Skip to content

MarkSymsCtx/planex

 
 

Repository files navigation

Planex Build Status

Planex is a toolkit for building medium-sized collections of RPM packages which may depend on each other. It fills the gap between tools to build individual RPMs, such as rpmbuild and mock, and tools to build entire distributions, such as koji.

Installing Planex

The easiest way to install Planex is to use pip in a Python virtualenv.

Planex uses the Python bindings for librpm, which must be installed separately using the system package manager.

$ dnf install python2-rpm

If you want to install Planex in a virtualenv, remember to pass the --system-site-packages so the librpm bindings are available in the virtualenv.

$ virtualenv venv --system-site-packages
New python executable in /tmp/venv/bin/python2
Also creating executable in /tmp/venv/bin/python
Installing setuptools, pip, wheel...done.
$ source venv/bin/activate

Clone the source, install the requirements and install Planex

$ git clone https://github.com/xenserver/planex
Cloning into 'planex'...
remote: Counting objects: 11951, done.
remote: Compressing objects: 100% (78/78), done.
remote: Total 11951 (delta 143), reused 176 (delta 130), pack-reused 11743
Receiving objects: 100% (11951/11951), 2.17 MiB | 931.00 KiB/s, done.
Resolving deltas: 100% (8368/8368), done.
$ cd planex
$ pip install -r requirements.txt
...
$ python setup.py install

For development work, also install the test requirements and use python setup.py develop, which symlinks the code so you do not have to run python setup.py install after every edit.

$ pip install -r test-requirements.txt
...
$ python setup.py develop
$ nosetests

Design principles

Small, single purpose tools sequenced by make

Planex is a set of single-purpose tools designed to be run by a generic Makefile. We arrived at this structure after previous experience with a monolithic Makefile which described the entire build process in make, and a monolithic Python system which described the entire build process in Python. Planex is intended to be a mid-point between these two extremes.

  • We use make to figure out which files to rebuild and in what order. All we need to do is generate the dependency graph, after which we can benefit from features such as incremental, parallel builds with no extra work.
  • Small, single purpose tools are easier to write, understand and maintain than monlithic scripts. Although the Planex tools are intended to be run by make, they can easily be run by hand for testing and development.
  • Where make cannot understand part of our build process, we can use small tools to adapt it. For instance, it is impossible to use a URL as a make prerequisite - make only understands files on disk - so we cannot write a rule which directly downloads a source tarball. Instead, we have a tool (planex-fetch) which downloads a source defined in a spec file. Make calls planex-fetch, passing it the spec and asking it to download the source tarball. If the spec later changes, the source will be downloaded again.

Use standard tools in standard ways (the Stackoverflow test)

Using standard tools such as rpmbuild, mock and make means that when we run into trouble we can often find a solution by searching the web. This is not possible with a custom monolithic build script. Even though our monolithic Makefile was based on a standard tool, it used complex and unusual features of make for which documentation and tutorials were hard to find.

Look like upstream

Planex is designed to build medium-sized collections of RPM packages which depend on each other and are maintained by a small number of people. Distribution builders such as Fedora have a slightly different problem - they have to build huge collections of packages, many of which do not depend on each other and which are maintained by a large number of maintainers. This means that upstream tools are not always suitable for our purposes. However even when we have to write our own tools we should try to stay as close as possible to the upstream way of doing things so we can benefit from other upstream tools. Examples of this include fetching source tarballs instead of checking code out from Git, avoiding patching or re-writing spec files copied from upstream, and following rpmbuild's working directory structure for the spec file repository.

Defining which packages to build

The main input to Planex is a repository containing RPM spec files, possibly a few source files and a small Makefile.

.
├── Makefile
├── SOURCES
│   └── bar
│       └── bar.service
└── SPECS
    ├── bar.spec
    ├── bar.lnk
    └── foo.spec

Each spec file describes the sources needed to build a package, any other packages which are required to build it, how to build it and how to pack the resulting files into a binary package. Most package sources are not kept with the spec files - instead planex-fetch downloads them from the URLs given in the spec files. The source files could be static files on HTTP servers or tarballs produced dynamically by source control systems such as GitHub or BitBucket. A few sources can be kept in the spec file directory - these could be small temporary patches or resources such as SystemD service files which do not really belong anywhere else. This approach is not suitable for large numbers of frequently-changing extra sources, such as patchqueues.

Overriding and augmenting packages

If a package relies on a source file which is not fully defined in its spec file, planex-fetch will not know where to get it. One way around this problem is to change the spec file to contain a full URL for the source, however if the spec file is for an upstream package which we just re-build we may not want to change it. Planex's solution to this is to add a 'link' file which defines additional sources to fetch and build into the package. The link file can modify the sources listed in the spec in several ways:

  • provide the URL of a source which does not have one
  • override a source URL in the spec file - for instance to use a local mirror instead of a public repository
  • provide the URL of a tarball of source files which are required by the package
  • provide the URL of a tarball containing a patchqueue which will be added to any patches already defined by the spec file

For development, it is also possible to override a source listed in the spec with the contents of a Git repository. To do this, create a link file with a .pin extension in the PINS directory. This will cause planex-fetch to make a tarball archive of the repository and use it in place of the tarball specified in the spec file.

About

RPM package and delivery

Resources

License

Stars

Watchers

Forks

Packages

No packages published

Languages

  • Python 95.4%
  • Makefile 2.9%
  • Other 1.7%