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|
====================
Bazaar Testing Guide
====================
The Importance of Testing
=========================
Reliability is a critical success factor for any version control system.
We want Bazaar to be highly reliable across multiple platforms while
evolving over time to meet the needs of its community.
In a nutshell, this is what we expect and encourage:
* New functionality should have test cases. Preferably write the
test before writing the code.
In general, you can test at either the command-line level or the
internal API level. See `Writing tests`_ below for more detail.
* Try to practice Test-Driven Development: before fixing a bug, write a
test case so that it does not regress. Similarly for adding a new
feature: write a test case for a small version of the new feature before
starting on the code itself. Check the test fails on the old code, then
add the feature or fix and check it passes.
By doing these things, the Bazaar team gets increased confidence that
changes do what they claim to do, whether provided by the core team or
by community members. Equally importantly, we can be surer that changes
down the track do not break new features or bug fixes that you are
contributing today.
As of September 2009, Bazaar ships with a test suite containing over
23,000 tests and growing. We are proud of it and want to remain so. As
community members, we all benefit from it. Would you trust version control
on your project to a product *without* a test suite like Bazaar has?
Running the Test Suite
======================
As of Bazaar 2.1, you must have the testtools_ library installed to run
the bzr test suite.
.. _testtools: https://launchpad.net/testtools/
To test all of Bazaar, just run::
bzr selftest
With ``--verbose`` bzr will print the name of every test as it is run.
This should always pass, whether run from a source tree or an installed
copy of Bazaar. Please investigate and/or report any failures.
Running particular tests
------------------------
Currently, bzr selftest is used to invoke tests.
You can provide a pattern argument to run a subset. For example,
to run just the blackbox tests, run::
./bzr selftest -v blackbox
To skip a particular test (or set of tests), use the --exclude option
(shorthand -x) like so::
./bzr selftest -v -x blackbox
To ensure that all tests are being run and succeeding, you can use the
--strict option which will fail if there are any missing features or known
failures, like so::
./bzr selftest --strict
To list tests without running them, use the --list-only option like so::
./bzr selftest --list-only
This option can be combined with other selftest options (like -x) and
filter patterns to understand their effect.
Once you understand how to create a list of tests, you can use the --load-list
option to run only a restricted set of tests that you kept in a file, one test
id by line. Keep in mind that this will never be sufficient to validate your
modifications, you still need to run the full test suite for that, but using it
can help in some cases (like running only the failed tests for some time)::
./bzr selftest -- load-list my_failing_tests
This option can also be combined with other selftest options, including
patterns. It has some drawbacks though, the list can become out of date pretty
quick when doing Test Driven Development.
To address this concern, there is another way to run a restricted set of tests:
the --starting-with option will run only the tests whose name starts with the
specified string. It will also avoid loading the other tests and as a
consequence starts running your tests quicker::
./bzr selftest --starting-with bzrlib.blackbox
This option can be combined with all the other selftest options including
--load-list. The later is rarely used but allows to run a subset of a list of
failing tests for example.
Disabling plugins
-----------------
To test only the bzr core, ignoring any plugins you may have installed,
use::
./bzr --no-plugins selftest
Disabling crash reporting
-------------------------
By default Bazaar uses apport_ to report program crashes. In developing
Bazaar it's normal and expected to have it crash from time to time, at
least because a test failed if for no other reason.
Therefore you should probably add ``debug_flags = no_apport`` to your
``bazaar.conf`` file (in ``~/.bazaar/`` on Unix), so that failures just
print a traceback rather than writing a crash file.
.. _apport: https://launchpad.net/apport/
Test suite debug flags
----------------------
Similar to the global ``-Dfoo`` debug options, bzr selftest accepts
``-E=foo`` debug flags. These flags are:
:allow_debug: do *not* clear the global debug flags when running a test.
This can provide useful logging to help debug test failures when used
with e.g. ``bzr -Dhpss selftest -E=allow_debug``
Note that this will probably cause some tests to fail, because they
don't expect to run with any debug flags on.
