doc/source/plugin.rst - packaging/sources/tempest - Gitiles

 =============================
 Tempest Test Plugin Interface
 =============================

 Tempest has an external test plugin interface which enables anyone to integrate
 an external test suite as part of a tempest run. This will let any project
 leverage being run with the rest of the tempest suite while not requiring the
 tests live in the tempest tree.

 Creating a plugin
 =================

 Creating a plugin is fairly straightforward and doesn't require much additional
 effort on top of creating a test suite using tempest.lib. One thing to note with
 doing this is that the interfaces exposed by tempest are not considered stable
 (with the exception of configuration variables which ever effort goes into
 ensuring backwards compatibility). You should not need to import anything from
 tempest itself except where explicitly noted.

 Stable Tempest APIs plugins may use
 -----------------------------------

 As noted above, several tempest APIs are acceptable to use from plugins, while
 others are not. A list of stable APIs available to plugins is provided below:

 * tempest.lib.*
 * tempest.config
 * tempest.test_discover.plugins

 If there is an interface from tempest that you need to rely on in your plugin
 which is not listed above, it likely needs to be migrated to tempest.lib. In
 that situation, file a bug, push a migration patch, etc. to expedite providing
 the interface in a reliable manner.

 Plugin Cookiecutter
 -------------------

 In order to create the basic structure with base classes and test directories
 you can use the tempest-plugin-cookiecutter project::

   > pip install -U cookiecutter && cookiecutter https://git.openstack.org/openstack/tempest-plugin-cookiecutter

   Cloning into 'tempest-plugin-cookiecutter'...
   remote: Counting objects: 17, done.
   remote: Compressing objects: 100% (13/13), done.
   remote: Total 17 (delta 1), reused 14 (delta 1)
   Unpacking objects: 100% (17/17), done.
   Checking connectivity... done.
   project (default is "sample")? foo
   testclass (default is "SampleTempestPlugin")? FooTempestPlugin

 This would create a folder called ``foo_tempest_plugin/`` with all necessary
 basic classes. You only need to move/create your test in
 ``foo_tempest_plugin/tests``.

 Entry Point
 -----------

 Once you've created your plugin class you need to add an entry point to your
 project to enable tempest to find the plugin. The entry point must be added
 to the "tempest.test_plugins" namespace.

 If you are using pbr this is fairly straightforward, in the setup.cfg just add
 something like the following::

   [entry_points]
   tempest.test_plugins =
       plugin_name = module.path:PluginClass

 Standalone Plugin vs In-repo Plugin
 -----------------------------------

 Since all that's required for a plugin to be detected by tempest is a valid
 setuptools entry point in the proper namespace there is no difference from the
 tempest perspective on either creating a separate python package to
 house the plugin or adding the code to an existing python project. However,
 there are tradeoffs to consider when deciding which approach to take when
 creating a new plugin.

 If you create a separate python project for your plugin this makes a lot of
 things much easier. Firstly it makes packaging and versioning much simpler, you
 can easily decouple the requirements for the plugin from the requirements for
 the other project. It lets you version the plugin independently and maintain a
 single version of the test code across project release boundaries (see the
 `Branchless Tempest Spec`_ for more details on this). It also greatly
 simplifies the install time story for external users. Instead of having to
 install the right version of a project in the same python namespace as tempest
 they simply need to pip install the plugin in that namespace. It also means
 that users don't have to worry about inadvertently installing a tempest plugin
 when they install another package.

 .. _Branchless Tempest Spec: http://specs.openstack.org/openstack/qa-specs/specs/tempest/implemented/branchless-tempest.html

 The sole advantage to integrating a plugin into an existing python project is
 that it enables you to land code changes at the same time you land test changes
 in the plugin. This reduces some of the burden on contributors by not having
 to land 2 changes to add a new API feature and then test it and doing it as a
 single combined commit.


 Plugin Class
 ============

 To provide tempest with all the required information it needs to be able to run
 your plugin you need to create a plugin class which tempest will load and call
 to get information when it needs. To simplify creating this tempest provides an
 abstract class that should be used as the parent for your plugin. To use this
 you would do something like the following::

   from tempest.test_discover import plugins

   class MyPlugin(plugins.TempestPlugin):

 Then you need to ensure you locally define all of the mandatory methods in the
 abstract class, you can refer to the api doc below for a reference of what that
 entails.

