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

 from test.test_support import verify, verbose, TestFailed, vereq
 import sys
 import gc

 def expect(actual, expected, name):
     if actual != expected:
         raise TestFailed, "test_%s: actual %d, expected %d" % (
             name, actual, expected)

 def expect_nonzero(actual, name):
     if actual == 0:
         raise TestFailed, "test_%s: unexpected zero" % name

 def run_test(name, thunk):
     if verbose:
         print "testing %s..." % name,
     thunk()
     if verbose:
         print "ok"

 def test_list():
     l = []
     l.append(l)
     gc.collect()
     del l
     expect(gc.collect(), 1, "list")

 def test_dict():
     d = {}
     d[1] = d
     gc.collect()
     del d
     expect(gc.collect(), 1, "dict")

 def test_tuple():
     # since tuples are immutable we close the loop with a list
     l = []
     t = (l,)
     l.append(t)
     gc.collect()
     del t
     del l
     expect(gc.collect(), 2, "tuple")

 def test_class():
     class A:
         pass
     A.a = A
     gc.collect()
     del A
     expect_nonzero(gc.collect(), "class")

 def test_newstyleclass():
     class A(object):
         pass
     gc.collect()
     del A
     expect_nonzero(gc.collect(), "staticclass")

 def test_instance():
     class A:
         pass
     a = A()
     a.a = a
     gc.collect()
     del a
     expect_nonzero(gc.collect(), "instance")

 def test_newinstance():
     class A(object):
         pass
     a = A()
     a.a = a
     gc.collect()
     del a
     expect_nonzero(gc.collect(), "newinstance")
     class B(list):
         pass
     class C(B, A):
         pass
     a = C()
     a.a = a
     gc.collect()
     del a
     expect_nonzero(gc.collect(), "newinstance(2)")
     del B, C
     expect_nonzero(gc.collect(), "newinstance(3)")
     A.a = A()
     del A
     expect_nonzero(gc.collect(), "newinstance(4)")
     expect(gc.collect(), 0, "newinstance(5)")

 def test_method():
     # Tricky: self.__init__ is a bound method, it references the instance.
     class A:
         def __init__(self):
             self.init = self.__init__
     a = A()
     gc.collect()
     del a
     expect_nonzero(gc.collect(), "method")

 def test_finalizer():
     # A() is uncollectable if it is part of a cycle, make sure it shows up
     # in gc.garbage.
     class A:
         def __del__(self): pass
     class B:
         pass
     a = A()
     a.a = a
     id_a = id(a)
     b = B()
     b.b = b
     gc.collect()
     del a
     del b
     expect_nonzero(gc.collect(), "finalizer")
     for obj in gc.garbage:
         if id(obj) == id_a:
             del obj.a
             break
     else:
         raise TestFailed, "didn't find obj in garbage (finalizer)"
     gc.garbage.remove(obj)

 def test_finalizer_newclass():
     # A() is uncollectable if it is part of a cycle, make sure it shows up
     # in gc.garbage.
     class A(object):
         def __del__(self): pass
     class B(object):
         pass
     a = A()
     a.a = a
     id_a = id(a)
     b = B()
     b.b = b
     gc.collect()
     del a
     del b
     expect_nonzero(gc.collect(), "finalizer")
     for obj in gc.garbage:
         if id(obj) == id_a:
             del obj.a
             break
     else:
         raise TestFailed, "didn't find obj in garbage (finalizer)"
     gc.garbage.remove(obj)

 def test_function():
     # Tricky: f -> d -> f, code should call d.clear() after the exec to
     # break the cycle.
     d = {}
     exec("def f(): pass\n") in d
     gc.collect()
     del d
     expect(gc.collect(), 2, "function")

 def test_frame():
     def f():
         frame = sys._getframe()
     gc.collect()
     f()
     expect(gc.collect(), 1, "frame")


 def test_saveall():
     # Verify that cyclic garbage like lists show up in gc.garbage if the
     # SAVEALL option is enabled.

     # First make sure we don't save away other stuff that just happens to
     # be waiting for collection.
     gc.collect()
     vereq(gc.garbage, []) # if this fails, someone else created immortal trash

     L = []
     L.append(L)
     id_L = id(L)

     debug = gc.get_debug()
     gc.set_debug(debug | gc.DEBUG_SAVEALL)
     del L
     gc.collect()
     gc.set_debug(debug)

     vereq(len(gc.garbage), 1)
     obj = gc.garbage.pop()
     vereq(id(obj), id_L)

 def test_del():
     # __del__ methods can trigger collection, make this to happen
     thresholds = gc.get_threshold()
     gc.enable()
     gc.set_threshold(1)

     class A:
         def __del__(self):
             dir(self)
     a = A()
     del a

     gc.disable()
     gc.set_threshold(*thresholds)

 def test_del_newclass():
     # __del__ methods can trigger collection, make this to happen
     thresholds = gc.get_threshold()
     gc.enable()
     gc.set_threshold(1)

     class A(object):
         def __del__(self):
             dir(self)
     a = A()
     del a

     gc.disable()
     gc.set_threshold(*thresholds)

 class Ouch:
     n = 0
     def __del__(self):
         Ouch.n = Ouch.n + 1
         if Ouch.n % 17 == 0:
             gc.collect()

 def test_trashcan():
     # "trashcan" is a hack to prevent stack overflow when deallocating
     # very deeply nested tuples etc.  It works in part by abusing the
     # type pointer and refcount fields, and that can yield horrible
     # problems when gc tries to traverse the structures.
     # If this test fails (as it does in 2.0, 2.1 and 2.2), it will
     # most likely die via segfault.