Using subunit
-------------
Bazaar can optionally produce output in the machine-readable subunit_
format, so that test output can be post-processed by various tools. To
generate a subunit test stream::
$ ./bzr selftest --subunit
Processing such a stream can be done using a variety of tools including:
* The builtin ``subunit2pyunit``, ``subunit-filter``, ``subunit-ls``,
``subunit2junitxml`` from the subunit project.
* tribunal_, a GUI for showing test results.
* testrepository_, a tool for gathering and managing test runs.
.. _subunit: https://launchpad.net/subunit/
.. _tribunal: https://launchpad.net/tribunal/
Using testrepository
--------------------
Bazaar ships with a config file for testrepository_. This can be very
useful for keeping track of failing tests and doing general workflow
support. To run tests using testrepository::
$ testr run
To run only failing tests::
$ testr run --failing
To run only some tests, without plugins::
$ test run test_selftest -- --no-plugins
See the testrepository documentation for more details.
.. _testrepository: https://launchpad.net/testrepository
Babune continuous integration
-----------------------------
We have a Hudson continuous-integration system that automatically runs
tests across various platforms. In the future we plan to add more
combinations including testing plugins. See
<http://babune.ladeuil.net:24842/>. (Babune = Bazaar Buildbot Network.)
Running tests in parallel
-------------------------
Bazaar can use subunit to spawn multiple test processes. There is
slightly more chance you will hit ordering or timing-dependent bugs but
it's much faster::
$ ./bzr selftest --parallel=fork
Note that you will need the Subunit library
<https://launchpad.net/subunit/> to use this, which is in
``python-subunit`` on Ubuntu.
Running tests from a ramdisk
----------------------------
The tests create and delete a lot of temporary files. In some cases you
can make the test suite run much faster by running it on a ramdisk. For
example::
$ sudo mkdir /ram
$ sudo mount -t tmpfs none /ram
$ TMPDIR=/ram ./bzr selftest ...
You could also change ``/tmp`` in ``/etc/fstab`` to have type ``tmpfs``,
if you don't mind possibly losing other files in there when the machine
restarts. Add this line (if there is none for ``/tmp`` already)::
none /tmp tmpfs defaults 0 0
With a 6-core machine and ``--parallel=fork`` using a tmpfs doubles the
test execution speed.
Writing Tests
=============
Normally you should add or update a test for all bug fixes or new features
in Bazaar.
Where should I put a new test?
------------------------------
Bzrlib's tests are organised by the type of test. Most of the tests in
bzr's test suite belong to one of these categories:
- Unit tests
- Blackbox (UI) tests
- Per-implementation tests
- Doctests
A quick description of these test types and where they belong in bzrlib's
source follows. Not all tests fall neatly into one of these categories;
in those cases use your judgement.
Unit tests
~~~~~~~~~~
Unit tests make up the bulk of our test suite. These are tests that are
focused on exercising a single, specific unit of the code as directly
as possible. Each unit test is generally fairly short and runs very
quickly.
They are found in ``bzrlib/tests/test_*.py``. So in general tests should
be placed in a file named test_FOO.py where FOO is the logical thing under
test.
For example, tests for merge3 in bzrlib belong in bzrlib/tests/test_merge3.py.
See bzrlib/tests/test_sampler.py for a template test script.
Blackbox (UI) tests
~~~~~~~~~~~~~~~~~~~
Tests can be written for the UI or for individual areas of the library.
Choose whichever is appropriate: if adding a new command, or a new command
option, then you should be writing a UI test. If you are both adding UI
functionality and library functionality, you will want to write tests for
both the UI and the core behaviours. We call UI tests 'blackbox' tests
and they belong in ``bzrlib/tests/blackbox/*.py``.
When writing blackbox tests please honour the following conventions:
1. Place the tests for the command 'name' in
bzrlib/tests/blackbox/test_name.py. This makes it easy for developers
to locate the test script for a faulty command.
2. Use the 'self.run_bzr("name")' utility function to invoke the command
rather than running bzr in a subprocess or invoking the
cmd_object.run() method directly. This is a lot faster than
subprocesses and generates the same logging output as running it in a
subprocess (which invoking the method directly does not).
