mirror of https://gitee.com/openkylin/qemu.git
688 lines
24 KiB
ReStructuredText
688 lines
24 KiB
ReStructuredText
===============
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Testing in QEMU
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===============
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This document describes the testing infrastructure in QEMU.
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Testing with "make check"
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=========================
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The "make check" testing family includes most of the C based tests in QEMU. For
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a quick help, run ``make check-help`` from the source tree.
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The usual way to run these tests is:
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.. code::
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make check
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which includes QAPI schema tests, unit tests, and QTests. Different sub-types
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of "make check" tests will be explained below.
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Before running tests, it is best to build QEMU programs first. Some tests
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expect the executables to exist and will fail with obscure messages if they
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cannot find them.
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Unit tests
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----------
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Unit tests, which can be invoked with ``make check-unit``, are simple C tests
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that typically link to individual QEMU object files and exercise them by
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calling exported functions.
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If you are writing new code in QEMU, consider adding a unit test, especially
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for utility modules that are relatively stateless or have few dependencies. To
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add a new unit test:
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1. Create a new source file. For example, ``tests/foo-test.c``.
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2. Write the test. Normally you would include the header file which exports
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the module API, then verify the interface behaves as expected from your
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test. The test code should be organized with the glib testing framework.
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Copying and modifying an existing test is usually a good idea.
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3. Add the test to ``tests/Makefile.include``. First, name the unit test
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program and add it to ``$(check-unit-y)``; then add a rule to build the
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executable. Optionally, you can add a magical variable to support ``gcov``.
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For example:
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.. code::
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check-unit-y += tests/foo-test$(EXESUF)
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tests/foo-test$(EXESUF): tests/foo-test.o $(test-util-obj-y)
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...
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gcov-files-foo-test-y = util/foo.c
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Since unit tests don't require environment variables, the simplest way to debug
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a unit test failure is often directly invoking it or even running it under
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``gdb``. However there can still be differences in behavior between ``make``
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invocations and your manual run, due to ``$MALLOC_PERTURB_`` environment
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variable (which affects memory reclamation and catches invalid pointers better)
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and gtester options. If necessary, you can run
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.. code::
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make check-unit V=1
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and copy the actual command line which executes the unit test, then run
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it from the command line.
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QTest
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-----
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QTest is a device emulation testing framework. It can be very useful to test
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device models; it could also control certain aspects of QEMU (such as virtual
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clock stepping), with a special purpose "qtest" protocol. Refer to the
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documentation in ``qtest.c`` for more details of the protocol.
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QTest cases can be executed with
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.. code::
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make check-qtest
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The QTest library is implemented by ``tests/libqtest.c`` and the API is defined
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in ``tests/libqtest.h``.
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Consider adding a new QTest case when you are introducing a new virtual
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hardware, or extending one if you are adding functionalities to an existing
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virtual device.
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On top of libqtest, a higher level library, ``libqos``, was created to
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encapsulate common tasks of device drivers, such as memory management and
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communicating with system buses or devices. Many virtual device tests use
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libqos instead of directly calling into libqtest.
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Steps to add a new QTest case are:
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1. Create a new source file for the test. (More than one file can be added as
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necessary.) For example, ``tests/test-foo-device.c``.
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2. Write the test code with the glib and libqtest/libqos API. See also existing
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tests and the library headers for reference.
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3. Register the new test in ``tests/Makefile.include``. Add the test executable
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name to an appropriate ``check-qtest-*-y`` variable. For example:
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``check-qtest-generic-y = tests/test-foo-device$(EXESUF)``
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4. Add object dependencies of the executable in the Makefile, including the
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test source file(s) and other interesting objects. For example:
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``tests/test-foo-device$(EXESUF): tests/test-foo-device.o $(libqos-obj-y)``
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Debugging a QTest failure is slightly harder than the unit test because the
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tests look up QEMU program names in the environment variables, such as
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``QTEST_QEMU_BINARY`` and ``QTEST_QEMU_IMG``, and also because it is not easy
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to attach gdb to the QEMU process spawned from the test. But manual invoking
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and using gdb on the test is still simple to do: find out the actual command
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from the output of
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.. code::
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make check-qtest V=1
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which you can run manually.
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QAPI schema tests
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-----------------
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The QAPI schema tests validate the QAPI parser used by QMP, by feeding
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predefined input to the parser and comparing the result with the reference
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output.
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The input/output data is managed under the ``tests/qapi-schema`` directory.
