A highly optimized, easy-to-use, auto-upgradable, HA-default & Load-Balanced, Kubernetes cluster powered by k3s-on-MicroOS and deployed for peanuts on Hetzner Cloud 🤑 🚀
Hetzner Cloud is a good cloud provider that offers very affordable prices for cloud instances, with data center locations in both Europe and the US.
This project aims to create a highly optimized Kubernetes installation that is easy to maintain, secure, and automatically upgrades both the nodes and Kubernetes. We aimed for functionality as close as possible to GKE's Auto-Pilot. Please note that we are not affiliates of Hetzner, but we do strive to be an optimal solution for deploying and maintaining Kubernetes clusters on Hetzner Cloud.
To achieve this, we built up on the shoulders of giants by choosing openSUSE MicroOS as the base operating system and k3s as the k8s engine.
Why OpenSUSE MicroOS (and not Ubuntu)?
- Optimized container OS that is fully locked down, most of the filesystem is read-only!
- Hardened by default with an automatic ban for abusive IPs on SSH for instance.
- Evergreen release, your node will stay valid forever, as it piggy-backs into OpenSUSE Tumbleweed's rolling release!
- Automatic updates by default and automatic roll-backs if something breaks, thanks to its use of BTRFS snapshots.
- Supports Kured to properly drain and reboot nodes in an HA fashion.
Why k3s?
- Certified Kubernetes Distribution, it is automatically synced to k8s source.
- Fast deployment, as it is a single binary and can be deployed with a single command.
- Comes with batteries included, with its in-cluster helm-controller.
- Easy automatic updates, via the system-upgrade-controller.
- Maintenance-free with auto-upgrades to the latest version of MicroOS and k3s.
- Multi-architecture support, choose any Hetzner cloud instances, including the cheaper CAX ARM instances.
- Proper use of the Hetzner private network to minimize latency.
- Choose between Flannel, Calico, or Cilium as CNI.
- Optional Wireguard encryption of the Kube network for added security.
- Traefik or Nginx as ingress controller attached to a Hetzner load balancer with Proxy Protocol turned on.
- Automatic HA with the default setting of three control-plane nodes and two agent nodes.
- Autoscaling nodes via the kubernetes autoscaler.
- Super-HA with Nodepools for both control-plane and agent nodes that can be in different locations.
- Possibility to have a single node cluster with a proper ingress controller.
- Can use Klipper as an on-metal LB or the Hetzner LB.
- Ability to add nodes and nodepools when the cluster is running.
- Possibility to toggle Longhorn and Hetzner CSI.
- Encryption at rest fully functional in both Longhorn and Hetzner CSI.
- Optional use of Floating IPs for use via Cilium's Egress Gateway.
- Proper IPv6 support for inbound/outbound traffic.
- Flexible configuration options via variables and an extra Kustomization option.
It uses Terraform to deploy as it's easy to use, and Hetzner has a great Hetzner Terraform Provider.
Follow those simple steps, and your world's cheapest Kubernetes cluster will be up and running.
First and foremost, you need to have a Hetzner Cloud account. You can sign up for free here.
Then you'll need to have terraform, packer (for the initial snapshot creation only, no longer needed once that's done), kubectl cli and hcloud the Hetzner cli for convenience. The easiest way is to use the homebrew package manager to install them (available on Linux, Mac, and Windows Linux Subsystem).