3. Only test the one command in a single test script. Use the bzrlib
library when setting up tests and when evaluating the side-effects of
the command. We do this so that the library api has continual pressure
on it to be as functional as the command line in a simple manner, and
to isolate knock-on effects throughout the blackbox test suite when a
command changes its name or signature. Ideally only the tests for a
given command are affected when a given command is changed.
4. If you have a test which does actually require running bzr in a
subprocess you can use ``run_bzr_subprocess``. By default the spawned
process will not load plugins unless ``--allow-plugins`` is supplied.
Per-implementation tests
~~~~~~~~~~~~~~~~~~~~~~~~
Per-implementation tests are tests that are defined once and then run
against multiple implementations of an interface. For example,
``per_transport.py`` defines tests that all Transport implementations
(local filesystem, HTTP, and so on) must pass. They are found in
``bzrlib/tests/per_*/*.py``, and ``bzrlib/tests/per_*.py``.
These are really a sub-category of unit tests, but an important one.
Along the same lines are tests for extension modules. We generally have
both a pure-python and a compiled implementation for each module. As such,
we want to run the same tests against both implementations. These can
generally be found in ``bzrlib/tests/*__*.py`` since extension modules are
usually prefixed with an underscore. Since there are only two
implementations, we have a helper function
``bzrlib.tests.permute_for_extension``, which can simplify the
``load_tests`` implementation.
Doctests
~~~~~~~~
We make selective use of doctests__. In general they should provide
*examples* within the API documentation which can incidentally be tested. We
don't try to test every important case using doctests |--| regular Python
tests are generally a better solution. That is, we just use doctests to make
our documentation testable, rather than as a way to make tests. Be aware that
doctests are not as well isolated as the unit tests, if you need more
isolation, you're likely want to write unit tests anyway if only to get a
better control of the test environment.
Most of these are in ``bzrlib/doc/api``. More additions are welcome.
__ http://docs.python.org/lib/module-doctest.html
There is an `assertDoctestExampleMatches` method in
`bzrlib.tests.TestCase` that allows you to match against doctest-style
string templates (including ``...`` to skip sections) from regular Python
tests.
Shell-like tests
----------------
``bzrlib/tests/script.py`` allows users to write tests in a syntax very
close to a shell session, using a restricted and limited set of commands
that should be enough to mimic most of the behaviours.
A script is a set of commands, each command is composed of:
* one mandatory command line,
* one optional set of input lines to feed the command,
* one optional set of output expected lines,
* one optional set of error expected lines.
Input, output and error lines can be specified in any order.
Except for the expected output, all lines start with a special
string (based on their origin when used under a Unix shell):
* '$ ' for the command,
* '<' for input,
* nothing for output,
* '2>' for errors,
Comments can be added anywhere, they start with '#' and end with
the line.
The execution stops as soon as an expected output or an expected error is not
matched.
If output occurs and no output is expected, the execution stops and the
test fails. If unexpected output occurs on the standard error, then
execution stops and the test fails.
If an error occurs and no expected error is specified, the execution stops.
An error is defined by a returned status different from zero, not by the
presence of text on the error stream.
The matching is done on a full string comparison basis unless '...' is used, in
which case expected output/errors can be less precise.
Examples:
The following will succeeds only if 'bzr add' outputs 'adding file'::
$ bzr add file
>adding file
If you want the command to succeed for any output, just use::
$ bzr add file
...
2>...
or use the ``--quiet`` option::
$ bzr add -q file
The following will stop with an error::
$ bzr not-a-command
If you want it to succeed, use::
$ bzr not-a-command
2> bzr: ERROR: unknown command "not-a-command"
You can use ellipsis (...) to replace any piece of text you don't want to be
matched exactly::
$ bzr branch not-a-branch
2>bzr: ERROR: Not a branch...not-a-branch/".
This can be used to ignore entire lines too::
$ cat
<first line
<second line
<third line
# And here we explain that surprising fourth line
<fourth line
<last line
>first line
>...
>last line
You can check the content of a file with cat::
$ cat <file
>expected content
You can also check the existence of a file with cat, the following will fail if
the file doesn't exist::
$ cat file
You can run files containing shell-like scripts with::
$ bzr test-script <script>
where ``<script>`` is the path to the file containing the shell-like script.
