40fb46f1e8
* fixes import paths for ansible unit testing * Update docs/docsite/rst/dev_guide/testing_units_modules.rst Co-Authored-By: Sandra McCann <samccann@redhat.com>
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.. _testing_units_modules:
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****************************
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Unit Testing Ansible Modules
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****************************
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.. highlight:: python
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.. contents:: Topics
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Introduction
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============
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This document explains why, how and when you should use unit tests for Ansible modules.
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The document doesn't apply to other parts of Ansible for which the recommendations are
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normally closer to the Python standard. There is basic documentation for Ansible unit
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tests in the developer guide :ref:`testing_units`. This document should
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be readable for a new Ansible module author. If you find it incomplete or confusing,
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please open a bug or ask for help on Ansible IRC.
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What Are Unit Tests?
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====================
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Ansible includes a set of unit tests in the :file:`test/units` directory. These tests primarily cover the
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internals but can also can cover Ansible modules. The structure of the unit tests matches
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the structure of the code base, so the tests that reside in the :file:`test/units/modules/` directory
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are organized by module groups.
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Integration tests can be used for most modules, but there are situations where
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cases cannot be verified using integration tests. This means that Ansible unit test cases
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may extend beyond testing only minimal units and in some cases will include some
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level of functional testing.
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Why Use Unit Tests?
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===================
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Ansible unit tests have advantages and disadvantages. It is important to understand these.
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Advantages include:
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* Most unit tests are much faster than most Ansible integration tests. The complete suite
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of unit tests can be run regularly by a developer on their local system.
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* Unit tests can be run by developers who don't have access to the system which the module is
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designed to work on, allowing a level of verification that changes to core functions
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haven't broken module expectations.
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* Unit tests can easily substitute system functions allowing testing of software that
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would be impractical. For example, the ``sleep()`` function can be replaced and we check
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that a ten minute sleep was called without actually waiting ten minutes.
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* Unit tests are run on different Python versions. This allows us to
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ensure that the code behaves in the same way on different Python versions.
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There are also some potential disadvantages of unit tests. Unit tests don't normally
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directly test actual useful valuable features of software, instead just internal
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implementation
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* Unit tests that test the internal, non-visible features of software may make
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refactoring difficult if those internal features have to change (see also naming in How
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below)
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* Even if the internal feature is working correctly it is possible that there will be a
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problem between the internal code tested and the actual result delivered to the user
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Normally the Ansible integration tests (which are written in Ansible YAML) provide better
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testing for most module functionality. If those tests already test a feature and perform
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well there may be little point in providing a unit test covering the same area as well.
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When To Use Unit Tests
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======================
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There are a number of situations where unit tests are a better choice than integration
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tests. For example, testing things which are impossible, slow or very difficult to test
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with integration tests, such as:
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* Forcing rare / strange / random situations that can't be forced, such as specific network
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failures and exceptions
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* Extensive testing of slow configuration APIs
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* Situations where the integration tests cannot be run as part of the main Ansible
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continuous integration running in Shippable.
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Providing quick feedback
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------------------------
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Example:
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A single step of the rds_instance test cases can take up to 20
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minutes (the time to create an RDS instance in Amazon). The entire
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test run can last for well over an hour. All 16 of the unit tests
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complete execution in less than 2 seconds.
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The time saving provided by being able to run the code in a unit test makes it worth
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creating a unit test when bug fixing a module, even if those tests do not often identify
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problems later. As a basic goal, every module should have at least one unit test which
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will give quick feedback in easy cases without having to wait for the integration tests to
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complete.
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Ensuring correct use of external interfaces
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-------------------------------------------
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Unit tests can check the way in which external services are run to ensure that they match
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specifications or are as efficient as possible *even when the final output will not be changed*.
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Example:
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Package managers are often far more efficient when installing multiple packages at once
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rather than each package separately. The final result is the
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same: the packages are all installed, so the efficiency is difficult to verify through
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integration tests. By providing a mock package manager and verifying that it is called
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once, we can build a valuable test for module efficiency.
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Another related use is in the situation where an API has versions which behave
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differently. A programmer working on a new version may change the module to work with the
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new API version and unintentionally break the old version. A test case
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which checks that the call happens properly for the old version can help avoid the
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problem. In this situation it is very important to include version numbering in the test case
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name (see `Naming unit tests`_ below).
