Firstly, ensure kolla is installed or ready for development.
Then the kolla-build command is responsible for building Docker images.
Note
When developing Kolla it can be useful to build images using files located in
a local copy of Kolla. Use the tools/build.py
script instead of
kolla-build command in all below instructions.
Install tox and generate the build configuration. The build configuration is designed to hold advanced customizations when building images.
If you have already cloned the Kolla Git repository to the kolla
folder,
generate the kolla-build.conf
file using the following steps.
If you don’t, you can also run kolla-build
without a kolla-build.conf
or with the file you find in the etc_examples
folder of the Kolla pip package.
But you should only do that for testing purposes, if at all.
pip install tox
cd kolla/
tox -e genconfig
The location of the generated configuration file is
etc/kolla/kolla-build.conf
, it can also be copied to /etc/kolla
. The
default location is one of /etc/kolla/kolla-build.conf
or
etc/kolla/kolla-build.conf
.
In general, images are built like this:
kolla-build
python tools/build.py
By default, the above command would build all images based on CentOS image.
The operator can change the base distro with the -b
option:
kolla-build -b ubuntu
python tools/build.py -b ubuntu
There are following distros available for building images:
Warning
Fedora images are deprecated since Newton and will be removed in the future.
It is possible to build only a subset of images by specifying them on the command line:
kolla-build keystone
python tools/build.py keystone
In this case, the build script builds all images whose name contains the
keystone
string along with their dependencies.
Multiple names may be specified on the command line:
kolla-build keystone nova
python tools/build.py keystone nova
The set of images built can be defined as a profile in the profiles
section
of kolla-build.conf
. Later, profile can be specified by --profile
CLI
argument or profile
option in kolla-build.conf
. Kolla provides some
pre-defined profiles:
infra
infrastructure-related imagesmain
core OpenStack imagesaux
auxiliary images such as trove, magnum, ironicdefault
minimal set of images for a working deployFor example, due to Magnum requires Heat, add the following profile to
profiles
section in kolla-build.conf
:
[profiles]
magnum = magnum,heat
These images can be built using command line:
kolla-build --profile magnum
Or put following line to DEFAULT
section in kolla-build.conf
file:
[DEFAULT]
profile = magnum
The kolla-build uses kolla
as default Docker namespace. This is
controlled with the -n
command line option. To push images to a Dockerhub
repository named mykollarepo
:
kolla-build -n mykollarepo --push
To push images to a local registry,
use --registry
flag:
kolla-build --registry 172.22.2.81:5000 --push
When building images, there are two methods of the OpenStack install. One is
binary
. Another is source
. The binary
means that OpenStack will be
installed from apt/yum. And the source
means that OpenStack will be
installed from source code. The default method of the OpenStack install is
binary
. It can be changed to source
using the -t
option:
kolla-build -t source
python tools/build.py -t source
The locations of OpenStack source code are written in
etc/kolla/kolla-build.conf
.
Now the source type supports url
, git
, and local
. The location of
the local
source type can point to either a directory containing the source
code or to a tarball of the source. The local
source type permits to make
the best use of the Docker cache.
The etc/kolla/kolla-build.conf
file looks like:
[glance-base]
type = url
location = http://tarballs.openstack.org/glance/glance-master.tar.gz
[keystone-base]
type = git
location = https://git.openstack.org/openstack/keystone
reference = stable/mitaka
[heat-base]
type = local
location = /home/kolla/src/heat
[ironic-base]
type = local
location = /tmp/ironic.tar.gz
To build RHEL containers, it is necessary to include registration with RHN of the container runtime operating system.To obtain a RHN username/password/pool id, contact Red Hat. Use a template’s header block overrides file, add the following:
RUN subscription-manager register --user=<user-name> \
--password=<password> && subscription-manager attach --pool <pool-id>
As of the Newton release, the kolla-build
tool provides a Jinja2 based
mechanism which allows operators to customise the Dockerfiles used to generate
Kolla images.
