1:mod:`unittest.mock` --- getting started
2========================================
3
4.. moduleauthor:: Michael Foord <michael@python.org>
5.. currentmodule:: unittest.mock
6
7.. versionadded:: 3.3
8
9
10.. _getting-started:
11
12
13.. testsetup::
14
15    import asyncio
16    import unittest
17    from unittest.mock import Mock, MagicMock, AsyncMock, patch, call, sentinel
18
19    class SomeClass:
20        attribute = 'this is a doctest'
21
22        @staticmethod
23        def static_method():
24            pass
25
26Using Mock
27----------
28
29Mock Patching Methods
30~~~~~~~~~~~~~~~~~~~~~
31
32Common uses for :class:`Mock` objects include:
33
34* Patching methods
35* Recording method calls on objects
36
37You might want to replace a method on an object to check that
38it is called with the correct arguments by another part of the system:
39
40    >>> real = SomeClass()
41    >>> real.method = MagicMock(name='method')
42    >>> real.method(3, 4, 5, key='value')
43    <MagicMock name='method()' id='...'>
44
45Once our mock has been used (``real.method`` in this example) it has methods
46and attributes that allow you to make assertions about how it has been used.
47
48.. note::
49
50    In most of these examples the :class:`Mock` and :class:`MagicMock` classes
51    are interchangeable. As the ``MagicMock`` is the more capable class it makes
52    a sensible one to use by default.
53
54Once the mock has been called its :attr:`~Mock.called` attribute is set to
55``True``. More importantly we can use the :meth:`~Mock.assert_called_with` or
56:meth:`~Mock.assert_called_once_with` method to check that it was called with
57the correct arguments.
58
59This example tests that calling ``ProductionClass().method`` results in a call to
60the ``something`` method:
61
62    >>> class ProductionClass:
63    ...     def method(self):
64    ...         self.something(1, 2, 3)
65    ...     def something(self, a, b, c):
66    ...         pass
67    ...
68    >>> real = ProductionClass()
69    >>> real.something = MagicMock()
70    >>> real.method()
71    >>> real.something.assert_called_once_with(1, 2, 3)
72
73
74
75Mock for Method Calls on an Object
76~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
77
78In the last example we patched a method directly on an object to check that it
79was called correctly. Another common use case is to pass an object into a
80method (or some part of the system under test) and then check that it is used
81in the correct way.
82
83The simple ``ProductionClass`` below has a ``closer`` method. If it is called with
84an object then it calls ``close`` on it.
85
86    >>> class ProductionClass:
87    ...     def closer(self, something):
88    ...         something.close()
89    ...
90
91So to test it we need to pass in an object with a ``close`` method and check
92that it was called correctly.
93
94    >>> real = ProductionClass()
95    >>> mock = Mock()
96    >>> real.closer(mock)
97    >>> mock.close.assert_called_with()
98
99We don't have to do any work to provide the 'close' method on our mock.
100Accessing close creates it. So, if 'close' hasn't already been called then
101accessing it in the test will create it, but :meth:`~Mock.assert_called_with`
102will raise a failure exception.
103
104
105Mocking Classes
106~~~~~~~~~~~~~~~
107
108A common use case is to mock out classes instantiated by your code under test.
109When you patch a class, then that class is replaced with a mock. Instances
110are created by *calling the class*. This means you access the "mock instance"
111by looking at the return value of the mocked class.
112
113In the example below we have a function ``some_function`` that instantiates ``Foo``
114and calls a method on it. The call to :func:`patch` replaces the class ``Foo`` with a
115mock. The ``Foo`` instance is the result of calling the mock, so it is configured
116by modifying the mock :attr:`~Mock.return_value`. ::
117
118    >>> def some_function():
119    ...     instance = module.Foo()
120    ...     return instance.method()
121    ...
122    >>> with patch('module.Foo') as mock:
123    ...     instance = mock.return_value
124    ...     instance.method.return_value = 'the result'
125    ...     result = some_function()
126    ...     assert result == 'the result'
127
128
129Naming your mocks
130~~~~~~~~~~~~~~~~~
131
132It can be useful to give your mocks a name. The name is shown in the repr of
133the mock and can be helpful when the mock appears in test failure messages. The
134name is also propagated to attributes or methods of the mock:
135
136    >>> mock = MagicMock(name='foo')
137    >>> mock
138    <MagicMock name='foo' id='...'>
139    >>> mock.method
140    <MagicMock name='foo.method' id='...'>
141
142
143Tracking all Calls
144~~~~~~~~~~~~~~~~~~
145
146Often you want to track more than a single call to a method. The
147:attr:`~Mock.mock_calls` attribute records all calls
148to child attributes of the mock - and also to their children.
149
150    >>> mock = MagicMock()
151    >>> mock.method()
152    <MagicMock name='mock.method()' id='...'>
153    >>> mock.attribute.method(10, x=53)
154    <MagicMock name='mock.attribute.method()' id='...'>
155    >>> mock.mock_calls
156    [call.method(), call.attribute.method(10, x=53)]
157
158If you make an assertion about ``mock_calls`` and any unexpected methods
159have been called, then the assertion will fail. This is useful because as well
160as asserting that the calls you expected have been made, you are also checking
161that they were made in the right order and with no additional calls:
162
163You use the :data:`call` object to construct lists for comparing with
164``mock_calls``:
165
166    >>> expected = [call.method(), call.attribute.method(10, x=53)]
167    >>> mock.mock_calls == expected
168    True
169
170However, parameters to calls that return mocks are not recorded, which means it is not
171possible to track nested calls where the parameters used to create ancestors are important:
172
173    >>> m = Mock()
174    >>> m.factory(important=True).deliver()
175    <Mock name='mock.factory().deliver()' id='...'>
176    >>> m.mock_calls[-1] == call.factory(important=False).deliver()
177    True
178
179
180Setting Return Values and Attributes
181~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
182
183Setting the return values on a mock object is trivially easy:
184
185    >>> mock = Mock()
186    >>> mock.return_value = 3
187    >>> mock()
188    3
189
190Of course you can do the same for methods on the mock:
191
192    >>> mock = Mock()
193    >>> mock.method.return_value = 3
194    >>> mock.method()
195    3
196
197The return value can also be set in the constructor:
198
199    >>> mock = Mock(return_value=3)
200    >>> mock()
201    3
202
203If you need an attribute setting on your mock, just do it:
204
205    >>> mock = Mock()
206    >>> mock.x = 3
207    >>> mock.x
208    3
209
210Sometimes you want to mock up a more complex situation, like for example
211``mock.connection.cursor().execute("SELECT 1")``. If we wanted this call to
212return a list, then we have to configure the result of the nested call.
