import gc import sys import unittest import UserList import weakref import operator from test import test_support # Used in ReferencesTestCase.test_ref_created_during_del() . ref_from_del = None class C: def method(self): pass class Callable: bar = None def __call__(self, x): self.bar = x def create_function(): def f(): pass return f def create_bound_method(): return C().method def create_unbound_method(): return C.method class TestBase(unittest.TestCase): def setUp(self): self.cbcalled = 0 def callback(self, ref): self.cbcalled += 1 class ReferencesTestCase(TestBase): def test_basic_ref(self): self.check_basic_ref(C) self.check_basic_ref(create_function) self.check_basic_ref(create_bound_method) self.check_basic_ref(create_unbound_method) # Just make sure the tp_repr handler doesn't raise an exception. # Live reference: o = C() wr = weakref.ref(o) repr(wr) # Dead reference: del o repr(wr) def test_basic_callback(self): self.check_basic_callback(C) self.check_basic_callback(create_function) self.check_basic_callback(create_bound_method) self.check_basic_callback(create_unbound_method) def test_multiple_callbacks(self): o = C() ref1 = weakref.ref(o, self.callback) ref2 = weakref.ref(o, self.callback) del o self.assertTrue(ref1() is None, "expected reference to be invalidated") self.assertTrue(ref2() is None, "expected reference to be invalidated") self.assertTrue(self.cbcalled == 2, "callback not called the right number of times") def test_multiple_selfref_callbacks(self): # Make sure all references are invalidated before callbacks are called # # What's important here is that we're using the first # reference in the callback invoked on the second reference # (the most recently created ref is cleaned up first). This # tests that all references to the object are invalidated # before any of the callbacks are invoked, so that we only # have one invocation of _weakref.c:cleanup_helper() active # for a particular object at a time. # def callback(object, self=self): self.ref() c = C() self.ref = weakref.ref(c, callback) ref1 = weakref.ref(c, callback) del c def test_proxy_ref(self): o = C() o.bar = 1 ref1 = weakref.proxy(o, self.callback) ref2 = weakref.proxy(o, self.callback) del o def check(proxy): proxy.bar self.assertRaises(weakref.ReferenceError, check, ref1) self.assertRaises(weakref.ReferenceError, check, ref2) self.assertRaises(weakref.ReferenceError, bool, weakref.proxy(C())) self.assertTrue(self.cbcalled == 2) def check_basic_ref(self, factory): o = factory() ref = weakref.ref(o) self.assertTrue(ref() is not None, "weak reference to live object should be live") o2 = ref() self.assertTrue(o is o2, "() should return original object if live") def check_basic_callback(self, factory): self.cbcalled = 0 o = factory() ref = weakref.ref(o, self.callback) del o self.assertTrue(self.cbcalled == 1, "callback did not properly set 'cbcalled'") self.assertTrue(ref() is None, "ref2 should be dead after deleting object reference") def test_ref_reuse(self): o = C() ref1 = weakref.ref(o) # create a proxy to make sure that there's an intervening creation # between these two; it should make no difference proxy = weakref.proxy(o) ref2 = weakref.ref(o) self.assertTrue(ref1 is ref2, "reference object w/out callback should be re-used") o = C() proxy = weakref.proxy(o) ref1 = weakref.ref(o) ref2 = weakref.ref(o) self.assertTrue(ref1 is ref2, "reference object w/out callback should be re-used") self.assertTrue(weakref.getweakrefcount(o) == 2, "wrong weak ref count for object") del proxy self.assertTrue(weakref.getweakrefcount(o) == 1, "wrong weak ref count for object after deleting proxy") def test_proxy_reuse(self): o = C() proxy1 = weakref.proxy(o) ref = weakref.ref(o) proxy2 = weakref.proxy(o) self.assertTrue(proxy1 is proxy2, "proxy object w/out callback should have been re-used") def test_basic_proxy(self): o = C() self.check_proxy(o, weakref.proxy(o)) L = UserList.UserList() p = weakref.proxy(L) self.assertFalse(p, "proxy for empty UserList should be false") p.append(12) self.assertEqual(len(L), 1) self.assertTrue(p, "proxy for non-empty UserList