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:B~ Customizing package installation

1~customizing-package-installation Customizing package installation

Perhaps the most basic customization of a live system is the selection of
packages to be included in the image. This chapter guides you through the
various build-time options to customize live-build's installation of
packages. The broadest choices influencing which packages are available to
install in the image are the distribution and archive areas. To ensure
decent download speeds, you should choose a nearby distribution mirror. You
can also add your own repositories for backports, experimental or custom
packages, or include packages directly as files. You can define lists of
packages, including metapackages which will install many related packages at
once, such as packages for a particular desktop or language. Finally, a
number of options give some control over /{apt}/, or if you prefer,
/{aptitude}/, at build time when packages are installed. You may find these
handy if you use a proxy, want to disable installation of recommended
packages to save space, or need to control which versions of packages are
installed via APT pinning, to name a few possibilities.

2~ Package sources

3~ Distribution, archive areas and mode

The distribution you choose has the broadest impact on which packages are
available to include in your live image. Specify the codename, which
defaults to ${testing} for the ${testing} version of live-build. Any current
distribution carried in the archive may be specified by its codename
here. (See {Terms}#terms for more details.) The #{--distribution}# option
not only influences the source of packages within the archive, but also
instructs live-build to behave as needed to build each supported
distribution. For example, to build against the *{unstable}* release, sid,
specify:

code{

 $ lb config --distribution sid

}code

Within the distribution archive, archive areas are major divisions of the
archive. In Debian, these are #{main}#, #{contrib}# and #{non-free}#. Only
#{main}# contains software that is part of the Debian distribution, hence
that is the default. One or more values may be specified, e.g.

code{

 $ lb config --archive-areas "main contrib non-free"

}code

Experimental support is available for some Debian derivatives through a
#{--mode}# option. By default, this option is set to #{debian}# only if you
are building on a Debian or on an unknown system. If #{lb config}# is
invoked on any of the supported derivatives, it will default to create an
image of that derivative. If #{lb config}# is run in e.g. #{ubuntu}# mode,
the distribution names and archive areas for the specified derivative are
supported instead of the ones for Debian. The mode also modifies live-build
behaviour to suit the derivatives.

*{Note:}* The projects for whom these modes were added are primarily responsible for supporting users of these options. The ${project}, in turn, provides development support on a best-effort basis only, based on feedback from the derivative projects as we do not develop or support these derivatives ourselves.

3~ Distribution mirrors

The Debian archive is replicated across a large network of mirrors around
the world so that people in each region can choose a nearby mirror for best
download speed. Each of the #{--mirror-*}# options governs which
distribution mirror is used at various stages of the build. Recall from
{Stages of the build}#stages-of-the-build that the *{bootstrap}* stage is
when the chroot is initially populated by /{debootstrap}/ with a minimal
system, and the *{chroot}* stage is when the chroot used to construct the
live system's filesystem is built. Thus, the corresponding mirror switches
are used for those stages, and later, in the *{binary}* stage, the
#{--mirror-binary}# and #{--mirror-binary-security}# values are used,
superseding any mirrors used in an earlier stage.

3~distribution-mirrors-build-time Distribution mirrors used at build time

To set the distribution mirrors used at build time to point at a local
mirror, it is sufficient to set #{--mirror-bootstrap}# and
#{--mirror-chroot-security}# as follows.

code{

 $ lb config --mirror-bootstrap http://localhost/debian/ \
          --mirror-chroot-security http://localhost/debian-security/

}code

The chroot mirror, specified by #{--mirror-chroot}#, defaults to the
#{--mirror-bootstrap}# value.

3~ Distribution mirrors used at run time

The #{--mirror-binary*}# options govern the distribution mirrors placed in
the binary image. These may be used to install additional packages while
running the live system. The defaults employ #{httpredir.debian.org}#, a
service that chooses a geographically close mirror based, among other
things, on the user's IP family and the availability of the mirrors. This is
a suitable choice when you cannot predict which mirror will be best for all
of your users. Or you may specify your own values as shown in the example
below. An image built from this configuration would only be suitable for
users on a network where "#{mirror}#" is reachable.

code{

 $ lb config --mirror-binary http://mirror/debian/ \
          --mirror-binary-security http://mirror/debian-security/ \
          --mirror-binary-backports http://mirror/debian-backports/

}code

3~additional-repositories Additional repositories

You may add more repositories, broadening your package choices beyond what
is available in your target distribution. These may be, for example, for
backports, experimental or custom packages. To configure additional
repositories, create #{config/archives/your-repository.list.chroot}#, and/or
#{config/archives/your-repository.list.binary}# files. As with the
#{--mirror-*}# options, these govern the repositories used in the *{chroot}*
stage when building the image, and in the *{binary}* stage, i.e. for use
when running the live system.