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Each test case includes four files that have a common base name:
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* ``${casename}.json`` - the file contains the JSON input for feeding the
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parser
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* ``${casename}.out`` - the file contains the expected stdout from the parser
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* ``${casename}.err`` - the file contains the expected stderr from the parser
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* ``${casename}.exit`` - the expected error code
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Consider adding a new QAPI schema test when you are making a change on the QAPI
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parser (either fixing a bug or extending/modifying the syntax). To do this:
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1. Add four files for the new case as explained above. For example:
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``$EDITOR tests/qapi-schema/foo.{json,out,err,exit}``.
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2. Add the new test in ``tests/Makefile.include``. For example:
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``qapi-schema += foo.json``
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check-block
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-----------
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``make check-block`` is a legacy command to invoke block layer iotests and is
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rarely used. See "QEMU iotests" section below for more information.
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GCC gcov support
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----------------
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``gcov`` is a GCC tool to analyze the testing coverage by
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instrumenting the tested code. To use it, configure QEMU with
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``--enable-gcov`` option and build. Then run ``make check`` as usual.
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If you want to gather coverage information on a single test the ``make
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clean-coverage`` target can be used to delete any existing coverage
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information before running a single test.
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You can generate a HTML coverage report by executing ``make
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coverage-report`` which will create
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./reports/coverage/coverage-report.html. If you want to create it
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elsewhere simply execute ``make /foo/bar/baz/coverage-report.html``.
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Further analysis can be conducted by running the ``gcov`` command
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directly on the various .gcda output files. Please read the ``gcov``
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documentation for more information.
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QEMU iotests
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============
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QEMU iotests, under the directory ``tests/qemu-iotests``, is the testing
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framework widely used to test block layer related features. It is higher level
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than "make check" tests and 99% of the code is written in bash or Python
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scripts. The testing success criteria is golden output comparison, and the
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test files are named with numbers.
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To run iotests, make sure QEMU is built successfully, then switch to the
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``tests/qemu-iotests`` directory under the build directory, and run ``./check``
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with desired arguments from there.
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By default, "raw" format and "file" protocol is used; all tests will be
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executed, except the unsupported ones. You can override the format and protocol
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with arguments:
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.. code::
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# test with qcow2 format
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./check -qcow2
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# or test a different protocol
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./check -nbd
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It's also possible to list test numbers explicitly:
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.. code::
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# run selected cases with qcow2 format
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./check -qcow2 001 030 153
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Cache mode can be selected with the "-c" option, which may help reveal bugs
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that are specific to certain cache mode.
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More options are supported by the ``./check`` script, run ``./check -h`` for
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help.
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Writing a new test case
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-----------------------
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Consider writing a tests case when you are making any changes to the block
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layer. An iotest case is usually the choice for that. There are already many
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test cases, so it is possible that extending one of them may achieve the goal
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and save the boilerplate to create one. (Unfortunately, there isn't a 100%
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reliable way to find a related one out of hundreds of tests. One approach is
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using ``git grep``.)
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Usually an iotest case consists of two files. One is an executable that
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produces output to stdout and stderr, the other is the expected reference
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output. They are given the same number in file names. E.g. Test script ``055``
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and reference output ``055.out``.
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In rare cases, when outputs differ between cache mode ``none`` and others, a
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``.out.nocache`` file is added. In other cases, when outputs differ between
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image formats, more than one ``.out`` files are created ending with the
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respective format names, e.g. ``178.out.qcow2`` and ``178.out.raw``.
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There isn't a hard rule about how to write a test script, but a new test is
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usually a (copy and) modification of an existing case. There are a few
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commonly used ways to create a test:
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* A Bash script. It will make use of several environmental variables related
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to the testing procedure, and could source a group of ``common.*`` libraries
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for some common helper routines.
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* A Python unittest script. Import ``iotests`` and create a subclass of
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``iotests.QMPTestCase``, then call ``iotests.main`` method. The downside of
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this approach is that the output is too scarce, and the script is considered
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harder to debug.
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* A simple Python script without using unittest module. This could also import
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``iotests`` for launching QEMU and utilities etc, but it doesn't inherit
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from ``iotests.QMPTestCase`` therefore doesn't use the Python unittest
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execution. This is a combination of 1 and 2.
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Pick the language per your preference since both Bash and Python have
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comparable library support for invoking and interacting with QEMU programs. If
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you opt for Python, it is strongly recommended to write Python 3 compatible
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code.
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Docker based tests
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==================
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Introduction
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------------
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The Docker testing framework in QEMU utilizes public Docker images to build and
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test QEMU in predefined and widely accessible Linux environments. This makes
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it possible to expand the test coverage across distros, toolchain flavors and
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library versions.
