Wikipedia said: In much the same way as the trade or vocation of smithing produced the common English surname Smith and the German name Schmidt, the cooper trade is also the origin of German names like Kübler.
There is still demand for high-quality
wooden barrelscontainers, and it is thought that the highest-qualitybarrelscontainers are those hand-made by professionalcooperskublers.
A generic, extendable build orchestrator, in Bash. The default batteries focus on creating and maintaining Docker base images.
- Why Should You Care?
- Requirements
- Installation
- Tour de Kubler
- The Basics
- Every Image needs a Home - Working Dirs and Namespaces
- Hello Image
- Anatomy of an Image
- Understanding the Build Process
- But Does it Work? - Image Tests
- Common Build Pitfalls
- Custom Build Containers
- Updating Build Containers
- Pushing Images to a Docker Repository
- Handling Software that doesn't have an Ebuild (yet ;)
- Other Resources
- Discord
Perhaps:
- You love Docker but are annoyed by some of the restrictions of it's
build
command that keep getting into your way. Wouldn't it be nice if you coulddocker build
your images with alldocker run
args, like-v
, at your disposal? Or if yourDockerfile
was fully parameterizable? - You are a SysAdmin or DevOps engineer who seeks complete governance over the contents of their container images, with full control of the update cycle and the ability to track all software version changes from a centralized vcs repository.
- You need to manage a lot of Docker base/service images in a sane way and want peace of mind with automated post-build tests.
- You are a Gentoo user and want to build slim Docker images with a toolset you are familiar with. Not having to wrestle with CrossDev would also be a plus.
- You are looking for an interactive OS host agnostic Gentoo playground or portable ebuild development environment.
- You want to create custom root file systems, possibly for different cpu architectures and/or libc implementations (i.e. musl, uclibc, etc) in an isolated and repeatable manner.
- Bash version 4.2+, using 4.4+ is highly recommended due to bugs in previous versions.
Optional:
- GPG for download verification
# Assuming a working gpg setup just import the Gentoo ebuild repository signing key:
gpg --keyserver keys.gentoo.org --recv-keys E1D6ABB63BFCFB4BA02FDF1CEC590EEAC9189250
- rlwrap for command history
- Working Docker or Podman setup
- Git
- jq to parse Docker/Podman json output
An ebuild can be found at https://github.com/edannenberg/kubler-overlay/
Add the overlay (see link for instructions) and install as usual:
emerge -av kubler
The standard version of Bash in macOS is too old. Easiest way to upgrade to a later version is to use Homebrew. Once Homebrew is installed, update Bash:
$ brew install bash
This will install an updated version of Bash in /usr/local/bin/
. To make it your default shell, you need to edit
Advanced Options...
in System Preferences. Just right-click your user icon to find the option.
Also, macOS does not load ~/.bashrc
by default, but uses ~/.bash_profile
, so when following the instructions
below, make sure to edit the correct file.
Kubler has been tested on Gentoo, CoreOS and macOS. It should run on all Linux distributions. Feel free to open an issue or ask on Discord if you run into problems.
- Clone the repo or download/extract the release archive to a location of your choice, i.e.
$ cd ~/tools/
$ curl -L https://github.com/edannenberg/kubler/archive/master.tar.gz | tar xz
- Optional, add
kubler.sh
to your path
The recommended way is to add the following at the end of your ~/.bashrc
file, don't forget to adjust the
Kubler path for each line accordingly:
export PATH="${PATH}:/path/to/kubler/bin"
# optional but highly recommended, adds bash completion support for all kubler commands
source /path/to/kubler/lib/kubler-completion.bash
Note: You will need to open a new shell for this to take effect, if this fails on a Linux SystemD host re-logging might be required instead.
Kubler doesn't require any further configuration but you may want to review the main config file
located at /etc/kubler.conf
. If the file doesn't exist the kubler.conf
file in Kubler's root folder is
used as a fallback.
All of Kubler's runtime data, like user config overrides, downloads or custom scripts, is kept at a path defined
via KUBLER_DATA_DIR
. This defaults to ~/.kubler/
, which is suitable if user accounts have Docker/Podman access on the host.
If you plan to use Docker/Podman/Kubler only with sudo
, like on a server, you may want to use /var/lib/kubler
, or some other location, as data dir instead.
Managing your KUBLER_DATA_DIR
with a VCS tool like Git is supported, a proper .gitignore
is added on initialization.
- Remove any build artifacts and container images created by Kubler:
$ kubler clean -N
-
Remove Kubler itself:
- On Gentoo and ebuild install:
emerge -C kubler
then remove the kubler overlay - Manual install: reverse the steps you did during manual installation
- On Gentoo and ebuild install:
-
Delete any namespace dirs and configured
KUBLER_DATA_DIR
(default is~/.kubler/
) you had in use, this may require su permissions.
