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In the discussion about renaming the `tests/acceptance` [1], the conclusion was that the folders inside `tests` are related to the framework running the tests and not directly related to the type of the tests. This changes the folder to `tests/avocado` and adjusts the MAKEFILE, the CI related files and the documentation. [1] https://lists.gnu.org/archive/html/qemu-devel/2021-05/msg06553.html Reviewed-by: Niek Linnenbank <nieklinnenbank@gmail.com> Reviewed-by: Philippe Mathieu-Daudé <philmd@redhat.com> Tested-by: Philippe Mathieu-Daudé <philmd@redhat.com> Signed-off-by: Willian Rampazzo <willianr@redhat.com> Message-Id: <20211105155354.154864-3-willianr@redhat.com> Signed-off-by: Philippe Mathieu-Daudé <philmd@redhat.com>
122 lines
5.2 KiB
PHP
122 lines
5.2 KiB
PHP
Definition of terms
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===================
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This section defines the terms used in this document and correlates them with
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what is currently used on QEMU.
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Automated tests
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---------------
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An automated test is written on a test framework using its generic test
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functions/classes. The test framework can run the tests and report their
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success or failure [1]_.
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An automated test has essentially three parts:
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1. The test initialization of the parameters, where the expected parameters,
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like inputs and expected results, are set up;
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2. The call to the code that should be tested;
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3. An assertion, comparing the result from the previous call with the expected
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result set during the initialization of the parameters. If the result
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matches the expected result, the test has been successful; otherwise, it has
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failed.
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Unit testing
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------------
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A unit test is responsible for exercising individual software components as a
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unit, like interfaces, data structures, and functionality, uncovering errors
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within the boundaries of a component. The verification effort is in the
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smallest software unit and focuses on the internal processing logic and data
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structures. A test case of unit tests should be designed to uncover errors due
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to erroneous computations, incorrect comparisons, or improper control flow [2]_.
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On QEMU, unit testing is represented by the 'check-unit' target from 'make'.
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Functional testing
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------------------
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A functional test focuses on the functional requirement of the software.
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Deriving sets of input conditions, the functional tests should fully exercise
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all the functional requirements for a program. Functional testing is
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complementary to other testing techniques, attempting to find errors like
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incorrect or missing functions, interface errors, behavior errors, and
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initialization and termination errors [3]_.
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On QEMU, functional testing is represented by the 'check-qtest' target from
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'make'.
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System testing
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--------------
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System tests ensure all application elements mesh properly while the overall
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functionality and performance are achieved [4]_. Some or all system components
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are integrated to create a complete system to be tested as a whole. System
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testing ensures that components are compatible, interact correctly, and
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transfer the right data at the right time across their interfaces. As system
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testing focuses on interactions, use case-based testing is a practical approach
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to system testing [5]_. Note that, in some cases, system testing may require
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interaction with third-party software, like operating system images, databases,
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networks, and so on.
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On QEMU, system testing is represented by the 'check-avocado' target from
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'make'.
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Flaky tests
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-----------
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A flaky test is defined as a test that exhibits both a passing and a failing
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result with the same code on different runs. Some usual reasons for an
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intermittent/flaky test are async wait, concurrency, and test order dependency
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[6]_.
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Gating
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------
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A gate restricts the move of code from one stage to another on a
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test/deployment pipeline. The step move is granted with approval. The approval
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can be a manual intervention or a set of tests succeeding [7]_.
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On QEMU, the gating process happens during the pull request. The approval is
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done by the project leader running its own set of tests. The pull request gets
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merged when the tests succeed.
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Continuous Integration (CI)
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---------------------------
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Continuous integration (CI) requires the builds of the entire application and
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the execution of a comprehensive set of automated tests every time there is a
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need to commit any set of changes [8]_. The automated tests can be composed of
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the unit, functional, system, and other tests.
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Keynotes about continuous integration (CI) [9]_:
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1. System tests may depend on external software (operating system images,
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firmware, database, network).
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2. It may take a long time to build and test. It may be impractical to build
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the system being developed several times per day.
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3. If the development platform is different from the target platform, it may
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not be possible to run system tests in the developer’s private workspace.
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There may be differences in hardware, operating system, or installed
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software. Therefore, more time is required for testing the system.
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References
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----------
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.. [1] Sommerville, Ian (2016). Software Engineering. p. 233.
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.. [2] Pressman, Roger S. & Maxim, Bruce R. (2020). Software Engineering,
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A Practitioner’s Approach. p. 48, 376, 378, 381.
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.. [3] Pressman, Roger S. & Maxim, Bruce R. (2020). Software Engineering,
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A Practitioner’s Approach. p. 388.
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.. [4] Pressman, Roger S. & Maxim, Bruce R. (2020). Software Engineering,
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A Practitioner’s Approach. Software Engineering, p. 377.
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.. [5] Sommerville, Ian (2016). Software Engineering. p. 59, 232, 240.
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.. [6] Luo, Qingzhou, et al. An empirical analysis of flaky tests.
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Proceedings of the 22nd ACM SIGSOFT International Symposium on
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Foundations of Software Engineering. 2014.
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.. [7] Humble, Jez & Farley, David (2010). Continuous Delivery:
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Reliable Software Releases Through Build, Test, and Deployment, p. 122.
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.. [8] Humble, Jez & Farley, David (2010). Continuous Delivery:
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Reliable Software Releases Through Build, Test, and Deployment, p. 55.
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.. [9] Sommerville, Ian (2016). Software Engineering. p. 743.
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