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Prerequisites
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-------------
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Install "docker" with the system package manager and start the Docker service
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on your development machine, then make sure you have the privilege to run
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Docker commands. Typically it means setting up passwordless ``sudo docker``
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command or login as root. For example:
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.. code::
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$ sudo yum install docker
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$ # or `apt-get install docker` for Ubuntu, etc.
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$ sudo systemctl start docker
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$ sudo docker ps
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The last command should print an empty table, to verify the system is ready.
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An alternative method to set up permissions is by adding the current user to
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"docker" group and making the docker daemon socket file (by default
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``/var/run/docker.sock``) accessible to the group:
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.. code::
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$ sudo groupadd docker
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$ sudo usermod $USER -G docker
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$ sudo chown :docker /var/run/docker.sock
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Note that any one of above configurations makes it possible for the user to
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exploit the whole host with Docker bind mounting or other privileged
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operations. So only do it on development machines.
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Quickstart
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----------
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From source tree, type ``make docker`` to see the help. Testing can be started
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without configuring or building QEMU (``configure`` and ``make`` are done in
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the container, with parameters defined by the make target):
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.. code::
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make docker-test-build@min-glib
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This will create a container instance using the ``min-glib`` image (the image
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is downloaded and initialized automatically), in which the ``test-build`` job
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is executed.
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Images
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------
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Along with many other images, the ``min-glib`` image is defined in a Dockerfile
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in ``tests/docker/dockefiles/``, called ``min-glib.docker``. ``make docker``
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command will list all the available images.
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To add a new image, simply create a new ``.docker`` file under the
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``tests/docker/dockerfiles/`` directory.
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A ``.pre`` script can be added beside the ``.docker`` file, which will be
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executed before building the image under the build context directory. This is
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mainly used to do necessary host side setup. One such setup is ``binfmt_misc``,
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for example, to make qemu-user powered cross build containers work.
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Tests
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-----
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Different tests are added to cover various configurations to build and test
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QEMU. Docker tests are the executables under ``tests/docker`` named
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``test-*``. They are typically shell scripts and are built on top of a shell
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library, ``tests/docker/common.rc``, which provides helpers to find the QEMU
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source and build it.
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The full list of tests is printed in the ``make docker`` help.
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Tools
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-----
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There are executables that are created to run in a specific Docker environment.
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This makes it easy to write scripts that have heavy or special dependencies,
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but are still very easy to use.
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Currently the only tool is ``travis``, which mimics the Travis-CI tests in a
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container. It runs in the ``travis`` image:
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.. code::
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make docker-travis@travis
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Debugging a Docker test failure
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-------------------------------
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When CI tasks, maintainers or yourself report a Docker test failure, follow the
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below steps to debug it:
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1. Locally reproduce the failure with the reported command line. E.g. run
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``make docker-test-mingw@fedora J=8``.
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2. Add "V=1" to the command line, try again, to see the verbose output.
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3. Further add "DEBUG=1" to the command line. This will pause in a shell prompt
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in the container right before testing starts. You could either manually
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build QEMU and run tests from there, or press Ctrl-D to let the Docker
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testing continue.
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4. If you press Ctrl-D, the same building and testing procedure will begin, and
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will hopefully run into the error again. After that, you will be dropped to
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the prompt for debug.
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Options
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-------
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Various options can be used to affect how Docker tests are done. The full
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list is in the ``make docker`` help text. The frequently used ones are:
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* ``V=1``: the same as in top level ``make``. It will be propagated to the
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container and enable verbose output.
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* ``J=$N``: the number of parallel tasks in make commands in the container,
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similar to the ``-j $N`` option in top level ``make``. (The ``-j`` option in
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top level ``make`` will not be propagated into the container.)
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* ``DEBUG=1``: enables debug. See the previous "Debugging a Docker test
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failure" section.
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VM testing
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==========
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This test suite contains scripts that bootstrap various guest images that have
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necessary packages to build QEMU. The basic usage is documented in ``Makefile``
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help which is displayed with ``make vm-test``.
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Quickstart
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----------
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Run ``make vm-test`` to list available make targets. Invoke a specific make
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command to run build test in an image. For example, ``make vm-build-freebsd``
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will build the source tree in the FreeBSD image. The command can be executed
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from either the source tree or the build dir; if the former, ``./configure`` is
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not needed. The command will then generate the test image in ``./tests/vm/``
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under the working directory.
