Developing Talos
This guide outlines steps and tricks to develop Talos operating systems and related components. The guide assumes Linux operating system on the development host. Some steps might work under Mac OS X, but using Linux is highly advised.
Prepare
Check out the Talos repository.
Try running make help
to see available make
commands.
You would need Docker and buildx
installed on the host.
Note: Usually it is better to install up to date Docker from Docker apt repositories, e.g. Ubuntu instructions.
If
buildx
plugin is not available with OS docker packages, it can be installed as a plugin from GitHub releases.
Set up a builder with access to the host network:
docker buildx create --driver docker-container --driver-opt network=host --name local1 --buildkitd-flags '--allow-insecure-entitlement security.insecure' --use
Note:
network=host
allows buildx builder to access host network, so that it can push to a local container registry (see below).
Make sure the following steps work:
make talosctl
make initramfs kernel
Set up a local docker registry:
docker run -d -p 5005:5000 \
--restart always \
--name local registry:2
Try to build and push to local registry an installer image:
make installer IMAGE_REGISTRY=127.0.0.1:5005 PUSH=true
Record the image name output in the step above.
Note: it is also possible to force a stable image tag by using
TAG
variable:make installer IMAGE_REGISTRY=127.0.0.1:5005 TAG=v1.0.0-alpha.1 PUSH=true
.
Running Talos cluster
Set up local caching docker registries (this speeds up Talos cluster boot a lot), script is in the Talos repo:
bash hack/start-registry-proxies.sh
Start your local cluster with:
sudo --preserve-env=HOME _out/talosctl-linux-amd64 cluster create \
--provisioner=qemu \
--cidr=172.20.0.0/24 \
--registry-mirror docker.io=http://172.20.0.1:5000 \
--registry-mirror registry.k8s.io=http://172.20.0.1:5001 \
--registry-mirror gcr.io=http://172.20.0.1:5003 \
--registry-mirror ghcr.io=http://172.20.0.1:5004 \
--registry-mirror 127.0.0.1:5005=http://172.20.0.1:5005 \
--install-image=127.0.0.1:5005/siderolabs/installer:<RECORDED HASH from the build step> \
--controlplanes 3 \
--workers 2 \
--with-bootloader=false
--provisioner
selects QEMU vs. default Docker- custom
--cidr
to make QEMU cluster use different network than default Docker setup (optional) --registry-mirror
uses the caching proxies set up above to speed up boot time a lot, last one adds your local registry (installer image was pushed to it)--install-image
is the image you built withmake installer
above--controlplanes
&--workers
configure cluster size, choose to match your resources; 3 controlplanes give you HA control plane; 1 controlplane is enough, never do 2 controlplanes--with-bootloader=false
disables boot from disk (Talos will always boot from_out/vmlinuz-amd64
and_out/initramfs-amd64.xz
). This speeds up development cycle a lot - no need to rebuild installer and perform install, rebooting is enough to get new code.
Note: as boot loader is not used, it’s not necessary to rebuild
installer
each time (old image is fine), but sometimes it’s needed (when configuration changes are done and old installer doesn’t validate the config).
talosctl cluster create
derives Talos machine configuration version from the install image tag, so sometimes early in the development cycle (when new minor tag is not released yet), machine config version can be overridden with--talos-version=v1.10
.
If the --with-bootloader=false
flag is not enabled, for Talos cluster to pick up new changes to the code (in initramfs
), it will require a Talos upgrade (so new installer
should be built).
With --with-bootloader=false
flag, Talos always boots from initramfs
in _out/
directory, so simple reboot is enough to pick up new code changes.
If the installation flow needs to be tested, --with-bootloader=false
shouldn’t be used.
Console Logs
Watching console logs is easy with tail
:
tail -F ~/.talos/clusters/talos-default/talos-default-*.log
Interacting with Talos
Once talosctl cluster create
finishes successfully, talosconfig
and kubeconfig
will be set up automatically to point to your cluster.
Start playing with talosctl
:
talosctl -n 172.20.0.2 version
talosctl -n 172.20.0.3,172.20.0.4 dashboard
talosctl -n 172.20.0.4 get members
Same with kubectl
:
kubectl get nodes -o wide
You can deploy some Kubernetes workloads to the cluster.