brew install terraform
brew install packer
brew install kubectl
brew install hcloud
-
Create a project in your Hetzner Cloud Console, and go to Security > API Tokens of that project to grab the API key, it needs to be Read & Write. Take note of the key! ✅
-
Generate a passphrase-less ed25519 SSH key pair for your cluster; take note of the respective paths of your private and public keys. Or, see our detailed SSH options. ✅
-
Now navigate to where you want to have your project live and execute the following command, which will help you get started with a a new folder along with the required files, and will propose you to create a needed MicroOS snapshot. ✅
tmp_script=$(mktemp) && curl -sSL -o "${tmp_script}" https://raw.githubusercontent.com/kube-hetzner/terraform-hcloud-kube-hetzner/master/scripts/create.sh && chmod +x "${tmp_script}" && "${tmp_script}" && rm "${tmp_script}"
Or for fish shell:
set tmp_script (mktemp); curl -sSL -o "{tmp_script}" https://raw.githubusercontent.com/kube-hetzner/terraform-hcloud-kube-hetzner/master/scripts/create.sh; chmod +x "{tmp_script}"; bash "{tmp_script}"; rm "{tmp_script}"
Optionally, for future usage, save that command as an alias in your shell preferences, like so:
alias createkh='tmp_script=$(mktemp) && curl -sSL -o "${tmp_script}" https://raw.githubusercontent.com/kube-hetzner/terraform-hcloud-kube-hetzner/master/scripts/create.sh && chmod +x "${tmp_script}" && "${tmp_script}" && rm "${tmp_script}"'
Or for fish shell:
alias createkh='set tmp_script (mktemp); curl -sSL -o "{tmp_script}" https://raw.githubusercontent.com/kube-hetzner/terraform-hcloud-kube-hetzner/master/scripts/create.sh; chmod +x "{tmp_script}"; bash "{tmp_script}"; rm "{tmp_script}"'
For the curious, here is what the script does:
mkdir /path/to/your/new/folder cd /path/to/your/new/folder curl -sL https://raw.githubusercontent.com/kube-hetzner/terraform-hcloud-kube-hetzner/master/kube.tf.example -o kube.tf curl -sL https://raw.githubusercontent.com/kube-hetzner/terraform-hcloud-kube-hetzner/master/packer-template/hcloud-microos-snapshots.pkr.hcl -o hcloud-microos-snapshots.pkr.hcl export HCLOUD_TOKEN="your_hcloud_token" packer build hcloud-microos-snapshots.pkr.hcl hcloud context create <project-name>
-
In that new project folder that gets created, you will find your
kube.tf
and it must be customized to suit your needs. ✅A complete reference of all inputs, outputs, modules etc. can be found in the terraform.md file.
Now that you have your kube.tf
file, along with the OS snapshot in Hetzner project, you can start the installation process:
cd <your-project-folder>
terraform init --upgrade
terraform validate
terraform apply -auto-approve
It will take around 5 minutes to complete, and then you should see a green output confirming a successful deployment.
Once you start with Terraform, it's best not to change the state of the project manually via the Hetzner UI; otherwise, you may get an error when you try to run terraform again for that cluster (when trying to change the number of nodes for instance). If you want to inspect your Hetzner project, learn to use the hcloud cli.
When your brand-new cluster is up and running, the sky is your limit! 🎉
You can immediately kubectl into it (using the clustername_kubeconfig.yaml
saved to the project's directory after the installation). By doing kubectl --kubeconfig clustername_kubeconfig.yaml
, but for more convenience, either create a symlink from ~/.kube/config
to clustername_kubeconfig.yaml
or add an export statement to your ~/.bashrc
or ~/.zshrc
file, as follows (you can get the path of clustername_kubeconfig.yaml
by running pwd
):
export KUBECONFIG=/<path-to>/clustername_kubeconfig.yaml
If chose to turn create_kubeconfig
to false in your kube.tf (good practice), you can still create this file by running terraform output --raw kubeconfig > clustername_kubeconfig.yaml
and then use it as described above.
You can also use it in an automated flow, in which case create_kubeconfig
should be set to false, and you can use the kubeconfig
output variable to get the kubeconfig file in a structured data format.
You can view all kinds of details about the cluster by running terraform output kubeconfig
or terraform output -json kubeconfig | jq
.
The default is Flannel, but you can also choose Calico or Cilium, by setting the cni_plugin
variable in kube.tf
to "calico" or "cilium".
As Cilium has a lot of interesting and powerful config possibilities, we give you the ability to configure Cilium with the helm cilium_values
variable (see the cilium specific helm values) before you deploy your cluster.
