# f3s: Kubernetes with FreeBSD - Part 7: k3s and first pod deployments > Published at 2025-10-02T11:27:19+03:00 This is the seventh blog post about the f3s series for my self-hosting demands in a home lab. f3s? The "f" stands for FreeBSD, and the "3s" stands for k3s, the Kubernetes distribution I use on FreeBSD-based physical machines. << template::inline::index f3s-kubernetes-with-freebsd-part => ./f3s-kubernetes-with-freebsd-part-1/f3slogo.png f3s logo << template::inline::toc ## Introduction In this blog post, I am finally going to install k3s (the Kubernetes distribution I use) to the whole setup and deploy the first workloads (helm charts, and a private registry) to it. => https://k3s.io ## Updating Before proceeding, I bring all systems involved up-to-date. On all three Rocky Linux 9 boxes `r0`, `r1`, and `r2`: ```sh dnf update -y reboot ``` On the FreeBSD hosts, I upgraded from FreeBSD 14.2 to 14.3-RELEASE, running this on all three hosts `f0`, `f1` and `f2`: ```sh paul@f0:~ % doas freebsd-update fetch paul@f0:~ % doas freebsd-update install paul@f0:~ % doas reboot . . . paul@f0:~ % doas freebsd-update -r 14.3-RELEASE upgrade paul@f0:~ % doas freebsd-update install paul@f0:~ % doas freebsd-update install paul@f0:~ % doas reboot . . . paul@f0:~ % doas freebsd-update install paul@f0:~ % doas pkg update paul@f0:~ % doas pkg upgrade paul@f0:~ % doas reboot . . . paul@f0:~ % uname -a FreeBSD f0.lan.buetow.org 14.3-RELEASE FreeBSD 14.3-RELEASE releng/14.3-n271432-8c9ce319fef7 GENERIC amd64 ``` ## Installing k3s ### Generating `K3S_TOKEN` and starting the first k3s node I generated the k3s token on my Fedora laptop with `pwgen -n 32` and selected one of the results. Then, on all three `r` hosts, I ran the following (replace SECRET_TOKEN with the actual secret): ```sh [root@r0 ~]# echo -n SECRET_TOKEN > ~/.k3s_token ``` The following steps are also documented on the k3s website: => https://docs.k3s.io/datastore/ha-embedded To bootstrap k3s on the first node, I ran this on `r0`: ```sh [root@r0 ~]# curl -sfL https://get.k3s.io | K3S_TOKEN=$(cat ~/.k3s_token) \ sh -s - server --cluster-init --tls-san=r0.wg0.wan.buetow.org [INFO] Finding release for channel stable [INFO] Using v1.32.6+k3s1 as release . . . [INFO] systemd: Starting k3s ``` ### Adding the remaining nodes to the cluster Then I ran on the other two nodes `r1` and `r2`: ```sh [root@r1 ~]# curl -sfL https://get.k3s.io | K3S_TOKEN=$(cat ~/.k3s_token) \ sh -s - server --server https://r0.wg0.wan.buetow.org:6443 \ --tls-san=r1.wg0.wan.buetow.org [root@r2 ~]# curl -sfL https://get.k3s.io | K3S_TOKEN=$(cat ~/.k3s_token) \ sh -s - server --server https://r0.wg0.wan.buetow.org:6443 \ --tls-san=r2.wg0.wan.buetow.org . . . ``` Once done, I had a three-node Kubernetes cluster control plane: ```sh [root@r0 ~]# kubectl get nodes NAME STATUS ROLES AGE VERSION r0.lan.buetow.org Ready control-plane,etcd,master 4m44s v1.32.6+k3s1 r1.lan.buetow.org Ready control-plane,etcd,master 3m13s v1.32.6+k3s1 r2.lan.buetow.org Ready control-plane,etcd,master 30s v1.32.6+k3s1 [root@r0 ~]# kubectl get pods --all-namespaces NAMESPACE NAME READY STATUS RESTARTS AGE kube-system coredns-5688667fd4-fs2jj 1/1 Running 0 5m27s kube-system helm-install-traefik-crd-f9hgd 0/1 Completed 0 5m27s kube-system helm-install-traefik-zqqqk 0/1 Completed 2 5m27s kube-system local-path-provisioner-774c6665dc-jqlnc 1/1 Running 0 5m27s kube-system metrics-server-6f4c6675d5-5xpmp 1/1 Running 0 5m27s kube-system svclb-traefik-411cec5b-cdp2l 2/2 Running 0 78s kube-system svclb-traefik-411cec5b-f625r 2/2 Running 0 4m58s kube-system svclb-traefik-411cec5b-twrd7 2/2 Running 0 4m2s kube-system traefik-c98fdf6fb-lt6fx 1/1 Running 0 4m58s ``` In order to connect with `kubectl` from my Fedora laptop, I had to copy `/etc/rancher/k3s/k3s.yaml` from `r0` to `~/.kube/config` and then replace the value of the server field with `r0.lan.buetow.org`. kubectl can now manage the cluster. Note that this step has to be repeated when I want to connect to another node of the cluster (e.g. when `r0` is down). ## Test deployments ### Test deployment to Kubernetes Let's create a test namespace: ```sh > ~ kubectl create namespace test namespace/test created > ~ kubectl get namespaces NAME STATUS AGE default Active 6h11m kube-node-lease Active 6h11m kube-public Active 6h11m kube-system Active 6h11m test Active 5s > ~ kubectl config set-context --current --namespace=test Context "default" modified. ``` And let's also create an Apache test pod: ```sh > ~ cat < apache-deployment.yaml # Apache HTTP Server Deployment apiVersion: apps/v1 kind: Deployment metadata: name: apache-deployment spec: replicas: 1 selector: matchLabels: app: apache template: metadata: labels: app: apache spec: containers: - name: apache image: httpd:latest ports: # Container port where Apache listens - containerPort: 80 END > ~ kubectl apply -f apache-deployment.yaml deployment.apps/apache-deployment created > ~ kubectl get all NAME READY STATUS RESTARTS AGE pod/apache-deployment-5fd955856f-4pjmf 1/1 Running 0 7s NAME READY UP-TO-DATE AVAILABLE AGE deployment.apps/apache-deployment 1/1 1 1 7s NAME DESIRED CURRENT READY AGE replicaset.apps/apache-deployment-5fd955856f 1 1 1 7s ``` Let's also create a service: ```sh > ~ cat < apache-service.yaml apiVersion: v1 kind: Service metadata: labels: app: apache name: apache-service spec: ports: - name: web port: 80 protocol: TCP # Expose port 80 on the service targetPort: 80 selector: # Link this service to pods with the label app=apache app: apache END > ~ kubectl apply -f apache-service.yaml service/apache-service created > ~ kubectl get service NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE apache-service ClusterIP 10.43.249.165 80/TCP 4s ``` Now let's create an ingress: > Note: I've modified the hosts listed in this example after I published this blog post to ensure that there aren't any bots scraping it. ```sh > ~ cat < apache-ingress.yaml apiVersion: networking.k8s.io/v1 kind: Ingress metadata: name: apache-ingress namespace: test annotations: spec.ingressClassName: traefik traefik.ingress.kubernetes.io/router.entrypoints: web spec: rules: - host: f3s.foo.zone http: paths: - path: / pathType: Prefix backend: service: name: apache-service port: number: 80 - host: standby.f3s.foo.zone http: paths: - path: / pathType: Prefix backend: service: name: apache-service port: number: 80 - host: www.f3s.foo.zone http: paths: - path: / pathType: Prefix backend: service: name: apache-service port: number: 80 END > ~ kubectl apply -f apache-ingress.yaml ingress.networking.k8s.io/apache-ingress created > ~ kubectl describe ingress Name: apache-ingress Labels: Namespace: test Address: 192.168.1.120,192.168.1.121,192.168.1.122 Ingress Class: traefik Default backend: Rules: Host Path Backends ---- ---- -------- f3s.foo.zone / apache-service:80 (10.42.1.11:80) standby.f3s.foo.zone / apache-service:80 (10.42.1.11:80) www.f3s.foo.zone / apache-service:80 (10.42.1.11:80) Annotations: spec.ingressClassName: traefik traefik.ingress.kubernetes.io/router.entrypoints: web Events: ``` Notes: * In the ingress, I use plain HTTP (web) for the Traefik rule, as all the "production" traffic will be routed through a WireGuard tunnel anyway, as I will show later. So I tested the Apache web server through the ingress rule: ```sh > ~ curl -H "Host: www.f3s.foo.zone" http://r0.lan.buetow.org:80

