blob: 81c24a8c3f4ef422d3ccfebd3a9899265d2dea49 [file] [log] [blame]
.. SPDX-License-Identifier: CC-BY-SA-2.0-UK
*****************************************
The Yocto Project Test Environment Manual
*****************************************
Welcome
=======
Welcome to the Yocto Project Test Environment Manual! This manual is a
work in progress. The manual contains information about the testing
environment used by the Yocto Project to make sure each major and minor
release works as intended. All the project's testing infrastructure and
processes are publicly visible and available so that the community can
see what testing is being performed, how it's being done and the current
status of the tests and the project at any given time. It is intended
that Other organizations can leverage off the process and testing
environment used by the Yocto Project to create their own automated,
production test environment, building upon the foundations from the
project core.
Currently, the Yocto Project Test Environment Manual has no projected
release date. This manual is a work-in-progress and is being initially
loaded with information from the README files and notes from key
engineers:
- *yocto-autobuilder2:* This
:yocto_git:`README.md </yocto-autobuilder2/tree/README.md>`
is the main README which detials how to set up the Yocto Project
Autobuilder. The ``yocto-autobuilder2`` repository represents the
Yocto Project's console UI plugin to Buildbot and the configuration
necessary to configure Buildbot to perform the testing the project
requires.
- *yocto-autobuilder-helper:* This :yocto_git:`README </yocto-autobuilder-helper/tree/README/>`
and repository contains Yocto Project Autobuilder Helper scripts and
configuration. The ``yocto-autobuilder-helper`` repository contains
the "glue" logic that defines which tests to run and how to run them.
As a result, it can be used by any Continuous Improvement (CI) system
to run builds, support getting the correct code revisions, configure
builds and layers, run builds, and collect results. The code is
independent of any CI system, which means the code can work `Buildbot <https://docs.buildbot.net/0.9.15.post1/>`__,
Jenkins, or others. This repository has a branch per release of the
project defining the tests to run on a per release basis.
Yocto Project Autobuilder Overview
==================================
The Yocto Project Autobuilder collectively refers to the software,
tools, scripts, and procedures used by the Yocto Project to test
released software across supported hardware in an automated and regular
fashion. Basically, during the development of a Yocto Project release,
the Autobuilder tests if things work. The Autobuilder builds all test
targets and runs all the tests.
The Yocto Project uses now uses standard upstream
`Buildbot <https://docs.buildbot.net/0.9.15.post1/>`__ (version 9) to
drive its integration and testing. Buildbot Nine has a plug-in interface
that the Yocto Project customizes using code from the
``yocto-autobuilder2`` repository, adding its own console UI plugin. The
resulting UI plug-in allows you to visualize builds in a way suited to
the project's needs.
A ``helper`` layer provides configuration and job management through
scripts found in the ``yocto-autobuilder-helper`` repository. The
``helper`` layer contains the bulk of the build configuration
information and is release-specific, which makes it highly customizable
on a per-project basis. The layer is CI system-agnostic and contains a
number of Helper scripts that can generate build configurations from
simple JSON files.
.. note::
The project uses Buildbot for historical reasons but also because
many of the project developers have knowledge of python. It is
possible to use the outer layers from another Continuous Integration
(CI) system such as
`Jenkins <https://en.wikipedia.org/wiki/Jenkins_(software)>`__
instead of Buildbot.
The following figure shows the Yocto Project Autobuilder stack with a
topology that includes a controller and a cluster of workers:
.. image:: figures/ab-test-cluster.png
:align: center
Yocto Project Tests - Types of Testing Overview
===============================================
The Autobuilder tests different elements of the project by using
thefollowing types of tests:
- *Build Testing:* Tests whether specific configurations build by
varying :term:`MACHINE`,
:term:`DISTRO`, other configuration
options, and the specific target images being built (or world). Used
to trigger builds of all the different test configurations on the
Autobuilder. Builds usually cover many different targets for
different architectures, machines, and distributions, as well as
different configurations, such as different init systems. The
Autobuilder tests literally hundreds of configurations and targets.
- *Sanity Checks During the Build Process:* Tests initiated through
the :ref:`insane <ref-classes-insane>`
class. These checks ensure the output of the builds are correct.
For example, does the ELF architecture in the generated binaries
match the target system? ARM binaries would not work in a MIPS
system!
- *Build Performance Testing:* Tests whether or not commonly used steps
during builds work efficiently and avoid regressions. Tests to time
commonly used usage scenarios are run through ``oe-build-perf-test``.
These tests are run on isolated machines so that the time
measurements of the tests are accurate and no other processes
interfere with the timing results. The project currently tests
performance on two different distributions, Fedora and Ubuntu, to
ensure we have no single point of failure and can ensure the
different distros work effectively.