To get a quick overview of available commands/options:
$ kubler --help
Or to view details for a specific command:
$ kubler build -h
Per default almost all of Kubler's commands will need to be run from a --working-dir
, if the option is
omitted the current working dir of the executing shell is used. It behaves much like Git in that
regard, executing any Kubler command from a sub directory of a valid working dir will also work as
expected.
A --working-dir
is considered valid if it has a kubler.conf
file and either an images/
dir, or
one ore more namespace dirs, which are just a collection of images.
Kubler currently ships with Docker and Podman build engines. The rest of this tour will focus on building Docker images, it's worth noting that the build process may be completely different, i.e. it may not involve Gentoo or Docker at all, for other build engines.
If you are not familiar with Gentoo some of it's terms you will encounter may be confusing, a short 101 glossary:
stage3 | A tar ball provided by Gentoo which on extraction provides an almost-complete root file system for a Gentoo installation |
Portage | Gentoo's default package manager, this is where all the magic happens |
emerge | Portage's main executable |
ebuild | text file which identifies a specific software package and how Portage should handle it |
Portage Tree | Categorized collection of ebuilds, Gentoo ships with ~20k ebuilds |
Portage Overlay | Additional ebuild repository maintained by the community/yourself |
To accommodate different use cases there are three types of working dirs:
multi | The working dir is a collection of one or more namespace dirs |
single | The working dir doubles as namespace dir, you can't create a new namespace in it, but you save a directory level |
local | Same as multi but --working-dir is equal to KUBLER_DATA_DIR |
First switch to a directory where you would like to store your Kubler managed images or namespaces:
$ cd ~/projects
Then use the new
command to take care of the boiler plate, choose 'single' when asked for the namespace type:
$ kubler new namespace mytest
$ cd mytest/
Although not strictly required it's recommended to install Kubler's example images by running:
$ kubler update
Let's start with a simple task and dockerize Figlet, a nifty tool that produces ascii fonts. First create a new image stub:
$ kubler new image mytest/figlet
When asked for the image parent, enter kubler/bash
and bt
when asked for tests:
»»» Extend an existing Kubler managed image? Fully qualified image id (i.e. kubler/busybox) or scratch
»[?]» Parent Image (scratch): kubler/bash
»»»
»»» Add test template(s)? Possible choices:
»»» hc - Add a stub for Docker's HEALTH-CHECK, recommended for images that run daemons
»»» bt - Add a stub for a custom build-test.sh script, a good choice if HEALTH-CHECK is not suitable
»»» yes - Add stubs for both test types
»»» no - Fck it, we'll do it live!
»[?]» Tests (hc): bt
»»»
»[✔]» Successfully created new image at projects/mytest/images/figlet
A handy feature when working on a Kubler managed image is the --interactive
build arg. As the name suggests it
allows us to poke around in a running build container and plan/debug the image build. Let's give it a try:
$ kubler build mytest/figlet -i
This will also build any missing parent images/builders, so the first run may take quite a bit of time. Don't worry, once the local binary package cache and build containers are seeded future runs will be much faster. When everything is ready you are dropped into a new shell:
»[✔]»[kubler/bash]» done.
»»»»»[mytest/figlet]» using: docker / builder: kubler/bob-bash
kubler-bob-bash / #
To search Portage's package db you may use eix
, or whatever your preferred method is:
kubler-bob-bash / # eix figlet
* app-misc/figlet
Available versions: 2.2.5 ~2.2.5-r1
Homepage: http://www.figlet.org/
Description: program for making large letters out of ordinary text
* dev-php/PEAR-Text_Figlet
As with most package managers, software in Portage is grouped by categories. The category and package name combined
form a unique package atom, in our case we want to install app-misc/figlet
.
Now manifest the new found knowledge by editing the image's build script:
kubler-bob-bash / # nano /config/build.sh
Note: The /config
folder in the build container is the host mounted image directory at mytest/images/figlet/
.
Feel free to use your local IDE/editor to edit build.sh
instead.
Add the app-misc/figlet
package atom to the _packages
variable in build.sh
:
_packages="app-misc/figlet"
Then start a test run of the first build phase (more on that later), if you are in a hurry you may skip this step:
kubler-bob-bash / # kubler-build-root
Once this finishes exit the interactive builder by hitting crtl+d
or typing exit
. All that is left to do is
building the actual image:
$ kubler build mytest/figlet -nF
The args are short hand for --no-deps
and --force-full-image-build
, omitting -n
would also rebuild all
parent images, which can be handy but is just a waste of time in this case.