     # Note:  In 2.3 the possibility for compiling without cyclic gc was
     # removed, and that in turn allows the trashcan mechanism to work
     # via much simpler means (e.g., it never abuses the type pointer or
     # refcount fields anymore).  Since it's much less likely to cause a
     # problem now, the various constants in this expensive (we force a lot
     # of full collections) test are cut back from the 2.2 version.
     gc.enable()
     N = 150
     for count in range(2):
         t = []
         for i in range(N):
             t = [t, Ouch()]
         u = []
         for i in range(N):
             u = [u, Ouch()]
         v = {}
         for i in range(N):
             v = {1: v, 2: Ouch()}
     gc.disable()

 def test_all():
     gc.collect() # Delete 2nd generation garbage
     run_test("lists", test_list)
     run_test("dicts", test_dict)
     run_test("tuples", test_tuple)
     run_test("classes", test_class)
     run_test("new style classes", test_newstyleclass)
     run_test("instances", test_instance)
     run_test("new instances", test_newinstance)
     run_test("methods", test_method)
     run_test("functions", test_function)
     run_test("frames", test_frame)
     run_test("finalizers", test_finalizer)
     run_test("finalizers (new class)", test_finalizer_newclass)
     run_test("__del__", test_del)
     run_test("__del__ (new class)", test_del_newclass)
     run_test("saveall", test_saveall)
     run_test("trashcan", test_trashcan)

 def test():
     if verbose:
         print "disabling automatic collection"
     enabled = gc.isenabled()
     gc.disable()
     verify(not gc.isenabled())
     debug = gc.get_debug()
     gc.set_debug(debug & ~gc.DEBUG_LEAK) # this test is supposed to leak

     try:
         test_all()
     finally:
         gc.set_debug(debug)
         # test gc.enable() even if GC is disabled by default
         if verbose:
             print "restoring automatic collection"
         # make sure to always test gc.enable()
         gc.enable()
         verify(gc.isenabled())
         if not enabled:
             gc.disable()


 test()
	from test.test_support import verify, verbose, TestFailed, vereq
	import sys
	import gc

	def expect(actual, expected, name):
	if actual != expected:
	raise TestFailed, "test_%s: actual %d, expected %d" % (
	name, actual, expected)

	def expect_nonzero(actual, name):
	if actual == 0:
	raise TestFailed, "test_%s: unexpected zero" % name

	def run_test(name, thunk):
	if verbose:
	print "testing %s..." % name,
	thunk()
	if verbose:
	print "ok"

	def test_list():
	l = []
	l.append(l)
	gc.collect()
	del l
	expect(gc.collect(), 1, "list")

	def test_dict():
	d = {}
	d[1] = d
	gc.collect()
	del d
	expect(gc.collect(), 1, "dict")

	def test_tuple():
	# since tuples are immutable we close the loop with a list
	l = []
	t = (l,)
	l.append(t)
	gc.collect()
	del t
	del l
	expect(gc.collect(), 2, "tuple")

	def test_class():
	class A:
	pass
	A.a = A
	gc.collect()
	del A
	expect_nonzero(gc.collect(), "class")

	def test_newstyleclass():
	class A(object):
	pass
	gc.collect()
	del A
	expect_nonzero(gc.collect(), "staticclass")

	def test_instance():
	class A:
	pass
	a = A()
	a.a = a
	gc.collect()
	del a
	expect_nonzero(gc.collect(), "instance")

	def test_newinstance():
	class A(object):
	pass
	a = A()
	a.a = a
	gc.collect()
	del a
	expect_nonzero(gc.collect(), "newinstance")
	class B(list):
	pass
	class C(B, A):
	pass
	a = C()
	a.a = a
	gc.collect()
	del a
	expect_nonzero(gc.collect(), "newinstance(2)")
	del B, C
	expect_nonzero(gc.collect(), "newinstance(3)")
	A.a = A()
	del A
	expect_nonzero(gc.collect(), "newinstance(4)")
	expect(gc.collect(), 0, "newinstance(5)")

	def test_method():
	# Tricky: self.__init__ is a bound method, it references the instance.
	class A:
	def __init__(self):
	self.init = self.__init__
	a = A()
	gc.collect()
	del a
	expect_nonzero(gc.collect(), "method")