You can edit machine config on the fly with talosctl edit mc --immediate
, config patches can be applied via --config-patch
flags, also many features have specific flags in talosctl cluster create
.
Quick Reboot
To reboot whole cluster quickly (e.g. to pick up a change made in the code):
for socket in ~/.talos/clusters/talos-default/talos-default-*.monitor; do echo "q" | sudo socat - unix-connect:$socket; done
Sending q
to a single socket allows to reboot a single node.
Note: This command performs immediate reboot (as if the machine was powered down and immediately powered back up), for normal Talos reboot use
talosctl reboot
.
Development Cycle
Fast development cycle:
- bring up a cluster
- make code changes
- rebuild
initramfs
withmake initramfs
- reboot a node to pick new
initramfs
- verify code changes
- more code changes…
Some aspects of Talos development require to enable bootloader (when working on installer
itself), in that case quick development cycle is no longer possible, and cluster should be destroyed and recreated each time.
Running Integration Tests
If integration tests were changed (or when running them for the first time), first rebuild the integration test binary:
rm -f _out/integration-test-linux-amd64; make _out/integration-test-linux-amd64
Running short tests against QEMU provisioned cluster:
_out/integration-test-linux-amd64 \
-talos.provisioner=qemu \
-test.v \
-test.short \
-talos.talosctlpath=$PWD/_out/talosctl-linux-amd64
Whole test suite can be run removing -test.short
flag.
Specfic tests can be run with -test.run=TestIntegration/api.ResetSuite
.
Build Flavors
make <something> WITH_RACE=1
enables Go race detector, Talos runs slower and uses more memory, but memory races are detected.
make <something> WITH_DEBUG=1
enables Go profiling and other debug features, useful for local development.
make initramfs WITH_DEBUG_SHELL=true
adds bash and minimal utilities for debugging purposes.
Combine with --with-debug-shell
flag when creating cluster to obtain shell access.
This is uncommonly used as in this case the bash shell will run in place of machined.
Destroying Cluster
sudo --preserve-env=HOME ../talos/_out/talosctl-linux-amd64 cluster destroy --provisioner=qemu
This command stops QEMU and helper processes, tears down bridged network on the host, and cleans up
cluster state in ~/.talos/clusters
.
Note: if the host machine is rebooted, QEMU instances and helpers processes won’t be started back. In that case it’s required to clean up files in
~/.talos/clusters/<cluster-name>
directory manually.
Optional
Set up cross-build environment with:
docker run --rm --privileged multiarch/qemu-user-static --reset -p yes
Note: the static qemu binaries which come with Ubuntu 21.10 seem to be broken.
Unit tests
Unit tests can be run in buildx with make unit-tests
, on Ubuntu systems some tests using loop
devices will fail because Ubuntu uses low-index loop
devices for snaps.
Most of the unit-tests can be run standalone as well, with regular go test
, or using IDE integration:
go test -v ./internal/pkg/circular/
This provides much faster feedback loop, but some tests require either elevated privileges (running as root
) or additional binaries available only in Talos rootfs
(containerd tests).
Running tests as root can be done with -exec
flag to go test
, but this is risky, as test code has root access and can potentially make undesired changes:
go test -exec sudo -v ./internal/app/machined/pkg/controllers/network/...
Go Profiling
Build initramfs
with debug enabled: make initramfs WITH_DEBUG=1
.
Launch Talos cluster with bootloader disabled, and use go tool pprof
to capture the profile and show the output in your browser:
go tool pprof http://172.20.0.2:9982/debug/pprof/heap
The IP address 172.20.0.2
is the address of the Talos node, and port :9982
depends on the Go application to profile:
- 9981:
apid
- 9982:
machined
- 9983:
trustd
Testing Air-gapped Environments
There is a hidden talosctl debug air-gapped
command which launches two components:
- HTTP proxy capable of proxying HTTP and HTTPS requests
- HTTPS server with a self-signed certificate
The command also writes down Talos machine configuration patch to enable the HTTP proxy and add a self-signed certificate to the list of trusted certificates:
$ talosctl debug air-gapped --advertised-address 172.20.0.1
2022/08/04 16:43:14 writing config patch to air-gapped-patch.yaml
2022/08/04 16:43:14 starting HTTP proxy on :8002
2022/08/04 16:43:14 starting HTTPS server with self-signed cert on :8001
The --advertised-address
should match the bridge IP of the Talos node.