»[✘]»[mytest/figlet]» fatal: build-test.sh for image mytest/figlet:20190228 failed with exit signal: 1
Oops, looks like we forgot the image test. Let's fix that by editing the mentioned build-test.sh
file:
#!/usr/bin/env sh
set -eo pipefail
# check figlet version string
figlet -v | grep -A 2 'FIGlet Copyright' || exit 1
Not exactly exhausting but it will do for now. Rebuild the image again but this time only pass -f
instead of -F
,
this too forces an image rebuild but skips the first build phase:
$ kubler build mytest/figlet -nf
»[✔]»[mytest/figlet]» done.
$ docker run -it --rm mytest/figlet figlet foooo
$ tree images/figlet
images/figlet/
├── Dockerfile <- generated, never edit this manually
├── Dockerfile.template <- standard Dockerfile, except it's fully parameterizable
├── PACKAGES.md <- generated, lists all installed packages with version and use flags
├── README.md <- optional, image specific documentation written by you
├── build-test.sh <- optional, if the file exists it activates a post-build test
├── build.conf <- general image/builder config, sourced on the host
├── build.sh <- configures the first build phase, only sourced in build containers
The stub files generated with the new
command are heavily commented with further details.
After executing a build command an image dependency graph is generated for the passed target ids by parsing
the IMAGE_PARENT
and BUILDER
vars in the respective build.conf
files. You can visualize the graph for any
given target ids with the dep-graph
command:
$ kubler dep-graph -b kubler/nginx mytest
Once all required data is gathered, each missing, as in not already built, image will go through a two phase build process:
-
The configured builder image is passed to
docker run
to produce arootfs.tar
file in the image folder- mounts current image dir into a fresh build container as
/config
- executes
build-root.sh
(a generic script provided by Kubler) inside build container build-root.sh
readsbuild.sh
from the mounted/config
directory- if
configure_builder()
hook is defined inbuild.sh
, execute it package.installed
file is generated which is used by depending images as package.providedROOT
env is set to custom path- if
configure_rootfs_build()
hook is defined inbuild.sh
, execute it _packages
defined inbuild.sh
are installed via Portage at custom empty root directory- if
finish_rootfs_build()
hook is defined inbuild.sh
, execute it ROOT
dir is packaged asrootfs.tar
and placed in image dir on the host- preserve exact builder state for child images by committing the used build container as a new builder image
- mounts current image dir into a fresh build container as
The build-root.sh
file effectively just uses a feature of Gentoo's package manager that allows us to install any given _packages
,
with all it's dependencies, at a custom path by setting the ROOT
env in the build container. The other piece to the
puzzle is Portage's package.provided file which is constantly updated and preserved by committing the build
container as a new builder image after each build. Thanks to Docker's shared layers the overhead of this is fairly minimal.
Kubler's default build container names generally start with bob
, when a new build container state is committed the
current image name gets appended. For example kubler/bob-openssl
refers to the container used to build the kubler/openssl
image.
Any image that has kubler/openssl
as IMAGE_PARENT
will use kubler/bob-openssl
as it's build container.
There are no further assumptions or magic, the hooks in build.sh
are just Bash functions so there are virtually no limits
on how you may produce the resulting rootfs.tar
. You have a full Gentoo installation at your disposal, orchestrate away.
-
Image dir is passed to
docker build
as build context, the Dockerfile has aADD rootfs.tar /
entry- Dockerfile is generated from Dockerfile.template on each run
- vars starting with
BOB_
in yourbuild.conf
can be used for parameterization, i.e.BOB_FOO=bar
- produces the final image
This approach is basically an alternative to Docker's multi-stage
builds that also allows host mounts and --privileged
builds in the first phase where all the heavy lifting is done.
A successful image build doesn't always equal a functional image. Kubler supports two types of image tests that can be run as part of the post-build process:
-
Docker's
HEALTH-CHECK
- set
POST_BUILD_HC=true
inbuild.conf
to activate - configure the health-check as usual in
Dockerfile.template
- built image is run in detached mode and container health status is queried until it's
healthy
or timeout is reached
- set
-
build-test.sh
- if the file exists it is executed in the built image and the container exit signal is checked to determine success/error
- file should be executable as it is only mounted for the test
- good alternative when a Docker health-check doesn't make sense
First of all if you run into errors don't panic and look for a towel.. erm read the output carefully for hints. The log file
is located at $KUBLER_DATA_DIR/log/build.log
. Some of the more common errors:
- Build fails due to missing files
Not all ebuilds support a custom ROOT
properly, in almost all of those cases the problem boils down to the ebuild
trying to execute files at the actual build container root, when in reality the files it expects just got installed at the
custom root defined via ROOT
.
The easiest solution is to install the failing package manually in the configure_builder()
hook first:
_packages="dev-lang/foo"
configure_builder()
{
# move any use flag/keywords config from configure_rootfs_build() hook to
# reuse the resulting binary package, keeps overhead to a minimum
emerge dev-lang/foo
}
While the above should always work, you may want to get a bit creative instead if the problem is obvious to resolve.