	def test_finalizer():
	# A() is uncollectable if it is part of a cycle, make sure it shows up
	# in gc.garbage.
	class A:
	def __del__(self): pass
	class B:
	pass
	a = A()
	a.a = a
	id_a = id(a)
	b = B()
	b.b = b
	gc.collect()
	del a
	del b
	expect_nonzero(gc.collect(), "finalizer")
	for obj in gc.garbage:
	if id(obj) == id_a:
	del obj.a
	break
	else:
	raise TestFailed, "didn't find obj in garbage (finalizer)"
	gc.garbage.remove(obj)

	def test_finalizer_newclass():
	# A() is uncollectable if it is part of a cycle, make sure it shows up
	# in gc.garbage.
	class A(object):
	def __del__(self): pass
	class B(object):
	pass
	a = A()
	a.a = a
	id_a = id(a)
	b = B()
	b.b = b
	gc.collect()
	del a
	del b
	expect_nonzero(gc.collect(), "finalizer")
	for obj in gc.garbage:
	if id(obj) == id_a:
	del obj.a
	break
	else:
	raise TestFailed, "didn't find obj in garbage (finalizer)"
	gc.garbage.remove(obj)

	def test_function():
	# Tricky: f -> d -> f, code should call d.clear() after the exec to
	# break the cycle.
	d = {}
	exec("def f(): pass\n") in d
	gc.collect()
	del d
	expect(gc.collect(), 2, "function")

	def test_frame():
	def f():
	frame = sys._getframe()
	gc.collect()
	f()
	expect(gc.collect(), 1, "frame")


	def test_saveall():
	# Verify that cyclic garbage like lists show up in gc.garbage if the
	# SAVEALL option is enabled.

	# First make sure we don't save away other stuff that just happens to
	# be waiting for collection.
	gc.collect()
	vereq(gc.garbage, []) # if this fails, someone else created immortal trash

	L = []
	L.append(L)
	id_L = id(L)

	debug = gc.get_debug()
	gc.set_debug(debug \| gc.DEBUG_SAVEALL)
	del L
	gc.collect()
	gc.set_debug(debug)

	vereq(len(gc.garbage), 1)
	obj = gc.garbage.pop()
	vereq(id(obj), id_L)

	def test_del():
	# __del__ methods can trigger collection, make this to happen
	thresholds = gc.get_threshold()
	gc.enable()
	gc.set_threshold(1)

	class A:
	def __del__(self):
	dir(self)
	a = A()
	del a

	gc.disable()
	gc.set_threshold(*thresholds)

	def test_del_newclass():
	# __del__ methods can trigger collection, make this to happen
	thresholds = gc.get_threshold()
	gc.enable()
	gc.set_threshold(1)

	class A(object):
	def __del__(self):
	dir(self)
	a = A()
	del a

	gc.disable()
	gc.set_threshold(*thresholds)

	class Ouch:
	n = 0
	def __del__(self):
	Ouch.n = Ouch.n + 1
	if Ouch.n % 17 == 0:
	gc.collect()

	def test_trashcan():
	# "trashcan" is a hack to prevent stack overflow when deallocating
	# very deeply nested tuples etc. It works in part by abusing the
	# type pointer and refcount fields, and that can yield horrible
	# problems when gc tries to traverse the structures.
	# If this test fails (as it does in 2.0, 2.1 and 2.2), it will
	# most likely die via segfault.

	# Note: In 2.3 the possibility for compiling without cyclic gc was
	# removed, and that in turn allows the trashcan mechanism to work
	# via much simpler means (e.g., it never abuses the type pointer or
	# refcount fields anymore). Since it's much less likely to cause a
	# problem now, the various constants in this expensive (we force a lot
	# of full collections) test are cut back from the 2.2 version.
	gc.enable()
	N = 150
	for count in range(2):
	t = []
	for i in range(N):
	t = [t, Ouch()]
	u = []
	for i in range(N):
	u = [u, Ouch()]
	v = {}
	for i in range(N):
	v = {1: v, 2: Ouch()}
	gc.disable()

	def test_all():
	gc.collect() # Delete 2nd generation garbage
	run_test("lists", test_list)
	run_test("dicts", test_dict)
	run_test("tuples", test_tuple)
	run_test("classes", test_class)
	run_test("new style classes", test_newstyleclass)
	run_test("instances", test_instance)
	run_test("new instances", test_newinstance)
	run_test("methods", test_method)
	run_test("functions", test_function)
	run_test("frames", test_frame)
	run_test("finalizers", test_finalizer)
	run_test("finalizers (new class)", test_finalizer_newclass)
	run_test("__del__", test_del)
	run_test("__del__ (new class)", test_del_newclass)
	run_test("saveall", test_saveall)
	run_test("trashcan", test_trashcan)

	def test():
	if verbose:
	print "disabling automatic collection"
	enabled = gc.isenabled()
	gc.disable()
	verify(not gc.isenabled())
	debug = gc.get_debug()
	gc.set_debug(debug & ~gc.DEBUG_LEAK) # this test is supposed to leak

	try:
	test_all()
	finally:
	gc.set_debug(debug)
	# test gc.enable() even if GC is disabled by default
	if verbose:
	print "restoring automatic collection"
	# make sure to always test gc.enable()
	gc.enable()
	verify(gc.isenabled())
	if not enabled:
	gc.disable()


	test()