Adding a documentation entry for the recently created multinode attribute. Change-Id: I082cce3a88a6ae88d6c671204155595c917ac08a
22 KiB
Tempest Coding Guide
- Step 1: Read the OpenStack Style Commandments https://docs.openstack.org/hacking/latest/
- Step 2: Read on
Tempest Specific Commandments
- [T102] Cannot import OpenStack python clients in tempest/api & tempest/scenario tests
- [T104] Scenario tests require a services decorator
- [T105] Tests cannot use setUpClass/tearDownClass
- [T107] Check that a service tag isn't in the module path
- [T108] Check no hyphen at the end of rand_name() argument
- [T109] Cannot use testtools.skip decorator; instead use decorators.skip_because from tempest.lib
- [T110] Check that service client names of GET should be consistent
- [T111] Check that service client names of DELETE should be consistent
- [T112] Check that tempest.lib should not import local tempest code
- [T113] Check that tests use data_utils.rand_uuid() instead of uuid.uuid4()
- [T114] Check that tempest.lib does not use tempest config
- [T115] Check that admin tests should exist under admin path
- [N322] Method's default argument shouldn't be mutable
- [T116] Unsupported 'message' Exception attribute in PY3
- [T117] Check negative tests have
@decorators.attr(type=['negative'])
applied. - [T118] LOG.warn is deprecated. Enforce use of LOG.warning.
It is recommended to use tox -eautopep8
before
submitting a patch.
Test Data/Configuration
- Assume nothing about existing test data
- Tests should be self contained (provide their own data)
- Clean up test data at the completion of each test
- Use configuration files for values that will vary by environment
Supported OpenStack Components
Tempest's library
and plugin interface <tempest_plugin>
can be
leveraged to support integration testing for virtually any OpenStack
component.
However, Tempest only offers in-tree integration testing coverage for the following components:
- Cinder
- Glance
- Keystone
- Neutron
- Nova
- Swift
Historically, Tempest offered in-tree testing for other components as well, but since the introduction of the External Plugin Interface, Tempest's in-tree testing scope has been limited to the projects above. Integration tests for projects not included above should go into one of the relevant plugin projects.
Exception Handling
According to the The Zen of Python
the
Errors should never pass silently.
Tempest usually runs in
special environment (jenkins gate jobs), in every error or failure
situation we should provide as much error related information as
possible, because we usually do not have the chance to investigate the
situation after the issue happened.
In every test case the abnormal situations must be very verbosely explained, by the exception and the log.
In most cases the very first issue is the most important information.
Try to avoid using try
blocks in the test cases, as both
the except
and finally
blocks could replace
the original exception, when the additional operations leads to another
exception.
Just letting an exception to propagate, is not a bad idea in a test case, at all.
Try to avoid using any exception handling construct which can hide the errors origin.
If you really need to use a try
block, please ensure the
original exception at least logged. When the exception is logged you
usually need to raise
the same or a different exception
anyway.
Use of self.addCleanup
is often a good way to avoid
having to catch exceptions and still ensure resources are correctly
cleaned up if the test fails part way through.
Use the self.assert*
methods provided by the unit test
framework. This signals the failures early on.
Avoid using the self.fail
alone, its stack trace will
signal the self.fail
line as the origin of the error.
Avoid constructing complex boolean expressions for assertion. The
self.assertTrue
or self.assertFalse
without a
msg
argument, will just tell you the single boolean value,
and you will not know anything about the values used in the formula, the
msg
argument might be good enough for providing more
information.
Most other assert method can include more information by default. For
example self.assertIn
can include the whole set.
It is recommended to use testtools matcher for the more tricky assertions. You can implement your own specific matcher as well.
If the test case fails you can see the related logs and the information carried by the exception (exception class, backtrack and exception info). This and the service logs are your only guide to finding the root cause of flaky issues.
Test cases are independent
Every test_method
must be callable individually and MUST
NOT depends on, any other test_method
or
test_method
ordering.
Test cases MAY depend on commonly initialized resources/facilities,
like credentials management, testresources and so on. These facilities,
MUST be able to work even if just one test_method
is
selected for execution.