Example from kubler/graph-easy
:
configure_rootfs_build()
{
# graphviz ebuild calls 'dot -c || die' as part of post-install. Fake dot and run the setup via Dockerfile instead.
ln -s /bin/true /usr/bin/dot
}
finish_rootfs_build()
{
# remove the fake symlink, the actual dot binary is in ${_EMERGE_ROOT}/usr/bin/dot
rm /usr/bin/dot
}
- Image was successfully built but can't find it's libraries on image run
This usually happens when the libs in question got installed at a new location which is not yet known to the system:
ImportError: libpq.so.5: cannot open shared object file: No such file or directory
The issue here is that the ebuild ran ldconfig
during install but the change was done in the builder context and not
the custom root. Adding RUN ldconfig
to your Dockerfile.template
resolves the issue.
- Image build fails with Operation not permitted
strace: test_ptrace_setoptions_for_all: PTRACE_TRACEME doesn't work: Operation not permitted
Some packages like glibc
require SYS_PTRACE
permissions for the build container during installation, this can be configured
via build.conf
:
BUILDER_CAPS_SYS_PTRACE='true'
The default builders provided by Kubler should do just fine for most tasks, however you can customize the default builders to your liking or create a new one from scratch.
Note that extending a builder is often overkill as you can also customize a builder in the configure_builder()
hook of
any image's build.sh
. The changes will persist to all depending image builds.
- Create the new builder and set a parent:
$ kubler new builder mytest/alice
»»» Extend existing Kubler builder image? Fully qualified image id (i.e. kubler/bob) or stage3
»[?]» Parent Image (stage3): kubler/bob
»[✔]» Successfully created new builder at projects/mytest/builder/alice
- Edit
build.sh
and customize away:
configure_builder()
{
emerge app-editors/vim
emerge -C app-editors/nano
echo "nano is for plebs!" > ~/foo.txt
}
- Set your builder as
DEFAULT_BUILDER
in your namespace or userkubler.conf
DEFAULT_BUILDER="mytest/alice"
If you set this via user config your custom builder is also used for all images in the kubler
namespace.
Note: You will need to rebuild with the -c
arg for this to take effect:
$ kubler build -c mytest
Pretty much the same process as above except:
- Create the new builder but don't set a parent:
$ kubler new builder mytest/s3b
»»» Extend existing Kubler builder image? Fully qualified image id (i.e. kubler/bob) or stage3
»[?]» Parent Image (stage3):
»[✔]» Successfully created new builder at projects/mytest/builder/s3b
- Additionally configure the used Gentoo stage3 file in
build.conf
:
STAGE3_BASE='stage3-amd64-musl-hardened'
ARCH='amd64'
ARCH_URL="${MIRROR}experimental/${ARCH}/musl/"
The ARCH_URL
should match the base path on Gentoo's distribution mirrors. Then run kubler update
to fetch the latest stage3 date.
Gentoo is a rolling distribution, Portage updates happen daily. The provided stage3 files are updated frequently and only kept for a limited time on Gentoo's servers and mirrors. To check for new releases:
$ kubler update
This will also check for updates to the example images provided by Kubler, usually updated at the end of each month. If updates were found found simply rebuild the stack by running:
$ kubler clean
$ kubler build -C mynamespace
To push images to Docker Hub:
$ kubler push mytest somenamespace/someimage
The default assumes that the given namespace equals the respective Docker Hub account names, i.e. mytest
and somenamespace
.
To override this you may place a push.conf
file in each namespace dir with the following format:
DOCKER_LOGIN=myacc
DOCKER_PW=mypassword
#[email protected]
While Gentoo's package tree is fairly massive it's doesn't have everything or maybe not as bleeding edge as you would like. In such cases you may try your luck on http://gpo.zugaina.org/ and search the community overlays that will cover an even wider range of ebuilds. Just keep the security implications of downloading random strangers' ebuilds in mind. ;)
If you are still out of luck after trying the above you can do a manual install in the finish_rootfs_hook()
,
as you usually would with a shell. However the recommended way is to maintain your own Portage overlay by writing an
ebuild file. Some study materials, sorted by complexity:
It's a fairly straight forward affair, once you wrapped your head around it, that provides benefits over the manual approach. For example you won't have to remember to strip the binaries after a manual installation.
The ebuild system is heavily modularized, a good approach is to study/copy existing ebuilds for similar software in the
Portage tree. You can browse Portage's ebuilds at /var/db/repos/gentoo/
in any interactive build container. Often you
just need to find a good ebuild source and change a few trivial things to be done with it.
The kubler-overlay repo has some pointers on how to setup a ebuild dev environment with Kubler.
For questions or chatting with other users you may join our Discord server at:
Although you'll need to create an account on Discord email verification with Discord is disabled for now.