.. SPDX-License-Identifier: GPL-2.0 ================== KUnit Architecture ================== The KUnit architecture is divided into two parts: - `In-Kernel Testing Framework`_ - `kunit_tool (Command-line Test Harness)`_ In-Kernel Testing Framework =========================== The kernel testing library supports KUnit tests written in C using KUnit. These KUnit tests are kernel code. KUnit performs the following tasks: - Organizes tests - Reports test results - Provides test utilities Test Cases ---------- The test case is the fundamental unit in KUnit. KUnit test cases are organised into suites. A KUnit test case is a function with type signature ``void (*)(struct kunit *test)``. These test case functions are wrapped in a struct called struct kunit_case. .. note: ``generate_params`` is optional for non-parameterized tests. Each KUnit test case receives a ``struct kunit`` context object that tracks a running test. The KUnit assertion macros and other KUnit utilities use the ``struct kunit`` context object. As an exception, there are two fields: - ``->priv``: The setup functions can use it to store arbitrary test user data. - ``->param_value``: It contains the parameter value which can be retrieved in the parameterized tests. Test Suites ----------- A KUnit suite includes a collection of test cases. The KUnit suites are represented by the ``struct kunit_suite``. For example: .. code-block:: c static struct kunit_case example_test_cases[] = { KUNIT_CASE(example_test_foo), KUNIT_CASE(example_test_bar), KUNIT_CASE(example_test_baz), {} }; static struct kunit_suite example_test_suite = { .name = "example", .init = example_test_init, .exit = example_test_exit, .test_cases = example_test_cases, }; kunit_test_suite(example_test_suite); In the above example, the test suite ``example_test_suite``, runs the test cases ``example_test_foo``, ``example_test_bar``, and ``example_test_baz``. Before running the test, the ``example_test_init`` is called and after running the test, ``example_test_exit`` is called. The ``kunit_test_suite(example_test_suite)`` registers the test suite with the KUnit test framework. Executor -------- The KUnit executor can list and run built-in KUnit tests on boot. The Test suites are stored in a linker section called ``.kunit_test_suites``. For the code, see ``KUNIT_TABLE()`` macro definition in `include/asm-generic/vmlinux.lds.h <https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/include/asm-generic/vmlinux.lds.h?h=v6.0#n950>`_. The linker section consists of an array of pointers to ``struct kunit_suite``, and is populated by the ``kunit_test_suites()`` macro. The KUnit executor iterates over the linker section array in order to run all the tests that are compiled into the kernel. .. kernel-figure:: kunit_suitememorydiagram.svg :alt: KUnit Suite Memory KUnit Suite Memory Diagram On the kernel boot, the KUnit executor uses the start and end addresses of this section to iterate over and run all tests. For the implementation of the executor, see `lib/kunit/executor.c <https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/lib/kunit/executor.c>`_. When built as a module, the ``kunit_test_suites()`` macro defines a ``module_init()`` function, which runs all the tests in the compilation unit instead of utilizing the executor. In KUnit tests, some error classes do not affect other tests or parts of the kernel, each KUnit case executes in a separate thread context. See the ``kunit_try_catch_run()`` function in `lib/kunit/try-catch.c <https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/lib/kunit/try-catch.c?h=v5.15#n58>`_. Assertion Macros ---------------- KUnit tests verify state using expectations/assertions. All expectations/assertions are formatted as: ``KUNIT_{EXPECT|ASSERT}_<op>[_MSG](kunit, property[, message])`` - ``{EXPECT|ASSERT}`` determines whether the check is an assertion or an expectation. In the event of a failure, the testing flow differs as follows: - For expectations, the test is marked as failed and the failure is logged. - Failing assertions, on the other hand, result in the test case being terminated immediately. - Assertions call the function: ``void __noreturn __kunit_abort(struct kunit *)``. - ``__kunit_abort`` calls the function: ``void __noreturn kunit_try_catch_throw(struct kunit_try_catch *try_catch)``. - ``kunit_try_catch_throw`` calls the function: ``void kthread_complete_and_exit(struct completion *, long) __noreturn;`` and terminates the special thread context. - ``<op>`` denotes a check with options: ``TRUE`` (supplied property has the boolean value "true"), ``EQ`` (two supplied properties are equal), ``NOT_ERR_OR_NULL`` (supplied pointer is not null and does not contain an "err" value). - ``[_MSG]`` prints a custom message on failure. Test Result Reporting --------------------- KUnit prints the test results in KTAP format. KTAP is based on TAP14, see Documentation/dev-tools/ktap.rst. KTAP works with KUnit and Kselftest. The KUnit executor prints KTAP results to dmesg, and debugfs (if configured). Parameterized Tests ------------------- Each KUnit parameterized test is associated with a collection of parameters. The test is invoked multiple times, once for each parameter value and the parameter is stored in the ``param_value`` field. The test case includes a KUNIT_CASE_PARAM() macro that accepts a generator function. The generator function is passed the previous parameter and returns the next parameter. It also includes a macro for generating array-based common-case generators. kunit_tool (Command-line Test Harness) ====================================== ``kunit_tool`` is a Python script, found in ``tools/testing/kunit/kunit.py``. It is used to configure, build, execute, parse test results and run all of the previous commands in correct order (i.e., configure, build, execute and parse). You have two options for running KUnit tests: either build the kernel with KUnit enabled and manually parse the results (see Documentation/dev-tools/kunit/run_manual.rst) or use ``kunit_tool`` (see Documentation/dev-tools/kunit/run_wrapper.rst). - ``configure`` command generates the kernel ``.config`` from a ``.kunitconfig`` file (and any architecture-specific options). The Python scripts available in ``qemu_configs`` folder (for example, ``tools/testing/kunit/qemu configs/powerpc.py``) contains additional configuration options for specific architectures. It parses both the existing ``.config`` and the ``.kunitconfig`` files to ensure that ``.config`` is a superset of ``.kunitconfig``. If not, it will combine the two and run ``make olddefconfig`` to regenerate the ``.config`` file. It then checks to see if ``.config`` has become a superset. This verifies that all the Kconfig dependencies are correctly specified in the file ``.kunitconfig``. The ``kunit_config.py`` script contains the code for parsing Kconfigs. The code which runs ``make olddefconfig`` is part of the ``kunit_kernel.py`` script. You can invoke this command through: ``./tools/testing/kunit/kunit.py config`` and generate a ``.config`` file. - ``build`` runs ``make`` on the kernel tree with required options (depends on the architecture and some options, for example: build_dir) and reports any errors. To build a KUnit kernel from the current ``.config``, you can use the ``build`` argument: ``./tools/testing/kunit/kunit.py build``. - ``exec`` command executes kernel results either directly (using User-mode Linux configuration), or through an emulator such as QEMU. It reads results from the log using standard output (stdout), and passes them to ``parse`` to be parsed. If you already have built a kernel with built-in KUnit tests, you can run the kernel and display the test results with the ``exec`` argument: ``./tools/testing/kunit/kunit.py exec``. - ``parse`` extracts the KTAP output from a kernel log, parses the test results, and prints a summary. For failed tests, any diagnostic output will be included.