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Weston test suite
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=================
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Weston test suite aims to test features of the Weston compositor and libweston.
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The automatic tests are executed as part of ``meson test`` and in the Gitlab CI.
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In addition to automatic tests, there are few manual tests that have not been
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automated, but being manual means they are also not routinely (or ever)
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executed.
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Test execution
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--------------
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The test execution hierarchy is:
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* ``meson test``
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* a test program
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* a fixture setup
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* a test
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* a sub-test from a data array
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When ``meson test`` is executed, it will run all defined *test programs*
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potentially in parallel and collect their exit status. Therefore it is
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important to design each test program to be executable in parallel with every
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other test program.
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A **test program** is essentially one ``.c`` source code file that is built into
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one executable file (not a library, module, or plugin). Each test program is
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possible to run manually without Meson straight from the build directory
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without any environment or command line setup, e.g. with GDB or Valgrind.
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A test program may define one **fixture setup** function. The function may be
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defined alone or with a data array of an arbitrary data type. If an array is
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defined, the fixture setup will be called and all the tests in the program
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executed for each element in the array serially. Fixture setups are used for
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setting up the Weston compositor for the tests that need it. The array is
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useful for running the compositor with different settings for the same tests,
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e.g. with Pixman-renderer and GL-renderer.
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**A test** in a test program is defined with one of the macros :c:func:`TEST`,
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:c:func:`TEST_P`, or :c:func:`PLUGIN_TEST`. :c:func:`TEST` defines a single
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test with no sub-tests. :c:func:`TEST_P` defines a data-driven array of tests:
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a set of sub-tests. :c:func:`PLUGIN_TEST` is used specifically by *plugin
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tests* that require access to :type:`weston_compositor`.
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All tests and sub-tests are executed serially in a test program. The test
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harness does not ``fork()`` which means that any test that crashes or hits an
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assert failure will quit the whole test program on the spot, leaving following
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tests in that program not executed.
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The test suite has no tests that are expected to fail in general. All tests
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that test for a failure must check the exact error condition expected and
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succeed if it is met or fail for any other or no error.
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Types of tests
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--------------
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Aside from manual vs. automatic, there are three types of tests:
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Standalone tests
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Standalone tests do not launch the full compositor.
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Plugin tests
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Plugin tests launch the Weston compositor and execute the list of tests
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from an idle callback handler in the compositor context, blocking the
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compositor while they run.
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Client tests
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Client tests launch the Weston compositor and execute the list of tests
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in a new thread that is created from an idle callback handler. This means
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the compositor runs independently from the tests and one can write a test
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like as a normal Wayland client.
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The type of all the tests in a test program is defined by the fixture setup
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function. A fixture setup function is any defined function with a specific
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signature and registered with either :c:func:`DECLARE_FIXTURE_SETUP` or
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:c:func:`DECLARE_FIXTURE_SETUP_WITH_ARG`.
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.. _test-suite-standalone:
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Standalone tests
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^^^^^^^^^^^^^^^^
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Standalone tests do not have a fixture setup function defined in the test
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program or the fixture setup function calls
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:func:`weston_test_harness_execute_standalone` explicitly. All test cases must
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be defined with :c:func:`TEST` or :c:func:`TEST_P`.
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This is the simplest possible test example:
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.. code-block:: c
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TEST(always_success)
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{
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/* true */
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}
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.. _test-suite-plugin:
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Plugin tests
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^^^^^^^^^^^^
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Plugin tests must have a fixture setup function that calls
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:func:`weston_test_harness_execute_as_plugin`. All test cases must be defined
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with :c:func:`PLUGIN_TEST` which declares an implicit function argument
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:type:`weston_compositor` ``*compositor``.
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The compositor fixture manufactures the necessary environment variables and the
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command line argument array to launch Weston, and calls :func:`wet_main`
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directly. An idle task handler is registered, which gets invoked when
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initialization is done. All tests are executed from that idle handler, and then
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the compositor exits.
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This is an example of a plugin test that just logs a line:
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.. code-block:: c
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static enum test_result_code
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fixture_setup(struct weston_test_harness *harness)
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{
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struct compositor_setup setup;
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compositor_setup_defaults(&setup);
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return weston_test_harness_execute_as_plugin(harness, &setup);
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}
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DECLARE_FIXTURE_SETUP(fixture_setup);
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PLUGIN_TEST(plugin_registry_test)
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{
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/* struct weston_compositor *compositor; */
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testlog("Got compositor %p\n", compositor);
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}
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.. _test-suite-client:
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Client tests
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^^^^^^^^^^^^
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Plugin tests must have a fixture setup function that calls
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:func:`weston_test_harness_execute_as_client`. All test cases must be
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defined with :c:func:`TEST` or :c:func:`TEST_P`.
