Salt comes with a powerful integration and unit test suite allowing for the fully automated run of integration and/or unit tests from a single interface.
To learn the basics of how Salt's test suite works, be sure to check out the Salt's Test Suite: An Introduction tutorial.
Salt's test suite is located in the
tests directory in the root of
Salt's codebase. The test suite is divided into two main groups:
Within each of these groups, the directory structure roughly mirrors the
structure of Salt's own codebase. Notice that there are directories for
output, and more in each testing
The files that are housed in the
modules directory of either the unit
or the integration testing factions contain respective integration or unit
test files for Salt execution modules.
The Integration section of Salt's test suite start up a number of Salt daemons to test functionality in a live environment. These daemons include two Salt Masters, one Syndic, and two Minions. This allows the Syndic interface to be tested and Master/Minion communication to be verified. All of the integration tests are executed as live Salt commands sent through the started daemons.
Integration tests are particularly good at testing modules, states, and shell commands, among other segments of Salt's ecosystem. By utilizing the integration test daemons, integration tests are easy to write. They are also SaltStack's generally preferred method of adding new tests.
The discussion in the Integration vs. Unit section of the testing tutorial is beneficial in learning why you might want to write integration tests vs. unit tests. Both testing arenas add value to Salt's test suite and you should consider adding both types of tests if possible and appropriate when contributing to Salt.
Unit tests do not spin up any Salt daemons, but instead find their value
in testing singular implementations of individual functions. Instead of
testing against specific interactions, unit tests should be used to test
a function's logic as well as any
Unit tests also rely heavily on mocking external resources.
The discussion in the Integration vs. Unit section of the testing tutorial is useful in determining when you should consider writing unit tests instead of, or in addition to, integration tests when contributing to Salt.
There are requirements, in addition to Salt's requirements, which need to be installed in order to run the test suite. Install one of the lines below, depending on the relevant Python version:
pip install -r requirements/dev_python26.txt pip install -r requirements/dev_python27.txt
To be able to run integration tests which utilizes ZeroMQ transport, you also need to install additional requirements for it. Make sure you have installed the C/C++ compiler and development libraries and header files needed for your Python version.
This is an example for RedHat-based operating systems:
yum install gcc gcc-c++ python-devel pip install -r requirements/zeromq.txt
On Debian, Ubuntu or their derivatives run the following commands:
apt-get install build-essential python-dev pip install -r requirements/zeromq.txt
This will install the latest
pyzmq (with bundled
libzmq) Python modules required for running integration tests suite.
Once all requirements are installed, use
runtests.py script to run all of
the tests included in Salt's test suite:
For more information about options you can pass the test runner, see the
python tests/runtests.py --help
An alternative way of invoking the test suite is available in
Instead of running the entire test suite all at once, which can take a long time, there are several ways to run only specific groups of tests or individual tests:
python tests/runtests.py --unit-tests
python tests/runtests.py --state
python tests/runtests.py -n integration.modules.virt
python tests/runtests.py -n unit.modules.virt_test
test_default_kvm_profiletest in the
python tests/runtests.py -n integration.module.virt.VirtTest.test_default_kvm_profile
For more specific examples of how to run various test subsections or individual tests, please see the Test Selection Options documentation or the Running Specific Tests section of the Salt's Test Suite: An Introduction tutorial.
Since the unit tests do not require a master or minion to execute, it is often useful to be able to
run unit tests individually, or as a whole group, without having to start up the integration testing
daemons. Starting up the master, minion, and syndic daemons takes a lot of time before the tests can
even start running and is unnecessary to run unit tests. To run unit tests without invoking the
integration test daemons, simply run the
runtests.py script with
python tests/runtests.py --unit
All of the other options to run individual tests, entire classes of tests, or entire test modules still apply.
Salt is used to change the settings and behavior of systems. In order to effectively test Salt's functionality, some integration tests are written to make actual changes to the underlying system. These tests are referred to as "destructive tests". Some examples of destructive tests are changes may be testing the addition of a user or installing packages. By default, destructive tests are disabled and will be skipped.
Generally, destructive tests should clean up after themselves by attempting to restore the system to its original state. For instance, if a new user is created during a test, the user should be deleted after the related test(s) have completed. However, no guarantees are made that test clean-up will complete successfully. Therefore, running destructive tests should be done with caution.
Running destructive tests will change the underlying system. Use caution when running destructive tests.
To run tests marked as destructive, set the
python tests/runtests.py --run-destructive
Salt's testing suite also includes integration tests to assess the successful creation and deletion of cloud instances using Salt-Cloud for providers supported by Salt-Cloud.
