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Conceptually, coreos-assembler ties together generating OSTree commits with disk images
into a single "build schema". The build target is defined by the "config git"
which should be in src/config (relative to the build directory).
We can hack on some local input configs by exporting them in the
COREOS_ASSEMBLER_CONFIG_GIT env variable. For example:
$ export COREOS_ASSEMBLER_CONFIG_GIT=/path/to/github.com/coreos/fedora-coreos-config/
$ cosa init --force /dev/null
$ cosa fetch && cosa build
For generating OSTree commits, cosa uses manifest.yaml: An rpm-ostree
"manifest" or "treefile", which mostly boils down to a list of RPMs and a set
of rpm-md repositories they come from. It also supports postprocess to make
arbitrary changes. See the rpm-ostree documentation for the Treefile format
reference.
coreos-assembler also supports a generic way to embed architecture-independent
configuration and scripts by creating subdirectories in overlay.d/. Each subdirectory
of the overlay.d. directory is added to the OSTree commit, in lexicographic order.
It's recommended to name directories with a numeric prefix - e.g. 05core, 10extras.
Non-directories are ignored. For example, a good practice is to add a README.md file
into your overlay directories describing their structure.
This YAML file configures the output disk images. Supported keys are:
size: Size in GB for cloud images (OpenStack, AWS, etc.) Required.extra-kargs: List of kernel arguments.include: path to another YAML file to include. List values are appended. For other type, the values in the sourcing config win.
It's likely in the future we will extend this to support e.g. a separate /var
partition or configuring the filesystem types. If you want to do anything like
that today it requires forking the assembler and rebuilding it.
See the fedora-coreos-config for an example.
First you can expand the size of the image; edit src/config/image.yaml and
e.g. change 8 to 9. Rerun cosa build, and notice that the OSTree commit
didn't change, but a new image is generated in builds. When you cosa run,
you'll get it.
Another thing to try is editing src/config/manifest.yaml - add or
remove entries from packages. You can also add local rpm-md file:///
repositories.
Development speed is closely tied to the "edit-compile-debug" cycle. coreos-assembler
supports an overrides/ sub-directory of the coreos-assembler working directory,
which allows easily overlaying locally-generated content on top of the base OS content.
There are two subdirectories of overrides/:
overrides/rootfsoverrides/rpm
Let's say you want to hack on both ostree and ignition-dracut. See
for example this PR
which added support for make install DESTDIR= to the latter. In general
most upstream build systems support something like this; if they don't
it's a good idea to add.
Concretely, if /path/to/cosa-workdir is where you ran cosa init,
then after doing edits in a project, run a command like this from
the source repository for the component:
$ make install DESTDIR=/path/to/cosa-workdir/overrides/rootfs
This would then install files like
/path/to/cosa-buildroot/overrides/rootfs/usr/bin/ostree
etc.
If you then run cosa build from the cosa workdir,
those overrides will be automatically incorporated.
You can also choose to use overrides/rpm - this accepts pre-built
binary RPMs. This can be convenient when you want to quickly test
a binary RPM built elsewhere, or if you want to go through a more
"official" build process. If any RPMs are present here, then coreos-assembler
will automatically run createrepo_c and ensure that they are used
in the build.
In the future, it's likely coreos-assembler will also support something
like overrides/src which could be a directory of symlinks to local
git repositories.
If you're working on e.g. the kernel or Ignition (things that go into the initramfs),
then you probably need a cosa build workflow (or cosa buildinitramfs-fast, see below).
However, let's say you want to test a change to something that runs purely in the real root,
such as e.g. rpm-ostree, podman, or console-login-helper-messages. Rather
than doing a full image build each time, a fast way to test out changes is to use
cosa build-fast.
This command assumes you have a previous local coreos-assembler build. From the git checkout of the project you want to add:
$ export COSA_DIR=/srv/builds/fcos
$ cosa build-fast
$ cosa run
The cosa build-fast command will run make and inject the resulting binaries
on a qcow2 overlay file, which will appear in your project working directory.
The cosa run command similarly knows to look for these qcow2 files.
This will not affect the "real" cosa build in /srv/builds/fcos, but will
use it as a data source.
This workflow can be used alongside cosa build-fast, or separate from it.
If you invoke e.g.
$ cosa run --bind-ro ~/src/github/containers/podman,/run/workdir
The target VM will have the source directory bound in /run/workdir; then you
can directly copy binaries from your development environment into the VM.