Service Tagging
Service tagging is used to specify which services are exercised by a
particular test method. You specify the services with the
tempest.common.utils.services
decorator. For example:
@utils.services('compute', 'image')
Valid service tag names are the same as the list of directories in tempest.api that have tests.
For scenario tests having a service tag is required. For the API
tests service tags are only needed if the test method makes an API call
(either directly or indirectly through another service) that differs
from the parent directory name. For example, any test that make an API
call to a service other than Nova in tempest.api.compute
would require a service tag for those services, however they do not need
to be tagged as compute
.
Test Attributes
Tempest leverages test
attributes which are a simple but effective way of distinguishing
between different "types" of API tests. A test can be "tagged" with such
attributes using the decorators.attr
decorator, for
example:
@decorators.attr(type=['negative'])
def test_aggregate_create_aggregate_name_length_less_than_1(self):
[...]
These test attributes can be used for test selection via regular
expressions. For example,
(?!.*\[.*\bslow\b.*\])(^tempest\.scenario)
runs all the
tests in the scenario
test module, except for
those tagged with the slow
attribute (via a negative
lookahead in the regular expression). These attributes are used in
Tempest's tox.ini
as well as Tempest's Zuul job definitions
for specifying particular batches of Tempest test suites to run.
Negative Attribute
The type='negative'
attribute is used to signify that a
test is a negative test, which is a test that handles invalid input
gracefully. This attribute should be applied to all negative test
scenarios.
This attribute must be applied to each test that belongs to a negative test class, i.e. a test class name ending with "Negative.*" substring.
Slow Attribute
The type='slow'
attribute is used to signify that a test
takes a long time to run, relatively speaking. This attribute is usually
applied to scenario tests <scenario_field_guide>
, which
involve a complicated series of API operations, the total runtime of
which can be relatively long. This long runtime has performance
implications on Zuul jobs, which is
why the slow
attribute is leveraged to run slow tests on a
selective basis, to keep total Zuul job runtime down
to a reasonable time frame.
Smoke Attribute
The type='smoke'
attribute is used to signify that a
test is a so-called smoke test, which is a type of test that tests the
most vital OpenStack functionality, like listing servers or flavors or
creating volumes. The attribute should be sparingly applied to only the
tests that sanity-check the most essential functionality of an OpenStack
cloud.
Multinode Attribute
The type='multinode'
attribute is used to signify that a
test is desired to be executed in a multinode environment. By marking
the tests with this attribute we can avoid running tests which aren't
that beneficial for the multinode setup and thus reduce the consumption
of resources.
Test fixtures and resources
Test level resources should be cleaned-up after the test execution.
Clean-up is best scheduled using addCleanup
which ensures
that the resource cleanup code is always invoked, and in reverse order
with respect to the creation order.
Test class level resources should be defined in the
resource_setup
method of the test class, except for any
credential obtained from the credentials provider, which should be
set-up in the setup_credentials
method. Cleanup is best
scheduled using addClassResourceCleanup
which ensures that
the cleanup code is always invoked, and in reverse order with respect to
the creation order.
In both cases - test level and class level cleanups - a wait loop should be scheduled before the actual delete of resources with an asynchronous delete.
The test base class BaseTestCase
defines Tempest
framework for class level fixtures. setUpClass
and
tearDownClass
are defined here and cannot be overwritten by
subclasses (enforced via hacking rule T105).
Set-up is split in a series of steps (setup stages), which can be overwritten by test classes. Set-up stages are:
skip_checks
setup_credentials
setup_clients
resource_setup
Tear-down is also split in a series of steps (teardown stages), which are stacked for execution only if the corresponding setup stage had been reached during the setup phase. Tear-down stages are:
clear_credentials
(defined in the base test class)resource_cleanup
Skipping Tests
Skipping tests should be based on configuration only. If that is not possible, it is likely that either a configuration flag is missing, or the test should fail rather than be skipped. Using discovery for skipping tests is generally discouraged.
When running a test that requires a certain "feature" in the target cloud, if that feature is missing we should fail, because either the test configuration is invalid, or the cloud is broken and the expected "feature" is not there even if the cloud was configured with it.
