Lib/test/test_thread.py - platform/external/python/cpython3 - Gitiles

 import os
 import unittest
 import random
 from test import support
 import _thread as thread
 import time

 from test import lock_tests

 NUMTASKS = 10
 NUMTRIPS = 3

 _print_mutex = thread.allocate_lock()

 def verbose_print(arg):
     """Helper function for printing out debugging output."""
     if support.verbose:
         with _print_mutex:
             print(arg)

 class BasicThreadTest(unittest.TestCase):

     def setUp(self):
         self.done_mutex = thread.allocate_lock()
         self.done_mutex.acquire()
         self.running_mutex = thread.allocate_lock()
         self.random_mutex = thread.allocate_lock()
         self.created = 0
         self.running = 0
         self.next_ident = 0


 class ThreadRunningTests(BasicThreadTest):

     def newtask(self):
         with self.running_mutex:
             self.next_ident += 1
             verbose_print("creating task %s" % self.next_ident)
             thread.start_new_thread(self.task, (self.next_ident,))
             self.created += 1
             self.running += 1

     def task(self, ident):
         with self.random_mutex:
             delay = random.random() / 10000.0
         verbose_print("task %s will run for %sus" % (ident, round(delay*1e6)))
         time.sleep(delay)
         verbose_print("task %s done" % ident)
         with self.running_mutex:
             self.running -= 1
             if self.created == NUMTASKS and self.running == 0:
                 self.done_mutex.release()

     def test_starting_threads(self):
         # Basic test for thread creation.
         for i in range(NUMTASKS):
             self.newtask()
         verbose_print("waiting for tasks to complete...")
         self.done_mutex.acquire()
         verbose_print("all tasks done")

     def test_stack_size(self):
         # Various stack size tests.
         self.assertEqual(thread.stack_size(), 0, "intial stack size is not 0")

         thread.stack_size(0)
         self.assertEqual(thread.stack_size(), 0, "stack_size not reset to default")

         if os.name not in ("nt", "os2", "posix"):
             return

         tss_supported = True
         try:
             thread.stack_size(4096)
         except ValueError:
             verbose_print("caught expected ValueError setting "
                             "stack_size(4096)")
         except thread.error:
             tss_supported = False
             verbose_print("platform does not support changing thread stack "
                             "size")

         if tss_supported:
             fail_msg = "stack_size(%d) failed - should succeed"
             for tss in (262144, 0x100000, 0):
                 thread.stack_size(tss)
                 self.assertEqual(thread.stack_size(), tss, fail_msg % tss)
                 verbose_print("successfully set stack_size(%d)" % tss)

             for tss in (262144, 0x100000):
                 verbose_print("trying stack_size = (%d)" % tss)
                 self.next_ident = 0
                 self.created = 0
                 for i in range(NUMTASKS):
                     self.newtask()

                 verbose_print("waiting for all tasks to complete")
                 self.done_mutex.acquire()
                 verbose_print("all tasks done")

             thread.stack_size(0)


 class Barrier:
     def __init__(self, num_threads):
         self.num_threads = num_threads
         self.waiting = 0
         self.checkin_mutex  = thread.allocate_lock()
         self.checkout_mutex = thread.allocate_lock()
         self.checkout_mutex.acquire()

     def enter(self):
         self.checkin_mutex.acquire()
         self.waiting = self.waiting + 1
         if self.waiting == self.num_threads:
             self.waiting = self.num_threads - 1
             self.checkout_mutex.release()
             return
         self.checkin_mutex.release()

         self.checkout_mutex.acquire()
         self.waiting = self.waiting - 1
         if self.waiting == 0:
             self.checkin_mutex.release()
             return
         self.checkout_mutex.release()


 class BarrierTest(BasicThreadTest):

     def test_barrier(self):
         self.bar = Barrier(NUMTASKS)
         self.running = NUMTASKS
         for i in range(NUMTASKS):
             thread.start_new_thread(self.task2, (i,))
         verbose_print("waiting for tasks to end")
         self.done_mutex.acquire()
         verbose_print("tasks done")

     def task2(self, ident):
         for i in range(NUMTRIPS):
             if ident == 0:
                 # give it a good chance to enter the next
                 # barrier before the others are all out
                 # of the current one
                 delay = 0
             else:
                 with self.random_mutex:
                     delay = random.random() / 10000.0
             verbose_print("task %s will run for %sus" %
                           (ident, round(delay * 1e6)))
             time.sleep(delay)
             verbose_print("task %s entering %s" % (ident, i))
             self.bar.enter()
             verbose_print("task %s leaving barrier" % ident)
         with self.running_mutex:
             self.running -= 1
             # Must release mutex before releasing done, else the main thread can
             # exit and set mutex to None as part of global teardown; then
             # mutex.release() raises AttributeError.
             finished = self.running == 0
         if finished:
             self.done_mutex.release()

 class LockTests(lock_tests.LockTests):
     locktype = thread.allocate_lock


 def test_main():
     support.run_unittest(ThreadRunningTests, BarrierTest, LockTests)