For example, #{config/archives/live.list.chroot}# allows you to install
packages from the debian-live snapshot repository at live system build time.

code{

 deb http://live-systems.org/ sid-snapshots main contrib non-free

}code

If you add the same line to #{config/archives/live.list.binary}#, the
repository will be added to your live system's #{/etc/apt/sources.list.d/}#
directory.

If such files exist, they will be picked up automatically.

You should also put the GPG key used to sign the repository into
#{config/archives/your-repository.key.{binary,chroot}}# files.

Should you need custom APT pinning, such APT preferences snippets can be
placed in #{config/archives/your-repository.pref.{binary,chroot}}# files and
will be automatically added to your live system's
#{/etc/apt/preferences.d/}# directory.

2~choosing-packages-to-install Choosing packages to install

There are a number of ways to choose which packages live-build will install
in your image, covering a variety of different needs. You can simply name
individual packages to install in a package list. You can also use
metapackages in those lists, or select them using package control file
fields. And finally, you may place package files in your #{config/}# tree,
which is well suited to testing of new or experimental packages before they
are available from a repository.

3~package-lists Package lists

Package lists are a powerful way of expressing which packages should be
installed. The list syntax supports conditional sections which makes it easy
to build lists and adapt them for use in multiple configurations. Package
names may also be injected into the list using shell helpers at build time.

*{Note:}* The behaviour of live-build when specifying a package that does not exist is determined by your choice of APT utility. See {Choosing apt or aptitude}#choosing-apt-or-aptitude for more details.

3~using-metapackages Using metapackages

The simplest way to populate your package list is to use a task metapackage
maintained by your distribution. For example:

code{

 $ lb config
 $ echo task-gnome-desktop > config/package-lists/desktop.list.chroot

}code

This supercedes the older predefined list method supported in #{live-build}#
2.x. Unlike predefined lists, task metapackages are not specific to the Live
System project. Instead, they are maintained by specialist working groups
within the distribution and therefore reflect the consensus of each group
about which packages best serve the needs of the intended users. They also
cover a much broader range of use cases than the predefined lists they
replace.

All task metapackages are prefixed #{task-}#, so a quick way to determine
which are available (though it may contain a handful of false hits that
match the name but aren't metapackages) is to match on the package name
with:

code{

 $ apt-cache search --names-only ^task-

}code

In addition to these, you will find other metapackages with various
purposes. Some are subsets of broader task packages, like #{gnome-core}#,
while others are individual specialized parts of a Debian Pure Blend, such
as the #{education-*}# metapackages. To list all metapackages in the
archive, install the #{debtags}# package and list all packages with the
#{role::metapackage}# tag as follows:

code{

 $ debtags search role::metapackage

}code

3~ Local package lists

Whether you list metapackages, individual packages, or a combination of
both, all local package lists are stored in #{config/package-lists/}#. Since
more than one list can be used, this lends itself well to modular
designs. For example, you may decide to devote one list to a particular
choice of desktop, another to a collection of related packages that might as
easily be used on top of a different desktop. This allows you to experiment
with different combinations of sets of packages with a minimum of fuss,
sharing common lists between different live image projects.

Package lists that exist in this directory need to have a #{.list}# suffix
in order to be processed, and then an additional stage suffix, #{.chroot}#
or #{.binary}# to indicate which stage the list is for.

*{Note:}* If you don't specify the stage suffix, the list will be used for both stages. Normally, you want to specify #{.list.chroot}# so that the packages will only be installed in the live filesystem and not have an extra copy of the #{.deb}# placed on the medium.

3~ Local binary package lists

To make a binary stage list, place a file suffixed with #{.list.binary}# in
#{config/package-lists/}#. These packages are not installed in the live
filesystem, but are included on the live medium under #{pool/}#. You would
typically use such a list with one of the non-live installer variants. As
mentioned above, if you want this list to be the same as your chroot stage
list, simply use the #{.list}# suffix by itself.

3~generated-package-lists Generated package lists

It sometimes happens that the best way to compose a list is to generate it
with a script. Any line starting with an exclamation point indicates a
command to be executed within the chroot when the image is built. For
example, one might include the line #{! grep-aptavail -n -sPackage
-FPriority standard | sort}# in a package list to produce a sorted list of
available packages with #{Priority: standard}#.