213
214We can use :data:`call` to construct the set of calls in a "chained call" like
215this for easy assertion afterwards:
216
217    >>> mock = Mock()
218    >>> cursor = mock.connection.cursor.return_value
219    >>> cursor.execute.return_value = ['foo']
220    >>> mock.connection.cursor().execute("SELECT 1")
221    ['foo']
222    >>> expected = call.connection.cursor().execute("SELECT 1").call_list()
223    >>> mock.mock_calls
224    [call.connection.cursor(), call.connection.cursor().execute('SELECT 1')]
225    >>> mock.mock_calls == expected
226    True
227
228It is the call to ``.call_list()`` that turns our call object into a list of
229calls representing the chained calls.
230
231
232Raising exceptions with mocks
233~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
234
235A useful attribute is :attr:`~Mock.side_effect`. If you set this to an
236exception class or instance then the exception will be raised when the mock
237is called.
238
239    >>> mock = Mock(side_effect=Exception('Boom!'))
240    >>> mock()
241    Traceback (most recent call last):
242      ...
243    Exception: Boom!
244
245
246Side effect functions and iterables
247~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
248
249``side_effect`` can also be set to a function or an iterable. The use case for
250``side_effect`` as an iterable is where your mock is going to be called several
251times, and you want each call to return a different value. When you set
252``side_effect`` to an iterable every call to the mock returns the next value
253from the iterable:
254
255    >>> mock = MagicMock(side_effect=[4, 5, 6])
256    >>> mock()
257    4
258    >>> mock()
259    5
260    >>> mock()
261    6
262
263
264For more advanced use cases, like dynamically varying the return values
265depending on what the mock is called with, ``side_effect`` can be a function.
266The function will be called with the same arguments as the mock. Whatever the
267function returns is what the call returns:
268
269    >>> vals = {(1, 2): 1, (2, 3): 2}
270    >>> def side_effect(*args):
271    ...     return vals[args]
272    ...
273    >>> mock = MagicMock(side_effect=side_effect)
274    >>> mock(1, 2)
275    1
276    >>> mock(2, 3)
277    2
278
279
280Mocking asynchronous iterators
281~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
282
283Since Python 3.8, ``AsyncMock`` and ``MagicMock`` have support to mock
284:ref:`async-iterators` through ``__aiter__``. The :attr:`~Mock.return_value`
285attribute of ``__aiter__`` can be used to set the return values to be used for
286iteration.
287
288    >>> mock = MagicMock()  # AsyncMock also works here
289    >>> mock.__aiter__.return_value = [1, 2, 3]
290    >>> async def main():
291    ...     return [i async for i in mock]
292    ...
293    >>> asyncio.run(main())
294    [1, 2, 3]
295
296
297Mocking asynchronous context manager
298~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
299
300Since Python 3.8, ``AsyncMock`` and ``MagicMock`` have support to mock
301:ref:`async-context-managers` through ``__aenter__`` and ``__aexit__``.
302By default, ``__aenter__`` and ``__aexit__`` are ``AsyncMock`` instances that
303return an async function.
304
305    >>> class AsyncContextManager:
306    ...     async def __aenter__(self):
307    ...         return self
308    ...     async def __aexit__(self, exc_type, exc, tb):
309    ...         pass
310    ...
311    >>> mock_instance = MagicMock(AsyncContextManager())  # AsyncMock also works here
312    >>> async def main():
313    ...     async with mock_instance as result:
314    ...         pass
315    ...
316    >>> asyncio.run(main())
317    >>> mock_instance.__aenter__.assert_awaited_once()
318    >>> mock_instance.__aexit__.assert_awaited_once()
319
320
321Creating a Mock from an Existing Object
322~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
323
324One problem with over use of mocking is that it couples your tests to the
325implementation of your mocks rather than your real code. Suppose you have a
326class that implements ``some_method``. In a test for another class, you
327provide a mock of this object that *also* provides ``some_method``. If later
328you refactor the first class, so that it no longer has ``some_method`` - then
329your tests will continue to pass even though your code is now broken!
330
331:class:`Mock` allows you to provide an object as a specification for the mock,
332using the *spec* keyword argument. Accessing methods / attributes on the
333mock that don't exist on your specification object will immediately raise an
334attribute error. If you change the implementation of your specification, then
335tests that use that class will start failing immediately without you having to
336instantiate the class in those tests.
337
338    >>> mock = Mock(spec=SomeClass)
339    >>> mock.old_method()
340    Traceback (most recent call last):
341       ...
342    AttributeError: object has no attribute 'old_method'
343
344Using a specification also enables a smarter matching of calls made to the
345mock, regardless of whether some parameters were passed as positional or
346named arguments::
347
348   >>> def f(a, b, c): pass
349   ...
350   >>> mock = Mock(spec=f)
351   >>> mock(1, 2, 3)
352   <Mock name='mock()' id='140161580456576'>
353   >>> mock.assert_called_with(a=1, b=2, c=3)
354
355If you want this smarter matching to also work with method calls on the mock,
356you can use :ref:`auto-speccing <auto-speccing>`.
357
358If you want a stronger form of specification that prevents the setting
359of arbitrary attributes as well as the getting of them then you can use
360*spec_set* instead of *spec*.
361
362
363
364Patch Decorators
365----------------
366
367.. note::
368
369   With :func:`patch` it matters that you patch objects in the namespace where
370   they are looked up. This is normally straightforward, but for a quick guide
371   read :ref:`where to patch <where-to-patch>`.
372
373
374A common need in tests is to patch a class attribute or a module attribute,
375for example patching a builtin or patching a class in a module to test that it
376is instantiated. Modules and classes are effectively global, so patching on
377them has to be undone after the test or the patch will persist into other
378tests and cause hard to diagnose problems.