The actual use of ScriptRunner within a TestCase looks something like
this::
from bzrlib.tests import script
def test_unshelve_keep(self):
# some setup here
script.run_script(self, '''
$ bzr add -q file
$ bzr shelve -q --all -m Foo
$ bzr shelve --list
1: Foo
$ bzr unshelve -q --keep
$ bzr shelve --list
1: Foo
$ cat file
contents of file
''')
You can also test commands that read user interaction::
def test_confirm_action(self):
"""You can write tests that demonstrate user confirmation"""
commands.builtin_command_registry.register(cmd_test_confirm)
self.addCleanup(commands.builtin_command_registry.remove, 'test-confirm')
self.run_script("""
$ bzr test-confirm
2>Really do it? [y/n]:
<yes
yes
""")
To avoid having to specify "-q" for all commands whose output is
irrelevant, the run_script() method may be passed the keyword argument
``null_output_matches_anything=True``. For example::
def test_ignoring_null_output(self):
self.run_script("""
$ bzr init
$ bzr ci -m 'first revision' --unchanged
$ bzr log --line
1: ...
""", null_output_matches_anything=True)
Import tariff tests
-------------------
`bzrlib.tests.test_import_tariff` has some tests that measure how many
Python modules are loaded to run some representative commands.
We want to avoid loading code unnecessarily, for reasons including:
* Python modules are interpreted when they're loaded, either to define
classes or modules or perhaps to initialize some structures.
* With a cold cache we may incur blocking real disk IO for each module.
* Some modules depend on many others.
* Some optional modules such as `testtools` are meant to be soft
dependencies and only needed for particular cases. If they're loaded in
other cases then bzr may break for people who don't have those modules.
`test_import_tariff` allows us to check that removal of imports doesn't
regress.
This is done by running the command in a subprocess with
``PYTHON_VERBOSE=1``. Starting a whole Python interpreter is pretty slow,
so we don't want exhaustive testing here, but just enough to guard against
distinct fixed problems.
Assertions about precisely what is loaded tend to be brittle so we instead
make assertions that particular things aren't loaded.
Unless selftest is run with ``--no-plugins``, modules will be loaded in
the usual way and checks made on what they cause to be loaded. This is
probably worth checking into, because many bzr users have at least some
plugins installed (and they're included in binary installers).
In theory, plugins might have a good reason to load almost anything:
someone might write a plugin that opens a network connection or pops up a
gui window every time you run 'bzr status'. However, it's more likely
that the code to do these things is just being loaded accidentally. We
might eventually need to have a way to make exceptions for particular
plugins.
Some things to check:
* non-GUI commands shouldn't load GUI libraries
* operations on bzr native formats sholudn't load foreign branch libraries
* network code shouldn't be loaded for purely local operations
* particularly expensive Python built-in modules shouldn't be loaded
unless there is a good reason
Testing locking behaviour
-------------------------
In order to test the locking behaviour of commands, it is possible to install
a hook that is called when a write lock is: acquired, released or broken.
(Read locks also exist, they cannot be discovered in this way.)
A hook can be installed by calling bzrlib.lock.Lock.hooks.install_named_hook.
The three valid hooks are: `lock_acquired`, `lock_released` and `lock_broken`.
Example::
locks_acquired = []
locks_released = []
lock.Lock.hooks.install_named_hook('lock_acquired',
locks_acquired.append, None)
lock.Lock.hooks.install_named_hook('lock_released',
locks_released.append, None)
`locks_acquired` will now receive a LockResult instance for all locks acquired
since the time the hook is installed.
The last part of the `lock_url` allows you to identify the type of object that is locked.
- BzrDir: `/branch-lock`
- Working tree: `/checkout/lock`
- Branch: `/branch/lock`
- Repository: `/repository/lock`
To test if a lock is a write lock on a working tree, one can do the following::
self.assertEndsWith(locks_acquired[0].lock_url, "/checkout/lock")
See bzrlib/tests/commands/test_revert.py for an example of how to use this for
testing locks.