If you are running cosa in a container, you will have to change your current working directory to a parent directory common to both project directories and use relative paths:
$ cd ~
$ cosa run \
--qemu-image src/fcos/build/latest/x86_64/fedora-coreos-*.x86_64.qcow2 \
--bind-ro src/github/containers/podman,/run/workdir
Then in the booted VM, /run/workdir will point to the libpod directory on your host,
allowing you to directly execute binaries from there. You can also use e.g.
rpm-ostree usroverlay and then copy binaries from your host /run/workdir into
the VM's rootfs.
Another related trick is:
$ cosa run --bind-ro /usr/bin,/run/hostbin
Then in the VM you have e.g. /run/hostbin/strace. (This may fail in some scenarios
where your dev container is different than the target).
If you are running cosa in a container, you will only have access to the binary installed in this container. You can install binaries before launching the VM with:
$ cosa shell
$ sudo dnf install ...
$ cosa run --bind-ro /usr/bin,/run/hostbin
If you're iterating on changes just to the initramfs, you can also use
cosa buildinitramfs-fast. For example, suppose you are working on ignition.
Follow these steps:
$ make
$ install -D -m 0755 bin/amd64/ignition /path/to/cosadir/overrides/initramfs/usr/bin/ignition
$ cd /path/to/cosadir
$ cosa buildinitramfs-fast
$ cosa run --qemu-image tmp/fastbuild/fastbuildinitrd-fedora-coreos-qemu.qcow2 -i config.ign
(Or instead of cosa run use e.g. cosa kola to run tests, etc.)
If you're adding new fields to the Ignition experimental spec, -i will
silently remove those fields, since the copy of Ignition that's vendored
into mantle won't know about them yet. Instead, you can specify that
kola should pass the config to the machine unmodified:
$ kola qemuexec --qemu-image tmp/fastbuild/fastbuildinitrd-fedora-coreos-qemu.qcow2 -i config.ign --ignition-direct
You'll need to manually configure autologin in the Ignition config, since kola won't be able to do it for you.
The output of coreos-assembler is conceptually two things:
- an ostree container image
- disk images (ISO, AWS AMI, qemu .qcow2, etc)
In many cases, rather than booting from a new disk image with the new OS, you will
want to explicitly test in-place upgrades. This uses an ostree native container, which is in the form of an .ociarchive file generated
by cosa build container (as well as the default cosa build, which also generates a qemu disk image).
You will need to make the container image available to your targeted system (VM or physical). One way to do this is to push the container to a public registry such as quay.io:
cosa push-container quay.io/exampleuser/fcos
Performing an in-place update from the cosa build output boils down to invoking a command of the form:
$ rpm-ostree rebase --experimental ostree-unverified-registry:quay.io/exampleuser/fcos
$ systemctl reboot
If you need access to CA certificates on your host (for example, when you need to access
a git repo that is not on the public Internet), you can mount in the host certificates
using the COREOS_ASSEMBLER_CONTAINER_RUNTIME_ARGS variable.
NOTE Sharing the /etc/pki/ca-trust directory may be blocked by SELinux so you may
have to use a directory with the system_u:object_r:container_file_t:s0 file context.
$ export COREOS_ASSEMBLER_CONTAINER_RUNTIME_ARGS='-v /etc/pki/ca-trust:/etc/pki/ca-trust:ro'
$ cosa init https://github.com/coreos/fedora-coreos-config.git
$ cosa fetch && cosa build
See this Stack Overflow question for additional discussion.
This is a guide to run a COSA pod in an OpenShift 4.6+ cluster in Google Compute Platform (GCP).
Install the KVM device plugin.
Up to this point, you needed to be kubeadmin.
From this point on though, best practice is to switch to an "unprivileged" user.
(In fact the steps until this point could be run by a separate team that manages the cluster; other developers could just use it as unprivileged users)
Personally, I added a httpasswd identity provider and logged in with a password.
I also did oc new-project coreos-virt etc.
Schedule a cosa pod:
apiVersion: v1
kind: Pod
metadata:
labels:
run: cosa
name: cosa
spec:
containers:
- args:
- shell
- sleep
- infinity
image: quay.io/coreos-assembler/coreos-assembler:latest
name: cosa
resources:
requests:
# Today COSA hardcodes 2048 for launching VMs. We could
# probably shrink that in the future.
memory: "3Gi"
devices.kubevirt.io/kvm: "1"
limits:
memory: "3Gi"
devices.kubevirt.io/kvm: "1"
volumeMounts:
- mountPath: /srv
name: workdir
volumes:
- name: workdir
emptyDir: {}
restartPolicy: Never
Then oc rsh pods/cosa and you should be able to ls -al /dev/kvm - and cosa build etc!