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Note: images created by the scripts accept a well-known RSA key pair for SSH
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access, so they SHOULD NOT be exposed to external interfaces if you are
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concerned about attackers taking control of the guest and potentially
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exploiting a QEMU security bug to compromise the host.
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QEMU binary
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-----------
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By default, qemu-system-x86_64 is searched in $PATH to run the guest. If there
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isn't one, or if it is older than 2.10, the test won't work. In this case,
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provide the QEMU binary in env var: ``QEMU=/path/to/qemu-2.10+``.
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Make jobs
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---------
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The ``-j$X`` option in the make command line is not propagated into the VM,
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specify ``J=$X`` to control the make jobs in the guest.
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Debugging
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---------
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Add ``DEBUG=1`` and/or ``V=1`` to the make command to allow interactive
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debugging and verbose output. If this is not enough, see the next section.
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Manual invocation
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-----------------
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Each guest script is an executable script with the same command line options.
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For example to work with the netbsd guest, use ``$QEMU_SRC/tests/vm/netbsd``:
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.. code::
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$ cd $QEMU_SRC/tests/vm
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# To bootstrap the image
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$ ./netbsd --build-image --image /var/tmp/netbsd.img
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<...>
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# To run an arbitrary command in guest (the output will not be echoed unless
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# --debug is added)
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$ ./netbsd --debug --image /var/tmp/netbsd.img uname -a
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# To build QEMU in guest
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$ ./netbsd --debug --image /var/tmp/netbsd.img --build-qemu $QEMU_SRC
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# To get to an interactive shell
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$ ./netbsd --interactive --image /var/tmp/netbsd.img sh
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Adding new guests
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-----------------
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Please look at existing guest scripts for how to add new guests.
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Most importantly, create a subclass of BaseVM and implement ``build_image()``
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method and define ``BUILD_SCRIPT``, then finally call ``basevm.main()`` from
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the script's ``main()``.
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* Usually in ``build_image()``, a template image is downloaded from a
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predefined URL. ``BaseVM._download_with_cache()`` takes care of the cache and
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the checksum, so consider using it.
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* Once the image is downloaded, users, SSH server and QEMU build deps should
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be set up:
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- Root password set to ``BaseVM.ROOT_PASS``
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- User ``BaseVM.GUEST_USER`` is created, and password set to
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``BaseVM.GUEST_PASS``
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- SSH service is enabled and started on boot,
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``$QEMU_SRC/tests/keys/id_rsa.pub`` is added to ssh's ``authorized_keys``
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file of both root and the normal user
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- DHCP client service is enabled and started on boot, so that it can
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automatically configure the virtio-net-pci NIC and communicate with QEMU
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user net (10.0.2.2)
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- Necessary packages are installed to untar the source tarball and build
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QEMU
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* Write a proper ``BUILD_SCRIPT`` template, which should be a shell script that
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untars a raw virtio-blk block device, which is the tarball data blob of the
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QEMU source tree, then configure/build it. Running "make check" is also
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recommended.
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Image fuzzer testing
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====================
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An image fuzzer was added to exercise format drivers. Currently only qcow2 is
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supported. To start the fuzzer, run
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.. code::
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tests/image-fuzzer/runner.py -c '[["qemu-img", "info", "$test_img"]]' /tmp/test qcow2
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Alternatively, some command different from "qemu-img info" can be tested, by
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changing the ``-c`` option.
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Acceptance tests using the Avocado Framework
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============================================
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The ``tests/acceptance`` directory hosts functional tests, also known
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as acceptance level tests. They're usually higher level tests, and
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may interact with external resources and with various guest operating
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systems.
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These tests are written using the Avocado Testing Framework (which must
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be installed separately) in conjunction with a the ``avocado_qemu.Test``
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class, implemented at ``tests/acceptance/avocado_qemu``.