The cloud provider tests are off by default and run on sample configuration files
tests/integration/files/conf/cloud.providers.d/. In order to run
the cloud provider tests, valid credentials, which differ per provider, must be
supplied. Each credential item that must be supplied is indicated by an empty
string value and should be edited by the user before running the tests. For
example, DigitalOcean requires a client key and an api key to operate. Therefore,
the default cloud provider configuration file for DigitalOcean looks like this:
digitalocean-config: driver: digital_ocean client_key: '' api_key: '' location: New York 1
As indicated by the empty string values, the
client_key and the
must be provided:
digitalocean-config: driver: digital_ocean client_key: wFGEwgregeqw3435gDger api_key: GDE43t43REGTrkilg43934t34qT43t4dgegerGEgg location: New York 1
When providing credential information in cloud provider configuration files, do not include the single quotes.
Once all of the valid credentials for the cloud provider have been supplied, the
cloud provider tests can be run by setting the
The test suite can be executed under a docker container using the
--docked option flag. The docker container must be properly configured
on the system invoking the tests and the container must have access to the
Here's a simple usage example:
python tests/runtests.py --docked=ubuntu-12.04 -v
The full docker container repository can also be provided:
python tests/runtests.py --docked=salttest/ubuntu-12.04 -v
The SaltStack team is creating some containers which will have the necessary dependencies pre-installed. Running the test suite on a container allows destructive tests to run without making changes to the main system. It also enables the test suite to run under a different distribution than the one the main system is currently using.
The current list of test suite images is on Salt's docker repository.
SaltStack maintains a Jenkins server to allow for the execution of tests across supported platforms. The tests executed from Salt's Jenkins server create fresh virtual machines for each test run, then execute destructive tests on the new, clean virtual machine.
SaltStack's Jenkins server continuously runs the entire test suite, including destructive tests, on an array of various supported operating systems throughout the day. Each actively supported branch of Salt's repository runs the tests located in the respective branch's code. Each set of branch tests also includes a pylint run. These branch tests help ensure the viability of Salt code at any given point in time as pull requests are merged into branches throughout the day.
In addition to branch tests, SaltStack's Jenkins server also runs tests on pull requests. These pull request tests include a smaller set of virtual machines that run on the branch tests. The pull request tests, like the branch tests, include a pylint test as well.
When a pull request is submitted to Salt's repository on GitHub, the suite of pull request tests are started by Jenkins. These tests are used to gauge the pull request's viability to merge into Salt's codebase. If these initial tests pass, the pull request can then merged into the Salt branch by one of Salt's core developers, pending their discretion. If the initial tests fail, core developers may request changes to the pull request. If the failure is unrelated to the changes in question, core developers may merge the pull request despite the initial failure.
As soon as the pull request is merged, the changes will be added to the next branch test run on Jenkins.
For a full list of currently running test environments, go to http://jenkins.saltstack.com.
For testing Salt on Jenkins, SaltStack uses Salt-Cloud to spin up virtual machines. The script using Salt-Cloud to accomplish this is open source and can be found here: https://github.com/saltstack/salt/blob/develop/tests/jenkins.py
The salt testing infrastructure is divided into two classes of tests, integration tests and unit tests. These terms may be defined differently in other contexts, but for Salt they are defined this way:
salt-callor any of the salt daemons.
Salt testing uses unittest2 from the python standard library and MagicMock.
Any function in either integration test files or unit test files that is doing
the actual testing, such as functions containing assertions, must start with
When functions in test files are not prepended with
test_, the function
acts as a normal, helper function and is not run as a test by the test suite.
Which branch of the Salt codebase should new tests be written against? The location of where new tests should be submitted depends largely on the reason you're writing the tests.
If you are adding new functionality to Salt, please write the tests for this new
feature in the same pull request as the new feature. New features should always be
submitted to the
If you have already submitted the new feature, but did not write tests in the original
pull request that has already been merged, please feel free to submit a new pull
request containing tests. If the feature was recently added to Salt's
branch, then the tests should be added there as well. However, if the feature was
develop some time ago and is already present in one or more release
branches, please refer to the Tests for Entire Files or Functions section below
for more details about where to submit tests for functions or files that do not
already have tests.
If you are writing tests for code that fixes a bug in Salt, please write the test in the same pull request as the bugfix. If you're unsure of where to submit your bugfix and accompanying test, please review the Which Salt Branch? documentation in Salt's Contributing guide.
Sometimes entire files in Salt are completely untested. If you are writing tests for a file that doesn't have any tests written for it, write your test against the earliest supported release branch that contains the file or function you're testing.
Once your tests are submitted in a pull request and is merged into the branch in
question, the tests you wrote will be merged-forward by SaltStack core engineers and
the new tests will propagate to the newer release branches. That way the tests you
wrote will apply to all current and relevant release branches, and not just the
branch, for example. This methodology will help protect against regressions on older
files in Salt's codebase.
There may be times when the tests you write against an older branch fail in the merge-forward process because functionality has changed in newer release branches. In these cases, a Salt core developer may reach out to you for advice on the tests in question if the path forward is unclear.
If tests are written against a file in an older release branch and then merged forward, there may be new functionality in the file that is present in the new release branch that is untested.It would be wise to see if new functionality could use additional testing once the test file has propagated to newer release branches.