In fact, selecting packages with the #{grep-aptavail}# command (from the
#{dctrl-tools}# package) is so useful that #{live-build}# provides a
#{Packages}# helper script as a convenience. This script takes two
arguments: #{field}# and #{pattern}#. Thus, you can create a list with the
following contents:

code{

 $ lb config
 $ echo '! Packages Priority standard' > config/package-lists/standard.list.chroot

}code

3~ Using conditionals inside package lists

Any of the live-build configuration variables stored in #{config/*}# (minus
the #{LB_}# prefix) may be used in conditional statements in package
lists. Generally, this means any #{lb config}# option uppercased and with
dashes changed to underscores. But in practice, it is only the ones that
influence package selection that make sense, such as #{DISTRIBUTION}#,
#{ARCHITECTURES}# or #{ARCHIVE_AREAS}#.

For example, to install #{ia32-libs}# if the #{--architectures amd64}# is
specified:

code{

 #if ARCHITECTURES amd64
 ia32-libs
 #endif

}code

You may test for any one of a number of values, e.g. to install
/{memtest86+}/ if either #{--architectures i386}# or #{--architectures
amd64}# is specified:

code{

 #if ARCHITECTURES i386 amd64
 memtest86+
 #endif

}code

You may also test against variables that may contain more than one value,
e.g. to install /{vrms}/ if either #{contrib}# or #{non-free}# is specified
via #{--archive-areas}#:

code{

 #if ARCHIVE_AREAS contrib non-free
 vrms
 #endif

}code

The nesting of conditionals is not supported.

% FIXME:

3~ Removing packages at install time

You can list packages in files with #{.list.chroot_live}# and
#{.list.chroot_install}# suffixes inside the #{config/package-lists}#
directory. If both a live and an install list exist, the packages in the
#{.list.chroot_live}# list are removed with a hook after the installation
(if the user uses the installer). The packages in the
#{.list.chroot_install}# list are present both in the live system and in the
installed system. This is a special tweak for the installer and may be
useful if you have #{--debian-installer live}# set in your config, and wish
to remove live system-specific packages at install time.

3~desktop-and-language-tasks Desktop and language tasks

Desktop and language tasks are special cases that need some extra planning
and configuration. Live images are different from Debian Installer images in
this respect. In the Debian Installer, if the medium was prepared for a
particular desktop environment flavour, the corresponding task will be
automatically installed. Thus, there are internal #{gnome-desktop}#,
#{kde-desktop}#, #{lxde-desktop}# and #{xfce-desktop}# tasks, none of which
are offered in #{tasksel}#'s menu. Likewise, there are no menu entries for
tasks for languages, but the user's language choice during the install
influences the selection of corresponding language tasks.

When developing a desktop live image, the image typically boots directly to
a working desktop, the choices of both desktop and default language having
been made at build time, not at run time as in the case of the Debian
Installer. That's not to say that a live image couldn't be built to support
multiple desktops or multiple languages and offer the user a choice, but
that is not live-build's default behaviour.

Because there is no provision made automatically for language tasks, which
include such things as language-specific fonts and input-method packages, if
you want them, you need to specify them in your configuration. For example,
a GNOME desktop image containing support for German might include these task
metapackages:

code{

 $ lb config
 $ echo "task-gnome-desktop task-laptop" >> config/package-lists/my.list.chroot
 $ echo "task-german task-german-desktop task-german-gnome-desktop" >> config/package-lists/my.list.chroot

}code

3~kernel-flavour-and-version Kernel flavour and version

One or more kernel flavours will be included in your image by default,
depending on the architecture. You can choose different flavours via the
#{--linux-flavours}# option. Each flavour is suffixed to the default stub
#{linux-image}# to form each metapackage name which in turn depends on an
exact kernel package to be included in your image.

Thus by default, an #{amd64}# architecture image will include the
#{linux-image-amd64}# flavour metapackage, and an #{i386}# architecture
image will include the #{linux-image-586}# metapackage.

When more than one kernel package version is available in your configured
archives, you can specify a different kernel package name stub with the
#{--linux-packages}# option. For example, supposing you are building an
#{amd64}# architecture image and add the experimental archive for testing
purposes so you can install the #{linux-image-3.18.0-trunk-amd64}#
kernel. You would configure that image as follows:

code{

 $ lb config --linux-packages linux-image-3.18.0-trunk
 $ echo "deb http://ftp.debian.org/debian/ experimental main" > config/archives/experimental.list.chroot

}code

3~custom-kernels Custom kernels

You can build and include your own custom kernels, so long as they are
integrated within the Debian package management system. The live-build
system does not support kernels not built as #{.deb}# packages.