It works!

``` ### Test deployment with persistent volume claim Next, I modified the Apache example to serve the `htdocs` directory from the NFS share I created in the previous blog post. I used the following manifests. Most of them are the same as before, except for the persistent volume claim and the volume mount in the Apache deployment. ```sh > ~ cat < apache-deployment.yaml # Apache HTTP Server Deployment apiVersion: apps/v1 kind: Deployment metadata: name: apache-deployment namespace: test spec: replicas: 2 selector: matchLabels: app: apache template: metadata: labels: app: apache spec: containers: - name: apache image: httpd:latest ports: # Container port where Apache listens - containerPort: 80 readinessProbe: httpGet: path: / port: 80 initialDelaySeconds: 5 periodSeconds: 10 livenessProbe: httpGet: path: / port: 80 initialDelaySeconds: 15 periodSeconds: 10 volumeMounts: - name: apache-htdocs mountPath: /usr/local/apache2/htdocs/ volumes: - name: apache-htdocs persistentVolumeClaim: claimName: example-apache-pvc END > ~ cat < apache-ingress.yaml apiVersion: networking.k8s.io/v1 kind: Ingress metadata: name: apache-ingress namespace: test annotations: spec.ingressClassName: traefik traefik.ingress.kubernetes.io/router.entrypoints: web spec: rules: - host: f3s.foo.zone http: paths: - path: / pathType: Prefix backend: service: name: apache-service port: number: 80 - host: standby.f3s.foo.zone http: paths: - path: / pathType: Prefix backend: service: name: apache-service port: number: 80 - host: www.f3s.foo.zone http: paths: - path: / pathType: Prefix backend: service: name: apache-service port: number: 80 END > ~ cat < apache-persistent-volume.yaml apiVersion: v1 kind: PersistentVolume metadata: name: example-apache-pv spec: capacity: storage: 1Gi volumeMode: Filesystem accessModes: - ReadWriteOnce persistentVolumeReclaimPolicy: Retain hostPath: path: /data/nfs/k3svolumes/example-apache-volume-claim type: Directory --- apiVersion: v1 kind: PersistentVolumeClaim metadata: name: example-apache-pvc namespace: test spec: storageClassName: "" accessModes: - ReadWriteOnce resources: requests: storage: 1Gi END > ~ cat < apache-service.yaml apiVersion: v1 kind: Service metadata: labels: app: apache name: apache-service namespace: test spec: ports: - name: web port: 80 protocol: TCP # Expose port 80 on the service targetPort: 80 selector: # Link this service to pods with the label app=apache app: apache END ``` I applied the manifests: ```sh > ~ kubectl apply -f apache-persistent-volume.yaml > ~ kubectl apply -f apache-service.yaml > ~ kubectl apply -f apache-deployment.yaml > ~ kubectl apply -f apache-ingress.yaml ``` Looking at the deployment, I could see it failed because the directory didn't exist yet on the NFS share (note that I also increased the replica count to 2 so if one node goes down there's already a replica running on another node for faster failover): ```sh > ~ kubectl get pods NAME READY STATUS RESTARTS AGE apache-deployment-5b96bd6b6b-fv2jx 0/1 ContainerCreating 0 9m15s apache-deployment-5b96bd6b6b-ax2ji 0/1 ContainerCreating 0 9m15s > ~ kubectl describe pod apache-deployment-5b96bd6b6b-fv2jx | tail -n 5 Events: Type Reason Age From Message ---- ------ ---- ---- ------- Normal Scheduled 9m34s default-scheduler Successfully assigned test/apache-deployment-5b96bd6b6b-fv2jx to r2.lan.buetow.org Warning FailedMount 80s (x12 over 9m34s) kubelet MountVolume.SetUp failed for volume "example-apache-pv" : hostPath type check failed: /data/nfs/k3svolumes/example-apache is not a directory ``` That's intentional—I needed to create the directory on the NFS share first, so I did that (e.g. on `r0`): ```sh [root@r0 ~]# mkdir /data/nfs/k3svolumes/example-apache-volume-claim/ [root@r0 ~]# cat < /data/nfs/k3svolumes/example-apache-volume-claim/index.html Hello, it works

Hello, it works!

This site is served via a PVC!

END ``` The `index.html` file gives us some actual content to serve. After deleting the pod, it recreates itself and the volume mounts correctly: ```sh > ~ kubectl delete pod apache-deployment-5b96bd6b6b-fv2jx > ~ curl -H "Host: www.f3s.foo.zone" http://r0.lan.buetow.org:80 Hello, it works

Hello, it works!

This site is served via a PVC!