Skipping tests
--------------
In our enhancements to unittest we allow for some addition results beyond
just success or failure.
If a test can't be run, it can say that it's skipped by raising a special
exception. This is typically used in parameterized tests |--| for example
if a transport doesn't support setting permissions, we'll skip the tests
that relating to that. ::
try:
return self.branch_format.initialize(repo.bzrdir)
except errors.UninitializableFormat:
raise tests.TestSkipped('Uninitializable branch format')
Raising TestSkipped is a good idea when you want to make it clear that the
test was not run, rather than just returning which makes it look as if it
was run and passed.
Several different cases are distinguished:
TestSkipped
Generic skip; the only type that was present up to bzr 0.18.
TestNotApplicable
The test doesn't apply to the parameters with which it was run.
This is typically used when the test is being applied to all
implementations of an interface, but some aspects of the interface
are optional and not present in particular concrete
implementations. (Some tests that should raise this currently
either silently return or raise TestSkipped.) Another option is
to use more precise parameterization to avoid generating the test
at all.
UnavailableFeature
The test can't be run because a dependency (typically a Python
library) is not available in the test environment. These
are in general things that the person running the test could fix
by installing the library. It's OK if some of these occur when
an end user runs the tests or if we're specifically testing in a
limited environment, but a full test should never see them.
See `Test feature dependencies`_ below.
KnownFailure
The test exists but is known to fail, for example this might be
appropriate to raise if you've committed a test for a bug but not
the fix for it, or if something works on Unix but not on Windows.
Raising this allows you to distinguish these failures from the
ones that are not expected to fail. If the test would fail
because of something we don't expect or intend to fix,
KnownFailure is not appropriate, and TestNotApplicable might be
better.
KnownFailure should be used with care as we don't want a
proliferation of quietly broken tests.
We plan to support three modes for running the test suite to control the
interpretation of these results. Strict mode is for use in situations
like merges to the mainline and releases where we want to make sure that
everything that can be tested has been tested. Lax mode is for use by
developers who want to temporarily tolerate some known failures. The
default behaviour is obtained by ``bzr selftest`` with no options, and
also (if possible) by running under another unittest harness.
======================= ======= ======= ========
result strict default lax
======================= ======= ======= ========
TestSkipped pass pass pass
TestNotApplicable pass pass pass
UnavailableFeature fail pass pass
KnownFailure fail pass pass
======================= ======= ======= ========
Test feature dependencies
-------------------------
Writing tests that require a feature
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Rather than manually checking the environment in each test, a test class
can declare its dependence on some test features. The feature objects are
checked only once for each run of the whole test suite.
(For historical reasons, as of May 2007 many cases that should depend on
features currently raise TestSkipped.)
For example::
class TestStrace(TestCaseWithTransport):
_test_needs_features = [StraceFeature]
This means all tests in this class need the feature. If the feature is
not available the test will be skipped using UnavailableFeature.
Individual tests can also require a feature using the ``requireFeature``
method::
self.requireFeature(StraceFeature)
The old naming style for features is CamelCase, but because they're
actually instances not classses they're now given instance-style names
like ``apport``.
Features already defined in ``bzrlib.tests`` and ``bzrlib.tests.features``
include:
- apport
- paramiko
- SymlinkFeature
- HardlinkFeature
- OsFifoFeature
- UnicodeFilenameFeature
- FTPServerFeature
- CaseInsensitiveFilesystemFeature.
- chown_feature: The test can rely on OS being POSIX and python
supporting os.chown.
- posix_permissions_feature: The test can use POSIX-style
user/group/other permission bits.