should be true") with test_support.check_py3k_warnings(): p[:] = [2, 3] self.assertEqual(len(L), 2) self.assertEqual(len(p), 2) self.assertIn(3, p, "proxy didn't support __contains__() properly") p[1] = 5 self.assertEqual(L[1], 5) self.assertEqual(p[1], 5) L2 = UserList.UserList(L) p2 = weakref.proxy(L2) self.assertEqual(p, p2) ## self.assertEqual(repr(L2), repr(p2)) L3 = UserList.UserList(range(10)) p3 = weakref.proxy(L3) with test_support.check_py3k_warnings(): self.assertEqual(L3[:], p3[:]) self.assertEqual(L3[5:], p3[5:]) self.assertEqual(L3[:5], p3[:5]) self.assertEqual(L3[2:5], p3[2:5]) def test_proxy_unicode(self): # See bug 5037 class C(object): def __str__(self): return "string" def __unicode__(self): return u"unicode" instance = C() self.assertIn("__unicode__", dir(weakref.proxy(instance))) self.assertEqual(unicode(weakref.proxy(instance)), u"unicode") def test_proxy_index(self): class C: def __index__(self): return 10 o = C() p = weakref.proxy(o) self.assertEqual(operator.index(p), 10) def test_proxy_div(self): class C: def __floordiv__(self, other): return 42 def __ifloordiv__(self, other): return 21 o = C() p = weakref.proxy(o) self.assertEqual(p // 5, 42) p //= 5 self.assertEqual(p, 21) # The PyWeakref_* C API is documented as allowing either NULL or # None as the value for the callback, where either means "no # callback". The "no callback" ref and proxy objects are supposed # to be shared so long as they exist by all callers so long as # they are active. In Python 2.3.3 and earlier, this guarantee # was not honored, and was broken in different ways for # PyWeakref_NewRef() and PyWeakref_NewProxy(). (Two tests.) def test_shared_ref_without_callback(self): self.check_shared_without_callback(weakref.ref) def test_shared_proxy_without_callback(self): self.check_shared_without_callback(weakref.proxy) def check_shared_without_callback(self, makeref): o = Object(1) p1 = makeref(o, None) p2 = makeref(o, None) self.assertTrue(p1 is p2, "both callbacks were None in the C API") del p1, p2 p1 = makeref(o) p2 = makeref(o, None) self.assertTrue(p1 is p2, "callbacks were NULL, None in the C API") del p1, p2 p1 = makeref(o) p2 = makeref(o) self.assertTrue(p1 is p2, "both callbacks were NULL in the C API") del p1, p2 p1 = makeref(o, None) p2 = makeref(o) self.assertTrue(p1 is p2, "callbacks were None, NULL in the C API") def test_callable_proxy(self): o = Callable() ref1 = weakref.proxy(o) self.check_proxy(o, ref1) self.assertTrue(type(ref1) is weakref.CallableProxyType, "proxy is not of callable type") ref1('twinkies!') self.assertTrue(o.bar == 'twinkies!', "call through proxy not passed through to original") ref1(x='Splat.') self.assertTrue(o.bar == 'Splat.', "call through proxy not passed through to original") # expect due to too few args self.assertRaises(TypeError, ref1) # expect due to too many args self.assertRaises(TypeError, ref1, 1, 2, 3) def check_proxy(self, o, proxy): o.foo = 1 self.assertTrue(proxy.foo == 1, "proxy does not reflect attribute addition") o.foo = 2 self.assertTrue(proxy.foo == 2, "proxy does not reflect attribute modification") del o.foo self.assertTrue(not hasattr(proxy, 'foo'), "proxy does not reflect attribute removal") proxy.foo = 1 self.assertTrue(o.foo == 1, "object does not reflect attribute addition via proxy") proxy.foo = 2 self.assertTrue( o.foo == 2, "object does not reflect attribute modification via proxy") del proxy.foo self.assertTrue(not hasattr(o, 'foo'), "object does not reflect attribute removal via proxy") def test_proxy_deletion(self): # Test clearing of SF bug #762891 class Foo: result = None def __delitem__(self, accessor): self.result = accessor g = Foo() f = weakref.proxy(g) del f[0] self.assertEqual(f.result, 0) def test_proxy_bool(self): # Test clearing of SF bug #1170766 class List(list): pass lyst = List() self.assertEqual(bool(weakref.proxy(lyst)), bool(lyst)) def test_getweakrefcount(self): o = C() ref1 = weakref.ref(o) ref2 = weakref.ref(o, self.callback) self.assertTrue(weakref.getweakrefcount(o) == 2, "got wrong number of weak reference objects") proxy1 = weakref.proxy(o) proxy2 = weakref.proxy(o, self.callback) self.assertTrue(weakref.getweakrefcount(o) == 4, "got wrong number of weak reference objects") del ref1, ref2, proxy1, proxy2 self.assertTrue(weakref.getweakrefcount(o) == 0, "weak reference objects not unlinked from" " referent when discarded.") # assumes ints do not support weakrefs self.assertTrue(weakref.getweakrefcount(1) == 0, "got wrong number of weak reference objects for int") def test_getweakrefs(self): o = C() ref1 = weakref.ref(o, self.callback) ref2 = weakref.ref(o, self.callback) del ref1 self.assertTrue(weakref.getweakrefs(o) == [ref2], "list of refs does not match") o = C() ref1 = weakref.ref(o, self.callback) ref2 = weakref.ref(o, self.callback) del ref2 self.assertTrue(weakref.getweakrefs(o) == [ref1], "list of refs does not match") del ref1 self.assertTrue(weakref.getweakrefs(o) == [], "list of refs not cleared") # assumes ints do not support weakrefs self.assertTrue(weakref.getweakrefs(1) == [], "list of refs does not match for int") def test_newstyle_number_ops(self): class F(float): pass f = F(2.0) p = weakref.proxy(f) self.assertTrue(p + 1.0 == 3.0) self.assertTrue(1.0 + p == 3.0) # this used to SEGV def test_callbacks_protected(self): # Callbacks protected from already-set exceptions? # Regression test for SF bug #478534. class BogusError(Exception): pass data = {} def remove(k): del data[k] def encapsulate(): f = lambda : () data[weakref.ref(f, remove)] = None raise BogusError try: encapsulate() except BogusError: pass else: self.fail("exception not properly restored") try: encapsulate() except BogusError: pass else: self.fail("exception not properly restored") def test_sf_bug_840829(self): # "weakref callbacks and gc corrupt memory" # subtype_dealloc erroneously exposed a new-style instance # already in the process of getting deallocated to gc, # causing double-deallocation if the instance had a weakref # callback that triggered gc. # If the bug exists, there probably won't be an obvious symptom # in a release build. In a debug build, a segfault will occur # when the second attempt to remove the instance from the "list # of all objects" occurs. import gc class C(object): pass c = C() wr = weakref.ref(c, lambda ignore: gc.collect()) del c # There endeth the first part. It gets worse. del wr c1 = C() c1.i = C() wr = weakref.ref(c1.i, lambda ignore: gc.collect()) c2 = C() c2.c1 = c1 del c1 # still alive because c2 points to it # Now when subtype_dealloc gets called on c2, it's not enough just # that c2 is immune from gc while the weakref callbacks associated # with c2 execute (there are none in this 2nd half of the test, btw). # subtype_dealloc goes on to call the base classes' deallocs too, # so any gc triggered by weakref callbacks associated with anything # torn down by a base class dealloc can also trigger double # deallocation of c2. del c2 def test_callback_in_cycle_1(self): import gc class J(object): pass class II(object): def acallback(self, ignore): self.J I = II() I.J = J I.wr = weakref.ref(J, I.acallback) # Now J and II are each in a self-cycle (as all new-style class # objects are, since their __mro__ points back to them). I holds # both a weak reference (I.wr) and a strong reference (I.J) to class # J. I is also in a cycle (I.wr points to a weakref that references # I.acallback). When we del these three, they all become trash, but # the cycles prevent any of them from getting cleaned up immediately. # Instead they have to wait for cyclic gc to deduce that they're # trash. # # gc used to call tp_clear on all of them, and the order in which # it does that is pretty accidental. The exact order in which we # built up these things manages to provoke gc into running tp_clear # in just the right order (I last). Calling tp_clear on II leaves # behind an insane class object (its __mro__ becomes NULL). Calling # tp_clear on J breaks its self-cycle, but J doesn't get deleted # just then because of the strong reference from I.J. Calling # tp_clear on I starts to clear I's __dict__, and just happens to # clear I.J first -- I.wr is still intact. That removes the last # reference to J, which triggers the weakref callback. The callback # tries to do "self.J", and instances of new-style classes look up # attributes ("J") in the class dict first. The class (II) wants to # search II.