``` ### Scaling Traefik for faster failover Traefik (used for ingress on k3s) ships with a single replica by default, but for faster failover I bumped it to two replicas so each worker node runs one pod. That way, if a node disappears, the service stays up while Kubernetes schedules a replacement. Here's the command I used: ```sh > ~ kubectl -n kube-system scale deployment traefik --replicas=2 ``` And the result: ```sh > ~ kubectl -n kube-system get pods -l app.kubernetes.io/name=traefik kube-system traefik-c98fdf6fb-97kqk 1/1 Running 19 (53d ago) 64d kube-system traefik-c98fdf6fb-9npg2 1/1 Running 11 (53d ago) 61d ``` ## Make it accessible from the public internet Next, I made this accessible through the public internet via the `www.f3s.foo.zone` hosts. As a reminder from part 1 of this series, I reviewed the section titled "OpenBSD/relayd to the rescue for external connectivity": => ./2024-11-17-f3s-kubernetes-with-freebsd-part-1.gmi f3s: Kubernetes with FreeBSD - Part 1: Setting the stage > All apps should be reachable through the internet (e.g., from my phone or computer when travelling). For external connectivity and TLS management, I've got two OpenBSD VMs (one hosted by OpenBSD Amsterdam and another hosted by Hetzner) handling public-facing services like DNS, relaying traffic, and automating Let's Encrypt certificates. > All of this (every Linux VM to every OpenBSD box) will be connected via WireGuard tunnels, keeping everything private and secure. There will be 6 WireGuard tunnels (3 k3s nodes times two OpenBSD VMs). > So, when I want to access a service running in k3s, I will hit an external DNS endpoint (with the authoritative DNS servers being the OpenBSD boxes). The DNS will resolve to the master OpenBSD VM (see my KISS highly-available with OpenBSD blog post), and from there, the relayd process (with a Let's Encrypt certificate—see my Let's Encrypt with OpenBSD and Rex blog post) will accept the TCP connection and forward it through the WireGuard tunnel to a reachable node port of one of the k3s nodes, thus serving the traffic. ```sh > ~ curl https://f3s.foo.zone