This offers a lot of flexibility on how images are built, for example, installing extra packages as part of the build, tweaking settings, installing plugins, and numerous other capabilities. Some of these examples are described in more detail below.
Note
The docker file for each image is found in docker/<image name> directory.
Anywhere the line {% block ... %}
appears may be modified. The Kolla
community have added blocks throughout the Dockerfiles where we think they will
be useful, however, operators are free to submit more if the ones provided are
inadequate.
The following is an example of how an operator would modify the setup steps within the Horizon Dockerfile.
First, create a file to contain the customisations, for example:
template-overrides.j2
. In this place the following:
{% extends parent_template %}
# Horizon
{% block horizon_redhat_binary_setup %}
RUN useradd --user-group myuser
{% endblock %}
Then rebuild the horizon image, passing the --template-override
argument:
kolla-build --template-override template-overrides.j2 horizon
python tools/build.py --template-override template-overrides.j2 horizon
Note
The above example will replace all contents from the original block. Hence in many cases one may want to copy the original contents of the block before making changes.
More specific functionality such as removing/appending entries is available for packages, described in the next section.
Packages installed as part of an image build can be overridden, appended to, and deleted. Taking the Horizon example, the following packages are installed as part of a binary install type build:
openstack-dashboard
httpd
mod_wsgi
mod_ssl
gettext
To add a package to this list, say, iproute
, first create a file,
for example, template-overrides.j2
. In this place the following:
{% extends parent_template %}
# Horizon
{% set horizon_packages_append = ['iproute'] %}
Then rebuild the horizon image, passing the --template-override
argument:
kolla-build --template-override template-overrides.j2 horizon
python tools/build.py --template-override template-overrides.j2 horizon
Alternatively template_override
can be set in kolla-build.conf
.
The append
suffix in the above example carries special significance. It
indicates the operation taken on the package list. The following is a complete
list of operations available:
Base-image can be specified by argument --base-image
. For example:
kolla-build --base-image registry.access.redhat.com/rhel7/rhel --base rhel
The Dockerfile customisation mechanism is also useful for adding/installing plugins to services. An example of this is Neutron’s third party L2 drivers.
The bottom of each Dockerfile contains two blocks, image_name_footer
, and
footer
. The image_name_footer
is intended for image specific
modifications, while the footer
can be used to apply a common set of
modifications to every Dockerfile.
For example, to add the networking-cisco
plugin to the neutron_server
image, one may want to add the following to the template-override
file:
{% extends parent_template %}
{% block neutron_server_footer %}
RUN git clone https://git.openstack.org/openstack/networking-cisco \
&& pip --no-cache-dir install networking-cisco
{% endblock %}
Astute readers may notice there is one problem with this however. Assuming
nothing else in the Dockerfile changes for a period of time, the above RUN
statement will be cached by Docker, meaning new commits added to the Git
repository may be missed on subsequent builds. To solve this the Kolla build
tool also supports cloning additional repositories at build time, which will be
automatically made available to the build, within an archive named
plugins-archive
.
Note
The following is available for source build types only.
To use this, add a section to /etc/kolla/kolla-build.conf
in the following
format:
[<image>-plugin-<plugin-name>]
Where <image>
is the image that the plugin should be installed into, and
<plugin-name>
is the chosen plugin identifier.
Continuing with the above example, add the following to
/etc/kolla/kolla-build.conf
:
[neutron-server-plugin-networking-cisco]
type = git
location = https://git.openstack.org/openstack/networking-cisco
reference = master
The build will clone the repository, resulting in the following archive structure:
plugins-archive.tar
|__ plugins
|__networking-cisco
The template now becomes:
{% block neutron_server_footer %}
ADD plugins-archive /
pip --no-cache-dir install /plugins/*
{% endblock %}
Many of the Dockerfiles already copy the plugins-archive
to the image and
install available plugins at build time.