379
380mock provides three convenient decorators for this: :func:`patch`, :func:`patch.object` and
381:func:`patch.dict`. ``patch`` takes a single string, of the form
382``package.module.Class.attribute`` to specify the attribute you are patching. It
383also optionally takes a value that you want the attribute (or class or
384whatever) to be replaced with. 'patch.object' takes an object and the name of
385the attribute you would like patched, plus optionally the value to patch it
386with.
387
388``patch.object``::
389
390    >>> original = SomeClass.attribute
391    >>> @patch.object(SomeClass, 'attribute', sentinel.attribute)
392    ... def test():
393    ...     assert SomeClass.attribute == sentinel.attribute
394    ...
395    >>> test()
396    >>> assert SomeClass.attribute == original
397
398    >>> @patch('package.module.attribute', sentinel.attribute)
399    ... def test():
400    ...     from package.module import attribute
401    ...     assert attribute is sentinel.attribute
402    ...
403    >>> test()
404
405If you are patching a module (including :mod:`builtins`) then use :func:`patch`
406instead of :func:`patch.object`:
407
408    >>> mock = MagicMock(return_value=sentinel.file_handle)
409    >>> with patch('builtins.open', mock):
410    ...     handle = open('filename', 'r')
411    ...
412    >>> mock.assert_called_with('filename', 'r')
413    >>> assert handle == sentinel.file_handle, "incorrect file handle returned"
414
415The module name can be 'dotted', in the form ``package.module`` if needed::
416
417    >>> @patch('package.module.ClassName.attribute', sentinel.attribute)
418    ... def test():
419    ...     from package.module import ClassName
420    ...     assert ClassName.attribute == sentinel.attribute
421    ...
422    >>> test()
423
424A nice pattern is to actually decorate test methods themselves:
425
426    >>> class MyTest(unittest.TestCase):
427    ...     @patch.object(SomeClass, 'attribute', sentinel.attribute)
428    ...     def test_something(self):
429    ...         self.assertEqual(SomeClass.attribute, sentinel.attribute)
430    ...
431    >>> original = SomeClass.attribute
432    >>> MyTest('test_something').test_something()
433    >>> assert SomeClass.attribute == original
434
435If you want to patch with a Mock, you can use :func:`patch` with only one argument
436(or :func:`patch.object` with two arguments). The mock will be created for you and
437passed into the test function / method:
438
439    >>> class MyTest(unittest.TestCase):
440    ...     @patch.object(SomeClass, 'static_method')
441    ...     def test_something(self, mock_method):
442    ...         SomeClass.static_method()
443    ...         mock_method.assert_called_with()
444    ...
445    >>> MyTest('test_something').test_something()
446
447You can stack up multiple patch decorators using this pattern::
448
449    >>> class MyTest(unittest.TestCase):
450    ...     @patch('package.module.ClassName1')
451    ...     @patch('package.module.ClassName2')
452    ...     def test_something(self, MockClass2, MockClass1):
453    ...         self.assertIs(package.module.ClassName1, MockClass1)
454    ...         self.assertIs(package.module.ClassName2, MockClass2)
455    ...
456    >>> MyTest('test_something').test_something()
457
458When you nest patch decorators the mocks are passed in to the decorated
459function in the same order they applied (the normal *Python* order that
460decorators are applied). This means from the bottom up, so in the example
461above the mock for ``test_module.ClassName2`` is passed in first.
462
463There is also :func:`patch.dict` for setting values in a dictionary just
464during a scope and restoring the dictionary to its original state when the test
465ends:
466
467   >>> foo = {'key': 'value'}
468   >>> original = foo.copy()
469   >>> with patch.dict(foo, {'newkey': 'newvalue'}, clear=True):
470   ...     assert foo == {'newkey': 'newvalue'}
471   ...
472   >>> assert foo == original
473
474``patch``, ``patch.object`` and ``patch.dict`` can all be used as context managers.
475
476Where you use :func:`patch` to create a mock for you, you can get a reference to the
477mock using the "as" form of the with statement:
478
479    >>> class ProductionClass:
480    ...     def method(self):
481    ...         pass
482    ...
483    >>> with patch.object(ProductionClass, 'method') as mock_method:
484    ...     mock_method.return_value = None
485    ...     real = ProductionClass()
486    ...     real.method(1, 2, 3)
487    ...
488    >>> mock_method.assert_called_with(1, 2, 3)
489
490
491As an alternative ``patch``, ``patch.object`` and ``patch.dict`` can be used as
492class decorators. When used in this way it is the same as applying the
493decorator individually to every method whose name starts with "test".
494
495
496.. _further-examples:
497
498Further Examples
499----------------
500
501
502Here are some more examples for some slightly more advanced scenarios.
503
504
505Mocking chained calls
506~~~~~~~~~~~~~~~~~~~~~
507
508Mocking chained calls is actually straightforward with mock once you
509understand the :attr:`~Mock.return_value` attribute. When a mock is called for
510the first time, or you fetch its ``return_value`` before it has been called, a
511new :class:`Mock` is created.
512
513This means that you can see how the object returned from a call to a mocked
514object has been used by interrogating the ``return_value`` mock:
515
516    >>> mock = Mock()
517    >>> mock().foo(a=2, b=3)
518    <Mock name='mock().foo()' id='...'>
519    >>> mock.return_value.foo.assert_called_with(a=2, b=3)
520
521From here it is a simple step to configure and then make assertions about
522chained calls. Of course another alternative is writing your code in a more
523testable way in the first place...
524
525So, suppose we have some code that looks a little bit like this:
526
527    >>> class Something:
528    ...     def __init__(self):
529    ...         self.backend = BackendProvider()
530    ...     def method(self):
531    ...         response = self.backend.get_endpoint('foobar').create_call('spam', 'eggs').start_call()
532    ...         # more code
533
534Assuming that ``BackendProvider`` is already well tested, how do we test
535``method()``? Specifically, we want to test that the code section ``# more
536code`` uses the response object in the correct way.
537
538As this chain of calls is made from an instance attribute we can monkey patch
539the ``backend`` attribute on a ``Something`` instance. In this particular case
540we are only interested in the return value from the final call to
541``start_call`` so we don't have much configuration to do. Let's assume the
542object it returns is 'file-like', so we'll ensure that our response object
543uses the builtin :func:`open` as its ``spec``.