Two things can be scaled: the number of nodepools or the number of nodes in these nodepools.
There are some limitations (to scaling down mainly) that you need to be aware of:
Once the cluster is up; you can change any nodepool count and even set it to 0 (in the case of the first control-plane nodepool, the minimum is 1); you can also rename a nodepool (if the count is to 0), but should not remove a nodepool from the list after once the cluster is up. That is due to how subnets and IPs get allocated. The only nodepools you can remove are those at the end of each list of nodepools.
However, you can freely add other nodepools at the end of each list. And for each nodepools, you can freely increase or decrease the node count (if you want to decrease a nodepool node count make sure you drain the nodes in question before, you can use terraform show
to identify the node names at the end of the nodepool list, otherwise, if you do not drain the nodes before removing them, it could leave your cluster in a bad state). The only nodepool that needs to have always at least a count of 1 is the first control-plane nodepool.
We support autoscaling node pools powered by the Kubernetes Cluster Autoscaler.
By adding at least one map to the array of autoscaler_nodepools
the feature will be enabled. More on this in the corresponding section of kube.tf.example.
Important to know, the nodes are booted based on a snapshot that is created from the initial control_plane. So please ensure that the disk of your chosen server type is at least the same size (or bigger) as the one of the first control_plane.
By default, we have three control planes and three agents configured, with automatic upgrades and reboots of the nodes.
If you want to remain HA (no downtime), it's essential to keep a count of control planes nodes of at least three (two minimum to maintain quorum when one goes down for automated upgrades and reboot), see Rancher's doc on HA.
Otherwise, it is essential to turn off automatic OS upgrades (k3s can continue to update without issue) for the control-plane nodes (when two or fewer control-plane nodes) and do the maintenance yourself.
By default, MicroOS gets upgraded automatically on each node and reboot safely via Kured installed in the cluster.
As for k3s, it also automatically upgrades thanks to Rancher's system upgrade controller. By default, it will be set to the initial_k3s_channel
, but you can also set it to stable
, latest
, or one more specific like v1.23
if needed or specify a target version to upgrade to via the upgrade plan (this also allows for downgrades).
You can copy and modify the one in the templates for that! More on the subject in k3s upgrades.
Per default, a node that installed updates will reboot within the next few minutes and updates are installed roughly every 24 hours. Kured can be instructed with specific timeframes for rebooting, to prevent too frequent drains and reboots. All options from the docs are available for modification.
registries.yaml
, ...), so keep in mind that configuration changes can take some time to propagate!
If you wish to turn off automatic MicroOS upgrades (Important if you are not launching an HA setup that requires at least 3 control-plane nodes), you need to set:
automatically_upgrade_os = false
Alternatively ssh into each node and issue the following command:
systemctl --now disable transactional-update.timer
If you wish to turn off automatic k3s upgrades, you need to set:
automatically_upgrade_k3s = false
Alternatively, you can either remove the k3s_upgrade=true
label or set it to false
. This needs to happen for all the nodes too! To remove it, apply:
kubectl -n system-upgrade label node <node-name> k3s_upgrade-
Alternatively, you can disable the k3s automatic upgrade without individually editing the labels on the nodes. Instead, you can just delete the two system controller upgrade plans with:
kubectl delete plan k3s-agent -n system-upgrade
kubectl delete plan k3s-server -n system-upgrade
Also, note that after turning off node upgrades, you will need to manually upgrade the nodes when needed. You can do so by SSH'ing into each node and running the following commands (and don't forget to drain the node before with kubectl drain <node-name>
):
transactional-update
reboot
Rarely needed, but can be handy in the long run. During the installation, we automatically download a backup of the kustomization to a kustomization_backup.yaml
file. You will find it next to your clustername_kubeconfig.yaml
at the root of your project.