- *eSDK Testing:* Image tests initiated through the following command::
$ bitbake image -c testsdkext
The tests utilize the ``testsdkext`` class and the ``do_testsdkext`` task.
- *Feature Testing:* Various scenario-based tests are run through the
:ref:`OpenEmbedded Self test (oe-selftest) <ref-manual/release-process:Testing and Quality Assurance>`. We test oe-selftest on each of the main distrubutions
we support.
- *Image Testing:* Image tests initiated through the following command::
$ bitbake image -c testimage
The tests utilize the :ref:`testimage* <ref-classes-testimage*>`
classes and the :ref:`ref-tasks-testimage` task.
- *Layer Testing:* The Autobuilder has the possibility to test whether
specific layers work with the test of the system. The layers tested
may be selected by members of the project. Some key community layers
are also tested periodically.
- *Package Testing:* A Package Test (ptest) runs tests against packages
built by the OpenEmbedded build system on the target machine. See the
:ref:`Testing Packages With
ptest <dev-manual/common-tasks:Testing Packages With ptest>` section
in the Yocto Project Development Tasks Manual and the
":yocto_wiki:`Ptest </Ptest>`" Wiki page for more
information on Ptest.
- *SDK Testing:* Image tests initiated through the following command::
$ bitbake image -c testsdk
The tests utilize the :ref:`testsdk <ref-classes-testsdk>` class and
the ``do_testsdk`` task.
- *Unit Testing:* Unit tests on various components of the system run
through :ref:`bitbake-selftest <ref-manual/release-process:Testing and Quality Assurance>` and
:ref:`oe-selftest <ref-manual/release-process:Testing and Quality Assurance>`.
- *Automatic Upgrade Helper:* This target tests whether new versions of
software are available and whether we can automatically upgrade to
those new versions. If so, this target emails the maintainers with a
patch to let them know this is possible.
How Tests Map to Areas of Code
==============================
Tests map into the codebase as follows:
- *bitbake-selftest:*
These tests are self-contained and test BitBake as well as its APIs,
which include the fetchers. The tests are located in
``bitbake/lib/*/tests``.
From within the BitBake repository, run the following::
$ bitbake-selftest
To skip tests that access the Internet, use the ``BB_SKIP_NETTEST``
variable when running "bitbake-selftest" as follows::
$ BB_SKIP_NETTEST=yes bitbake-selftest
The default output is quiet and just prints a summary of what was
run. To see more information, there is a verbose option::
$ bitbake-selftest -v
Use this option when you wish to skip tests that access the network,
which are mostly necessary to test the fetcher modules. To specify
individual test modules to run, append the test module name to the
"bitbake-selftest" command. For example, to specify the tests for the
bb.data.module, run::
$ bitbake-selftest bb.test.data.module
You can also specify individual tests by defining the full name and module
plus the class path of the test, for example::
$ bitbake-selftest bb.tests.data.TestOverrides.test_one_override
The tests are based on `Python
unittest <https://docs.python.org/3/library/unittest.html>`__.
- *oe-selftest:*
- These tests use OE to test the workflows, which include testing
specific features, behaviors of tasks, and API unit tests.
- The tests can take advantage of parallelism through the "-j"
option, which can specify a number of threads to spread the tests
across. Note that all tests from a given class of tests will run
in the same thread. To parallelize large numbers of tests you can
split the class into multiple units.
- The tests are based on Python unittest.
- The code for the tests resides in
``meta/lib/oeqa/selftest/cases/``.
- To run all the tests, enter the following command::
$ oe-selftest -a
- To run a specific test, use the following command form where
testname is the name of the specific test::
$ oe-selftest -r <testname>
For example, the following command would run the tinfoil
getVar API test::
$ oe-selftest -r tinfoil.TinfoilTests.test_getvar
It is also possible to run a set
of tests. For example the following command will run all of the
tinfoil tests::
$ oe-selftest -r tinfoil
- *testimage:*
- These tests build an image, boot it, and run tests against the
image's content.
- The code for these tests resides in ``meta/lib/oeqa/runtime/cases/``.
- You need to set the :term:`IMAGE_CLASSES` variable as follows::
IMAGE_CLASSES += "testimage"
- Run the tests using the following command form::
$ bitbake image -c testimage
- *testsdk:*
- These tests build an SDK, install it, and then run tests against
that SDK.
- The code for these tests resides in ``meta/lib/oeqa/sdk/cases/``.
- Run the test using the following command form::
$ bitbake image -c testsdk
- *testsdk_ext:*
- These tests build an extended SDK (eSDK), install that eSDK, and
run tests against the eSDK.
- The code for these tests resides in ``meta/lib/oeqa/esdk``.