544
545To do this we create a mock instance as our mock backend and create a mock
546response object for it. To set the response as the return value for that final
547``start_call`` we could do this::
548
549    mock_backend.get_endpoint.return_value.create_call.return_value.start_call.return_value = mock_response
550
551We can do that in a slightly nicer way using the :meth:`~Mock.configure_mock`
552method to directly set the return value for us::
553
554    >>> something = Something()
555    >>> mock_response = Mock(spec=open)
556    >>> mock_backend = Mock()
557    >>> config = {'get_endpoint.return_value.create_call.return_value.start_call.return_value': mock_response}
558    >>> mock_backend.configure_mock(**config)
559
560With these we monkey patch the "mock backend" in place and can make the real
561call::
562
563    >>> something.backend = mock_backend
564    >>> something.method()
565
566Using :attr:`~Mock.mock_calls` we can check the chained call with a single
567assert. A chained call is several calls in one line of code, so there will be
568several entries in ``mock_calls``. We can use :meth:`call.call_list` to create
569this list of calls for us::
570
571    >>> chained = call.get_endpoint('foobar').create_call('spam', 'eggs').start_call()
572    >>> call_list = chained.call_list()
573    >>> assert mock_backend.mock_calls == call_list
574
575
576Partial mocking
577~~~~~~~~~~~~~~~
578
579In some tests I wanted to mock out a call to :meth:`datetime.date.today`
580to return a known date, but I didn't want to prevent the code under test from
581creating new date objects. Unfortunately :class:`datetime.date` is written in C, and
582so I couldn't just monkey-patch out the static :meth:`date.today` method.
583
584I found a simple way of doing this that involved effectively wrapping the date
585class with a mock, but passing through calls to the constructor to the real
586class (and returning real instances).
587
588The :func:`patch decorator <patch>` is used here to
589mock out the ``date`` class in the module under test. The :attr:`side_effect`
590attribute on the mock date class is then set to a lambda function that returns
591a real date. When the mock date class is called a real date will be
592constructed and returned by ``side_effect``. ::
593
594    >>> from datetime import date
595    >>> with patch('mymodule.date') as mock_date:
596    ...     mock_date.today.return_value = date(2010, 10, 8)
597    ...     mock_date.side_effect = lambda *args, **kw: date(*args, **kw)
598    ...
599    ...     assert mymodule.date.today() == date(2010, 10, 8)
600    ...     assert mymodule.date(2009, 6, 8) == date(2009, 6, 8)
601
602Note that we don't patch :class:`datetime.date` globally, we patch ``date`` in the
603module that *uses* it. See :ref:`where to patch <where-to-patch>`.
604
605When ``date.today()`` is called a known date is returned, but calls to the
606``date(...)`` constructor still return normal dates. Without this you can find
607yourself having to calculate an expected result using exactly the same
608algorithm as the code under test, which is a classic testing anti-pattern.
609
610Calls to the date constructor are recorded in the ``mock_date`` attributes
611(``call_count`` and friends) which may also be useful for your tests.
612
613An alternative way of dealing with mocking dates, or other builtin classes,
614is discussed in `this blog entry
615<https://williambert.online/2011/07/how-to-unit-testing-in-django-with-mocking-and-patching/>`_.
616
617
618Mocking a Generator Method
619~~~~~~~~~~~~~~~~~~~~~~~~~~
620
621A Python generator is a function or method that uses the :keyword:`yield` statement
622to return a series of values when iterated over [#]_.
623
624A generator method / function is called to return the generator object. It is
625the generator object that is then iterated over. The protocol method for
626iteration is :meth:`~container.__iter__`, so we can
627mock this using a :class:`MagicMock`.
628
629Here's an example class with an "iter" method implemented as a generator:
630
631    >>> class Foo:
632    ...     def iter(self):
633    ...         for i in [1, 2, 3]:
634    ...             yield i
635    ...
636    >>> foo = Foo()
637    >>> list(foo.iter())
638    [1, 2, 3]
639
640
641How would we mock this class, and in particular its "iter" method?
642
643To configure the values returned from the iteration (implicit in the call to
644:class:`list`), we need to configure the object returned by the call to ``foo.iter()``.
645
646    >>> mock_foo = MagicMock()
647    >>> mock_foo.iter.return_value = iter([1, 2, 3])
648    >>> list(mock_foo.iter())
649    [1, 2, 3]
650
651.. [#] There are also generator expressions and more `advanced uses
652    <http://www.dabeaz.com/coroutines/index.html>`_ of generators, but we aren't
653    concerned about them here. A very good introduction to generators and how
654    powerful they are is: `Generator Tricks for Systems Programmers
655    <http://www.dabeaz.com/generators/>`_.
656
657
658Applying the same patch to every test method
659~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
660
661If you want several patches in place for multiple test methods the obvious way
662is to apply the patch decorators to every method. This can feel like unnecessary
663repetition. For Python 2.6 or more recent you can use :func:`patch` (in all its
664various forms) as a class decorator. This applies the patches to all test
665methods on the class. A test method is identified by methods whose names start
666with ``test``::
667
668    >>> @patch('mymodule.SomeClass')
669    ... class MyTest(unittest.TestCase):
670    ...
671    ...     def test_one(self, MockSomeClass):
672    ...         self.assertIs(mymodule.SomeClass, MockSomeClass)
673    ...
674    ...     def test_two(self, MockSomeClass):
675    ...         self.assertIs(mymodule.SomeClass, MockSomeClass)
676    ...
677    ...     def not_a_test(self):
678    ...         return 'something'
679    ...
680    >>> MyTest('test_one').test_one()
681    >>> MyTest('test_two').test_two()
682    >>> MyTest('test_two').not_a_test()
683    'something'
684
685An alternative way of managing patches is to use the :ref:`start-and-stop`.
686These allow you to move the patching into your ``setUp`` and ``tearDown`` methods.
687::
688
689    >>> class MyTest(unittest.TestCase):
690    ...     def setUp(self):
691    ...         self.patcher = patch('mymodule.foo')
692    ...         self.mock_foo = self.patcher.start()
693    ...
694    ...     def test_foo(self):
695    ...         self.assertIs(mymodule.foo, self.mock_foo)
696    ...
697    ...     def tearDown(self):
698    ...         self.patcher.stop()
699    ...
