Packaging Practices
The primary goal of ypkg
is ease of maintenance. In order to do so we ensure packages in the binary repository adhere to a strict set of conventions and practices.
The next few sections will detail these.
Package naming
The ypkg
tool does not allow for custom subpackages or subpackage naming, and will enforce its own policy. This can be eased somewhat through the use of patterns
, however the available subpackage names are limited.
We request you use (where possible) the upstream source name for your package. Subpackage names (when generated) are constructed by using the name
value first, then applying the subpackage name as such:
pkgname-$subpackage
Subpackages are fully automatic with ypkg
, and are created based on file patterns. All subpackages automatically depend on the main package, to ensure correct operation. In the following explanations, $lib
is used to refer to the host library directory, i.e. lib
or lib64
(or lib32
on emul32
builds).
For the libraries / packages of the following programming languages, you should typically use the following template for it.
Language | Prefix | Example |
---|---|---|
Haskell | haskell- | text-binary would be haskell-text-binary |
Perl | perl- | algorithm-diff would be perl-algorithm-diff |
Python | python- | wikipedia would be python-wikipedia even if only Python3 is enabled |
Ruby | ruby- | gssapi would be ruby-gssapi |
The devel subpackage
This is invariably created for packages that provide libraries and development headers. The following rules will result in files being placed in a devel
subpackage:
/usr/include
/usr/$lib/lib*.so
/usr/$lib/lib*.a
/usr/share/man2/
/usr/share/man3/
/usr/share/pkgconfig
/usr/$lib/pkgconfig
/usr/share/cmake
/usr/share/vala
Note that for some packages, /usr/$lib/lib*.so
files are not symlinks. In this instance, the main package will be broken with no library files present. This can quickly be determined by looking at the resulting .xml file generated after running the build.
If this happens, simply override with patterns
or set libsplit
to “no”.
A note on static archives: Unless it is absolutely unavoidable, you should disable static libraries within your build. This is usually fixed by adding --disable-static
to your configure routine. If *.a
files are shown in your packaging request, it will be
questioned, as they can pose a greater security risk if packages link against these static archives.
The docs subpackage
Currently there is only one pattern which is forced into a docs
subpackage:
/usr/share/gtk-doc
If required, you can use patterns
to move other files into the docs
subpackage, making it smaller.
The 32bit subpackage
This subpackage is only generated during an emul32
build. The folowing paths will automatically be placed into a 32bit
subpackage
/usr/lib32/lib*.so
/usr/lib32/lib*.so.*
/usr/lib32/lib*.a
Note the same static archive rules apply to 32bit
packages. These packages aren’t as heavily split as we try to discourage their use, though they must be provided in some instances.
The utils subpackage
This is not an automatic subpackage, you must use patterns
to utilise it. It is provided for instances that it may not be suitable to have binaries present, i.e. for a library package.
Maintenance
When submitting a change package.yml
, it must be accompanied by its corresponding pspec_*.xml
file, which was generated at build time. This machine file allows the repository maintainers to evaluate the package condition.
When providing a new version of a package, or a fix, always ensure you increment the release
number by 1. This ensures that users of your package are correctly updated to the latest version.
Never submit a package without having first tested it, and ensuring it builds within solbuild
, a clean chroot environment.
Generating a Package.yml
Making a package.yml file is not necessarily a manual process. In fact, once you have common setup, you already have a script capable of generating a package.yml file based on the source archive URL.
You can generate a package.yml by using common/Scripts/yauto.py URL_TO_ARCHIVE
. We recommend creation an alias in your .bashrc
or .zshrc
, so you can access it wherever you are. For example:
alias fetchYml="$HOME/repository/common/Scripts/yauto.py"
Licenses
All new packages or updates to packages should abide by the SPDX 3.x definitions, with the following policy:
-only
licenses, such asGPL-2.0-only
, should only be declared as such when the upstream explicitly states “only”, otherwise it should always be-or-later
.