The proper and recommended way to deploy your own kernel packages is to
follow the instructions in the #{kernel-handbook}#. Remember to modify the
ABI and flavour suffixes appropriately, then include a complete build of the
#{linux}# and matching #{linux-latest}# packages in your repository.

If you opt to build the kernel packages without the matching metapackages,
you need to specify an appropriate #{--linux-packages}# stub as discussed in
{Kernel flavour and version}#kernel-flavour-and-version. As we explain in
{Installing modified or third-party
packages}#installing-modified-or-third-party-packages, it is best if you
include your custom kernel packages in your own repository, though the
alternatives discussed in that section work as well.

It is beyond the scope of this document to give advice on how to customize
your kernel. However, you must at least ensure your configuration satisfies
these minimum requirements:

_* Use an initial ramdisk.

_* Include the union filesystem module (i.e. usually #{aufs}#).

_* Include any other filesystem modules required by your configuration
(i.e. usually #{squashfs}#).

2~installing-modified-or-third-party-packages Installing modified or
third-party packages

While it is against the philosophy of a live system, it may sometimes be
necessary to build a live system with modified versions of packages that are
in the Debian repository. This may be to modify or support additional
features, languages and branding, or even to remove elements of existing
packages that are undesirable. Similarly, "third-party" packages may be used
to add bespoke and/or proprietary functionality.

This section does not cover advice regarding building or maintaining
modified packages. Joachim Breitner's 'How to fork privately' method from
http://www.joachim-breitner.de/blog/archives/282-How-to-fork-privately.html
may be of interest, however. The creation of bespoke packages is covered in
the Debian New Maintainers' Guide at https://www.debian.org/doc/maint-guide/
and elsewhere.

There are two ways of installing modified custom packages:

_* #{packages.chroot}#

_* Using a custom APT repository

Using #{packages.chroot}# is simpler to achieve and useful for "one-off"
customizations but has a number of drawbacks, while using a custom APT
repository is more time-consuming to set up.

3~ Using #{packages.chroot}# to install custom packages

To install a custom package, simply copy it to the
#{config/packages.chroot/}# directory. Packages that are inside this
directory will be automatically installed into the live system during build
- you do not need to specify them elsewhere.

Packages *{must}* be named in the prescribed way. One simple way to do this
is to use #{dpkg-name}#.

Using #{packages.chroot}# for installation of custom packages has
disadvantages:

_* It is not possible to use secure APT.

_* You must install all appropriate packages in the
#{config/packages.chroot/}# directory.

_* It does not lend itself to storing live system configurations in revision
control.

3~ Using an APT repository to install custom packages

Unlike using #{packages.chroot}#, when using a custom APT repository you
must ensure that you specify the packages elsewhere. See {Choosing packages
to install}#choosing-packages-to-install for details.

While it may seem unnecessary effort to create an APT repository to install
custom packages, the infrastructure can be easily re-used at a later date to
offer updates of the modified packages.

3~ Custom packages and APT

live-build uses APT to install all packages into the live system so will
therefore inherit behaviours from this program. One relevant example is that
(assuming a default configuration) given a package available in two
different repositories with different version numbers, APT will elect to
install the package with the higher version number.

Because of this, you may wish to increment the version number in your custom
packages' #{debian/changelog}# files to ensure that your modified version is
installed over one in the official Debian repositories. This may also be
achieved by altering the live system's APT pinning preferences - see {APT
pinning}#apt-pinning for more information.

2~ Configuring APT at build time

You can configure APT through a number of options applied only at build
time. (APT configuration used in the running live system may be configured
in the normal way for live system contents, that is, by including the
appropriate configurations through #{config/includes.chroot/}#.) For a
complete list, look for options starting with #{apt}# in the #{lb_config}#
man page.

3~choosing-apt-or-aptitude Choosing apt or aptitude

You can elect to use either /{apt}/ or /{aptitude}/ when installing packages
at build time. Which utility is used is governed by the #{--apt}# argument
to #{lb config}#. Choose the method implementing the preferred behaviour for
package installation, the notable difference being how missing packages are
handled.

_* #{apt}#: With this method, if a missing package is specified, the package
installation will fail. This is the default setting.

_* #{aptitude}#: With this method, if a missing package is specified, the
package installation will succeed.

3~ Using a proxy with APT

One commonly required APT configuration is to deal with building an image
behind a proxy. You may specify your APT proxy with the #{--apt-ftp-proxy}#
or #{--apt-http-proxy}# options as needed, e.g.

code{

 $ lb config --apt-http-proxy http://proxy/

}code

3~tweaking-apt-to-save-space Tweaking APT to save space

You may find yourself needing to save some space on the image medium, in
which case one or the other or both of the following options may be of
interest.