__mro__, but that's NULL. The result was a segfault in # a release build, and an assert failure in a debug build. del I, J, II gc.collect() def test_callback_in_cycle_2(self): import gc # This is just like test_callback_in_cycle_1, except that II is an # old-style class. The symptom is different then: an instance of an # old-style class looks in its own __dict__ first. 'J' happens to # get cleared from I.__dict__ before 'wr', and 'J' was never in II's # __dict__, so the attribute isn't found. The difference is that # the old-style II doesn't have a NULL __mro__ (it doesn't have any # __mro__), so no segfault occurs. Instead it got: # test_callback_in_cycle_2 (__main__.ReferencesTestCase) ... # Exception exceptions.AttributeError: # "II instance has no attribute 'J'" in > ignored class J(object): pass class II: def acallback(self, ignore): self.J I = II() I.J = J I.wr = weakref.ref(J, I.acallback) del I, J, II gc.collect() def test_callback_in_cycle_3(self): import gc # This one broke the first patch that fixed the last two. In this # case, the objects reachable from the callback aren't also reachable # from the object (c1) *triggering* the callback: you can get to # c1 from c2, but not vice-versa. The result was that c2's __dict__ # got tp_clear'ed by the time the c2.cb callback got invoked. class C: def cb(self, ignore): self.me self.c1 self.wr c1, c2 = C(), C() c2.me = c2 c2.c1 = c1 c2.wr = weakref.ref(c1, c2.cb) del c1, c2 gc.collect() def test_callback_in_cycle_4(self): import gc # Like test_callback_in_cycle_3, except c2 and c1 have different # classes. c2's class (C) isn't reachable from c1 then, so protecting # objects reachable from the dying object (c1) isn't enough to stop # c2's class (C) from getting tp_clear'ed before c2.cb is invoked. # The result was a segfault (C.__mro__ was NULL when the callback # tried to look up self.me). class C(object): def cb(self, ignore): self.me self.c1 self.wr class D: pass c1, c2 = D(), C() c2.me = c2 c2.c1 = c1 c2.wr = weakref.ref(c1, c2.cb) del c1, c2, C, D gc.collect() def test_callback_in_cycle_resurrection(self): import gc # Do something nasty in a weakref callback: resurrect objects # from dead cycles. For this to be attempted, the weakref and # its callback must also be part of the cyclic trash (else the # objects reachable via the callback couldn't be in cyclic trash # to begin with -- the callback would act like an external root). # But gc clears trash weakrefs with callbacks early now, which # disables the callbacks, so the callbacks shouldn't get called # at all (and so nothing actually gets resurrected). alist = [] class C(object): def __init__(self, value): self.attribute = value def acallback(self, ignore): alist.append(self.c) c1, c2 = C(1), C(2) c1.c = c2 c2.c = c1 c1.wr = weakref.ref(c2, c1.acallback) c2.wr = weakref.ref(c1, c2.acallback) def C_went_away(ignore): alist.append("C went away") wr = weakref.ref(C, C_went_away) del c1, c2, C # make them all trash self.assertEqual(alist, []) # del isn't enough to reclaim anything gc.collect() # c1.wr and c2.wr were part of the cyclic trash, so should have # been cleared without their callbacks executing. OTOH, the weakref # to C is bound to a function local (wr), and wasn't trash, so that # callback should have been invoked when C went away. self.assertEqual(alist, ["C went away"]) # The remaining weakref should be dead now (its callback ran). self.assertEqual(wr(), None) del alist[:] gc.collect() self.assertEqual(alist, []) def test_callbacks_on_callback(self): import gc # Set up weakref callbacks *on* weakref callbacks. alist = [] def safe_callback(ignore): alist.append("safe_callback called") class C(object): def cb(self, ignore): alist.append("cb called") c, d = C(), C() c.other = d d.other = c callback = c.cb c.wr = weakref.ref(d, callback) # this won't trigger d.wr = weakref.ref(callback, d.cb) # ditto