Defining a new feature that tests can require
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
New features for use with ``_test_needs_features`` or ``requireFeature``
are defined by subclassing ``bzrlib.tests.Feature`` and overriding the
``_probe`` and ``feature_name`` methods. For example::
class _SymlinkFeature(Feature):
def _probe(self):
return osutils.has_symlinks()
def feature_name(self):
return 'symlinks'
SymlinkFeature = _SymlinkFeature()
A helper for handling running tests based on whether a python
module is available. This can handle 3rd-party dependencies (is
``paramiko`` available?) as well as stdlib (``termios``) or
extension modules (``bzrlib._groupcompress_pyx``). You create a
new feature instance with::
# in bzrlib/tests/features.py
apport = tests.ModuleAvailableFeature('apport')
# then in bzrlib/tests/test_apport.py
class TestApportReporting(TestCaseInTempDir):
_test_needs_features = [features.apport]
Testing deprecated code
-----------------------
When code is deprecated, it is still supported for some length of time,
usually until the next major version. The ``applyDeprecated`` helper
wraps calls to deprecated code to verify that it is correctly issuing the
deprecation warning, and also prevents the warnings from being printed
during test runs.
Typically patches that apply the ``@deprecated_function`` decorator should
update the accompanying tests to use the ``applyDeprecated`` wrapper.
``applyDeprecated`` is defined in ``bzrlib.tests.TestCase``. See the API
docs for more details.
Testing exceptions and errors
-----------------------------
It's important to test handling of errors and exceptions. Because this
code is often not hit in ad-hoc testing it can often have hidden bugs --
it's particularly common to get NameError because the exception code
references a variable that has since been renamed.
.. TODO: Something about how to provoke errors in the right way?
In general we want to test errors at two levels:
1. A test in ``test_errors.py`` checking that when the exception object is
constructed with known parameters it produces an expected string form.
This guards against mistakes in writing the format string, or in the
``str`` representations of its parameters. There should be one for
each exception class.
2. Tests that when an api is called in a particular situation, it raises
an error of the expected class. You should typically use
``assertRaises``, which in the Bazaar test suite returns the exception
object to allow you to examine its parameters.
In some cases blackbox tests will also want to check error reporting. But
it can be difficult to provoke every error through the commandline
interface, so those tests are only done as needed |--| eg in response to a
particular bug or if the error is reported in an unusual way(?) Blackbox
tests should mostly be testing how the command-line interface works, so
should only test errors if there is something particular to the cli in how
they're displayed or handled.
Testing warnings
----------------
The Python ``warnings`` module is used to indicate a non-fatal code
problem. Code that's expected to raise a warning can be tested through
callCatchWarnings.
The test suite can be run with ``-Werror`` to check no unexpected errors
occur.
However, warnings should be used with discretion. It's not an appropriate
way to give messages to the user, because the warning is normally shown
only once per source line that causes the problem. You should also think
about whether the warning is serious enought that it should be visible to
users who may not be able to fix it.
Interface implementation testing and test scenarios
---------------------------------------------------
There are several cases in Bazaar of multiple implementations of a common
conceptual interface. ("Conceptual" because it's not necessary for all
the implementations to share a base class, though they often do.)
Examples include transports and the working tree, branch and repository
classes.
In these cases we want to make sure that every implementation correctly
fulfils the interface requirements. For example, every Transport should
support the ``has()`` and ``get()`` and ``clone()`` methods. We have a
sub-suite of tests in ``test_transport_implementations``. (Most
per-implementation tests are in submodules of ``bzrlib.tests``, but not
the transport tests at the moment.)
These tests are repeated for each registered Transport, by generating a
new TestCase instance for the cross product of test methods and transport
implementations. As each test runs, it has ``transport_class`` and
``transport_server`` set to the class it should test. Most tests don't
access these directly, but rather use ``self.get_transport`` which returns
a transport of the appropriate type.
The goal is to run per-implementation only the tests that relate to that
particular interface. Sometimes we discover a bug elsewhere that happens
with only one particular transport. Once it's isolated, we can consider
whether a test should be added for that particular implementation,
or for all implementations of the interface.
See also `Per-implementation tests`_ (above).
Test scenarios and variations
-----------------------------
Some utilities are provided for generating variations of tests. This can
be used for per-implementation tests, or other cases where the same test
code needs to run several times on different scenarios.
The general approach is to define a class that provides test methods,
which depend on attributes of the test object being pre-set with the
values to which the test should be applied. The test suite should then
also provide a list of scenarios in which to run the tests.
A single *scenario* is defined by a `(name, parameter_dict)` tuple. The
short string name is combined with the name of the test method to form the
test instance name. The parameter dict is merged into the instance's
attributes.