Patching / extra files
Files that may be required during the build can be accessed via the $pkgfiles
variable. Note that you must store your files in the ./files
directory relative to your package.yml
Both patches and extra files (such as systemd units) are stored in this directory. Note that if your patch is to address a CVE, you must use the following naming scheme: ./files/security/cve-xxxx-xxxx.patch
Where xxxx-xxxx
is replaced with the full CVE ID. Complying with this simple rule ensures that we can know at any time the security status of packages when using tools such as cve-check-tool
Solus tooling allows the use of ./files/security/cve-xxxx-xxxx.nopatch
(which isn’t applied in the build) to indicate that a CVE has been validated as not applicable to the Solus package. This can be because another patch resolves this CVE, or there is a false positive via cve-check-tool
. The contents of the file can describe why it doesn’t apply without requiring a patch (i.e. Resolved by cve-xxxx-xxxx.patch).
Applying a patch
It is common practice to apply the patch within the setup
section of your build staging. We can achieve this using the %patch
macro, and the $pkgfiles
variable. In this example, the required file is located
at ./files/0002-Sample-commit-2.patch
%patch -p1 < $pkgfiles/0002-Sample-commit-2.patch
Note you use the macro as you would normally use the patch command, however use of the macro ensures it performs a clean batch-mode patch.
If you are using compressed patches, i.e. for the bash
or readline
packages, you can pipe the call through zcat
or similar:
zcat $pkgfiles/bash43-032.gz | %patch -p0
Handling multiple patches
In the event you need to apply multiple patches, such as a multitude of CVE patches, it may be sensible to use our %apply_patches
macro, which will apply all the patches listed in a series
file in your package’s ./files
folder. Example below:
security/cve-xxxx-xxxx.patch
fix-silliness.patch
Both of the files above will be applied using -p1
. If you need to use stripping num, like -p4
, you can do something like:
security/cve-xxxx-xxxx.patch -p4
fix-silliness.patch
Installing extra files
We recommend using patches where possible first, as they ensure correct maintainence and will be updated across package versions. If you must install extra files into the directory, please use the install
command, ensuring you set the correct permissions. Again, files are accessible from the ./files/
directory, relative to package.yml
.
This is an example of installing a custom profile file, seen in the bash
package:
install -m 0644 $pkgfiles/profile $installdir/etc/profile
Build dependencies
Most software packages that you build will in one way or another, depend on another software package to provide specific functionality. This is usually achieved by using a library.
Any package that is submitted to our repositories is always built in a clean chroot environment, therefore any dependencies required to build that package in a reproducible and sane fashion, must be listed.
This is achieved by populating the builddeps
key with a list of build dependencies. We support two kinds of build dependencies: explicitly named, or pkgconfig
dependencies.
We prefer the use of pkgconfig
dependencies. Most modern software will use the pkg-config
tool (package configuration) to determine which files are required to build the current software. This may include
compiler flags, library to link against and where the package headers are located.
An obvious advantage to supporting pkgconfig
dependencies is that there is a 1:1 mapping between the name requested by the build and the name used within the package.yml
. Instead of trying to hunt down
the package providing that dependency, you simply list the same name. Any package in the repository will export information about the .pc
files (for pkg-config
) it contains, enabling you to use those as a build dependency.
A secondary advantage is that this allows for easily switching or replacing a providing package. When no pkgconfig
name is available (some packages do not provide these, or it doesn’t make sense for them to), you
may use the explicit package name. Always ensure you select the correct package, i.e. the -devel
subpackage. This provides the necessary symlinks and headers to build packages.
Using pkgconfig dependencies
In the builddeps
list, simply use the pkgconfig(name)
syntax. For example, to add gtk+-3.0 to the build dependencies, we would do the following:
builddeps:
- pkgconfig(gtk+-3.0)
At build time the appropriate provider package is selected, in this instance libgtk-3-devel
You can determine if there are pkgconfigs available from a -devel package by doing eopkg info (name)
and looking for the Provides
key.