external_wr = weakref.ref(callback, safe_callback) # but this will self.assertTrue(external_wr() is callback) # The weakrefs attached to c and d should get cleared, so that # C.cb is never called. But external_wr isn't part of the cyclic # trash, and no cyclic trash is reachable from it, so safe_callback # should get invoked when the bound method object callback (c.cb) # -- which is itself a callback, and also part of the cyclic trash -- # gets reclaimed at the end of gc. del callback, c, d, C self.assertEqual(alist, []) # del isn't enough to clean up cycles gc.collect() self.assertEqual(alist, ["safe_callback called"]) self.assertEqual(external_wr(), None) del alist[:] gc.collect() self.assertEqual(alist, []) def test_gc_during_ref_creation(self): self.check_gc_during_creation(weakref.ref) def test_gc_during_proxy_creation(self): self.check_gc_during_creation(weakref.proxy) def check_gc_during_creation(self, makeref): thresholds = gc.get_threshold() gc.set_threshold(1, 1, 1) gc.collect() class A: pass def callback(*args): pass referenced = A() a = A() a.a = a a.wr = makeref(referenced) try: # now make sure the object and the ref get labeled as # cyclic trash: a = A() weakref.ref(referenced, callback) finally: gc.set_threshold(*thresholds) def test_ref_created_during_del(self): # Bug #1377858 # A weakref created in an object's __del__() would crash the # interpreter when the weakref was cleaned up since it would refer to # non-existent memory. This test should not segfault the interpreter. class Target(object): def __del__(self): global ref_from_del ref_from_del = weakref.ref(self) w = Target() def test_init(self): # Issue 3634 # .__init__() doesn't check errors correctly r = weakref.ref(Exception) self.assertRaises(TypeError, r.__init__, 0, 0, 0, 0, 0) # No exception should be raised here gc.collect() def test_classes(self): # Check that both old-style classes and new-style classes # are weakrefable. class A(object): pass class B: pass l = [] weakref.ref(int) a = weakref.ref(A, l.append) A = None gc.collect() self.assertEqual(a(), None) self.assertEqual(l, [a]) b = weakref.ref(B, l.append) B = None gc.collect() self.assertEqual(b(), None) self.assertEqual(l, [a, b]) class SubclassableWeakrefTestCase(TestBase): def test_subclass_refs(self): class MyRef(weakref.ref): def __init__(self, ob, callback=None, value=42): self.value = value super(MyRef, self).__init__(ob, callback) def __call__(self): self.called = True return super(MyRef, self).__call__() o = Object("foo") mr = MyRef(o, value=24) self.assertTrue(mr() is o) self.assertTrue(mr.called) self.assertEqual(mr.value, 24) del o self.assertTrue(mr() is None) self.assertTrue(mr.called) def test_subclass_refs_dont_replace_standard_refs(self): class MyRef(weakref.ref): pass o = Object(42) r1 = MyRef(o) r2 = weakref.ref(o) self.assertTrue(r1 is not r2) self.assertEqual(weakref.getweakrefs(o), [r2, r1]) self.assertEqual(weakref.getweakrefcount(o), 2) r3 = MyRef(o) self.assertEqual(weakref.getweakrefcount(o), 3) refs = weakref.getweakrefs(o) self.assertEqual(len(refs), 3) self.assertTrue(r2 is refs[0]) self.assertIn(r1, refs[1:]) self.assertIn(r3, refs[1:]) def test_subclass_refs_dont_conflate_callbacks(self): class MyRef(weakref.ref): pass o = Object(42) r1 = MyRef(o, id) r2 = MyRef(o, str) self.assertTrue(r1 is not r2) refs = weakref.getweakrefs(o) self.assertIn(r1, refs) self.assertIn(r2, refs) def test_subclass_refs_with_slots(self): class MyRef(weakref.ref): __slots__ = "slot1", "slot2" def __new__(type, ob, callback, slot1, slot2): return weakref.ref.