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The compositor fixture manufactures the necessary environment variables and the
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command line argument array to launch Weston, and calls :func:`wet_main`
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directly. An idle task handler is registered, which gets invoked when
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initialization is done. The idle handler creates a new thread and returns. The
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new thread will execute all tests and then signal the compositor to exit.
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This is an incomplete example of an array of sub-tests and another test as
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clients:
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.. code-block:: c
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static enum test_result_code
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fixture_setup(struct weston_test_harness *harness)
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{
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struct compositor_setup setup;
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compositor_setup_defaults(&setup);
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return weston_test_harness_execute_as_client(harness, &setup);
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}
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DECLARE_FIXTURE_SETUP(fixture_setup);
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struct bad_source_rect_args {
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int x, y, w, h;
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};
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static const struct bad_source_rect_args bad_source_rect_args[] = {
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{ -5, 0, 20, 10 },
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{ 0, -5, 20, 10 },
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{ 5, 6, 0, 10 },
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{ 5, 6, 20, 0 },
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{ 5, 6, -20, 10 },
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{ 5, 6, 20, -10 },
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{ -1, -1, 20, 10 },
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{ 5, 6, -1, -1 },
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};
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TEST_P(test_viewporter_bad_source_rect, bad_source_rect_args)
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{
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const struct bad_source_rect_args *args = data;
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struct client *client;
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struct wp_viewport *vp;
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client = create_client_and_test_surface(100, 50, 123, 77);
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vp = create_viewport(client);
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testlog("wp_viewport.set_source x=%d, y=%d, w=%d, h=%d\n",
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args->x, args->y, args->w, args->h);
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set_source(vp, args->x, args->y, args->w, args->h);
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expect_protocol_error(client, &wp_viewport_interface,
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WP_VIEWPORT_ERROR_BAD_VALUE);
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}
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TEST(test_roundtrip)
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{
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struct client *client;
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client = create_client_and_test_surface(100, 50, 123, 77);
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client_roundtrip(client);
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}
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DRM-backend tests
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-----------------
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DRM-backend tests require a DRM device, so they are a special case. To select a
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device the test suite will simply look at the environment variable
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``WESTON_TEST_SUITE_DRM_DEVICE``. So the first thing the user has to do in order
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to run DRM-backend tests is to set this environment variable with the card that
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should run the tests. For instance, in order to run DRM-backend tests with
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``card0`` we need to run ``export WESTON_TEST_SUITE_DRM_DEVICE=card0``.
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Note that the card should not be in use by a desktop environment (or any other
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program that requires master status), as there can only be one user at a time
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with master status in a DRM device. Also, this is the reason why we can not run
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two or more DRM-backend tests simultaneously. Since the test suite tries to run
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the tests in parallel, we have a lock mechanism to enforce that DRM-backend
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tests run sequentially, one at a time. Note that this will not avoid them to run
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in parallel with other types of tests.
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Another specificity of DRM-backend tests is that they run using the non-default
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seat ``seat-weston-test``. This avoids unnecessarily opening input devices that
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may be present in the default seat ``seat0``. On the other hand, this will make
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``launcher-logind`` fail, as we are trying to use a seat that is different from
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the one we are logged in. In the CI we do not rely on ``logind``, so it should
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fallback to ``launcher-direct`` anyway. It requires root, but this is also not a
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problem for the CI, as ``virtme`` starts as root. The problem is that to run
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the tests locally with a real hardware the users need to run as root.
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Writing tests
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-------------
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Test programs do not have a ``main()`` of their own. They all share the
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``main()`` from the test harness and only define test cases and a fixture
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setup.
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It is recommended to have one test program (one ``.c`` file) contain only one
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type of tests to keep the fixture setup simple. See
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:ref:`test-suite-standalone`, :ref:`test-suite-plugin` and
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:ref:`test-suite-client` how to set up each type in a test program.
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.. note::
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**TODO:** Currently it is not possible to gracefully skip or fail a test.
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You can skip with ``exit(RESULT_SKIP)`` but that will quit the whole test
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program and all defined tests that were not ran yet will be counted as
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failed. You can fail a test by any means, e.g. ``exit(RESULT_FAIL)``, but
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the same caveat applies. Succeeded tests must simply return and not call any
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exit function.
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.. toctree::
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:hidden:
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test-suite-api.rst
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