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Providing specific design tests
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--------------------------------
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By building a requirement for a particular part of the
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code and then coding to that requirement, unit tests _can_ sometimes improve the code and
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help future developers understand that code.
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Unit tests that test internal implementation details of code, on the other hand, almost
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always do more harm than good. Testing that your packages to install are stored in a list
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would slow down and confuse a future developer who might need to change that list into a
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dictionary for efficiency. This problem can be reduced somewhat with clear test naming so
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that the future developer immediately knows to delete the test case, but it is often
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better to simply leave out the test case altogether and test for a real valuable feature
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of the code, such as installing all of the packages supplied as arguments to the module.
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How to unit test Ansible modules
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================================
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There are a number of techniques for unit testing modules. Beware that most
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modules without unit tests are structured in a way that makes testing quite difficult and
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can lead to very complicated tests which need more work than the code. Effectively using unit
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tests may lead you to restructure your code. This is often a good thing and leads
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to better code overall. Good restructuring can make your code clearer and easier to understand.
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Naming unit tests
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-----------------
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Unit tests should have logical names. If a developer working on the module being tested
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breaks the test case, it should be easy to figure what the unit test covers from the name.
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If a unit test is designed to verify compatibility with a specific software or API version
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then include the version in the name of the unit test.
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As an example, ``test_v2_state_present_should_call_create_server_with_name()`` would be a
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good name, ``test_create_server()`` would not be.
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Use of Mocks
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------------
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Mock objects (from https://docs.python.org/3/library/unittest.mock.html) can be very
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useful in building unit tests for special / difficult cases, but they can also
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lead to complex and confusing coding situations. One good use for mocks would be in
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simulating an API. As for 'six', the 'mock' python package is bundled with Ansible (use
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``import units.compat.mock``).
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Ensuring failure cases are visible with mock objects
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----------------------------------------------------
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Functions like :meth:`module.fail_json` are normally expected to terminate execution. When you
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run with a mock module object this doesn't happen since the mock always returns another mock
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from a function call. You can set up the mock to raise an exception as shown above, or you can
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assert that these functions have not been called in each test. For example::
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module = MagicMock()
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function_to_test(module, argument)
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module.fail_json.assert_not_called()
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This applies not only to calling the main module but almost any other
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function in a module which gets the module object.
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Mocking of the actual module
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----------------------------
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The setup of an actual module is quite complex (see `Passing Arguments`_ below) and often
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isn't needed for most functions which use a module. Instead you can use a mock object as
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the module and create any module attributes needed by the function you are testing. If
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you do this, beware that the module exit functions need special handling as mentioned
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above, either by throwing an exception or ensuring that they haven't been called. For example::
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class AnsibleExitJson(Exception):
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"""Exception class to be raised by module.exit_json and caught by the test case"""
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pass
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# you may also do the same to fail json
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module = MagicMock()
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module.exit_json.side_effect = AnsibleExitJson(Exception)
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with self.assertRaises(AnsibleExitJson) as result:
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return = my_module.test_this_function(module, argument)
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module.fail_json.assert_not_called()
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assert return["changed"] == True
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API definition with unit test cases
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-----------------------------------
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API interaction is usually best tested with the function tests defined in Ansible's
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integration testing section, which run against the actual API. There are several cases
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where the unit tests are likely to work better.
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Defining a module against an API specification
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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This case is especially important for modules interacting with web services, which provide
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an API that Ansible uses but which are beyond the control of the user.
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By writing a custom emulation of the calls that return data from the API, we can ensure
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that only the features which are clearly defined in the specification of the API are
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present in the message. This means that we can check that we use the correct
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parameters and nothing else.