__new__(type, ob, callback) def __init__(self, ob, callback, slot1, slot2): self.slot1 = slot1 self.slot2 = slot2 def meth(self): return self.slot1 + self.slot2 o = Object(42) r = MyRef(o, None, "abc", "def") self.assertEqual(r.slot1, "abc") self.assertEqual(r.slot2, "def") self.assertEqual(r.meth(), "abcdef") self.assertFalse(hasattr(r, "__dict__")) def test_subclass_refs_with_cycle(self): # Bug #3110 # An instance of a weakref subclass can have attributes. # If such a weakref holds the only strong reference to the object, # deleting the weakref will delete the object. In this case, # the callback must not be called, because the ref object is # being deleted. class MyRef(weakref.ref): pass # Use a local callback, for "regrtest -R::" # to detect refcounting problems def callback(w): self.cbcalled += 1 o = C() r1 = MyRef(o, callback) r1.o = o del o del r1 # Used to crash here self.assertEqual(self.cbcalled, 0) # Same test, with two weakrefs to the same object # (since code paths are different) o = C() r1 = MyRef(o, callback) r2 = MyRef(o, callback) r1.r = r2 r2.o = o del o del r2 del r1 # Used to crash here self.assertEqual(self.cbcalled, 0) class Object: def __init__(self, arg): self.arg = arg def __repr__(self): return "" % self.arg class MappingTestCase(TestBase): COUNT = 10 def test_weak_values(self): # # This exercises d.copy(), d.items(), d[], del d[], len(d). # dict, objects = self.make_weak_valued_dict() for o in objects: self.assertTrue(weakref.getweakrefcount(o) == 1, "wrong number of weak references to %r!" % o) self.assertTrue(o is dict[o.arg], "wrong object returned by weak dict!") items1 = dict.items() items2 = dict.copy().items() items1.sort() items2.sort() self.assertTrue(items1 == items2, "cloning of weak-valued dictionary did not work!") del items1, items2 self.assertTrue(len(dict) == self.COUNT) del objects[0] self.assertTrue(len(dict) == (self.COUNT - 1), "deleting object did not cause dictionary update") del objects, o self.assertTrue(len(dict) == 0, "deleting the values did not clear the dictionary") # regression on SF bug #447152: dict = weakref.WeakValueDictionary() self.assertRaises(KeyError, dict.__getitem__, 1) dict[2] = C() self.assertRaises(KeyError, dict.__getitem__, 2) def test_weak_keys(self): # # This exercises d.copy(), d.items(), d[] = v, d[], del d[], # len(d), in d. # dict, objects = self.make_weak_keyed_dict() for o in objects: self.assertTrue(weakref.getweakrefcount(o) == 1, "wrong number of weak references to %r!" % o) self.assertTrue(o.arg is dict[o], "wrong object returned by weak dict!") items1 = dict.items() items2 = dict.copy().items() self.assertTrue(set(items1) == set(items2), "cloning of weak-keyed dictionary did not work!") del items1, items2 self.assertTrue(len(dict) == self.COUNT) del objects[0] self.assertTrue(len(dict) == (self.COUNT - 1), "deleting object did not cause dictionary update") del objects, o self.assertTrue(len(dict) == 0, "deleting the keys did not clear the dictionary") o = Object(42) dict[o] = "What is the meaning of the universe?" self.assertIn(o, dict) self.assertNotIn(34, dict) def test_weak_keyed_iters(self): dict, objects = self.make_weak_keyed_dict() self.check_iters(dict) # Test keyrefs() refs = dict.keyrefs() self.assertEqual(len(refs), len(objects)) objects2 = list(objects) for wr in refs: ob = wr() self.assertIn(ob, dict) self.assertEqual(ob.arg, dict[ob]) objects2.remove(ob) self.assertEqual(len(objects2), 0) # Test iterkeyrefs() objects2 = list(objects) self.assertEqual(len(list(dict.iterkeyrefs())), len(objects)) for wr in dict.iterkeyrefs(): ob = wr() self.assertIn(ob, dict) self.assertEqual(ob.arg, dict[ob]) objects2.remove(ob) self.assertEqual(len(objects2), 0) def test_weak_valued_iters(self): dict, objects = self.make_weak_valued_dict() self.check_iters(dict) # Test valuerefs() refs = dict.valuerefs() self.assertEqual(len(refs), len(objects)) objects2 = list(objects) for wr in refs: ob = wr() self.assertEqual(ob, dict[ob.arg]) self.assertEqual(ob.arg, dict[ob.arg].arg) objects2.remove(ob) self.assertEqual(len(objects2), 0) # Test itervaluerefs() objects2 = list(objects) self.assertEqual(len(list(dict.itervaluerefs())), len(objects)) for wr in dict.itervaluerefs(): ob = wr() self.assertEqual(ob, dict[ob.arg]) self.assertEqual(ob.arg, dict[ob.arg].arg) objects2.remove(ob) self.assertEqual(len(objects2), 0) def check_iters(self, dict): # item iterator: items = dict.items() for item in dict.iteritems(): items.remove(item) self.assertTrue(len(items) == 0, "iteritems() did not touch all items") # key iterator, via __iter__(): keys = dict.keys() for k in