Binary dependency automation
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
Jenkins b33f97af2f Merge "Update newsfile entry for default filename change" 2 years ago
bindep Add bindep.txt as default filename 2 years ago
doc/source Merge "Use current year for copyright" 2 years ago
.coveragerc Change ignore-errors to ignore_errors 3 years ago
.gitignore Ignore coverage output files. 3 years ago
.gitreview Update .gitreview for project rename 4 years ago
.mailmap Sync with openstack-dev/cookiecutter 4 years ago
.testr.conf Sync with openstack-dev/cookiecutter 4 years ago
CONTRIBUTING.rst fix small typo and link 3 years ago
LICENSE Initial project docs and framework. 6 years ago
NEWS.rst Update newsfile entry for default filename change 2 years ago
README.rst Update a couple of old references in README file 2 years ago
requirements.txt Sync with openstack-dev/cookiecutter 4 years ago
setup.cfg Build universal wheels 2 years ago
setup.py Sync with openstack-dev/cookiecutter 4 years ago
test-requirements.txt Remove discover from test-requirements 2 years ago
tox.ini Merge "Remove py26 support from bindep" 3 years ago

README.rst

Introduction

Bindep is a tool for checking the presence of binary packages needed to use an application / library. It started life as a way to make it easier to set up a development environment for OpenStack projects. While OpenStack depends heavily on pip for installation of Python dependencies, some dependencies are not Python based, and particularly for testing, some dependencies have to be installed before pip can be used - such as virtualenv and pip itself.

Basics

Create a file called bindep.txt and in that list any requirements your application / library has. In your README or INSTALL or other documentation you can tell users to run bindep to report on missing dependencies. Users without bindep installed can consult the bindep.txt file by hand if they choose, or install bindep first and then use it.

If no bindep.txt file exists, bindep will look at the old location other-requirements.txt.

The output from bindep is fairly verbose normally, but passing an option of -b/--brief outputs just the missing packages one per line, suitable for feeding to your package management tool of choice.

If you need to maintain multiple requirements list files you can pass a specific filename with the -f/--file command line option. If you want to read the list from standard input in a pipeline instead, use a filename of "-".

When bindep runs, its exit code is 0 if no described packages are missing, but 1 if there are packages which it believes need to be installed.

Profiles

Profiles can be used to describe different scenarios. For instance, you might have a profile for using PostgreSQL which requires the PostgreSQL client library, a profile for MySQL needing that client library, and a profile for testing which requires both libraries as well as the servers. To select a profile just pass it when running bindep - e.g.:

$ bindep test

When running bindep a single profile can be chosen by the user, with no explicit selection resulting in the selected profile being default. bindep will automatically activate additional profiles representing the platform bindep is running under, making it easy to handle platform specific quirks.

The available profiles are inferred by inspecting the requirements file and collating the used profile names. Users can get a report on the available profiles:

$ bindep --profiles

Writing Requirements Files

The requirements file bindep.txt lists the dependencies for projects. Where non-ascii characters are needed, they should be UTF8 encoded.

The file is line orientated - each line is a Debian binary package name, an optional profile selector and optional version constraints. (Note - if you are writing an alternative parser, see the Debian policy manual for the parsing rules for packagenames). Debian package names are used as a single source of truth - bindep can be taught the mapping onto specific packaging systems. Alternatively, profiles may be used to encode platform specific requirements.

Profiles are used to decide which lines in the requirements file should be considered when checking dependencies. Profile selectors are a list of space separated strings contained in []. A selector prefixed with ! is a negative selector. For a line in the requirements file to be active:

  • it must not have a negative selector that matches the active profile.
  • it must either have no positive selectors, or a positive selector that matches the active profile.

For instance, the profile selector [!qpid] will match every profile except qpid and would be suitable for disabling installation of rabbitmq when qpid is in use. [default] would match only if the user has not selected a profile (or selected default). [default postgresql test] would match those three profiles but not mysql. [platform:rhel] will match only when running in a RHEL linux environment.

Note that platform selectors are treated as kind of filter: If a line contains a platform selector, then the package only gets installed if at least one of the platform selectors matches in addition to the match on the other selectors. As an example, [platform:rpm test] would only install a package on a RPM platform if the test selector is used.

Version constraints are a comma separated list of constraints where each constraint is (== | < | <= | >= | > | !=) VERSION, and the constraints are ANDed together (the same as pip requirements version constraints).

Comments are allowed: everything from the first # to the end of the line is ignored.

Developing bindep

Either install bindep and run bindep test to check you have the needed tools, or review bindep.txt by hand.

Running Tests

The testing system is based on a combination of tox and testr. The canonical approach to running tests is to simply run the command tox. This will create virtual environments, populate them with dependencies and run all of the tests that OpenStack CI systems run. Behind the scenes, tox is running testr run --parallel, but is set up such that you can supply any additional testr arguments that are needed to tox. For example, you can run: tox -- --analyze-isolation to cause tox to tell testr to add --analyze-isolation to its argument list.

It is also possible to run the tests inside of a virtual environment you have created, or it is possible that you have all of the dependencies installed locally already. If you'd like to go this route, the requirements are listed in requirements.txt and the requirements for testing are in test-requirements.txt. Installing them via pip, for instance, is simply:

pip install -r requirements.txt -r test-requirements.txt

In you go this route, you can interact with the testr command directly. Running testr run will run the entire test suite. testr run --parallel will run it in parallel (this is the default incantation tox uses.) More information about testr can be found at: http://wiki.openstack.org/testr