 Abstract Plugin Class
 ---------------------

 .. autoclass:: tempest.test_discover.plugins.TempestPlugin
    :members:

 Plugin Structure
 ================
 While there are no hard and fast rules for the structure a plugin, there are
 basically no constraints on what the plugin looks like as long as the 2 steps
 above are done. However,  there are some recommended patterns to follow to make
 it easy for people to contribute and work with your plugin. For example, if you
 create a directory structure with something like::

     plugin_dir/
       config.py
       plugin.py
       tests/
         api/
         scenario/
       services/
         client.py

 That will mirror what people expect from tempest. The file

 * **config.py**: contains any plugin specific configuration variables
 * **plugin.py**: contains the plugin class used for the entry point
 * **tests**: the directory where test discovery will be run, all tests should
              be under this dir
 * **services**: where the plugin specific service clients are

 Additionally, when you're creating the plugin you likely want to follow all
 of the tempest developer and reviewer documentation to ensure that the tests
 being added in the plugin act and behave like the rest of tempest.

 Dealing with configuration options
 ----------------------------------

 Historically Tempest didn't provide external guarantees on its configuration
 options. However, with the introduction of the plugin interface this is no
 longer the case. An external plugin can rely on using any configuration option
 coming from Tempest, there will be at least a full deprecation cycle for any
 option before it's removed. However, just the options provided by Tempest
 may not be sufficient for the plugin. If you need to add any plugin specific
 configuration options you should use the ``register_opts`` and
 ``get_opt_lists`` methods to pass them to Tempest when the plugin is loaded.
 When adding configuration options the ``register_opts`` method gets passed the
 CONF object from tempest. This enables the plugin to add options to both
 existing sections and also create new configuration sections for new options.

 Service Clients
 ---------------

 If a plugin defines a service client, it is beneficial for it to implement the
 ``get_service_clients`` method in the plugin class. All service clients which
 are exposed via this interface will be automatically configured and be
 available in any instance of the service clients class, defined in
 ``tempest.lib.services.clients.ServiceClients``. In case multiple plugins are
 installed, all service clients from all plugins will be registered, making it
 easy to write tests which rely on multiple APIs whose service clients are in
 different plugins.

 Example implementation of ``get_service_clients``::

     def get_service_clients(self):
         # Example implementation with two service clients
         my_service1_config = config.service_client_config('my_service')
         params_my_service1 = {
             'name': 'my_service_v1',
             'service_version': 'my_service.v1',
             'module_path': 'plugin_tempest_tests.services.my_service.v1',
             'client_names': ['API1Client', 'API2Client'],
         }
         params_my_service1.update(my_service_config)
         my_service2_config = config.service_client_config('my_service')
         params_my_service2 = {
             'name': 'my_service_v2',
             'service_version': 'my_service.v2',
             'module_path': 'plugin_tempest_tests.services.my_service.v2',
             'client_names': ['API1Client', 'API2Client'],
         }
         params_my_service2.update(my_service2_config)
         return [params_my_service1, params_my_service2]

 Parameters:

 * **name**: Name of the attribute used to access the ``ClientsFactory`` from
   the ``ServiceClients`` instance. See example below.
 * **service_version**: Tempest enforces a single implementation for each
   service client. Available service clients are held in a ``ClientsRegistry``
   singleton, and registered with ``service_version``, which means that
   ``service_version`` must be unique and it should represent the service API
   and version implemented by the service client.
 * **module_path**: Relative to the service client module, from the root of the
   plugin.
 * **client_names**: Name of the classes that implement service clients in the
   service clients module.

 Example usage of the the service clients in tests::

    # my_creds is instance of tempest.lib.auth.Credentials
    # identity_uri is v2 or v3 depending on the configuration
    from tempest.lib.services import clients

    my_clients = clients.ServiceClients(my_creds, identity_uri)
    my_service1_api1_client = my_clients.my_service_v1.API1Client()
    my_service2_api1_client = my_clients.my_service_v2.API1Client(my_args='any')

 Automatic configuration and registration of service clients imposes some extra
 constraints on the structure of the configuration options exposed by the
 plugin.

 First ``service_version`` should be in the format `service_config[.version]`.
 The `.version` part is optional, and should only be used if there are multiple
 versions of the same API available. The `service_config` must match the name of
 a configuration options group defined by the plugin. Different versions of one
 API must share the same configuration group.

 Second the configuration options group `service_config` must contain the
 following options:

 * `catalog_type`: corresponds to `service` in the catalog
 * `endpoint_type`

 The following options will be honoured if defined, but they are not mandatory,
 as they do not necessarily apply to all service clients.

