from __future__ import unicode_literals from django.db import IntegrityError, connection, transaction from django.test import TestCase from .models import ( Bar, Director, Favorites, HiddenPointer, ManualPrimaryKey, MultiModel, Place, RelatedModel, Restaurant, School, Target, UndergroundBar, Waiter, ) class OneToOneTests(TestCase): def setUp(self): self.p1 = Place.objects.create(name='Demon Dogs', address='944 W. Fullerton') self.p2 = Place.objects.create(name='Ace Hardware', address='1013 N. Ashland') self.r1 = Restaurant.objects.create(place=self.p1, serves_hot_dogs=True, serves_pizza=False) self.b1 = Bar.objects.create(place=self.p1, serves_cocktails=False) def test_getter(self): # A Restaurant can access its place. self.assertEqual(repr(self.r1.place), '') # A Place can access its restaurant, if available. self.assertEqual(repr(self.p1.restaurant), '') # p2 doesn't have an associated restaurant. with self.assertRaisesMessage(Restaurant.DoesNotExist, 'Place has no restaurant'): self.p2.restaurant # The exception raised on attribute access when a related object # doesn't exist should be an instance of a subclass of `AttributeError` # refs #21563 self.assertFalse(hasattr(self.p2, 'restaurant')) def test_setter(self): # Set the place using assignment notation. Because place is the primary # key on Restaurant, the save will create a new restaurant self.r1.place = self.p2 self.r1.save() self.assertEqual(repr(self.p2.restaurant), '') self.assertEqual(repr(self.r1.place), '') self.assertEqual(self.p2.pk, self.r1.pk) # Set the place back again, using assignment in the reverse direction. self.p1.restaurant = self.r1 self.assertEqual(repr(self.p1.restaurant), '') r = Restaurant.objects.get(pk=self.p1.id) self.assertEqual(repr(r.place), '') def test_manager_all(self): # Restaurant.objects.all() just returns the Restaurants, not the Places. self.assertQuerysetEqual(Restaurant.objects.all(), [ '', ]) # Place.objects.all() returns all Places, regardless of whether they # have Restaurants. self.assertQuerysetEqual(Place.objects.order_by('name'), [ '', '', ]) def test_manager_get(self): def assert_get_restaurant(**params): self.assertEqual(repr(Restaurant.objects.get(**params)), '') assert_get_restaurant(place__id__exact=self.p1.pk) assert_get_restaurant(place__id=self.p1.pk) assert_get_restaurant(place__exact=self.p1.pk) assert_get_restaurant(place__exact=self.p1) assert_get_restaurant(place=self.p1.pk) assert_get_restaurant(place=self.p1) assert_get_restaurant(pk=self.p1.pk) assert_get_restaurant(place__pk__exact=self.p1.pk) assert_get_restaurant(place__pk=self.p1.pk) assert_get_restaurant(place__name__startswith="Demon") def assert_get_place(**params): self.assertEqual(repr(Place.objects.get(**params)), '') assert_get_place(restaurant__place__exact=self.p1.pk) assert_get_place(restaurant__place__exact=self.p1) assert_get_place(restaurant__place__pk=self.p1.pk) assert_get_place(restaurant__exact=self.p1.pk) assert_get_place(restaurant__exact=self.r1) assert_get_place(restaurant__pk=self.p1.pk) assert_get_place(restaurant=self.p1.pk) assert_get_place(restaurant=self.r1) assert_get_place(id__exact=self.p1.pk) assert_get_place(pk=self.p1.pk) def test_foreign_key(self): # Add a Waiter to the Restaurant. w = self.r1.waiter_set.create(name='Joe') self.assertEqual(repr(w), '') # Query the waiters def assert_filter_waiters(**params): self.assertQuerysetEqual(Waiter.objects.filter(**params), [ '' ]) assert_filter_waiters(restaurant__place__exact=self.p1.pk) assert_filter_waiters(restaurant__place__exact=self.p1) assert_filter_waiters(restaurant__place__pk=self.p1.pk) assert_filter_waiters(restaurant__exact=self.r1.pk) assert_filter_waiters(restaurant__exact=self.r1) assert_filter_waiters(restaurant__pk=self.r1.pk) assert_filter_waiters(restaurant=self.r1.pk) assert_filter_waiters(restaurant=self.r1) assert_filter_waiters(id__exact=w.pk) assert_filter_waiters(pk=w.pk) # Delete the restaurant; the waiter should also be removed r = Restaurant.objects.get(pk=self.r1.pk) r.delete() self.assertEqual(Waiter.objects.count(), 0) def test_multiple_o2o(self): # One-to-one fields still work if you create your own primary key o1 = ManualPrimaryKey(primary_key="abc123", name="primary") o1.save() o2 = RelatedModel(link=o1, name="secondary") o2.save() # You can have multiple one-to-one fields on a model, too. x1 = MultiModel(link1=self.p1, link2=o1, name="x1") x1.save() self.assertEqual(repr(o1.multimodel), '') # This will fail because each one-to-one field must be unique (and # link2=o1 was used for x1, above). mm = MultiModel(link1=self.p2, link2=o1, name="x1") with self.assertRaises(IntegrityError): with transaction.atomic(): mm.save() def test_unsaved_object(self): """ #10811 -- Assigning an unsaved object to a OneToOneField should raise an exception. """ place = Place(name='User', address='London') with self.assertRaisesMessage(ValueError, 'Cannot assign "%r": "%s" instance isn\'t saved in the database.' % (place, Restaurant.place.field.rel.to._meta.object_name)): Restaurant.objects.create(place=place, serves_hot_dogs=True, serves_pizza=False) bar = UndergroundBar() p = Place(name='User', address='London') with self.assertRaisesMessage(ValueError, 'Cannot assign "%r": "%s" instance isn\'t saved in the database.' % (bar, p._meta.object_name)): p.undergroundbar = bar def test_reverse_relationship_cache_cascade(self): """ Regression test for #9023: accessing the reverse relationship shouldn't result in a cascading delete(). """ bar = UndergroundBar.objects.create(place=self.p1, serves_cocktails=False) # The bug in #9023: if you access the one-to-one relation *before* # setting to None and deleting, the cascade happens anyway. self.p1.undergroundbar bar.place.name = 'foo' bar.place = None bar.save() self.p1.delete() self.assertEqual(Place.objects.all().count(), 1) self.assertEqual(UndergroundBar.objects.all().count(), 1) def test_create_models_m2m(self): """ Regression test for #1064 and #1506 Check that we create models via the m2m relation if the remote model has a OneToOneField. """ f = Favorites(name='Fred') f.save() f.restaurants = [self.r1] self.assertQuerysetEqual( f.restaurants.all(), [''] ) def test_reverse_object_cache(self): """ Regression test for #7173 Check that the name of the cache for the reverse object is correct. """ self.assertEqual(self.p1.restaurant, self.r1) self.assertEqual(self.p1.bar, self.b1) def test_related_object_cache(self): """ Regression test for #6886 (the related-object cache) """ # Look up the objects again so that we get "fresh" objects p = Place.objects.get(name="Demon Dogs") r = p.restaurant # Accessing the related object again returns the exactly same object self.assertIs(p.restaurant, r) # But if we kill the cache, we get a new object del p._restaurant_cache self.assertIsNot(p.restaurant, r) # Reassigning the Restaurant object results in an immediate cache update # We can't use a new Restaurant because that'll violate one-to-one, but # with a new *instance* the is test below will fail if #6886 regresses. r2 = Restaurant.objects.get(pk=r.pk) p.restaurant = r2 self.assertIs(p.restaurant, r2) # Assigning None succeeds if field is null=True. ug_bar = UndergroundBar.objects.create(place=p, serves_cocktails=False) ug_bar.place = None self.assertIsNone(ug_bar.place) # Assigning None fails: Place.restaurant is null=False self.assertRaises(ValueError, setattr, p, 'restaurant', None) # You also can't assign an object of the wrong type here self.assertRaises(ValueError, setattr, p, 'restaurant', p) # Creation using keyword argument should cache the related object. p = Place.objects.get(name="Demon Dogs") r = Restaurant(place=p) self.assertIs(r.place, p) # Creation using attname keyword argument and an id will cause the related # object to be fetched. p = Place.objects.get(name="Demon Dogs") r = Restaurant(place_id=p.id) self.assertIsNot(r.place, p) self.assertEqual(r.place, p) def test_filter_one_to_one_relations(self): """ Regression test for #9968 filtering reverse one-to-one relations with primary_key=True was misbehaving. We test both (primary_key=True & False) cases here to prevent any reappearance of the problem. """ Target.objects.create() self.assertQuerysetEqual( Target.objects.filter(pointer=None), [''] ) self.assertQuerysetEqual( Target.objects.exclude(pointer=None), [] ) self.assertQuerysetEqual( Target.objects.filter(second_pointer=None), [''] ) self.assertQuerysetEqual( Target.objects.exclude(second_pointer=None), [] ) def test_reverse_object_does_not_exist_cache(self): """ Regression for #13839 and #17439. DoesNotExist on a reverse one-to-one relation is cached. """ p = Place(name='Zombie Cats', address='Not sure') p.save() with self.assertNumQueries(1): with self.assertRaises(Restaurant.DoesNotExist): p.restaurant with self.assertNumQueries(0): with self.assertRaises(Restaurant.DoesNotExist): p.restaurant def test_reverse_object_cached_when_related_is_accessed(self): """ Regression for #13839 and #17439. The target of a one-to-one relation is cached when the origin is accessed through the reverse relation. """ # Use a fresh object without caches r = Restaurant.objects.get(pk=self.r1.pk) p = r.place with self.assertNumQueries(0): self.assertEqual(p.restaurant, r) def test_related_object_cached_when_reverse_is_accessed(self): """ Regression for #13839 and #17439. The origin of a one-to-one relation is cached when the target is accessed