If you don't want to include APT indices in the image, you can omit those
with:

code{

 $ lb config --apt-indices false

}code

This will not influence the entries in #{/etc/apt/sources.list}#, but merely
whether #{/var/lib/apt}# contains the indices files or not. The tradeoff is
that APT needs those indices in order to operate in the live system, so
before performing #{apt-cache search}# or #{apt-get install}#, for instance,
the user must #{apt-get update}# first to create those indices.

If you find the installation of recommended packages bloats your image too
much, provided you are prepared to deal with the consequences discussed
below, you may disable that default option of APT with:

code{

 $ lb config --apt-recommends false

}code

The most important consequence of turning off recommends is that
#{live-boot}# and #{live-config}# themselves recommend some packages that
provide important functionality used by most Live configurations, such as
#{user-setup}# which #{live-config}# recommends and is used to create the
live user. In all but the most exceptional circumstances you need to add
back at least some of these recommends to your package lists or else your
image will not work as expected, if at all. Look at the recommended packages
for each of the #{live-*}# packages included in your build and if you are
not certain you can omit them, add them back into your package lists.

The more general consequence is that if you don't install recommended
packages for any given package, that is, "packages that would be found
together with this one in all but unusual installations" (Debian Policy
Manual, section 7.2), some packages that users of your Live system actually
need may be omitted. Therefore, we suggest you review the difference turning
off recommends makes to your packages list (see the #{binary.packages}# file
generated by #{lb build}#) and re-include in your list any missing packages
that you still want installed. Alternatively, if you find you only want a
small number of recommended packages left out, leave recommends enabled and
set a negative APT pin priority on selected packages to prevent them from
being installed, as explained in {APT pinning}#apt-pinning.

3~ Passing options to apt or aptitude

If there is not a #{lb config}# option to alter APT's behaviour in the way
you need, use #{--apt-options}# or #{--aptitude-options}# to pass any
options through to your configured APT tool. See the man pages for #{apt}#
and #{aptitude}# for details. Note that both options have default values
that you will need to retain in addition to any overrides you may
provide. So, for example, suppose you have included something from
#{snapshot.debian.org}# for testing purposes and want to specify
#{Acquire::Check-Valid-Until=false}# to make APT happy with the stale
#{Release}# file, you would do so as per the following example, appending
the new option after the default value #{--yes}#:

code{

 $ lb config --apt-options "--yes -oAcquire::Check-Valid-Until=false"

}code

Please check the man pages to fully understand these options and when to use
them. This is an example only and should not be construed as advice to
configure your image this way. This option would not be appropriate for,
say, a final release of a live image.

For more complicated APT configurations involving #{apt.conf}# options you
might want to create a #{config/apt/apt.conf}# file instead. See also the
other #{apt-*}# options for a few convenient shortcuts for frequently needed
options.

3~apt-pinning APT pinning

For background, please first read the #{apt_preferences(5)}# man page. APT
pinning can be configured either for build time, or else for run time. For
the former, create #{config/archives/*.pref}#,
#{config/archives/*.pref.chroot}#, and #{config/apt/preferences}#. For the
latter, create #{config/includes.chroot/etc/apt/preferences}#.

Let's say you are building a ${testing} live system but need all the live
packages that end up in the binary image to be installed from sid at build
time. You need to add sid to your APT sources and pin the live packages from
it higher, but all other packages from it lower, than the default
priority. Thus, only the packages you want are installed from sid at build
time and all others are taken from the target system distribution,
${testing}. The following will accomplish this:

code{

 $ echo "deb http://mirror/debian/ sid main" > config/archives/sid.list.chroot
 $ cat >> config/archives/sid.pref.chroot << EOF
 Package: live-*
 Pin: release n=sid
 Pin-Priority: 600

 Package: *
 Pin: release n=sid
 Pin-Priority: 1
 EOF

}code

Negative pin priorities will prevent a package from being installed, as in
the case where you do not want a package that is recommended by another
package. Suppose you are building an LXDE image using #{task-lxde-desktop}#
in #{config/package-lists/desktop.list.chroot}#, but don't want the user
prompted to store wifi passwords in the keyring. This metapackage depends on
/{lxde-core}/, which recommends /{gksu}/, which in turn recommends
/{gnome-keyring}/. So you want to omit the recommended /{gnome-keyring}/
package. This can be done by adding the following stanza to
#{config/apt/preferences}#:

code{

 Package: gnome-keyring
 Pin: version *
 Pin-Priority: -1

}code