700    >>> MyTest('test_foo').run()
701
702If you use this technique you must ensure that the patching is "undone" by
703calling ``stop``. This can be fiddlier than you might think, because if an
704exception is raised in the setUp then tearDown is not called.
705:meth:`unittest.TestCase.addCleanup` makes this easier::
706
707    >>> class MyTest(unittest.TestCase):
708    ...     def setUp(self):
709    ...         patcher = patch('mymodule.foo')
710    ...         self.addCleanup(patcher.stop)
711    ...         self.mock_foo = patcher.start()
712    ...
713    ...     def test_foo(self):
714    ...         self.assertIs(mymodule.foo, self.mock_foo)
715    ...
716    >>> MyTest('test_foo').run()
717
718
719Mocking Unbound Methods
720~~~~~~~~~~~~~~~~~~~~~~~
721
722Whilst writing tests today I needed to patch an *unbound method* (patching the
723method on the class rather than on the instance). I needed self to be passed
724in as the first argument because I want to make asserts about which objects
725were calling this particular method. The issue is that you can't patch with a
726mock for this, because if you replace an unbound method with a mock it doesn't
727become a bound method when fetched from the instance, and so it doesn't get
728self passed in. The workaround is to patch the unbound method with a real
729function instead. The :func:`patch` decorator makes it so simple to
730patch out methods with a mock that having to create a real function becomes a
731nuisance.
732
733If you pass ``autospec=True`` to patch then it does the patching with a
734*real* function object. This function object has the same signature as the one
735it is replacing, but delegates to a mock under the hood. You still get your
736mock auto-created in exactly the same way as before. What it means though, is
737that if you use it to patch out an unbound method on a class the mocked
738function will be turned into a bound method if it is fetched from an instance.
739It will have ``self`` passed in as the first argument, which is exactly what I
740wanted:
741
742    >>> class Foo:
743    ...   def foo(self):
744    ...     pass
745    ...
746    >>> with patch.object(Foo, 'foo', autospec=True) as mock_foo:
747    ...   mock_foo.return_value = 'foo'
748    ...   foo = Foo()
749    ...   foo.foo()
750    ...
751    'foo'
752    >>> mock_foo.assert_called_once_with(foo)
753
754If we don't use ``autospec=True`` then the unbound method is patched out
755with a Mock instance instead, and isn't called with ``self``.
756
757
758Checking multiple calls with mock
759~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
760
761mock has a nice API for making assertions about how your mock objects are used.
762
763    >>> mock = Mock()
764    >>> mock.foo_bar.return_value = None
765    >>> mock.foo_bar('baz', spam='eggs')
766    >>> mock.foo_bar.assert_called_with('baz', spam='eggs')
767
768If your mock is only being called once you can use the
769:meth:`assert_called_once_with` method that also asserts that the
770:attr:`call_count` is one.
771
772    >>> mock.foo_bar.assert_called_once_with('baz', spam='eggs')
773    >>> mock.foo_bar()
774    >>> mock.foo_bar.assert_called_once_with('baz', spam='eggs')
775    Traceback (most recent call last):
776        ...
777    AssertionError: Expected to be called once. Called 2 times.
778
779Both ``assert_called_with`` and ``assert_called_once_with`` make assertions about
780the *most recent* call. If your mock is going to be called several times, and
781you want to make assertions about *all* those calls you can use
782:attr:`~Mock.call_args_list`:
783
784    >>> mock = Mock(return_value=None)
785    >>> mock(1, 2, 3)
786    >>> mock(4, 5, 6)
787    >>> mock()
788    >>> mock.call_args_list
789    [call(1, 2, 3), call(4, 5, 6), call()]
790
791The :data:`call` helper makes it easy to make assertions about these calls. You
792can build up a list of expected calls and compare it to ``call_args_list``. This
793looks remarkably similar to the repr of the ``call_args_list``:
794
795    >>> expected = [call(1, 2, 3), call(4, 5, 6), call()]
796    >>> mock.call_args_list == expected
797    True
798
799
800Coping with mutable arguments
801~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
802
803Another situation is rare, but can bite you, is when your mock is called with
804mutable arguments. ``call_args`` and ``call_args_list`` store *references* to the
805arguments. If the arguments are mutated by the code under test then you can no
806longer make assertions about what the values were when the mock was called.
807
808Here's some example code that shows the problem. Imagine the following functions
809defined in 'mymodule'::
810
811    def frob(val):
812        pass
813
814    def grob(val):
815        "First frob and then clear val"
816        frob(val)
817        val.clear()
818
819When we try to test that ``grob`` calls ``frob`` with the correct argument look
820what happens::
821
822    >>> with patch('mymodule.frob') as mock_frob:
823    ...     val = {6}
824    ...     mymodule.grob(val)
825    ...
826    >>> val
827    set()
828    >>> mock_frob.assert_called_with({6})
829    Traceback (most recent call last):
830        ...
831    AssertionError: Expected: (({6},), {})
832    Called with: ((set(),), {})
833
834One possibility would be for mock to copy the arguments you pass in. This
835could then cause problems if you do assertions that rely on object identity
836for equality.
837
838Here's one solution that uses the :attr:`side_effect`
839functionality. If you provide a ``side_effect`` function for a mock then
840``side_effect`` will be called with the same args as the mock. This gives us an
841opportunity to copy the arguments and store them for later assertions. In this
842example I'm using *another* mock to store the arguments so that I can use the
843mock methods for doing the assertion. Again a helper function sets this up for
844me. ::
845
846    >>> from copy import deepcopy
847    >>> from unittest.mock import Mock, patch, DEFAULT
848    >>> def copy_call_args(mock):
849    ...     new_mock = Mock()
850    ...     def side_effect(*args, **kwargs):
851    ...         args = deepcopy(args)
852    ...         kwargs = deepcopy(kwargs)
853    ...         new_mock(*args, **kwargs)
854    ...         return DEFAULT
855    ...     mock.side_effect = side_effect
856    ...     return new_mock
857    ...
858    >>> with patch('mymodule.frob') as mock_frob:
859    ...     new_mock = copy_call_args(mock_frob)
860    ...     val = {6}
861    ...     mymodule.grob(val)
862    ...