Generated machine configuration patch looks like:
machine:
files:
- content: |
-----BEGIN CERTIFICATE-----
MIIBijCCAS+gAwIBAgIBATAKBggqhkjOPQQDAjAUMRIwEAYDVQQKEwlUZXN0IE9u
bHkwHhcNMjIwODA0MTI0MzE0WhcNMjIwODA1MTI0MzE0WjAUMRIwEAYDVQQKEwlU
ZXN0IE9ubHkwWTATBgcqhkjOPQIBBggqhkjOPQMBBwNCAAQfOJdaOFSOI1I+EeP1
RlMpsDZJaXjFdoo5zYM5VYs3UkLyTAXAmdTi7JodydgLhty0pwLEWG4NUQAEvip6
EmzTo3IwcDAOBgNVHQ8BAf8EBAMCBaAwHQYDVR0lBBYwFAYIKwYBBQUHAwEGCCsG
AQUFBwMCMA8GA1UdEwEB/wQFMAMBAf8wHQYDVR0OBBYEFCwxL+BjG0pDwaH8QgKW
Ex0J2mVXMA8GA1UdEQQIMAaHBKwUAAEwCgYIKoZIzj0EAwIDSQAwRgIhAJoW0z0D
JwpjFcgCmj4zT1SbBFhRBUX64PHJpAE8J+LgAiEAvfozZG8Or6hL21+Xuf1x9oh4
/4Hx3jozbSjgDyHOLk4=
-----END CERTIFICATE-----
permissions: 0o644
path: /etc/ssl/certs/ca-certificates
op: append
env:
http_proxy: http://172.20.0.1:8002
https_proxy: http://172.20.0.1:8002
no_proxy: 172.20.0.1/24
cluster:
extraManifests:
- https://172.20.0.1:8001/debug.yaml
The first section appends a self-signed certificate of the HTTPS server to the list of trusted certificates, followed by the HTTP proxy setup (in-cluster traffic is excluded from the proxy). The last section adds an extra Kubernetes manifest hosted on the HTTPS server.
The machine configuration patch can now be used to launch a test Talos cluster:
talosctl cluster create ... --config-patch @air-gapped-patch.yaml
The following lines should appear in the output of the talosctl debug air-gapped
command:
CONNECT discovery.talos.dev:443
: the HTTP proxy is used to talk to the discovery servicehttp: TLS handshake error from 172.20.0.2:53512: remote error: tls: bad certificate
: an expected error on Talos side, as self-signed cert is not written yet to the fileGET /debug.yaml
: Talos successfully fetches the extra manifest successfully
There might be more output depending on the registry caches being used or not.
Running Upgrade Integration Tests
Talos has a separate set of provision upgrade tests, which create a cluster on older versions of Talos, perform an upgrade, and verify that the cluster is still functional.
Build the test binary:
rm -f _out/integration-test-provision-linux-amd64; make _out/integration-test-provision-linux-amd64
Prepare the test artifacts for the upgrade test:
make release-artifacts
Build and push an installer image for the development version of Talos:
make installer IMAGE_REGISTRY=127.0.0.1:5005 PUSH=true
Run the tests (the tests will create the cluster on the older version of Talos, perform an upgrade, and verify that the cluster is still functional):
sudo --preserve-env=HOME _out/integration-test-provision-linux-amd64 \
-test.v \
-talos.talosctlpath _out/talosctl-linux-amd64 \
-talos.provision.target-installer-registry=127.0.0.1:5005 \
-talos.provision.registry-mirror 127.0.0.1:5005=http://172.20.0.1:5005,docker.io=http://172.20.0.1:5000,registry.k8s.io=http://172.20.0.1:5001,quay.io=http://172.20.0.1:5002,gcr.io=http://172.20.0.1:5003,ghcr.io=http://172.20.0.1:5004 \
-talos.provision.cidr 172.20.0.0/24