 * `region`: default to identity.region
 * `build_timeout` : default to compute.build_timeout
 * `build_interval`: default to compute.build_interval

 Third the service client classes should inherit from ``RestClient``, should
 accept generic keyword arguments, and should pass those arguments to the
 ``__init__`` method of ``RestClient``. Extra arguments can be added. For
 instance::

    class MyAPIClient(rest_client.RestClient):

     def __init__(self, auth_provider, service, region,
                  my_arg, my_arg2=True, **kwargs):
         super(MyAPIClient, self).__init__(
             auth_provider, service, region, **kwargs)
         self.my_arg = my_arg
         self.my_args2 = my_arg

 Finally the service client should be structured in a python module, so that all
 service client classes are importable from it. Each major API version should
 have its own module.

 The following folder and module structure is recommended for a single major
 API version::

     plugin_dir/
       services/
         __init__.py
         client_api_1.py
         client_api_2.py

 The content of __init__.py module should be::

    from client_api_1.py import API1Client
    from client_api_2.py import API2Client

    __all__ = ['API1Client', 'API2Client']

 The following folder and module structure is recommended for multiple major
 API version::

     plugin_dir/
       services/
         v1/
            __init__.py
            client_api_1.py
            client_api_2.py
         v2/
            __init__.py
            client_api_1.py
            client_api_2.py

 The content each of __init__.py module under vN should be::

    from client_api_1.py import API1Client
    from client_api_2.py import API2Client

    __all__ = ['API1Client', 'API2Client']

 Using Plugins
 =============

 Tempest will automatically discover any installed plugins when it is run. So by
 just installing the python packages which contain your plugin you'll be using
 them with tempest, nothing else is really required.

 However, you should take care when installing plugins. By their very nature
 there are no guarantees when running tempest with plugins enabled about the
 quality of the plugin. Additionally, while there is no limitation on running
 with multiple plugins it's worth noting that poorly written plugins might not
 properly isolate their tests which could cause unexpected cross interactions
 between plugins.

 Notes for using plugins with virtualenvs
 ----------------------------------------

 When using a tempest inside a virtualenv (like when running under tox) you have
 to ensure that the package that contains your plugin is either installed in the
 venv too or that you have system site-packages enabled. The virtualenv will
 isolate the tempest install from the rest of your system so just installing the
 plugin package on your system and then running tempest inside a venv will not
 work.

 Tempest also exposes a tox job, all-plugin, which will setup a tox virtualenv
 with system site-packages enabled. This will let you leverage tox without
 requiring to manually install plugins in the tox venv before running tests.
	=============================
	Tempest Test Plugin Interface
	=============================

	Tempest has an external test plugin interface which enables anyone to integrate
	an external test suite as part of a tempest run. This will let any project
	leverage being run with the rest of the tempest suite while not requiring the
	tests live in the tempest tree.

	Creating a plugin
	=================

	Creating a plugin is fairly straightforward and doesn't require much additional
	effort on top of creating a test suite using tempest.lib. One thing to note with
	doing this is that the interfaces exposed by tempest are not considered stable
	(with the exception of configuration variables which ever effort goes into
	ensuring backwards compatibility). You should not need to import anything from
	tempest itself except where explicitly noted.

	Stable Tempest APIs plugins may use
	-----------------------------------

	As noted above, several tempest APIs are acceptable to use from plugins, while
	others are not. A list of stable APIs available to plugins is provided below:

	* tempest.lib.*
	* tempest.config
	* tempest.test_discover.plugins

	If there is an interface from tempest that you need to rely on in your plugin
	which is not listed above, it likely needs to be migrated to tempest.lib. In
	that situation, file a bug, push a migration patch, etc. to expedite providing
	the interface in a reliable manner.

	Plugin Cookiecutter
	-------------------

	In order to create the basic structure with base classes and test directories
	you can use the tempest-plugin-cookiecutter project::

	> pip install -U cookiecutter && cookiecutter https://git.openstack.org/openstack/tempest-plugin-cookiecutter

	Cloning into 'tempest-plugin-cookiecutter'...
	remote: Counting objects: 17, done.
	remote: Compressing objects: 100% (13/13), done.
	remote: Total 17 (delta 1), reused 14 (delta 1)
	Unpacking objects: 100% (17/17), done.
	Checking connectivity... done.
	project (default is "sample")? foo
	testclass (default is "SampleTempestPlugin")? FooTempestPlugin

	This would create a folder called ``foo_tempest_plugin/`` with all necessary
	basic classes. You only need to move/create your test in
	``foo_tempest_plugin/tests``.

	Entry Point
	-----------

	Once you've created your plugin class you need to add an entry point to your
	project to enable tempest to find the plugin. The entry point must be added
	to the "tempest.test_plugins" namespace.