863    >>> new_mock.assert_called_with({6})
864    >>> new_mock.call_args
865    call({6})
866
867``copy_call_args`` is called with the mock that will be called. It returns a new
868mock that we do the assertion on. The ``side_effect`` function makes a copy of
869the args and calls our ``new_mock`` with the copy.
870
871.. note::
872
873    If your mock is only going to be used once there is an easier way of
874    checking arguments at the point they are called. You can simply do the
875    checking inside a ``side_effect`` function.
876
877        >>> def side_effect(arg):
878        ...     assert arg == {6}
879        ...
880        >>> mock = Mock(side_effect=side_effect)
881        >>> mock({6})
882        >>> mock(set())
883        Traceback (most recent call last):
884            ...
885        AssertionError
886
887An alternative approach is to create a subclass of :class:`Mock` or
888:class:`MagicMock` that copies (using :func:`copy.deepcopy`) the arguments.
889Here's an example implementation:
890
891    >>> from copy import deepcopy
892    >>> class CopyingMock(MagicMock):
893    ...     def __call__(self, /, *args, **kwargs):
894    ...         args = deepcopy(args)
895    ...         kwargs = deepcopy(kwargs)
896    ...         return super(CopyingMock, self).__call__(*args, **kwargs)
897    ...
898    >>> c = CopyingMock(return_value=None)
899    >>> arg = set()
900    >>> c(arg)
901    >>> arg.add(1)
902    >>> c.assert_called_with(set())
903    >>> c.assert_called_with(arg)
904    Traceback (most recent call last):
905        ...
906    AssertionError: Expected call: mock({1})
907    Actual call: mock(set())
908    >>> c.foo
909    <CopyingMock name='mock.foo' id='...'>
910
911When you subclass ``Mock`` or ``MagicMock`` all dynamically created attributes,
912and the ``return_value`` will use your subclass automatically. That means all
913children of a ``CopyingMock`` will also have the type ``CopyingMock``.
914
915
916Nesting Patches
917~~~~~~~~~~~~~~~
918
919Using patch as a context manager is nice, but if you do multiple patches you
920can end up with nested with statements indenting further and further to the
921right::
922
923    >>> class MyTest(unittest.TestCase):
924    ...
925    ...     def test_foo(self):
926    ...         with patch('mymodule.Foo') as mock_foo:
927    ...             with patch('mymodule.Bar') as mock_bar:
928    ...                 with patch('mymodule.Spam') as mock_spam:
929    ...                     assert mymodule.Foo is mock_foo
930    ...                     assert mymodule.Bar is mock_bar
931    ...                     assert mymodule.Spam is mock_spam
932    ...
933    >>> original = mymodule.Foo
934    >>> MyTest('test_foo').test_foo()
935    >>> assert mymodule.Foo is original
936
937With unittest ``cleanup`` functions and the :ref:`start-and-stop` we can
938achieve the same effect without the nested indentation. A simple helper
939method, ``create_patch``, puts the patch in place and returns the created mock
940for us::
941
942    >>> class MyTest(unittest.TestCase):
943    ...
944    ...     def create_patch(self, name):
945    ...         patcher = patch(name)
946    ...         thing = patcher.start()
947    ...         self.addCleanup(patcher.stop)
948    ...         return thing
949    ...
950    ...     def test_foo(self):
951    ...         mock_foo = self.create_patch('mymodule.Foo')
952    ...         mock_bar = self.create_patch('mymodule.Bar')
953    ...         mock_spam = self.create_patch('mymodule.Spam')
954    ...
955    ...         assert mymodule.Foo is mock_foo
956    ...         assert mymodule.Bar is mock_bar
957    ...         assert mymodule.Spam is mock_spam
958    ...
959    >>> original = mymodule.Foo
960    >>> MyTest('test_foo').run()
961    >>> assert mymodule.Foo is original
962
963
964Mocking a dictionary with MagicMock
965~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
966
967You may want to mock a dictionary, or other container object, recording all
968access to it whilst having it still behave like a dictionary.
969
970We can do this with :class:`MagicMock`, which will behave like a dictionary,
971and using :data:`~Mock.side_effect` to delegate dictionary access to a real
972underlying dictionary that is under our control.
973
974When the :meth:`__getitem__` and :meth:`__setitem__` methods of our ``MagicMock`` are called
975(normal dictionary access) then ``side_effect`` is called with the key (and in
976the case of ``__setitem__`` the value too). We can also control what is returned.
977
978After the ``MagicMock`` has been used we can use attributes like
979:data:`~Mock.call_args_list` to assert about how the dictionary was used:
980
981    >>> my_dict = {'a': 1, 'b': 2, 'c': 3}
982    >>> def getitem(name):
983    ...      return my_dict[name]
984    ...
985    >>> def setitem(name, val):
986    ...     my_dict[name] = val
987    ...
988    >>> mock = MagicMock()
989    >>> mock.__getitem__.side_effect = getitem
990    >>> mock.__setitem__.side_effect = setitem
991
992.. note::
993
994    An alternative to using ``MagicMock`` is to use ``Mock`` and *only* provide
995    the magic methods you specifically want:
996
997        >>> mock = Mock()
998        >>> mock.__getitem__ = Mock(side_effect=getitem)
999        >>> mock.__setitem__ = Mock(side_effect=setitem)
1000
1001    A *third* option is to use ``MagicMock`` but passing in ``dict`` as the *spec*
1002    (or *spec_set*) argument so that the ``MagicMock`` created only has
1003    dictionary magic methods available:
1004
1005        >>> mock = MagicMock(spec_set=dict)
1006        >>> mock.__getitem__.side_effect = getitem
1007        >>> mock.__setitem__.side_effect = setitem
1008
1009With these side effect functions in place, the ``mock`` will behave like a normal
1010dictionary but recording the access. It even raises a :exc:`KeyError` if you try
1011to access a key that doesn't exist.
1012
1013    >>> mock['a']
1014    1
1015    >>> mock['c']
1016    3
1017    >>> mock['d']
1018    Traceback (most recent call last):
1019        ...