Negative Tests
Error handling is an important aspect of API design and usage. Negative tests are a way to ensure that an application can gracefully handle invalid or unexpected input. However, as a black box integration test suite, Tempest is not suitable for handling all negative test cases, as the wide variety and complexity of negative tests can lead to long test runs and knowledge of internal implementation details. The bulk of negative testing should be handled with project function tests. All negative tests should be based on API-WG guideline . Such negative tests can block any changes from accurate failure code to invalid one.
If facing some gray area which is not clarified on the above guideline, propose a new guideline to the API-WG. With a proposal to the API-WG we will be able to build a consensus across all OpenStack projects and improve the quality and consistency of all the APIs.
In addition, we have some guidelines for additional negative tests.
- About BadRequest(HTTP400) case: We can add a single negative tests of BadRequest for each resource and method(POST, PUT). Please don't implement more negative tests on the same combination of resource and method even if API request parameters are different from the existing test.
- About NotFound(HTTP404) case: We can add a single negative tests of NotFound for each resource and method(GET, PUT, DELETE, HEAD). Please don't implement more negative tests on the same combination of resource and method.
The above guidelines don't cover all cases and we will grow these guidelines organically over time. Patches outside of the above guidelines are left up to the reviewers' discretion and if we face some conflicts between reviewers, we will expand the guideline based on our discussion and experience.
Test skips because of Known Bugs
If a test is broken because of a bug it is appropriate to skip the
test until bug has been fixed. You should use the
skip_because
decorator so that Tempest's skip tracking tool
can watch the bug status.
Example:
@skip_because(bug="980688")
def test_this_and_that(self):
...
Guidelines
- Do not submit changesets with only testcases which are skipped as they will not be merged.
- Consistently check the status code of responses in testcases. The earlier a problem is detected the easier it is to debug, especially where there is complicated setup required.
Parallel Test Execution
Tempest by default runs its tests in parallel this creates the possibility for interesting interactions between tests which can cause unexpected failures. Dynamic credentials provides protection from most of the potential race conditions between tests outside the same class. But there are still a few of things to watch out for to try to avoid issues when running your tests in parallel.
- Resources outside of a project scope still have the potential to conflict. This is a larger concern for the admin tests since most resources and actions that require admin privileges are outside of projects.
- Races between methods in the same class are not a problem because parallelization in Tempest is at the test class level, but if there is a json and xml version of the same test class there could still be a race between methods.
- The rand_name() function from tempest.lib.common.utils.data_utils should be used anywhere a resource is created with a name. Static naming should be avoided to prevent resource conflicts.
- If the execution of a set of tests is required to be serialized then
locking can be used to perform this. See usage of
LockFixture
for examples of using locking. However, LockFixture only helps if you want to separate the execution of two small sets of test cases. On the other hand, if you need to run a set of tests separately from potentially all other tests thenLockFixture
does not scale as you would need to take the lock in all the other tests too. In this case, you can use the@serial
decorator on top of the test class holding the tests that need to run separately from the potentially parallel test set. See more intempest_test_writing
.
Sample Configuration File
The sample config file is autogenerated using a script. If any changes are made to the config variables in tempest/config.py then the sample config file must be regenerated. This can be done running:
tox -e genconfig
Unit Tests
Unit tests are a separate class of tests in Tempest. They verify Tempest itself, and thus have a different set of guidelines around them:
- They can not require anything running externally. All you should need to run the unit tests is the git tree, python and the dependencies installed. This includes running services, a config file, etc.
- The unit tests cannot use setUpClass, instead fixtures and testresources should be used for shared state between tests.
Test Documentation
For tests being added we need to require inline documentation in the form of docstrings to explain what is being tested. In API tests for a new API a class level docstring should be added to an API reference doc. If one doesn't exist a TODO comment should be put indicating that the reference needs to be added. For individual API test cases a method level docstring should be used to explain the functionality being tested if the test name isn't descriptive enough. For example:
def test_get_role_by_id(self):
"""Get a role by its id."""
the docstring there is superfluous and shouldn't be added. but for a method like:
def test_volume_backup_create_get_detailed_list_restore_delete(self):
pass
a docstring would be useful because while the test title is fairly descriptive the operations being performed are complex enough that a bit more explanation will help people figure out the intent of the test.