dict: keys.remove(k) self.assertTrue(len(keys) == 0, "__iter__() did not touch all keys") # key iterator, via iterkeys(): keys = dict.keys() for k in dict.iterkeys(): keys.remove(k) self.assertTrue(len(keys) == 0, "iterkeys() did not touch all keys") # value iterator: values = dict.values() for v in dict.itervalues(): values.remove(v) self.assertTrue(len(values) == 0, "itervalues() did not touch all values") def test_make_weak_keyed_dict_from_dict(self): o = Object(3) dict = weakref.WeakKeyDictionary({o:364}) self.assertTrue(dict[o] == 364) def test_make_weak_keyed_dict_from_weak_keyed_dict(self): o = Object(3) dict = weakref.WeakKeyDictionary({o:364}) dict2 = weakref.WeakKeyDictionary(dict) self.assertTrue(dict[o] == 364) def make_weak_keyed_dict(self): dict = weakref.WeakKeyDictionary() objects = map(Object, range(self.COUNT)) for o in objects: dict[o] = o.arg return dict, objects def make_weak_valued_dict(self): dict = weakref.WeakValueDictionary() objects = map(Object, range(self.COUNT)) for o in objects: dict[o.arg] = o return dict, objects def check_popitem(self, klass, key1, value1, key2, value2): weakdict = klass() weakdict[key1] = value1 weakdict[key2] = value2 self.assertTrue(len(weakdict) == 2) k, v = weakdict.popitem() self.assertTrue(len(weakdict) == 1) if k is key1: self.assertTrue(v is value1) else: self.assertTrue(v is value2) k, v = weakdict.popitem() self.assertTrue(len(weakdict) == 0) if k is key1: self.assertTrue(v is value1) else: self.assertTrue(v is value2) def test_weak_valued_dict_popitem(self): self.check_popitem(weakref.WeakValueDictionary, "key1", C(), "key2", C()) def test_weak_keyed_dict_popitem(self): self.check_popitem(weakref.WeakKeyDictionary, C(), "value 1", C(), "value 2") def check_setdefault(self, klass, key, value1, value2): self.assertTrue(value1 is not value2, "invalid test" " -- value parameters must be distinct objects") weakdict = klass() o = weakdict.setdefault(key, value1) self.assertIs(o, value1) self.assertIn(key, weakdict) self.assertIs(weakdict.get(key), value1) self.assertIs(weakdict[key], value1) o = weakdict.setdefault(key, value2) self.assertIs(o, value1) self.assertIn(key, weakdict) self.assertIs(weakdict.get(key), value1) self.assertIs(weakdict[key], value1) def test_weak_valued_dict_setdefault(self): self.check_setdefault(weakref.WeakValueDictionary, "key", C(), C()) def test_weak_keyed_dict_setdefault(self): self.check_setdefault(weakref.WeakKeyDictionary, C(), "value 1", "value 2") def check_update(self, klass, dict): # # This exercises d.update(), len(d), d.keys(), in d, # d.get(), d[]. # weakdict = klass() weakdict.update(dict) self.assertEqual(len(weakdict), len(dict)) for k in weakdict.keys(): self.assertIn(k, dict, "mysterious new key appeared in weak dict") v = dict.get(k) self.assertIs(v, weakdict[k]) self.assertIs(v, weakdict.get(k)) for k in dict.keys(): self.assertIn(k, weakdict, "original key disappeared in weak dict") v = dict[k] self.assertIs(v, weakdict[k]) self.assertIs(v, weakdict.get(k)) def test_weak_valued_dict_update(self): self.check_update(weakref.WeakValueDictionary, {1: C(), 'a': C(), C(): C()}) def test_weak_keyed_dict_update(self): self.check_update(weakref.WeakKeyDictionary, {C(): 1, C(): 2, C(): 3}) def test_weak_keyed_delitem(self): d = weakref.WeakKeyDictionary() o1 = Object('1') o2 = Object('2') d[o1] = 'something' d[o2] = 'something' self.assertTrue(len(d) == 2) del d[o1] self.assertTrue(len(d) == 1) self.assertTrue(d.keys() == [o2]) def test_weak_valued_delitem(self): d = weakref.WeakValueDictionary() o1 = Object('1') o2 = Object('2') d['something'] = o1 d['something else'] = o2 self.assertTrue(len(d) == 2) del d['something'] self.assertTrue(len(d) == 1) self.assertTrue(d.items() == [('something else', o2)]) def test_weak_keyed_bad_delitem(self): d = weakref.WeakKeyDictionary() o = Object('1') # An attempt to delete an object that isn't there should raise # KeyError. It didn't before 2.3. self.assertRaises(KeyError, d.__delitem__, o) self.assertRaises(KeyError, d.