def get(self):
	return self.value

	class TestThread(threading.Thread):
	def __init__(self, name, testcase, sema, mutex, nrunning):
	threading.Thread.__init__(self, name=name)
	self.testcase = testcase
	self.sema = sema
	self.mutex = mutex
	self.nrunning = nrunning

	def run(self):
	delay = random.random() * 2
	if verbose:
	print 'task', self.getName(), 'will run for', delay, 'sec'

	self.sema.acquire()

	self.mutex.acquire()
	self.nrunning.inc()
	if verbose:
	print self.nrunning.get(), 'tasks are running'
	self.testcase.assert_(self.nrunning.get() <= 3)
	self.mutex.release()

	time.sleep(delay)
	if verbose:
	print 'task', self.getName(), 'done'

	self.mutex.acquire()
	self.nrunning.dec()
	self.testcase.assert_(self.nrunning.get() >= 0)
	if verbose:
	print self.getName(), 'is finished.', self.nrunning.get(), \
	'tasks are running'
	self.mutex.release()

	self.sema.release()

	class ThreadTests(unittest.TestCase):

	# Create a bunch of threads, let each do some work, wait until all are
	# done.
	def test_various_ops(self):
	# This takes about n/3 seconds to run (about n/3 clumps of tasks,
	# times about 1 second per clump).
	NUMTASKS = 10

	# no more than 3 of the 10 can run at once
	sema = threading.BoundedSemaphore(value=3)
	mutex = threading.RLock()
	numrunning = Counter()

	threads = []

	for i in range(NUMTASKS):
	t = TestThread("<thread %d>"%i, self, sema, mutex, numrunning)
	threads.append(t)
	t.start()

	if verbose:
	print 'waiting for all tasks to complete'
	for t in threads:
	t.join(NUMTASKS)
	self.assert_(not t.isAlive())
	if verbose:
	print 'all tasks done'
	self.assertEqual(numrunning.get(), 0)

	# run with a small(ish) thread stack size (256kB)
	def test_various_ops_small_stack(self):
	if verbose:
	print 'with 256kB thread stack size...'
	try:
	threading.stack_size(262144)
	except thread.error:
	if verbose:
	print 'platform does not support changing thread stack size'
	return
	self.test_various_ops()
	threading.stack_size(0)

	# run with a large thread stack size (1MB)
	def test_various_ops_large_stack(self):
	if verbose:
	print 'with 1MB thread stack size...'
	try:
	threading.stack_size(0x100000)
	except thread.error:
	if verbose:
	print 'platform does not support changing thread stack size'
	return
	self.test_various_ops()
	threading.stack_size(0)

	def test_foreign_thread(self):
	# Check that a "foreign" thread can use the threading module.
	def f(mutex):
	# Acquiring an RLock forces an entry for the foreign
	# thread to get made in the threading._active map.
	r = threading.RLock()
	r.acquire()
	r.release()
	mutex.release()

	mutex = threading.Lock()
	mutex.acquire()
	tid = thread.start_new_thread(f, (mutex,))
	# Wait for the thread to finish.
	mutex.acquire()
	self.assert_(tid in threading._active)
	self.assert_(isinstance(threading._active[tid],
	threading._DummyThread))
	del threading._active[tid]

	# PyThreadState_SetAsyncExc() is a CPython-only gimmick, not (currently)
	# exposed at the Python level. This test relies on ctypes to get at it.
	def test_PyThreadState_SetAsyncExc(self):
	try:
	import ctypes
	except ImportError:
	if verbose:
	print "test_PyThreadState_SetAsyncExc can't import ctypes"
	return # can't do anything

	set_async_exc = ctypes.pythonapi.PyThreadState_SetAsyncExc

	class AsyncExc(Exception):
	pass

	exception = ctypes.py_object(AsyncExc)

	# `worker_started` is set by the thread when it's inside a try/except
	# block waiting to catch the asynchronously set AsyncExc exception.
	# `worker_saw_exception` is set by the thread upon catching that
	# exception.
	worker_started = threading.Event()
	worker_saw_exception = threading.Event()

	class Worker(threading.Thread):
	def run(self):
	self.id = thread.get_ident()
	self.finished = False

	try:
	while True:
	worker_started.set()
	time.sleep(0.1)
	except AsyncExc:
	self.finished = True
	worker_saw_exception.set()

	t = Worker()
	t.setDaemon(True) # so if this fails, we don't hang Python at shutdown
	t.start()
	if verbose:
	print " started worker thread"

	# Try a thread id that doesn't make sense.
	if verbose:
	print " trying nonsensical thread id"
	result = set_async_exc(ctypes.c_long(-1), exception)
	self.assertEqual(result, 0) # no thread states modified

	# Now raise an exception in the worker thread.
	if verbose:
	print " waiting for worker thread to get started"
	worker_started.wait()
	if verbose:
	print " verifying worker hasn't exited"
	self.assert_(not t.finished)
	if verbose:
	print " attempting to raise asynch exception in worker"
	result = set_async_exc(ctypes.c_long(t.id), exception)
	self.assertEqual(result, 1) # one thread state modified
	if verbose:
	print " waiting for worker to say it caught the exception"
	worker_saw_exception.wait(timeout=10)
	self.assert_(t.finished)
	if verbose:
	print " all OK -- joining worker"
	if t.finished:
	t.join()
	# else the thread is still running, and we have no way to kill it

	def test_enumerate_after_join(self):
	# Try hard to trigger #1703448: a thread is still returned in
	# threading.enumerate() after it has been join()ed.
	enum = threading.enumerate
	old_interval = sys.getcheckinterval()
	sys.setcheckinterval(1)
	try:
	for i in xrange(1, 1000):
	t = threading.Thread(target=lambda: None)
	t.start()
	t.join()
	l = enum()
	self.assertFalse(t in l,
	"#1703448 triggered after %d trials: %s" % (i, l))
	finally:
	sys.setcheckinterval(old_interval)


	def test_main():
	test.test_support.run_unittest(ThreadTests)

	if __name__ == "__main__":
	test_main()