Example:
$ eopkg info libgtk-3-devel
In output:
Provides: pkgconfig(gtk+-3.0) pkgconfig(gdk-3.0) pkgconfig(gdk-wayland-3.0) pkgconfig(gail-3.0) pkgconfig(gdk-x11-3.0) pkgconfig(gtk+-unix-print-3.0)
pkgconfig(gtk+-wayland-3.0) pkgconfig(gtk+-x11-3.0)
If you want to do a reverse process and figure out what package is part of pkgconfig you can use:
common/Scripts/epcsearch.py NAME
Using explict named dependencies
As may be obvious, simply list the package name. Note we discourage this when a pkgconfig
dependency is available.
builddeps:
- stk-devel
Runtime dependencies
Runtime dependencies are extra packages that a package needs in order to function correctly. A common example of this is other libraries. Solus eopkg
packages will automatically add any binary dependencies at
runtime, so that you do not have to.
All devel
subpackages automatically depend on their parent package. On top of this, if they provide a .pc
pkg-config file, we export this information, and automatically determine the packages this particular
package would need to be able to build against correctly. As such, the majority of dependencies for builds are automatically resolved.
In certain instances, binary dependencies aren’t enough. An example of this might be an extra Python package, or a font, something that is not accounted for by binary checks.
To account for this, you may add extra explicit runtime dependencies to your package. These are taken from the optional rundeps
ypkg key.
This key uses the dict(s)
type, and the default key is the current package name
. You may express a different subpackage to apply dependencies to by using that name as a key, i.e. devel
, or docs
.
This would add the “python-gobject” runtime dependency to the main package:
rundeps:
- python-gobject
This would add the same dependency, as well as adding it to the devel
subpackage:
rundeps:
- python-gobject
- devel: python-gobject
Remember this uses the dict(s)
type, which is very flexible. You can equally express this as follows (adding more deps as an example):
rundeps:
- python-gobject
- devel:
- somepackage
- someotherpackage
Patterns
In most instances, ypkg
will assign the correct location for files, whether it be in the main name
package, or a subpackage. However there may be instances where the default does not match the intended behaviour.
In these instances it is possible to override the default assignment by way of patterns. These are simply a list of paths or globs to ensure a particular file, or set of files, end up in the desired location.
The patterns
key expects a dict(s)
argument. The default key for each pattern is assumed to be the name
of the package, so omitting the name would place files into the main package. The value should be a
path or pattern you wish to match, ensuring files go to a specific location.
In this example from libjpeg-turbo, we move all documentation into the docs
subpackage:
patterns:
- docs: [/usr/share/man]
This example, taken from the wayland package, ensures the binaries from /usr/bin
and the /usr/share/wayland
are located in the devel
subpackage:
patterns:
- devel:
- /usr/bin
- /usr/share/wayland
Replace / rename
In some situations, it may be required to replace one package with another, or to rename an existing package. In these instances you should coordinate with a repository maintainer to ensure the replaced package is marked Obsolete within the index. This will ensure correct upgrade paths for users.
Note that to retire a package, you must also coordinate with a repository maintainer. An Obsolete package is removed by the package manager when the user upgrades. As such, correct upgrade paths need to be established.
The replaces
ypkg key uses the dict(s)
type, and the default key is assumed to be the current package name
.
In this example, we rename the libgeoclue*
packages to use the correct names, and ensure a working upgrade path.
replaces:
- devel: libgeoclue-devel
- libgeoclue
The name
of this package is geoclue, and the new package names are now:
- geoclue
- geoclue-devel
Given the replaces
values above, geoclue now replaces libgeoclue, and geoclue-devel replaces libgeoclue-devel. This is entirely transparent to the user, with a seamless update replacing the old
packages with the new renamed packages.
The repository maintainer marked the old names as Obsolete in the index.