	If you are using pbr this is fairly straightforward, in the setup.cfg just add
	something like the following::

	[entry_points]
	tempest.test_plugins =
	plugin_name = module.path:PluginClass

	Standalone Plugin vs In-repo Plugin
	-----------------------------------

	Since all that's required for a plugin to be detected by tempest is a valid
	setuptools entry point in the proper namespace there is no difference from the
	tempest perspective on either creating a separate python package to
	house the plugin or adding the code to an existing python project. However,
	there are tradeoffs to consider when deciding which approach to take when
	creating a new plugin.

	If you create a separate python project for your plugin this makes a lot of
	things much easier. Firstly it makes packaging and versioning much simpler, you
	can easily decouple the requirements for the plugin from the requirements for
	the other project. It lets you version the plugin independently and maintain a
	single version of the test code across project release boundaries (see the
	`Branchless Tempest Spec`_ for more details on this). It also greatly
	simplifies the install time story for external users. Instead of having to
	install the right version of a project in the same python namespace as tempest
	they simply need to pip install the plugin in that namespace. It also means
	that users don't have to worry about inadvertently installing a tempest plugin
	when they install another package.

	.. _Branchless Tempest Spec: http://specs.openstack.org/openstack/qa-specs/specs/tempest/implemented/branchless-tempest.html

	The sole advantage to integrating a plugin into an existing python project is
	that it enables you to land code changes at the same time you land test changes
	in the plugin. This reduces some of the burden on contributors by not having
	to land 2 changes to add a new API feature and then test it and doing it as a
	single combined commit.


	Plugin Class
	============

	To provide tempest with all the required information it needs to be able to run
	your plugin you need to create a plugin class which tempest will load and call
	to get information when it needs. To simplify creating this tempest provides an
	abstract class that should be used as the parent for your plugin. To use this
	you would do something like the following::

	from tempest.test_discover import plugins

	class MyPlugin(plugins.TempestPlugin):

	Then you need to ensure you locally define all of the mandatory methods in the
	abstract class, you can refer to the api doc below for a reference of what that
	entails.

	Abstract Plugin Class
	---------------------

	.. autoclass:: tempest.test_discover.plugins.TempestPlugin
	:members:

	Plugin Structure
	================
	While there are no hard and fast rules for the structure a plugin, there are
	basically no constraints on what the plugin looks like as long as the 2 steps
	above are done. However, there are some recommended patterns to follow to make
	it easy for people to contribute and work with your plugin. For example, if you
	create a directory structure with something like::

	plugin_dir/
	config.py
	plugin.py
	tests/
	api/
	scenario/
	services/
	client.py

	That will mirror what people expect from tempest. The file

	* config.py: contains any plugin specific configuration variables
	* plugin.py: contains the plugin class used for the entry point
	* tests: the directory where test discovery will be run, all tests should
	be under this dir
	* services: where the plugin specific service clients are

	Additionally, when you're creating the plugin you likely want to follow all
	of the tempest developer and reviewer documentation to ensure that the tests
	being added in the plugin act and behave like the rest of tempest.

	Dealing with configuration options
	----------------------------------

	Historically Tempest didn't provide external guarantees on its configuration
	options. However, with the introduction of the plugin interface this is no
	longer the case. An external plugin can rely on using any configuration option
	coming from Tempest, there will be at least a full deprecation cycle for any
	option before it's removed. However, just the options provided by Tempest
	may not be sufficient for the plugin. If you need to add any plugin specific
	configuration options you should use the ``register_opts`` and
	``get_opt_lists`` methods to pass them to Tempest when the plugin is loaded.
	When adding configuration options the ``register_opts`` method gets passed the
	CONF object from tempest. This enables the plugin to add options to both
	existing sections and also create new configuration sections for new options.

	Service Clients
	---------------

	If a plugin defines a service client, it is beneficial for it to implement the
	``get_service_clients`` method in the plugin class. All service clients which
	are exposed via this interface will be automatically configured and be
	available in any instance of the service clients class, defined in
	``tempest.lib.services.clients.ServiceClients``. In case multiple plugins are
	installed, all service clients from all plugins will be registered, making it
	easy to write tests which rely on multiple APIs whose service clients are in
	different plugins.