- First create a duplicate of that file and name it
kustomization.yaml
, keeping the original file intact, in case you need to restore the old config. - Edit the
kustomization.yaml
file; you want to go to the very bottom where you have the links to the different source files; grab the latest versions for each on GitHub, and replace. If present, remove any local reference to traefik_config.yaml, as Traefik is updated automatically by the system upgrade controller. - Apply the updated
kustomization.yaml
withkubectl apply -k ./
.
Most cluster components of Kube-Hetzner are deployed with the Rancher Helm Chart yaml definition and managed by the Helm Controller inside k3s.
By default, we strive to give you optimal defaults, but if wish, you can customize them.
For Traefik, Nginx, Rancher, Cilium, Traefik, and Longhorn, for maximum flexibility, we give you the ability to configure them even better via helm values variables (e.g. cilium_values
, see the advanced section in the kube.tf.example for more).
If you need to install additional Helm charts or Kubernetes manifests that are not provided by default, you can easily do so by using Kustomize. This is done by creating the extra-manifests/kustomization.yaml.tpl
directory/file beside your kube.tf
.
This file needs to be a valid Kustomization
manifest, but it supports terraform templating! (The templating parameters can be passed via the extra_kustomize_parameters
variable (via a map) to the module).
All files in the extra-manifests
directory including the rendered version of kustomization.yaml.tpl
will be applied to k3s with kubectl apply -k
(which will be executed after and independently of the basic cluster configuration).
You can use the above to pass all kinds of Kubernetes YAML configs, including HelmChart and/or HelmChartConfig definitions (see the previous section if you do not know what those are in the context of k3s).
That said, you can also use pure Terraform and import the kube-hetzner module as part of a larger project, and then use things like the Terraform helm provider to add additional stuff, all up to you!
Useful Cilium commands
With Kube-Hetzner, you have the possibility to use Cilium as a CNI. It's very powerful and has great observability features. Below you will find a few useful commands.
- Check the status of cilium with the following commands (get the cilium pod name first and replace it in the command):
kubectl -n kube-system exec --stdin --tty cilium-xxxx -- cilium status
kubectl -n kube-system exec --stdin --tty cilium-xxxx -- cilium status --verbose
- Monitor cluster traffic with:
kubectl -n kube-system exec --stdin --tty cilium-xxxx -- cilium monitor
- See the list of kube services with:
kubectl -n kube-system exec --stdin --tty cilium-xxxx -- cilium service list
For more cilium commands, please refer to their corresponding Documentation.
Cilium Egress Gateway (via Floating IPs)
Cilium Egress Gateway provides the ability to control outgoing traffic from POD.
Using Floating IPs makes it possible to get rid of the problem of changing the primary IPs when recreating a node in the cluster.
To implement the Cilium Egress Gateway feature, you need to define a separate nodepool with the setting floating_ip = true
in the nodepool configuration parameter block.
Example nodepool configuration:
{
name = "egress",
server_type = "cpx11",
location = "fsn1",
labels = [
"node.kubernetes.io/role=egress"
],
taints = [
"node.kubernetes.io/role=egress:NoSchedule"
],
floating_ip = true
count = 1
},
Configure Cilium:
locals {
cluster_ipv4_cidr = "10.42.0.0/16"
}
cluster_ipv4_cidr = local.cluster_ipv4_cidr
cilium_values = <<EOT
ipam:
operator:
clusterPoolIPv4PodCIDRList:
- ${local.cluster_ipv4_cidr}
kubeProxyReplacement: strict
l7Proxy: "false"
bpf:
masquerade: "true"
egressGateway:
enabled: "true"
EOT
Deploy the K8S cluster infrastructure.