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*Example: in rds_instance unit tests a simple instance state is defined*::
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def simple_instance_list(status, pending):
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return {u'DBInstances': [{u'DBInstanceArn': 'arn:aws:rds:us-east-1:1234567890:db:fakedb',
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u'DBInstanceStatus': status,
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u'PendingModifiedValues': pending,
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u'DBInstanceIdentifier': 'fakedb'}]}
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This is then used to create a list of states::
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rds_client_double = MagicMock()
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rds_client_double.describe_db_instances.side_effect = [
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simple_instance_list('rebooting', {"a": "b", "c": "d"}),
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simple_instance_list('available', {"c": "d", "e": "f"}),
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simple_instance_list('rebooting', {"a": "b"}),
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simple_instance_list('rebooting', {"e": "f", "g": "h"}),
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simple_instance_list('rebooting', {}),
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simple_instance_list('available', {"g": "h", "i": "j"}),
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simple_instance_list('rebooting', {"i": "j", "k": "l"}),
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simple_instance_list('available', {}),
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simple_instance_list('available', {}),
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]
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These states are then used as returns from a mock object to ensure that the ``await`` function
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waits through all of the states that would mean the RDS instance has not yet completed
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configuration::
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rds_i.await_resource(rds_client_double, "some-instance", "available", mod_mock,
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await_pending=1)
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assert(len(sleeper_double.mock_calls) > 5), "await_pending didn't wait enough"
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By doing this we check that the ``await`` function will keep waiting through
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potentially unusual that it would be impossible to reliably trigger through the
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integration tests but which happen unpredictably in reality.
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Defining a module to work against multiple API versions
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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This case is especially important for modules interacting with many different versions of
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software; for example, package installation modules that might be expected to work with
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many different operating system versions.
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By using previously stored data from various versions of an API we can ensure that the
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code is tested against the actual data which will be sent from that version of the system
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even when the version is very obscure and unlikely to be available during testing.
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Ansible special cases for unit testing
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======================================
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There are a number of special cases for unit testing the environment of an Ansible module.
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The most common are documented below, and suggestions for others can be found by looking
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at the source code of the existing unit tests or asking on the Ansible IRC channel or mailing
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lists.
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Module argument processing
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--------------------------
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There are two problems with running the main function of a module:
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* Since the module is supposed to accept arguments on ``STDIN`` it is a bit difficult to
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set up the arguments correctly so that the module will get them as parameters.
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* All modules should finish by calling either the :meth:`module.fail_json` or
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:meth:`module.exit_json`, but these won't work correctly in a testing environment.
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Passing Arguments
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-----------------
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.. This section should be updated once https://github.com/ansible/ansible/pull/31456 is
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closed since the function below will be provided in a library file.
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To pass arguments to a module correctly, use the ``set_module_args`` method which accepts a dictionary
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as its parameter. Module creation and argument processing is
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handled through the :class:`AnsibleModule` object in the basic section of the utilities. Normally
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this accepts input on ``STDIN``, which is not convenient for unit testing. When the special
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variable is set it will be treated as if the input came on ``STDIN`` to the module. Simply call that function before setting up your module::
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import json
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from units.modules.utils import set_module_args
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from ansible.module_utils._text import to_bytes
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def test_already_registered(self):
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set_module_args({
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'activationkey': 'key',
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'username': 'user',
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'password': 'pass',
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})
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Handling exit correctly
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-----------------------
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.. This section should be updated once https://github.com/ansible/ansible/pull/31456 is
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closed since the exit and failure functions below will be provided in a library file.
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The :meth:`module.exit_json` function won't work properly in a testing environment since it
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writes error information to ``STDOUT`` upon exit, where it
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is difficult to examine. This can be mitigated by replacing it (and :meth:`module.fail_json`) with
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a function that raises an exception::
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def exit_json(*args, **kwargs):
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if 'changed' not in kwargs:
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kwargs['changed'] = False
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raise AnsibleExitJson(kwargs)
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Now you can ensure that the first function called is the one you expected simply by
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testing for the correct exception::
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def test_returned_value(self):
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set_module_args({
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'activationkey': 'key',
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'username': 'user',
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'password': 'pass',
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})
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with self.assertRaises(AnsibleExitJson) as result:
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my_module.main()
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The same technique can be used to replace :meth:`module.fail_json` (which is used for failure
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returns from modules) and for the ``aws_module.fail_json_aws()`` (used in modules for Amazon
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Web Services).