	Example implementation of ``get_service_clients``::

	def get_service_clients(self):
	# Example implementation with two service clients
	my_service1_config = config.service_client_config('my_service')
	params_my_service1 = {
	'name': 'my_service_v1',
	'service_version': 'my_service.v1',
	'module_path': 'plugin_tempest_tests.services.my_service.v1',
	'client_names': ['API1Client', 'API2Client'],
	}
	params_my_service1.update(my_service_config)
	my_service2_config = config.service_client_config('my_service')
	params_my_service2 = {
	'name': 'my_service_v2',
	'service_version': 'my_service.v2',
	'module_path': 'plugin_tempest_tests.services.my_service.v2',
	'client_names': ['API1Client', 'API2Client'],
	}
	params_my_service2.update(my_service2_config)
	return [params_my_service1, params_my_service2]

	Parameters:

	* name: Name of the attribute used to access the ``ClientsFactory`` from
	the ``ServiceClients`` instance. See example below.
	* service_version: Tempest enforces a single implementation for each
	service client. Available service clients are held in a ``ClientsRegistry``
	singleton, and registered with ``service_version``, which means that
	``service_version`` must be unique and it should represent the service API
	and version implemented by the service client.
	* module_path: Relative to the service client module, from the root of the
	plugin.
	* client_names: Name of the classes that implement service clients in the
	service clients module.

	Example usage of the the service clients in tests::

	# my_creds is instance of tempest.lib.auth.Credentials
	# identity_uri is v2 or v3 depending on the configuration
	from tempest.lib.services import clients

	my_clients = clients.ServiceClients(my_creds, identity_uri)
	my_service1_api1_client = my_clients.my_service_v1.API1Client()
	my_service2_api1_client = my_clients.my_service_v2.API1Client(my_args='any')

	Automatic configuration and registration of service clients imposes some extra
	constraints on the structure of the configuration options exposed by the
	plugin.

	First ``service_version`` should be in the format `service_config[.version]`.
	The `.version` part is optional, and should only be used if there are multiple
	versions of the same API available. The `service_config` must match the name of
	a configuration options group defined by the plugin. Different versions of one
	API must share the same configuration group.

	Second the configuration options group `service_config` must contain the
	following options:

	* `catalog_type`: corresponds to `service` in the catalog
	* `endpoint_type`

	The following options will be honoured if defined, but they are not mandatory,
	as they do not necessarily apply to all service clients.

	* `region`: default to identity.region
	* `build_timeout` : default to compute.build_timeout
	* `build_interval`: default to compute.build_interval

	Third the service client classes should inherit from ``RestClient``, should
	accept generic keyword arguments, and should pass those arguments to the
	``__init__`` method of ``RestClient``. Extra arguments can be added. For
	instance::

	class MyAPIClient(rest_client.RestClient):

	def __init__(self, auth_provider, service, region,
	my_arg, my_arg2=True, **kwargs):
	super(MyAPIClient, self).__init__(
	auth_provider, service, region, **kwargs)
	self.my_arg = my_arg
	self.my_args2 = my_arg

	Finally the service client should be structured in a python module, so that all
	service client classes are importable from it. Each major API version should
	have its own module.

	The following folder and module structure is recommended for a single major
	API version::

	plugin_dir/
	services/
	__init__.py
	client_api_1.py
	client_api_2.py

	The content of __init__.py module should be::

	from client_api_1.py import API1Client
	from client_api_2.py import API2Client

	__all__ = ['API1Client', 'API2Client']

	The following folder and module structure is recommended for multiple major
	API version::

	plugin_dir/
	services/
	v1/
	__init__.py
	client_api_1.py
	client_api_2.py
	v2/
	__init__.py
	client_api_1.py
	client_api_2.py

	The content each of __init__.py module under vN should be::

	from client_api_1.py import API1Client
	from client_api_2.py import API2Client

	__all__ = ['API1Client', 'API2Client']

	Using Plugins
	=============

	Tempest will automatically discover any installed plugins when it is run. So by
	just installing the python packages which contain your plugin you'll be using
	them with tempest, nothing else is really required.

	However, you should take care when installing plugins. By their very nature
	there are no guarantees when running tempest with plugins enabled about the
	quality of the plugin. Additionally, while there is no limitation on running
	with multiple plugins it's worth noting that poorly written plugins might not
	properly isolate their tests which could cause unexpected cross interactions
	between plugins.

	Notes for using plugins with virtualenvs
	----------------------------------------

	When using a tempest inside a virtualenv (like when running under tox) you have
	to ensure that the package that contains your plugin is either installed in the
	venv too or that you have system site-packages enabled. The virtualenv will
	isolate the tempest install from the rest of your system so just installing the
	plugin package on your system and then running tempest inside a venv will not
	work.

	Tempest also exposes a tox job, all-plugin, which will setup a tox virtualenv
	with system site-packages enabled. This will let you leverage tox without
	requiring to manually install plugins in the tox venv before running tests.