See the Cilium documentation for further steps (policy writing and testing): Writing egress gateway policies
CiliumEgressGatewayPolicy example:
apiVersion: cilium.io/v2
kind: CiliumEgressGatewayPolicy
metadata:
name: egress-sample
spec:
selectors:
- podSelector:
matchLabels:
org: empire
class: mediabot
io.kubernetes.pod.namespace: default
destinationCIDRs:
- "0.0.0.0/0"
egressGateway:
nodeSelector:
matchLabels:
node.kubernetes.io/role: egress
# Specify the IP address used to SNAT traffic matched by the policy.
# It must exist as an IP associated with a network interface on the instance.
egressIP: {FLOATING_IP}
Ingress with TLS
We advise you to use Cert-Manager
, as it supports HA setups without requiring you to use the enterprise version of Traefik. The reason for that is that according to Traefik themselves, Traefik CE (community edition) is stateless, and it's not possible to run multiple instances of Traefik CE with LetsEncrypt enabled. Meaning, you cannot have your ingress be HA with Traefik if you use the community edition and have activated the LetsEncrypt resolver. You could however use Traefik EE (enterprise edition) to achieve that. Long story short, if you are going to use Traefik CE (like most of us), you should use Cert-Manager to generate the certificates. Source here.
Create your issuers as described here https://cert-manager.io/docs/configuration/acme/.
Then in your Ingress definition, just mentioning the issuer as an annotation and giving a secret name will take care of instructing Cert-Manager to generate a certificate for it! You just have to configure your issuer(s) first with the method of your choice.
Ingress example:
apiVersion: networking.k8s.io/v1
kind: Ingress
metadata:
name: my-ingress
annotations:
cert-manager.io/cluster-issuer: letsencrypt
spec:
tls:
- hosts:
- '*.example.com'
secretName: example-com-letsencrypt-tls
rules:
- host: '*.example.com'
http:
paths:
- path: /
pathType: Prefix
backend:
service:
name: my-service
port:
number: 80
lb_hostname = "cluster.example.org"
to your kube.tf. You must set it to an FQDN that points to your LB address.
This is to circumvent this known issue cert-manager/cert-manager/issues/466. Otherwise, you can just use the DNS challenge, which does not require any additional tweaks to work.
Create or delete a snapshot
Apart from the installation script, you can always create or delete the OS snapshot manually.
To create a snapshot, run the following command:
export HCLOUD_TOKEN=<your-token>
packer build ./packer-template/hcloud-microos-snapshots.pkr.hcl
To delete a snapshot, first find it with:
hcloud image list
Then delete it with:
hcloud image delete <image-id>
Single-node cluster
Running a development cluster on a single node without any high availability is also possible.
When doing so, automatically_upgrade_os
should be set to false
, especially with attached volumes the automatic reboots won't work properly. In this case, we don't deploy an external load-balancer but use the default k3s service load balancer on the host itself and open up port 80 & 443 in the firewall (done automatically).
Use in Terraform cloud
To use Kube-Hetzner on Terraform cloud, use as a Terraform module as mentioned above, but also change the execution mode from remote
to local
.
Also make sure you have the OS snapshot already created in your project, for that, follow the installation script.
Configure add-ons with HelmChartConfig
For instance, to customize the Rancher install, if you choose to enable it, you can create and apply the following HelmChartConfig
:
apiVersion: helm.cattle.io/v1
kind: HelmChartConfig
metadata:
name: rancher
namespace: kube-system
spec:
valuesContent: |-
**values.yaml content you want to customize**
The helm options for Rancher can be seen here https://github.com/rancher/rancher/blob/release/v2.6/chart/values.yaml.
The same goes for all add-ons, like Longhorn, Cert-manager, and Traefik.
Encryption at rest with HCloud CSI
The easiest way to get encrypted volumes working is actually to use the new encryption functionality of hcloud csi itself, see hetznercloud/csi-driver.