- To run the tests, use the following command form::
$ bitbake image -c testsdkext
- *oe-build-perf-test:*
- These tests run through commonly used usage scenarios and measure
the performance times.
- The code for these tests resides in ``meta/lib/oeqa/buildperf``.
- To run the tests, use the following command form::
$ oe-build-perf-test <options>
The command takes a number of options,
such as where to place the test results. The Autobuilder Helper
Scripts include the ``build-perf-test-wrapper`` script with
examples of how to use the oe-build-perf-test from the command
line.
Use the ``oe-git-archive`` command to store test results into a
Git repository.
Use the ``oe-build-perf-report`` command to generate text reports
and HTML reports with graphs of the performance data. For
examples, see
:yocto_dl:`/releases/yocto/yocto-2.7/testresults/buildperf-centos7/perf-centos7.yoctoproject.org_warrior_20190414204758_0e39202.html`
and
:yocto_dl:`/releases/yocto/yocto-2.7/testresults/buildperf-centos7/perf-centos7.yoctoproject.org_warrior_20190414204758_0e39202.txt`.
- The tests are contained in ``lib/oeqa/buildperf/test_basic.py``.
Test Examples
=============
This section provides example tests for each of the tests listed in the
:ref:`test-manual/intro:How Tests Map to Areas of Code` section.
For oeqa tests, testcases for each area reside in the main test
directory at ``meta/lib/oeqa/selftest/cases`` directory.
For oe-selftest. bitbake testcases reside in the ``lib/bb/tests/``
directory.
``bitbake-selftest``
--------------------
A simple test example from ``lib/bb/tests/data.py`` is::
class DataExpansions(unittest.TestCase):
def setUp(self):
self.d = bb.data.init()
self.d["foo"] = "value_of_foo"
self.d["bar"] = "value_of_bar"
self.d["value_of_foo"] = "value_of_'value_of_foo'"
def test_one_var(self):
val = self.d.expand("${foo}")
self.assertEqual(str(val), "value_of_foo")
In this example, a ``DataExpansions`` class of tests is created,
derived from standard python unittest. The class has a common ``setUp``
function which is shared by all the tests in the class. A simple test is
then added to test that when a variable is expanded, the correct value
is found.
Bitbake selftests are straightforward python unittest. Refer to the
Python unittest documentation for additional information on writing
these tests at: https://docs.python.org/3/library/unittest.html.
``oe-selftest``
---------------
These tests are more complex due to the setup required behind the scenes
for full builds. Rather than directly using Python's unittest, the code
wraps most of the standard objects. The tests can be simple, such as
testing a command from within the OE build environment using the
following example::
class BitbakeLayers(OESelftestTestCase):
def test_bitbakelayers_showcrossdepends(self):
result = runCmd('bitbake-layers show-cross-depends')
self.assertTrue('aspell' in result.output, msg = "No dependencies were shown. bitbake-layers show-cross-depends output: %s"% result.output)
This example, taken from ``meta/lib/oeqa/selftest/cases/bblayers.py``,
creates a testcase from the ``OESelftestTestCase`` class, derived
from ``unittest.TestCase``, which runs the ``bitbake-layers`` command
and checks the output to ensure it contains something we know should be
here.
The ``oeqa.utils.commands`` module contains Helpers which can assist
with common tasks, including:
- *Obtaining the value of a bitbake variable:* Use
``oeqa.utils.commands.get_bb_var()`` or use
``oeqa.utils.commands.get_bb_vars()`` for more than one variable
- *Running a bitbake invocation for a build:* Use
``oeqa.utils.commands.bitbake()``
- *Running a command:* Use ``oeqa.utils.commandsrunCmd()``
There is also a ``oeqa.utils.commands.runqemu()`` function for launching
the ``runqemu`` command for testing things within a running, virtualized
image.
You can run these tests in parallel. Parallelism works per test class,
so tests within a given test class should always run in the same build,
while tests in different classes or modules may be split into different
builds. There is no data store available for these tests since the tests
launch the ``bitbake`` command and exist outside of its context. As a
result, common bitbake library functions (bb.\*) are also unavailable.
``testimage``
-------------
These tests are run once an image is up and running, either on target
hardware or under QEMU. As a result, they are assumed to be running in a
target image environment, as opposed to a host build environment. A
simple example from ``meta/lib/oeqa/runtime/cases/python.py`` contains
the following::
class PythonTest(OERuntimeTestCase):
@OETestDepends(['ssh.SSHTest.test_ssh'])
@OEHasPackage(['python3-core'])
def test_python3(self):
cmd = "python3 -c \\"import codecs; print(codecs.encode('Uryyb, jbeyq', 'rot13'))\""
status, output = self.target.run(cmd)
msg = 'Exit status was not 0. Output: %s' % output
self.assertEqual(status, 0, msg=msg)
In this example, the ``OERuntimeTestCase`` class wraps
``unittest.TestCase``. Within the test, ``self.target`` represents the
target system, where commands can be run on it using the ``run()``
method.