1020    KeyError: 'd'
1021    >>> mock['b'] = 'fish'
1022    >>> mock['d'] = 'eggs'
1023    >>> mock['b']
1024    'fish'
1025    >>> mock['d']
1026    'eggs'
1027
1028After it has been used you can make assertions about the access using the normal
1029mock methods and attributes:
1030
1031    >>> mock.__getitem__.call_args_list
1032    [call('a'), call('c'), call('d'), call('b'), call('d')]
1033    >>> mock.__setitem__.call_args_list
1034    [call('b', 'fish'), call('d', 'eggs')]
1035    >>> my_dict
1036    {'a': 1, 'b': 'fish', 'c': 3, 'd': 'eggs'}
1037
1038
1039Mock subclasses and their attributes
1040~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
1041
1042There are various reasons why you might want to subclass :class:`Mock`. One
1043reason might be to add helper methods. Here's a silly example:
1044
1045    >>> class MyMock(MagicMock):
1046    ...     def has_been_called(self):
1047    ...         return self.called
1048    ...
1049    >>> mymock = MyMock(return_value=None)
1050    >>> mymock
1051    <MyMock id='...'>
1052    >>> mymock.has_been_called()
1053    False
1054    >>> mymock()
1055    >>> mymock.has_been_called()
1056    True
1057
1058The standard behaviour for ``Mock`` instances is that attributes and the return
1059value mocks are of the same type as the mock they are accessed on. This ensures
1060that ``Mock`` attributes are ``Mocks`` and ``MagicMock`` attributes are ``MagicMocks``
1061[#]_. So if you're subclassing to add helper methods then they'll also be
1062available on the attributes and return value mock of instances of your
1063subclass.
1064
1065    >>> mymock.foo
1066    <MyMock name='mock.foo' id='...'>
1067    >>> mymock.foo.has_been_called()
1068    False
1069    >>> mymock.foo()
1070    <MyMock name='mock.foo()' id='...'>
1071    >>> mymock.foo.has_been_called()
1072    True
1073
1074Sometimes this is inconvenient. For example, `one user
1075<https://code.google.com/archive/p/mock/issues/105>`_ is subclassing mock to
1076created a `Twisted adaptor
1077<https://twistedmatrix.com/documents/11.0.0/api/twisted.python.components.html>`_.
1078Having this applied to attributes too actually causes errors.
1079
1080``Mock`` (in all its flavours) uses a method called ``_get_child_mock`` to create
1081these "sub-mocks" for attributes and return values. You can prevent your
1082subclass being used for attributes by overriding this method. The signature is
1083that it takes arbitrary keyword arguments (``**kwargs``) which are then passed
1084onto the mock constructor:
1085
1086    >>> class Subclass(MagicMock):
1087    ...     def _get_child_mock(self, /, **kwargs):
1088    ...         return MagicMock(**kwargs)
1089    ...
1090    >>> mymock = Subclass()
1091    >>> mymock.foo
1092    <MagicMock name='mock.foo' id='...'>
1093    >>> assert isinstance(mymock, Subclass)
1094    >>> assert not isinstance(mymock.foo, Subclass)
1095    >>> assert not isinstance(mymock(), Subclass)
1096
1097.. [#] An exception to this rule are the non-callable mocks. Attributes use the
1098    callable variant because otherwise non-callable mocks couldn't have callable
1099    methods.
1100
1101
1102Mocking imports with patch.dict
1103~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
1104
1105One situation where mocking can be hard is where you have a local import inside
1106a function. These are harder to mock because they aren't using an object from
1107the module namespace that we can patch out.
1108
1109Generally local imports are to be avoided. They are sometimes done to prevent
1110circular dependencies, for which there is *usually* a much better way to solve
1111the problem (refactor the code) or to prevent "up front costs" by delaying the
1112import. This can also be solved in better ways than an unconditional local
1113import (store the module as a class or module attribute and only do the import
1114on first use).
1115
1116That aside there is a way to use ``mock`` to affect the results of an import.
1117Importing fetches an *object* from the :data:`sys.modules` dictionary. Note that it
1118fetches an *object*, which need not be a module. Importing a module for the
1119first time results in a module object being put in `sys.modules`, so usually
1120when you import something you get a module back. This need not be the case
1121however.
1122
1123This means you can use :func:`patch.dict` to *temporarily* put a mock in place
1124in :data:`sys.modules`. Any imports whilst this patch is active will fetch the mock.
1125When the patch is complete (the decorated function exits, the with statement
1126body is complete or ``patcher.stop()`` is called) then whatever was there
1127previously will be restored safely.
1128
1129Here's an example that mocks out the 'fooble' module.
1130
1131    >>> import sys
1132    >>> mock = Mock()
1133    >>> with patch.dict('sys.modules', {'fooble': mock}):
1134    ...    import fooble
1135    ...    fooble.blob()
1136    ...
1137    <Mock name='mock.blob()' id='...'>
1138    >>> assert 'fooble' not in sys.modules
1139    >>> mock.blob.assert_called_once_with()
1140
1141As you can see the ``import fooble`` succeeds, but on exit there is no 'fooble'
1142left in :data:`sys.modules`.
1143
1144This also works for the ``from module import name`` form:
1145
1146    >>> mock = Mock()
1147    >>> with patch.dict('sys.modules', {'fooble': mock}):
1148    ...    from fooble import blob
1149    ...    blob.blip()
1150    ...
1151    <Mock name='mock.blob.blip()' id='...'>
1152    >>> mock.blob.blip.assert_called_once_with()
1153
1154With slightly more work you can also mock package imports:
1155
1156    >>> mock = Mock()
1157    >>> modules = {'package': mock, 'package.module': mock.module}
1158    >>> with patch.dict('sys.modules', modules):
1159    ...    from package.module import fooble
1160    ...    fooble()
1161    ...
1162    <Mock name='mock.module.fooble()' id='...'>
1163    >>> mock.module.fooble.assert_called_once_with()
1164
1165
1166Tracking order of calls and less verbose call assertions
1167~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
1168
1169The :class:`Mock` class allows you to track the *order* of method calls on
1170your mock objects through the :attr:`~Mock.method_calls` attribute. This
1171doesn't allow you to track the order of calls between separate mock objects,
1172however we can use :attr:`~Mock.mock_calls` to achieve the same effect.