For this, you just need to create a secret containing the encryption key:
apiVersion: v1
kind: Secret
metadata:
name: encryption-secret
namespace: kube-system
stringData:
encryption-passphrase: foobar
And to create a new storage class:
apiVersion: storage.k8s.io/v1
kind: StorageClass
metadata:
name: hcloud-volumes-encrypted
provisioner: csi.hetzner.cloud
reclaimPolicy: Delete
volumeBindingMode: WaitForFirstConsumer
allowVolumeExpansion: true
parameters:
csi.storage.k8s.io/node-publish-secret-name: encryption-secret
csi.storage.k8s.io/node-publish-secret-namespace: kube-system
Encryption at rest with Longhorn
To get started, use a cluster-wide key for all volumes like this:apiVersion: v1
kind: Secret
metadata:
name: longhorn-crypto
namespace: longhorn-system
stringData:
CRYPTO_KEY_VALUE: "I have nothing to hide."
CRYPTO_KEY_PROVIDER: "secret"
CRYPTO_KEY_CIPHER: "aes-xts-plain64"
CRYPTO_KEY_HASH: "sha256"
CRYPTO_KEY_SIZE: "256"
CRYPTO_PBKDF: "argon2i"
And create a new storage class:
kind: StorageClass
apiVersion: storage.k8s.io/v1
metadata:
name: longhorn-crypto-global
provisioner: driver.longhorn.io
allowVolumeExpansion: true
parameters:
nodeSelector: "node-storage"
numberOfReplicas: "1"
staleReplicaTimeout: "2880" # 48 hours in minutes
fromBackup: ""
fsType: ext4
encrypted: "true"
# global secret that contains the encryption key that will be used for all volumes
csi.storage.k8s.io/provisioner-secret-name: "longhorn-crypto"
csi.storage.k8s.io/provisioner-secret-namespace: "longhorn-system"
csi.storage.k8s.io/node-publish-secret-name: "longhorn-crypto"
csi.storage.k8s.io/node-publish-secret-namespace: "longhorn-system"
csi.storage.k8s.io/node-stage-secret-name: "longhorn-crypto"
csi.storage.k8s.io/node-stage-secret-namespace: "longhorn-system"
For more details, see Longhorn's documentation.
Assign all pods in a namespace to either arm64 or amd64 nodes with admission controllers
To enable the PodNodeSelector and optionally the PodTolerationRestriction api modules, set the following value:
k3s_exec_server_args = "--kube-apiserver-arg enable-admission-plugins=PodTolerationRestriction,PodNodeSelector"
Next, you can set default nodeSelector values per namespace. This lets you assign namespaces to specific nodes. Note though, that this is the default as well as the whitelist, so if a pod sets its own nodeSelector value that must be a subset of the default. Otherwise the pod will not be scheduled.
Then set the according annotations on your namespaces:
apiVersion: v1
kind: Namespace
metadata:
annotations:
scheduler.alpha.kubernetes.io/node-selector: kubernetes.io/arch=amd64
name: this-runs-on-amd64
or with taints and tolerations:
apiVersion: v1
kind: Namespace
metadata:
annotations:
scheduler.alpha.kubernetes.io/node-selector: kubernetes.io/arch=arm64
scheduler.alpha.kubernetes.io/defaultTolerations: "[{ \"operator\" : \"Equal\", \"effect\" : \"NoSchedule\", \"key\" : \"workload-type\", \"value\" : \"machine-learning\" }]"
name: this-runs-on-arm64
This can be helpful when you setup a mixed-architecture cluster, and there are many other use cases.
First and foremost, it depends, but it's always good to have a quick look into Hetzner quickly without logging in to the UI. That is where the hcloud
cli comes in.
- Activate it with
hcloud context create Kube-hetzner
; it will prompt for your Hetzner API token, paste that, and hitenter
. - To check the nodes, if they are running, use
hcloud server list
. - To check the network, use
hcloud network describe k3s
. - To look at the LB, use
hcloud loadbalancer describe traefik
.
Then for the rest, you'll often need to log in to your cluster via ssh, to do that, use:
ssh root@xxx.xxx.xxx.xxx -i ~/.ssh/id_ed25519 -o StrictHostKeyChecking=no
Then, for control-plane nodes, use journalctl -u k3s
to see the k3s logs, and for agents, use journalctl -u k3s-agent
instead.