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Tests based on ``avocado_qemu.Test`` can easily:
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* Customize the command line arguments given to the convenience
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``self.vm`` attribute (a QEMUMachine instance)
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* Interact with the QEMU monitor, send QMP commands and check
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their results
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* Interact with the guest OS, using the convenience console device
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(which may be useful to assert the effectiveness and correctness of
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command line arguments or QMP commands)
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* Interact with external data files that accompany the test itself
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(see ``self.get_data()``)
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* Download (and cache) remote data files, such as firmware and kernel
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images
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* Have access to a library of guest OS images (by means of the
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``avocado.utils.vmimage`` library)
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* Make use of various other test related utilities available at the
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test class itself and at the utility library:
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- http://avocado-framework.readthedocs.io/en/latest/api/test/avocado.html#avocado.Test
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- http://avocado-framework.readthedocs.io/en/latest/api/utils/avocado.utils.html
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Installation
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------------
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To install Avocado and its dependencies, run:
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.. code::
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pip install --user avocado-framework
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Alternatively, follow the instructions on this link:
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http://avocado-framework.readthedocs.io/en/latest/GetStartedGuide.html#installing-avocado
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Overview
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--------
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This directory provides the ``avocado_qemu`` Python module, containing
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the ``avocado_qemu.Test`` class. Here's a simple usage example:
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.. code::
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from avocado_qemu import Test
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class Version(Test):
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"""
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:avocado: enable
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:avocado: tags=quick
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"""
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def test_qmp_human_info_version(self):
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self.vm.launch()
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res = self.vm.command('human-monitor-command',
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command_line='info version')
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self.assertRegexpMatches(res, r'^(\d+\.\d+\.\d)')
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To execute your test, run:
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.. code::
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avocado run version.py
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Tests may be classified according to a convention by using docstring
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directives such as ``:avocado: tags=TAG1,TAG2``. To run all tests
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in the current directory, tagged as "quick", run:
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.. code::
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avocado run -t quick .
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The ``avocado_qemu.Test`` base test class
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-----------------------------------------
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The ``avocado_qemu.Test`` class has a number of characteristics that
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are worth being mentioned right away.
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First of all, it attempts to give each test a ready to use QEMUMachine
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instance, available at ``self.vm``. Because many tests will tweak the
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QEMU command line, launching the QEMUMachine (by using ``self.vm.launch()``)
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is left to the test writer.
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At test "tear down", ``avocado_qemu.Test`` handles the QEMUMachine
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shutdown.
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QEMUMachine
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~~~~~~~~~~~
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The QEMUMachine API is already widely used in the Python iotests,
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device-crash-test and other Python scripts. It's a wrapper around the
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execution of a QEMU binary, giving its users:
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* the ability to set command line arguments to be given to the QEMU
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binary
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* a ready to use QMP connection and interface, which can be used to
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send commands and inspect its results, as well as asynchronous
|
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events
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* convenience methods to set commonly used command line arguments in
|
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a more succinct and intuitive way
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QEMU binary selection
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~~~~~~~~~~~~~~~~~~~~~
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The QEMU binary used for the ``self.vm`` QEMUMachine instance will
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primarily depend on the value of the ``qemu_bin`` parameter. If it's
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not explicitly set, its default value will be the result of a dynamic
|
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probe in the same source tree. A suitable binary will be one that
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targets the architecture matching host machine.
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Based on this description, test writers will usually rely on one of
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the following approaches:
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1) Set ``qemu_bin``, and use the given binary
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2) Do not set ``qemu_bin``, and use a QEMU binary named like
|
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"${arch}-softmmu/qemu-system-${arch}", either in the current
|
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working directory, or in the current source tree.
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The resulting ``qemu_bin`` value will be preserved in the
|
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``avocado_qemu.Test`` as an attribute with the same name.
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Attribute reference
|
|
-------------------
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Besides the attributes and methods that are part of the base
|
|
``avocado.Test`` class, the following attributes are available on any
|
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``avocado_qemu.Test`` instance.
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vm
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|
~~
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A QEMUMachine instance, initially configured according to the given
|
|
``qemu_bin`` parameter.
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|
|
qemu_bin
|
|
~~~~~~~~
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|
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The preserved value of the ``qemu_bin`` parameter or the result of the
|
|
dynamic probe for a QEMU binary in the current working directory or
|
|
source tree.
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|
|
Parameter reference
|
|
-------------------
|
|
|
|
To understand how Avocado parameters are accessed by tests, and how
|
|
they can be passed to tests, please refer to::
|
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|
|
http://avocado-framework.readthedocs.io/en/latest/WritingTests.html#accessing-test-parameters
|
|
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|
Parameter values can be easily seen in the log files, and will look
|
|
like the following:
|
|
|
|
.. code::
|
|
|
|
PARAMS (key=qemu_bin, path=*, default=x86_64-softmmu/qemu-system-x86_64) => 'x86_64-softmmu/qemu-system-x86_64
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|
|
qemu_bin
|
|
~~~~~~~~
|
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|
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The exact QEMU binary to be used on QEMUMachine.
|
|
|
|
Uninstalling Avocado
|
|
--------------------
|
|
|
|
If you've followed the installation instructions above, you can easily
|
|
uninstall Avocado. Start by listing the packages you have installed::
|
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|
|
pip list --user
|
|
|
|
And remove any package you want with::
|
|
|
|
pip uninstall <package_name>
|