For example::
load_tests = load_tests_apply_scenarios
class TestCheckout(TestCase):
scenarios = multiply_scenarios(
VaryByRepositoryFormat(),
VaryByTreeFormat(),
)
The `load_tests` declaration or definition should be near the top of the
file so its effect can be seen.
Test support
------------
We have a rich collection of tools to support writing tests. Please use
them in preference to ad-hoc solutions as they provide portability and
performance benefits.
TestCase and its subclasses
~~~~~~~~~~~~~~~~~~~~~~~~~~~
The ``bzrlib.tests`` module defines many TestCase classes to help you
write your tests.
TestCase
A base TestCase that extends the Python standard library's
TestCase in several ways. TestCase is build on
``testtools.TestCase``, which gives it support for more assertion
methods (e.g. ``assertContainsRe``), ``addCleanup``, and other
features (see its API docs for details). It also has a ``setUp`` that
makes sure that global state like registered hooks and loggers won't
interfere with your test. All tests should use this base class
(whether directly or via a subclass). Note that we are trying not to
add more assertions at this point, and instead to build up a library
of ``bzrlib.tests.matchers``.
TestCaseWithMemoryTransport
Extends TestCase and adds methods like ``get_transport``,
``make_branch`` and ``make_branch_builder``. The files created are
stored in a MemoryTransport that is discarded at the end of the test.
This class is good for tests that need to make branches or use
transports, but that don't require storing things on disk. All tests
that create bzrdirs should use this base class (either directly or via
a subclass) as it ensures that the test won't accidentally operate on
real branches in your filesystem.
TestCaseInTempDir
Extends TestCaseWithMemoryTransport. For tests that really do need
files to be stored on disk, e.g. because a subprocess uses a file, or
for testing functionality that accesses the filesystem directly rather
than via the Transport layer (such as dirstate).
TestCaseWithTransport
Extends TestCaseInTempDir. Provides ``get_url`` and
``get_readonly_url`` facilities. Subclasses can control the
transports used by setting ``vfs_transport_factory``,
``transport_server`` and/or ``transport_readonly_server``.
See the API docs for more details.
BranchBuilder
~~~~~~~~~~~~~
When writing a test for a feature, it is often necessary to set up a
branch with a certain history. The ``BranchBuilder`` interface allows the
creation of test branches in a quick and easy manner. Here's a sample
session::
builder = self.make_branch_builder('relpath')
builder.build_commit()
builder.build_commit()
builder.build_commit()
branch = builder.get_branch()
``make_branch_builder`` is a method of ``TestCaseWithMemoryTransport``.
Note that many current tests create test branches by inheriting from
``TestCaseWithTransport`` and using the ``make_branch_and_tree`` helper to
give them a ``WorkingTree`` that they can commit to. However, using the
newer ``make_branch_builder`` helper is preferred, because it can build
the changes in memory, rather than on disk. Tests that are explictly
testing how we work with disk objects should, of course, use a real
``WorkingTree``.
Please see bzrlib.branchbuilder for more details.
If you're going to examine the commit timestamps e.g. in a test for log
output, you should set the timestamp on the tree, rather than using fuzzy
matches in the test.
TreeBuilder
~~~~~~~~~~~
The ``TreeBuilder`` interface allows the construction of arbitrary trees
with a declarative interface. A sample session might look like::
tree = self.make_branch_and_tree('path')
builder = TreeBuilder()
builder.start_tree(tree)
builder.build(['foo', "bar/", "bar/file"])
tree.commit('commit the tree')
builder.finish_tree()
Usually a test will create a tree using ``make_branch_and_memory_tree`` (a
method of ``TestCaseWithMemoryTransport``) or ``make_branch_and_tree`` (a
method of ``TestCaseWithTransport``).
Please see bzrlib.treebuilder for more details.
PreviewTree
~~~~~~~~~~~
PreviewTrees are based on TreeTransforms. This means they can represent
virtually any state that a WorkingTree can have, including unversioned files.
They can be used to test the output of anything that produces TreeTransforms,
such as merge algorithms and revert. They can also be used to test anything
that takes arbitrary Trees as its input.