__getitem__, o) # If a key isn't of a weakly referencable type, __getitem__ and # __setitem__ raise TypeError. __delitem__ should too. self.assertRaises(TypeError, d.__delitem__, 13) self.assertRaises(TypeError, d.__getitem__, 13) self.assertRaises(TypeError, d.__setitem__, 13, 13) def test_weak_keyed_cascading_deletes(self): # SF bug 742860. For some reason, before 2.3 __delitem__ iterated # over the keys via self.data.iterkeys(). If things vanished from # the dict during this (or got added), that caused a RuntimeError. d = weakref.WeakKeyDictionary() mutate = False class C(object): def __init__(self, i): self.value = i def __hash__(self): return hash(self.value) def __eq__(self, other): if mutate: # Side effect that mutates the dict, by removing the # last strong reference to a key. del objs[-1] return self.value == other.value objs = [C(i) for i in range(4)] for o in objs: d[o] = o.value del o # now the only strong references to keys are in objs # Find the order in which iterkeys sees the keys. objs = d.keys() # Reverse it, so that the iteration implementation of __delitem__ # has to keep looping to find the first object we delete. objs.reverse() # Turn on mutation in C.__eq__. The first time thru the loop, # under the iterkeys() business the first comparison will delete # the last item iterkeys() would see, and that causes a # RuntimeError: dictionary changed size during iteration # when the iterkeys() loop goes around to try comparing the next # key. After this was fixed, it just deletes the last object *our* # "for o in obj" loop would have gotten to. mutate = True count = 0 for o in objs: count += 1 del d[o] self.assertEqual(len(d), 0) self.assertEqual(count, 2) from test import mapping_tests class WeakValueDictionaryTestCase(mapping_tests.BasicTestMappingProtocol): """Check that WeakValueDictionary conforms to the mapping protocol""" __ref = {"key1":Object(1), "key2":Object(2), "key3":Object(3)} type2test = weakref.WeakValueDictionary def _reference(self): return self.__ref.copy() class WeakKeyDictionaryTestCase(mapping_tests.BasicTestMappingProtocol): """Check that WeakKeyDictionary conforms to the mapping protocol""" __ref = {Object("key1"):1, Object("key2"):2, Object("key3"):3} type2test = weakref.WeakKeyDictionary def _reference(self): return self.__ref.copy() libreftest = """ Doctest for examples in the library reference: weakref.rst >>> import weakref >>> class Dict(dict): ... pass ... >>> obj = Dict(red=1, green=2, blue=3) # this object is weak referencable >>> r = weakref.ref(obj) >>> print r() is obj True >>> import weakref >>> class Object: ... pass ... >>> o = Object() >>> r = weakref.ref(o) >>> o2 = r() >>> o is o2 True >>> del o, o2 >>> print r() None >>> import weakref >>> class ExtendedRef(weakref.ref): ... def __init__(self, ob, callback=None, **annotations): ... super(ExtendedRef, self).__init__(ob, callback) ... self.__counter = 0 ... for k, v in annotations.iteritems(): ... setattr(self, k, v) ... def __call__(self): ... '''Return a pair containing the referent and the number of ... times the reference has been called. ... ''' ... ob = super(ExtendedRef, self).__call__() ... if ob is not None: ... self.__counter += 1 ... ob = (ob, self.__counter) ... return ob ... >>> class A: # not in docs from here, just testing the ExtendedRef ... pass ... >>> a = A() >>> r = ExtendedRef(a, foo=1, bar="baz") >>> r.foo 1 >>> r.bar 'baz' >>> r()[1] 1 >>> r()[1] 2 >>> r()[0] is a True >>> import weakref >>> _id2obj_dict = weakref.WeakValueDictionary() >>> def remember(obj): ... oid = id(obj) ... _id2obj_dict[oid] = obj ... return oid ... >>> def id2obj(oid): ... return _id2obj_dict[oid] ... >>> a = A() # from here, just testing >>> a_id = remember(a) >>> id2obj(a_id) is a True >>> del a >>> try: ... id2obj(a_id) ... except KeyError: ... print 'OK' ... else: ... print 'WeakValueDictionary error' OK """ __test__ = {'libreftest' : libreftest} def test_main(): test_support.run_unittest( ReferencesTestCase, MappingTestCase, WeakValueDictionaryTestCase, WeakKeyDictionaryTestCase, SubclassableWeakrefTestCase, ) test_support.run_doctest(sys.modules[__name__]) if __name__ == "__main__": test_main()