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Running the main function
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-------------------------
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If you do want to run the actual main function of a module you must import the module, set
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the arguments as above, set up the appropriate exit exception and then run the module::
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# This test is based around pytest's features for individual test functions
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import pytest
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import ansible.modules.module.group.my_module as my_module
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def test_main_function(monkeypatch):
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monkeypatch.setattr(my_module.AnsibleModule, "exit_json", fake_exit_json)
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set_module_args({
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'activationkey': 'key',
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'username': 'user',
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'password': 'pass',
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})
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my_module.main()
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Handling calls to external executables
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--------------------------------------
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Module must use :meth:`AnsibleModule.run_command` in order to execute an external command. This
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method needs to be mocked:
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Here is a simple mock of :meth:`AnsibleModule.run_command` (taken from :file:`test/units/modules/packaging/os/test_rhn_register.py`)::
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with patch.object(basic.AnsibleModule, 'run_command') as run_command:
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run_command.return_value = 0, '', '' # successful execution, no output
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with self.assertRaises(AnsibleExitJson) as result:
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self.module.main()
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self.assertFalse(result.exception.args[0]['changed'])
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# Check that run_command has been called
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run_command.assert_called_once_with('/usr/bin/command args')
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self.assertEqual(run_command.call_count, 1)
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self.assertFalse(run_command.called)
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A Complete Example
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------------------
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The following example is a complete skeleton that reuses the mocks explained above and adds a new
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mock for :meth:`Ansible.get_bin_path`::
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import json
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from units.compat import unittest
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from units.compat.mock import patch
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from ansible.module_utils import basic
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from ansible.module_utils._text import to_bytes
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from ansible.modules.namespace import my_module
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def set_module_args(args):
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"""prepare arguments so that they will be picked up during module creation"""
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args = json.dumps({'ANSIBLE_MODULE_ARGS': args})
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basic._ANSIBLE_ARGS = to_bytes(args)
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class AnsibleExitJson(Exception):
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"""Exception class to be raised by module.exit_json and caught by the test case"""
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pass
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class AnsibleFailJson(Exception):
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"""Exception class to be raised by module.fail_json and caught by the test case"""
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pass
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def exit_json(*args, **kwargs):
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"""function to patch over exit_json; package return data into an exception"""
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if 'changed' not in kwargs:
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kwargs['changed'] = False
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raise AnsibleExitJson(kwargs)
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def fail_json(*args, **kwargs):
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"""function to patch over fail_json; package return data into an exception"""
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kwargs['failed'] = True
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raise AnsibleFailJson(kwargs)
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def get_bin_path(self, arg, required=False):
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"""Mock AnsibleModule.get_bin_path"""
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if arg.endswith('my_command'):
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return '/usr/bin/my_command'
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else:
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if required:
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fail_json(msg='%r not found !' % arg)
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class TestMyModule(unittest.TestCase):
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def setUp(self):
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self.mock_module_helper = patch.multiple(basic.AnsibleModule,
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exit_json=exit_json,
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fail_json=fail_json,
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get_bin_path=get_bin_path)
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self.mock_module_helper.start()
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self.addCleanup(self.mock_module_helper.stop)
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def test_module_fail_when_required_args_missing(self):
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with self.assertRaises(AnsibleFailJson):
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set_module_args({})
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self.module.main()
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def test_ensure_command_called(self):