::
# Get an empty tree to base the transform on.
b = self.make_branch('.')
empty_tree = b.repository.revision_tree(_mod_revision.NULL_REVISION)
tt = TransformPreview(empty_tree)
self.addCleanup(tt.finalize)
# Empty trees don't have a root, so add it first.
root = tt.new_directory('', ROOT_PARENT, 'tree-root')
# Set the contents of a file.
tt.new_file('new-file', root, 'contents', 'file-id')
preview = tt.get_preview_tree()
# Test the contents.
self.assertEqual('contents', preview.get_file_text('file-id'))
PreviewTrees can stack, with each tree falling back to the previous::
tt2 = TransformPreview(preview)
self.addCleanup(tt2.finalize)
tt2.new_file('new-file2', tt2.root, 'contents2', 'file-id2')
preview2 = tt2.get_preview_tree()
self.assertEqual('contents', preview2.get_file_text('file-id'))
self.assertEqual('contents2', preview2.get_file_text('file-id2'))
Temporarily changing state
~~~~~~~~~~~~~~~~~~~~~~~~~~
If your test needs to temporarily mutate some global state, and you need
it restored at the end, you can say for example::
self.overrideAttr(osutils, '_cached_user_encoding', 'latin-1')
This should be used with discretion; sometimes it's better to make the
underlying code more testable so that you don't need to rely on monkey
patching.
Observing calls to a function
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Sometimes it's useful to observe how a function is called, typically when
calling it has side effects but the side effects are not easy to observe
from a test case. For instance the function may be expensive and we want
to assert it is not called too many times, or it has effects on the
machine that are safe to run during a test but not easy to measure. In
these cases, you can use `recordCalls` which will monkey-patch in a
wrapper that records when the function is called.
Temporarily changing environment variables
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
If yout test needs to temporarily change some environment variable value
(which generally means you want it restored at the end), you can use::
self.overrideEnv('BZR_ENV_VAR', 'new_value')
If you want to remove a variable from the environment, you should use the
special ``None`` value::
self.overrideEnv('PATH', None)
If you add a new feature which depends on a new environment variable, make
sure it behaves properly when this variable is not defined (if applicable) and
if you need to enforce a specific default value, check the
``TestCase._cleanEnvironment`` in ``bzrlib.tests.__init__.py`` which defines a
proper set of values for all tests.
Cleaning up
~~~~~~~~~~~
Our base ``TestCase`` class provides an ``addCleanup`` method, which
should be used instead of ``tearDown``. All the cleanups are run when the
test finishes, regardless of whether it passes or fails. If one cleanup
fails, later cleanups are still run.
(The same facility is available outside of tests through
``bzrlib.cleanup``.)
Manual testing
==============
Generally we prefer automated testing but sometimes a manual test is the
right thing, especially for performance tests that want to measure elapsed
time rather than effort.
Simulating slow networks
------------------------
To get realistically slow network performance for manually measuring
performance, we can simulate 500ms latency (thus 1000ms round trips)::
$ sudo tc qdisc add dev lo root netem delay 500ms
Normal system behaviour is restored with ::
$ sudo tc qdisc del dev lo root
A more precise version that only filters traffic to port 4155 is::
tc qdisc add dev lo root handle 1: prio
tc qdisc add dev lo parent 1:3 handle 30: netem delay 500ms
tc qdisc add dev lo parent 30:1 handle 40: prio
tc filter add dev lo protocol ip parent 1:0 prio 3 u32 match ip dport 4155 0xffff flowid 1:3 handle 800::800
tc filter add dev lo protocol ip parent 1:0 prio 3 u32 match ip sport 4155 0xffff flowid 1:3 handle 800::801
and to remove this::
tc filter del dev lo protocol ip parent 1: pref 3 u32
tc qdisc del dev lo root handle 1:
You can use similar code to add additional delay to a real network
interface, perhaps only when talking to a particular server or pointing at
a VM. For more information see <http://lartc.org/>.
.. |--| unicode:: U+2014
..
vim: ft=rst tw=74 ai et sw=4
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