1173
1174Because mocks track calls to child mocks in ``mock_calls``, and accessing an
1175arbitrary attribute of a mock creates a child mock, we can create our separate
1176mocks from a parent one. Calls to those child mock will then all be recorded,
1177in order, in the ``mock_calls`` of the parent:
1178
1179    >>> manager = Mock()
1180    >>> mock_foo = manager.foo
1181    >>> mock_bar = manager.bar
1182
1183    >>> mock_foo.something()
1184    <Mock name='mock.foo.something()' id='...'>
1185    >>> mock_bar.other.thing()
1186    <Mock name='mock.bar.other.thing()' id='...'>
1187
1188    >>> manager.mock_calls
1189    [call.foo.something(), call.bar.other.thing()]
1190
1191We can then assert about the calls, including the order, by comparing with
1192the ``mock_calls`` attribute on the manager mock:
1193
1194    >>> expected_calls = [call.foo.something(), call.bar.other.thing()]
1195    >>> manager.mock_calls == expected_calls
1196    True
1197
1198If ``patch`` is creating, and putting in place, your mocks then you can attach
1199them to a manager mock using the :meth:`~Mock.attach_mock` method. After
1200attaching calls will be recorded in ``mock_calls`` of the manager. ::
1201
1202    >>> manager = MagicMock()
1203    >>> with patch('mymodule.Class1') as MockClass1:
1204    ...     with patch('mymodule.Class2') as MockClass2:
1205    ...         manager.attach_mock(MockClass1, 'MockClass1')
1206    ...         manager.attach_mock(MockClass2, 'MockClass2')
1207    ...         MockClass1().foo()
1208    ...         MockClass2().bar()
1209    <MagicMock name='mock.MockClass1().foo()' id='...'>
1210    <MagicMock name='mock.MockClass2().bar()' id='...'>
1211    >>> manager.mock_calls
1212    [call.MockClass1(),
1213    call.MockClass1().foo(),
1214    call.MockClass2(),
1215    call.MockClass2().bar()]
1216
1217If many calls have been made, but you're only interested in a particular
1218sequence of them then an alternative is to use the
1219:meth:`~Mock.assert_has_calls` method. This takes a list of calls (constructed
1220with the :data:`call` object). If that sequence of calls are in
1221:attr:`~Mock.mock_calls` then the assert succeeds.
1222
1223    >>> m = MagicMock()
1224    >>> m().foo().bar().baz()
1225    <MagicMock name='mock().foo().bar().baz()' id='...'>
1226    >>> m.one().two().three()
1227    <MagicMock name='mock.one().two().three()' id='...'>
1228    >>> calls = call.one().two().three().call_list()
1229    >>> m.assert_has_calls(calls)
1230
1231Even though the chained call ``m.one().two().three()`` aren't the only calls that
1232have been made to the mock, the assert still succeeds.
1233
1234Sometimes a mock may have several calls made to it, and you are only interested
1235in asserting about *some* of those calls. You may not even care about the
1236order. In this case you can pass ``any_order=True`` to ``assert_has_calls``:
1237
1238    >>> m = MagicMock()
1239    >>> m(1), m.two(2, 3), m.seven(7), m.fifty('50')
1240    (...)
1241    >>> calls = [call.fifty('50'), call(1), call.seven(7)]
1242    >>> m.assert_has_calls(calls, any_order=True)
1243
1244
1245More complex argument matching
1246~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
1247
1248Using the same basic concept as :data:`ANY` we can implement matchers to do more
1249complex assertions on objects used as arguments to mocks.
1250
1251Suppose we expect some object to be passed to a mock that by default
1252compares equal based on object identity (which is the Python default for user
1253defined classes). To use :meth:`~Mock.assert_called_with` we would need to pass
1254in the exact same object. If we are only interested in some of the attributes
1255of this object then we can create a matcher that will check these attributes
1256for us.
1257
1258You can see in this example how a 'standard' call to ``assert_called_with`` isn't
1259sufficient:
1260
1261    >>> class Foo:
1262    ...     def __init__(self, a, b):
1263    ...         self.a, self.b = a, b
1264    ...
1265    >>> mock = Mock(return_value=None)
1266    >>> mock(Foo(1, 2))
1267    >>> mock.assert_called_with(Foo(1, 2))
1268    Traceback (most recent call last):
1269        ...
1270    AssertionError: Expected: call(<__main__.Foo object at 0x...>)
1271    Actual call: call(<__main__.Foo object at 0x...>)
1272
1273A comparison function for our ``Foo`` class might look something like this:
1274
1275    >>> def compare(self, other):
1276    ...     if not type(self) == type(other):
1277    ...         return False
1278    ...     if self.a != other.a:
1279    ...         return False
1280    ...     if self.b != other.b:
1281    ...         return False
1282    ...     return True
1283    ...
1284
1285And a matcher object that can use comparison functions like this for its
1286equality operation would look something like this:
1287
1288    >>> class Matcher:
1289    ...     def __init__(self, compare, some_obj):
1290    ...         self.compare = compare
1291    ...         self.some_obj = some_obj
1292    ...     def __eq__(self, other):
1293    ...         return self.compare(self.some_obj, other)
1294    ...
1295
1296Putting all this together:
1297
1298    >>> match_foo = Matcher(compare, Foo(1, 2))
1299    >>> mock.assert_called_with(match_foo)
1300
1301The ``Matcher`` is instantiated with our compare function and the ``Foo`` object
1302we want to compare against. In ``assert_called_with`` the ``Matcher`` equality
1303method will be called, which compares the object the mock was called with
1304against the one we created our matcher with. If they match then
1305``assert_called_with`` passes, and if they don't an :exc:`AssertionError` is raised:
1306
1307    >>> match_wrong = Matcher(compare, Foo(3, 4))
1308    >>> mock.assert_called_with(match_wrong)
1309    Traceback (most recent call last):
1310        ...
1311    AssertionError: Expected: ((<Matcher object at 0x...>,), {})
1312    Called with: ((<Foo object at 0x...>,), {})
1313
1314With a bit of tweaking you could have the comparison function raise the
1315:exc:`AssertionError` directly and provide a more useful failure message.
1316
1317As of version 1.5, the Python testing library `PyHamcrest
1318<https://pyhamcrest.readthedocs.io/>`_ provides similar functionality,
1319that may be useful here, in the form of its equality matcher
1320(`hamcrest.library.integration.match_equality
1321<https://pyhamcrest.readthedocs.io/en/release-1.8/integration/#module-hamcrest.library.integration.match_equality>`_).
1322