If you're a contributor unfamiliar with how CoreOS is built or provisioned and you're looking at fixing a bug in an RPM component (thank you!), here's the minimum you need to know to get started debugging and iterating on CoreOS. This requires access to podman and /dev/kvm.
-
First, download the latest QEMU CoreOS image. If you're handling a bug report from someone on the CoreOS team, they may have asked you to download a specific image. Otherwise, for Fedora, you can get the latest from https://fedoraproject.org/coreos/download or by using coreos-installer:
# as privileged podman run --privileged --rm -v .:/srv -w /srv quay.io/coreos/coreos-installer:release \ download --decompress -p qemu -f qcow2.xz # as unprivileged, but relabeling the working directory podman run --rm -v .:/srv:z -w /srv quay.io/coreos/coreos-installer:release \ download --decompress -p qemu -f qcow2.xz
For RHCOS, you can get an image from the OpenShift mirrors at https://mirror.openshift.com/pub/openshift-v4/x86_64/dependencies/rhcos/. If you are a Red Hat employee, you can also access development builds not yet available on the mirrors from the RHCOS release browser.
-
Run the VM:
# as privileged podman run --privileged --rm -ti -v .:/srv quay.io/coreos-assembler/coreos-assembler \ run --bind-ro /srv,/var/srv fedora-coreos-40.20240519.3.0-qemu.x86_64.qcow2 # as unprivileged, but relabeling the working directory and passing /dev/kvm podman run --rm -ti -v .:/srv:z --device /dev/kvm quay.io/coreos-assembler/coreos-assembler \ run --bind-ro /srv,/var/srv fedora-coreos-40.20240519.3.0-qemu.x86_64.qcow2
This will mount the working directory at /srv as read-only in the VM so that you can more easily pass data into it.
-
Modifying the OS:
Once you're in the VM, you can test your changes multiple ways.
(1) One universal way is to build a custom RPM, and put it in the mounted directory, then use
rpm-ostree override replace /srv/path/to/my.rpm. You can then either reboot, orrpm-ostree apply-liveto have the change apply immediately.(2) Alternatively, you can do
rpm-ostree usroverlayto make the rootfs writable. Then you can do e.g.rpm -Uvh /srv/my.rpmfor example as you would on a traditional system. Or at this point, you can directly rsync over the output from your local project build. E.g. assuming your build system uses a Makefile and it supportsDESTDIR=, on your host, you can domake install DESTDIR=/path/to/mounted/dir/subdir, and in the VM,rsync -av /srv/subdir/ /.(3) Another newer approach is to build a derived container image with your changes. For example, to customize the rawhide image, you can build a Containerfile like:
FROM quay.io/fedora/fedora-coreos:rawhide # using a locally built RPM COPY my.rpm / RUN dnf install /my.rpm && dnf clean all # or using project output directly from a `make install DESTDIR=installtree/ COPY installtree/ /tmp RUN rsync /tmp/ / && rm -rf /tmp
You can build this image, then copy it to the VM as an OCI archive:
podman build -t localhost/my-image . skopeo copy containers-storage:localhost/my-image oci-archive:/path/to/mounted/dir/my.ociarchiveAnd then on the VM:
rpm-ostree rebase ostree-unverified-image:oci-archive:/srv/my.ociarchive(4) That said, sometimes you just have to build FCOS/RHCOS from scratch. In that case, follow the steps in https://coreos.github.io/coreos-assembler/building-fcos/ and see the other sections on this page for ways to modify inputs (e.g. custom RPMs or rootfs content). But roughly, the flow looks something like this:
# for building FCOS cosa init https://github.com/coreos/fedora-coreos-config # for building SCOS cosa init --variant c9s https://github.com/openshift/os # copy any modifications in e.g. the overrides/rpm directory cp /path/to/my.rpm overrides/rpm/ # or overrides/rootfs directory (cd /path/to/my/project && make install DESTDIR=/path/to/overrides/rootfs) # now we're ready to build cosa fetch && cosa build # to run the freshly built image cosa run # to build the live ISO cosa buildextend-metal && cosa buildextend-live --fast # to run the live ISO cosa run -p qemu-iso