through the reverse relation. """ # Use a fresh object without caches p = Place.objects.get(pk=self.p1.pk) r = p.restaurant with self.assertNumQueries(0): self.assertEqual(r.place, p) def test_reverse_object_cached_when_related_is_set(self): """ Regression for #13839 and #17439. The target of a one-to-one relation is always cached. """ p = Place(name='Zombie Cats', address='Not sure') p.save() self.r1.place = p self.r1.save() with self.assertNumQueries(0): self.assertEqual(p.restaurant, self.r1) def test_reverse_object_cached_when_related_is_unset(self): """ Regression for #13839 and #17439. The target of a one-to-one relation is always cached. """ b = UndergroundBar(place=self.p1, serves_cocktails=True) b.save() with self.assertNumQueries(0): self.assertEqual(self.p1.undergroundbar, b) b.place = None b.save() with self.assertNumQueries(0): with self.assertRaises(UndergroundBar.DoesNotExist): self.p1.undergroundbar def test_get_reverse_on_unsaved_object(self): """ Regression for #18153 and #19089. Accessing the reverse relation on an unsaved object always raises an exception. """ p = Place() # When there's no instance of the origin of the one-to-one with self.assertNumQueries(0): with self.assertRaises(UndergroundBar.DoesNotExist): p.undergroundbar UndergroundBar.objects.create() # When there's one instance of the origin # (p.undergroundbar used to return that instance) with self.assertNumQueries(0): with self.assertRaises(UndergroundBar.DoesNotExist): p.undergroundbar # Several instances of the origin are only possible if database allows # inserting multiple NULL rows for a unique constraint if connection.features.supports_nullable_unique_constraints: UndergroundBar.objects.create() # When there are several instances of the origin with self.assertNumQueries(0): with self.assertRaises(UndergroundBar.DoesNotExist): p.undergroundbar def test_set_reverse_on_unsaved_object(self): """ Writing to the reverse relation on an unsaved object is impossible too. """ p = Place() b = UndergroundBar.objects.create() with self.assertNumQueries(0): with self.assertRaises(ValueError): p.undergroundbar = b def test_nullable_o2o_delete(self): u = UndergroundBar.objects.create(place=self.p1) u.place_id = None u.save() self.p1.delete() self.assertTrue(UndergroundBar.objects.filter(pk=u.pk).exists()) self.assertIsNone(UndergroundBar.objects.get(pk=u.pk).place) def test_hidden_accessor(self): """ When a '+' ending related name is specified no reverse accessor should be added to the related model. """ self.assertFalse( hasattr(Target, HiddenPointer._meta.get_field('target').rel.get_accessor_name()) ) def test_related_object(self): public_school = School.objects.create(is_public=True) public_director = Director.objects.create(school=public_school, is_temp=False) private_school = School.objects.create(is_public=False) private_director = Director.objects.create(school=private_school, is_temp=True) # Only one school is available via all() due to the custom default manager. self.assertQuerysetEqual( School.objects.all(), [""] ) # Only one director is available via all() due to the custom default manager. self.assertQuerysetEqual( Director.objects.all(), [""] ) self.assertEqual(public_director.school, public_school) self.assertEqual(public_school.director, public_director) # Make sure the base manager is used so that the related objects # is still accessible even if the default manager doesn't normally # allow it. self.assertEqual(private_director.school, private_school) # Make sure the base manager is used so that an student can still access # its related school even if the default manager doesn't normally # allow it. self.assertEqual(private_school.director, private_director) # If the manager is marked "use_for_related_fields", it'll get used instead # of the "bare" queryset. Usually you'd define this as a property on the class, # but this approximates that in a way that's easier in tests. School.objects.use_for_related_fields = True try: private_director = Director._base_manager.get(pk=private_director.pk) self.assertRaises(School.DoesNotExist, lambda: private_director.school) finally: School.objects.use_for_related_fields = False Director.objects.use_for_related_fields = True try: private_school = School._base_manager.get(pk=private_school.pk) self.assertRaises(Director.DoesNotExist, lambda: private_school.director) finally: Director.objects.use_for_related_fields = False def test_hasattr_related_object(self): # The exception raised on attribute access when a related object # doesn't exist should be an instance of a subclass of `AttributeError` # refs #21563 self.assertFalse(hasattr(Director(), 'director')) self.assertFalse(hasattr(School(), 'school'))