For scenario tests a class level docstring describing the steps in the scenario is required. If there is more than one test case in the class individual docstrings for the workflow in each test methods can be used instead. A good example of this would be:
class TestServerBasicOps(manager.ScenarioTest):
"""The test suite for server basic operations
This smoke test case follows this basic set of operations:
* Create a keypair for use in launching an instance
* Create a security group to control network access in instance
* Add simple permissive rules to the security group
* Launch an instance
* Perform ssh to instance
* Verify metadata service
* Verify metadata on config_drive
* Terminate the instance
"""
Test Identification with Idempotent ID
Every function that provides a test must have an
idempotent_id
decorator that is a unique
uuid-4
instance. This ID is used to complement the fully
qualified test name and track test functionality through refactoring.
The format of the metadata looks like:
@decorators.idempotent_id('585e934c-448e-43c4-acbf-d06a9b899997')
def test_list_servers_with_detail(self):
# The created server should be in the detailed list of all servers
...
Tempest.lib includes a check-uuid
tool that will test
for the existence and uniqueness of idempotent_id metadata for every
test. If you have Tempest installed you run the tool against Tempest by
calling from the Tempest repo:
check-uuid
It can be invoked against any test suite by passing a package name:
check-uuid --package <package_name>
Tests without an idempotent_id
can be automatically
fixed by running the command with the --fix
flag, which
will modify the source package by inserting randomly generated uuids for
every test that does not have one:
check-uuid --fix
The check-uuid
tool is used as part of the Tempest gate
job to ensure that all tests have an idempotent_id
decorator.
Branchless Tempest Considerations
Starting with the OpenStack Icehouse release Tempest no longer has any stable branches. This is to better ensure API consistency between releases because the API behavior should not change between releases. This means that the stable branches are also gated by the Tempest master branch, which also means that proposed commits to Tempest must work against both the master and all the currently supported stable branches of the projects. As such there are a few special considerations that have to be accounted for when pushing new changes to Tempest.
1. New Tests for new features
When adding tests for new features that were not in previous releases
of the projects the new test has to be properly skipped with a feature
flag. This can be just as simple as using the
@utils.requires_ext()
or testtools.skipUnless
decorators to check if the required extension (or discoverable optional
API) or feature is enabled or can be as difficult as adding a new config
option to the appropriate section. If there isn't a method of selecting
the new feature from the config file then there won't
be a mechanism to disable the test with older stable releases and the
new test won't be able to merge.
Introduction of a new feature flag requires specifying a default value for the corresponding config option that is appropriate in the latest OpenStack release. Because Tempest is branchless, the feature flag's default value will need to be overridden to a value that is appropriate in earlier releases in which the feature isn't available. In DevStack, this can be accomplished by modifying Tempest's lib installation script for previous branches (because DevStack is branched).
2. Bug fix on core project needing Tempest changes
When trying to land a bug fix which changes a tested API you'll have to use the following procedure:
1. Propose change to the project, get a +2 on the change even with failing
2. Propose skip on Tempest which will only be approved after the
corresponding change in the project has a +2 on change
3. Land project change in master and all open stable branches (if required)
4. Land changed test in Tempest
Otherwise the bug fix won't be able to land in the project.
Handily, Zuul's cross-repository dependencies. can be leveraged to do without step 2 and to have steps 3 and 4 happen "atomically". To do that, make the patch written in step 1 to depend (refer to Zuul's documentation above) on the patch written in step 4. The commit message for the Tempest change should have a link to the Gerrit review that justifies that change.
3. New Tests for existing features
If a test is being added for a feature that exists in all the current releases of the projects then the only concern is that the API behavior is the same across all the versions of the project being tested. If the behavior is not consistent the test will not be able to merge.
API Stability
For new tests being added to Tempest the assumption is that the API being tested is considered stable and adheres to the OpenStack API stability guidelines. If an API is still considered experimental or in development then it should not be tested by Tempest until it is considered stable.