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set_module_args({
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'param1': 10,
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'param2': 'test',
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})
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with patch.object(basic.AnsibleModule, 'run_command') as mock_run_command:
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stdout = 'configuration updated'
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stderr = ''
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rc = 0
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mock_run_command.return_value = rc, stdout, stderr # successful execution
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with self.assertRaises(AnsibleExitJson) as result:
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my_module.main()
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self.assertFalse(result.exception.args[0]['changed']) # ensure result is changed
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mock_run_command.assert_called_once_with('/usr/bin/my_command --value 10 --name test')
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Restructuring modules to enable testing module set up and other processes
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-------------------------------------------------------------------------
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Often modules have a ``main()`` function which sets up the module and then performs other
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actions. This can make it difficult to check argument processing. This can be made easier by
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moving module configuration and initialization into a separate function. For example::
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argument_spec = dict(
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# module function variables
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state=dict(choices=['absent', 'present', 'rebooted', 'restarted'], default='present'),
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apply_immediately=dict(type='bool', default=False),
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wait=dict(type='bool', default=False),
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wait_timeout=dict(type='int', default=600),
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allocated_storage=dict(type='int', aliases=['size']),
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db_instance_identifier=dict(aliases=["id"], required=True),
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)
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def setup_module_object():
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module = AnsibleAWSModule(
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argument_spec=argument_spec,
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required_if=required_if,
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mutually_exclusive=[['old_instance_id', 'source_db_instance_identifier',
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'db_snapshot_identifier']],
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)
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return module
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def main():
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module = setup_module_object()
|
|
validate_parameters(module)
|
|
conn = setup_client(module)
|
|
return_dict = run_task(module, conn)
|
|
module.exit_json(**return_dict)
|
|
|
|
This now makes it possible to run tests against the module initiation function::
|
|
|
|
def test_rds_module_setup_fails_if_db_instance_identifier_parameter_missing():
|
|
# db_instance_identifier parameter is missing
|
|
set_module_args({
|
|
'state': 'absent',
|
|
'apply_immediately': 'True',
|
|
})
|
|
|
|
with self.assertRaises(AnsibleFailJson) as result:
|
|
self.module.setup_json
|
|
|
|
See also ``test/units/module_utils/aws/test_rds.py``
|
|
|
|
Note that the ``argument_spec`` dictionary is visible in a module variable. This has
|
|
advantages, both in allowing explicit testing of the arguments and in allowing the easy
|
|
creation of module objects for testing.
|
|
|
|
The same restructuring technique can be valuable for testing other functionality, such as the part of the module which queries the object that the module configures.
|
|
|
|
Traps for maintaining Python 2 compatibility
|
|
============================================
|
|
|
|
If you use the ``mock`` library from the Python 2.6 standard library, a number of the
|
|
assert functions are missing but will return as if successful. This means that test cases should take great care *not* use
|
|
functions marked as _new_ in the Python 3 documentation, since the tests will likely always
|
|
succeed even if the code is broken when run on older versions of Python.
|
|
|
|
A helpful development approach to this should be to ensure that all of the tests have been
|
|
run under Python 2.6 and that each assertion in the test cases has been checked to work by breaking
|
|
the code in Ansible to trigger that failure.
|
|
|
|
.. warning:: Maintain Python 2.6 compatibility
|
|
|
|
Please remember that modules need to maintain compatibility with Python 2.6 so the unittests for
|
|
modules should also be compatible with Python 2.6.
|
|
|
|
|
|
.. seealso::
|
|
|
|
:ref:`testing_units`
|
|
Ansible unit tests documentation
|
|
:ref:`testing_running_locally`
|
|
Running tests locally including gathering and reporting coverage data
|
|
:ref:`developing_modules_general`
|
|
Get started developing a module
|
|
`Python 3 documentation - 26.4. unittest — Unit testing framework <https://docs.python.org/3/library/unittest.html>`_
|
|
The documentation of the unittest framework in python 3
|
|
`Python 2 documentation - 25.3. unittest — Unit testing framework <https://docs.python.org/3/library/unittest.html>`_
|
|
The documentation of the earliest supported unittest framework - from Python 2.6
|
|
`pytest: helps you write better programs <https://docs.pytest.org/en/latest/>`_
|
|
The documentation of pytest - the framework actually used to run Ansible unit tests
|
|
`Development Mailing List <https://groups.google.com/group/ansible-devel>`_
|
|
Mailing list for development topics
|
|
`Testing Your Code (from The Hitchhiker's Guide to Python!) <https://docs.python-guide.org/writing/tests/>`_
|
|
General advice on testing Python code
|
|
`Uncle Bob's many videos on YouTube <https://www.youtube.com/watch?v=QedpQjxBPMA&list=PLlu0CT-JnSasQzGrGzddSczJQQU7295D2>`_
|
|
Unit testing is a part of the of various philosophies of software development, including
|
|
Extreme Programming (XP), Clean Coding. Uncle Bob talks through how to benefit from this
|
|
`"Why Most Unit Testing is Waste" <https://rbcs-us.com/documents/Why-Most-Unit-Testing-is-Waste.pdf>`_
|
|
An article warning against the costs of unit testing
|
|
`'A Response to "Why Most Unit Testing is Waste"' <https://henrikwarne.com/2014/09/04/a-response-to-why-most-unit-testing-is-waste/>`_
|
|
An response pointing to how to maintain the value of unit tests
|