 if __name__ == "__main__":
     test_main()
	import os
	import unittest
	import random
	from test import support
	import _thread as thread
	import time

	from test import lock_tests

	NUMTASKS = 10
	NUMTRIPS = 3

	_print_mutex = thread.allocate_lock()

	def verbose_print(arg):
	"""Helper function for printing out debugging output."""
	if support.verbose:
	with _print_mutex:
	print(arg)

	class BasicThreadTest(unittest.TestCase):

	def setUp(self):
	self.done_mutex = thread.allocate_lock()
	self.done_mutex.acquire()
	self.running_mutex = thread.allocate_lock()
	self.random_mutex = thread.allocate_lock()
	self.created = 0
	self.running = 0
	self.next_ident = 0


	class ThreadRunningTests(BasicThreadTest):

	def newtask(self):
	with self.running_mutex:
	self.next_ident += 1
	verbose_print("creating task %s" % self.next_ident)
	thread.start_new_thread(self.task, (self.next_ident,))
	self.created += 1
	self.running += 1

	def task(self, ident):
	with self.random_mutex:
	delay = random.random() / 10000.0
	verbose_print("task %s will run for %sus" % (ident, round(delay*1e6)))
	time.sleep(delay)
	verbose_print("task %s done" % ident)
	with self.running_mutex:
	self.running -= 1
	if self.created == NUMTASKS and self.running == 0:
	self.done_mutex.release()

	def test_starting_threads(self):
	# Basic test for thread creation.
	for i in range(NUMTASKS):
	self.newtask()
	verbose_print("waiting for tasks to complete...")
	self.done_mutex.acquire()
	verbose_print("all tasks done")

	def test_stack_size(self):
	# Various stack size tests.
	self.assertEqual(thread.stack_size(), 0, "intial stack size is not 0")

	thread.stack_size(0)
	self.assertEqual(thread.stack_size(), 0, "stack_size not reset to default")

	if os.name not in ("nt", "os2", "posix"):
	return

	tss_supported = True
	try:
	thread.stack_size(4096)
	except ValueError:
	verbose_print("caught expected ValueError setting "
	"stack_size(4096)")
	except thread.error:
	tss_supported = False
	verbose_print("platform does not support changing thread stack "
	"size")

	if tss_supported:
	fail_msg = "stack_size(%d) failed - should succeed"
	for tss in (262144, 0x100000, 0):
	thread.stack_size(tss)
	self.assertEqual(thread.stack_size(), tss, fail_msg % tss)
	verbose_print("successfully set stack_size(%d)" % tss)

	for tss in (262144, 0x100000):
	verbose_print("trying stack_size = (%d)" % tss)
	self.next_ident = 0
	self.created = 0
	for i in range(NUMTASKS):
	self.newtask()

	verbose_print("waiting for all tasks to complete")
	self.done_mutex.acquire()
	verbose_print("all tasks done")

	thread.stack_size(0)


	class Barrier:
	def __init__(self, num_threads):
	self.num_threads = num_threads
	self.waiting = 0
	self.checkin_mutex = thread.allocate_lock()
	self.checkout_mutex = thread.allocate_lock()
	self.checkout_mutex.acquire()

	def enter(self):
	self.checkin_mutex.acquire()
	self.waiting = self.waiting + 1
	if self.waiting == self.num_threads:
	self.waiting = self.num_threads - 1
	self.checkout_mutex.release()
	return
	self.checkin_mutex.release()

	self.checkout_mutex.acquire()
	self.waiting = self.waiting - 1
	if self.waiting == 0:
	self.checkin_mutex.release()
	return
	self.checkout_mutex.release()


	class BarrierTest(BasicThreadTest):

	def test_barrier(self):
	self.bar = Barrier(NUMTASKS)
	self.running = NUMTASKS
	for i in range(NUMTASKS):
	thread.start_new_thread(self.task2, (i,))
	verbose_print("waiting for tasks to end")
	self.done_mutex.acquire()
	verbose_print("tasks done")

	def task2(self, ident):
	for i in range(NUMTRIPS):
	if ident == 0:
	# give it a good chance to enter the next
	# barrier before the others are all out
	# of the current one
	delay = 0
	else:
	with self.random_mutex:
	delay = random.random() / 10000.0
	verbose_print("task %s will run for %sus" %
	(ident, round(delay * 1e6)))
	time.sleep(delay)
	verbose_print("task %s entering %s" % (ident, i))
	self.bar.enter()
	verbose_print("task %s leaving barrier" % ident)
	with self.running_mutex:
	self.running -= 1
	# Must release mutex before releasing done, else the main thread can
	# exit and set mutex to None as part of global teardown; then
	# mutex.release() raises AttributeError.
	finished = self.running == 0
	if finished:
	self.done_mutex.release()

	class LockTests(lock_tests.LockTests):
	locktype = thread.allocate_lock


	def test_main():
	support.run_unittest(ThreadRunningTests, BarrierTest, LockTests)

	if __name__ == "__main__":
	test_main()