Inspect the value of the k3s config.yaml file with: cat /etc/rancher/k3s/config.yaml
, see if it looks kosher.
Last but not least, to see when the previous reboot took place, you can use both last reboot
and uptime
.
If you want to take down the cluster, you can proceed as follows:
terraform destroy -auto-approve
If you see the destroy hanging, it's probably because of the Hetzner LB and the autoscaled nodes. You can use the following command to delete everything (dry run option is available don't worry, and it will only delete ressources specific to your cluster):
tmp_script=$(mktemp) && curl -sSL -o "${tmp_script}" https://raw.githubusercontent.com/kube-hetzner/terraform-hcloud-kube-hetzner/master/scripts/cleanup.sh && chmod +x "${tmp_script}" && "${tmp_script}" && rm "${tmp_script}"
As a one time thing, for convenience, you can also save it as an alias in your shell config file, like so:
alias cleanupkh='tmp_script=$(mktemp) && curl -sSL -o "${tmp_script}" https://raw.githubusercontent.com/kube-hetzner/terraform-hcloud-kube-hetzner/master/scripts/cleanup.sh && chmod +x "${tmp_script}" && "${tmp_script}" && rm "${tmp_script}"'
Careful, the above commands will delete everything, including volumes in your projects. You can always try with a dry run, it will give you that option.
Usually, you will want to upgrade the module in your project to the latest version. Just change the version attribute in your kube.tf and terraform apply. This will upgrade the module to the latest version.
When moving from 1.x to 2.x:
- Within your project folder, run the
createkh
installation command, see Do Not Skip section above. This will create the snapshot for you. Don't worry, it's non-destructive and will leave your kube.tf and terraform state alone, but will download the required other packer file. - Then modify your kube.tf to use version >= 2.0, and remove
extra_packages_to_install
andopensuse_microos_mirror_link
variables if used. This functionality has been moved to the packer snapshot definition, see packer-template/hcloud-microos-snapshots.pkr.hlc. - Then run
terraform init -upgrade && terraform apply
.
This project has tried two other OS flavors before settling on MicroOS. Fedora Server, and k3OS. The latter, k3OS, is now defunct! However, our code base for it lives on in the k3os branch. Do not hesitate to check it out, it should still work.
There is also a branch where openSUSE MicroOS came preinstalled with the k3s RPM from devel:kubic/k3s, but we moved away from that solution as the k3s version was rarely getting updates. See the microOS-k3s-rpm branch for more.
🌱 This project currently installs openSUSE MicroOS via the Hetzner rescue mode, making things a few minutes slower. To help with that, you could take a few minutes to send a support request to Hetzner, asking them to please add openSUSE MicroOS as a default image, not just an ISO. The more requests they receive, the likelier they are to add support for it, and if they do, that will cut the deployment time by half. The official link to openSUSE MicroOS is https://get.opensuse.org/microos, and their OpenStack Cloud
image has full support for Cloud-init, which would probably very much suit the Hetzner Ops team!
Code contributions are very much welcome.
-
Fork the Project
-
Create your Branch (
git checkout -b AmazingFeature
) -
Develop your feature
In your kube.tf, point the
source
of module to your local clone of the repo.Useful commands:
# To cleanup a Hetzner project ../kube-hetzner/scripts/cleanup.sh # To build the Packer image packer build ../kube-hetzner/packer-template/hcloud-microos-snapshots.pkr.hcl
-
Commit your Changes (`git commit -m 'Add some AmazingFeature')
-
Push to the Branch (
git push origin AmazingFeature
) -
Open a Pull Request targeting the
staging
branch.
- k-andy was the starting point for this project. It wouldn't have been possible without it.
- Best-README-Template made writing this readme a lot easier.
- Hetzner Cloud for providing a solid infrastructure and terraform package.
- Hashicorp for the amazing terraform framework that makes all the magic happen.
- Rancher for k3s, an amazing Kube distribution that is the core engine of this project.
- openSUSE for MicroOS, which is just next-level Container OS technology.