The Dockerfile customisation mechanism is also useful for adding/installing additions into images. An example of this is adding your jenkins job build metadata (say formatted into a jenkins.json file) into the image.
Similarly to the plugins mechanism, the Kolla build tool also supports cloning
additional repositories at build time, which will be automatically made
available to the build, within an archive named additions-archive
. The main
difference between plugins-archive
and additions-archive
is that
plugins-archive
is copied to the relevant images and processed to install
available plugins while additions-archive
processing is left to the Kolla
user.
Note
The following is available for source build types only.
To use this, add a section to /etc/kolla/kolla-build.conf
in the following
format:
[<image>-additions-<additions-name>]
Where <image>
is the image that the plugin should be installed into, and
<additions-name>
is the chosen additions identifier.
Continuing with the above example, add the following to
/etc/kolla/kolla-build.conf
file:
[neutron-server-additions-jenkins]
type = local
location = /path/to/your/jenkins/data
The build will copy the directory, resulting in the following archive structure:
additions-archive.tar
|__ additions
|__jenkins
Alternatively, it is also possible to create an additions-archive.tar
file
yourself without passing by /etc/kolla/kolla-build.conf
in order to use the
feature for binary build type.
The template now becomes:
{% block neutron_server_footer %}
ADD additions-archive /
RUN cp /additions/jenkins/jenkins.json /jenkins.json
{% endblock %}
The build method allows the operator to build containers from custom repos.
The repos are accepted as a list of comma separated values and can be in the
form of .repo
, .rpm
, or a url. See examples below.
Update rpm_setup_config
in /etc/kolla/kolla-build.conf
:
rpm_setup_config = https://trunk.rdoproject.org/centos7/currrent/delorean.repo,https://trunk.rdoproject.org/centos7/delorean-deps.repo
If specifying a .repo
file, each .repo
file will need to exist in the
same directory as the base Dockerfile (kolla/docker/base
):
rpm_setup_config = epel.repo,delorean.repo,delorean-deps.repo
For Debian based images, additional apt sources may be added to the build as follows:
apt_sources_list = custom.list
Can’t build base image because Docker fails to install systemd or httpd.
There are some issues between Docker and AUFS. The simple workaround to
avoid the issue is that add -s devicemapper
or -s btrfs
to
DOCKER_OPTS
. Get more information about the issue from the Docker bug
tracker and how to
configure Docker with BTRFS back end.
Mirrors are unreliable.
Some of the mirrors Kolla uses can be unreliable. As a result occasionally
some containers fail to build. To rectify build problems, the build tool
will automatically attempt three retries of a build operation if the first
one fails. The retry count is modified with the --retries
option.
To make kolla-ansible pull images from a local registry, set
"docker_registry"
to "172.22.2.81:5000"
in
"/etc/kolla/globals.yml"
. Make sure Docker is allowed to pull images from
insecure registry. See
Docker Insecure Registry.
We can insert http_proxy settings into the images to fetch packages during build, and then unset them at the end to avoid having them carry through to the environment of the final images. Note however, it’s not possible to drop the info completely using this method; it will still be visible in the layers of the image.
To set the proxy settings, we can add this to the template’s header block:
ENV http_proxy=https://evil.corp.proxy:80
ENV https_proxy=https://evil.corp.proxy:80
To unset the proxy settings, we can add this to the template’s footer block:
ENV http_proxy=""
ENV https_proxy=""
Besides this configuration options, the script will automatically read these environment variables. If the host system proxy parameters match the ones going to be used, no other input parameters will be needed. These are the variables that will be picked up from the user env:
HTTP_PROXY, http_proxy, HTTPS_PROXY, https_proxy, FTP_PROXY,
ftp_proxy, NO_PROXY, no_proxy
Also these variables could be overwritten using --build-args
, which have
precedence.
Except where otherwise noted, this document is licensed under Creative Commons Attribution 3.0 License. See all OpenStack Legal Documents.