To ensure certain test or package dependencies are met, you can use the
``OETestDepends`` and ``OEHasPackage`` decorators. For example, the test
in this example would only make sense if python3-core is installed in
the image.
``testsdk_ext``
---------------
These tests are run against built extensible SDKs (eSDKs). The tests can
assume that the eSDK environment has already been setup. An example from
``meta/lib/oeqa/sdk/cases/devtool.py`` contains the following::
class DevtoolTest(OESDKExtTestCase):
@classmethod def setUpClass(cls):
myapp_src = os.path.join(cls.tc.esdk_files_dir, "myapp")
cls.myapp_dst = os.path.join(cls.tc.sdk_dir, "myapp")
shutil.copytree(myapp_src, cls.myapp_dst)
subprocess.check_output(['git', 'init', '.'], cwd=cls.myapp_dst)
subprocess.check_output(['git', 'add', '.'], cwd=cls.myapp_dst)
subprocess.check_output(['git', 'commit', '-m', "'test commit'"], cwd=cls.myapp_dst)
@classmethod
def tearDownClass(cls):
shutil.rmtree(cls.myapp_dst)
def _test_devtool_build(self, directory):
self._run('devtool add myapp %s' % directory)
try:
self._run('devtool build myapp')
finally:
self._run('devtool reset myapp')
def test_devtool_build_make(self):
self._test_devtool_build(self.myapp_dst)
In this example, the ``devtool``
command is tested to see whether a sample application can be built with
the ``devtool build`` command within the eSDK.
``testsdk``
-----------
These tests are run against built SDKs. The tests can assume that an SDK
has already been extracted and its environment file has been sourced. A
simple example from ``meta/lib/oeqa/sdk/cases/python2.py`` contains the
following::
class Python3Test(OESDKTestCase):
def setUp(self):
if not (self.tc.hasHostPackage("nativesdk-python3-core") or
self.tc.hasHostPackage("python3-core-native")):
raise unittest.SkipTest("No python3 package in the SDK")
def test_python3(self):
cmd = "python3 -c \\"import codecs; print(codecs.encode('Uryyb, jbeyq', 'rot13'))\""
output = self._run(cmd)
self.assertEqual(output, "Hello, world\n")
In this example, if nativesdk-python3-core has been installed into the SDK, the code runs
the python3 interpreter with a basic command to check it is working
correctly. The test would only run if python3 is installed in the SDK.
``oe-build-perf-test``
----------------------
The performance tests usually measure how long operations take and the
resource utilisation as that happens. An example from
``meta/lib/oeqa/buildperf/test_basic.py`` contains the following::
class Test3(BuildPerfTestCase):
def test3(self):
"""Bitbake parsing (bitbake -p)"""
# Drop all caches and parse
self.rm_cache()
oe.path.remove(os.path.join(self.bb_vars['TMPDIR'], 'cache'), True)
self.measure_cmd_resources(['bitbake', '-p'], 'parse_1',
'bitbake -p (no caches)')
# Drop tmp/cache
oe.path.remove(os.path.join(self.bb_vars['TMPDIR'], 'cache'), True)
self.measure_cmd_resources(['bitbake', '-p'], 'parse_2',
'bitbake -p (no tmp/cache)')
# Parse with fully cached data
self.measure_cmd_resources(['bitbake', '-p'], 'parse_3',
'bitbake -p (cached)')
This example shows how three specific parsing timings are
measured, with and without various caches, to show how BitBake's parsing
performance trends over time.
Considerations When Writing Tests
=================================
When writing good tests, there are several things to keep in mind. Since
things running on the Autobuilder are accessed concurrently by multiple
workers, consider the following:
**Running "cleanall" is not permitted.**
This can delete files from DL_DIR which would potentially break other
builds running in parallel. If this is required, DL_DIR must be set to
an isolated directory.
**Running "cleansstate" is not permitted.**
This can delete files from SSTATE_DIR which would potentially break
other builds running in parallel. If this is required, SSTATE_DIR must
be set to an isolated directory. Alternatively, you can use the "-f"
option with the ``bitbake`` command to "taint" tasks by changing the
sstate checksums to ensure sstate cache items will not be reused.
**Tests should not change the metadata.**
This is particularly true for oe-selftests since these can run in
parallel and changing metadata leads to changing checksums, which
confuses BitBake while running in parallel. If this is necessary, copy
layers to a temporary location and modify them. Some tests need to
change metadata, such as the devtool tests. To prevent the metadate from
changes, set up temporary copies of that data first.