It works!

> ~ curl https://www.f3s.foo.zone

It works!

> ~ curl https://standby.f3s.foo.zone

It works!

``` This is how it works in `relayd.conf` on OpenBSD: ### OpenBSD relayd configuration The OpenBSD edge relays keep the Kubernetes-facing addresses for the f3s ingress endpoints in a shared backend table so TLS traffic for every `f3s` hostname lands on the same pool of k3s nodes (pointing to the WireGuard IP addresses of those nodes - remember, they are running locally in my LAN, wheras the OpenBSD edge relays operate in the public internet): ``` table { 192.168.2.120 192.168.2.121 192.168.2.122 } ``` Inside the `http protocol "https"` block each public hostname gets its Let's Encrypt certificate and is matched to that backend table. Besides the primary trio, every service-specific hostname (`anki`, `bag`, `flux`, `audiobookshelf`, `gpodder`, `radicale`, `vault`, `syncthing`, `uprecords`) and their `www` / `standby` aliases reuse the same pool so new apps can go live just by publishing an ingress rule, whereas they will all map to a service running in k3s: ``` http protocol "https" { tls keypair f3s.foo.zone tls keypair www.f3s.foo.zone tls keypair standby.f3s.foo.zone tls keypair anki.f3s.foo.zone tls keypair www.anki.f3s.foo.zone tls keypair standby.anki.f3s.foo.zone tls keypair bag.f3s.foo.zone tls keypair www.bag.f3s.foo.zone tls keypair standby.bag.f3s.foo.zone tls keypair flux.f3s.foo.zone tls keypair www.flux.f3s.foo.zone tls keypair standby.flux.f3s.foo.zone tls keypair audiobookshelf.f3s.foo.zone tls keypair www.audiobookshelf.f3s.foo.zone tls keypair standby.audiobookshelf.f3s.foo.zone tls keypair gpodder.f3s.foo.zone tls keypair www.gpodder.f3s.foo.zone tls keypair standby.gpodder.f3s.foo.zone tls keypair radicale.f3s.foo.zone tls keypair www.radicale.f3s.foo.zone tls keypair standby.radicale.f3s.foo.zone tls keypair vault.f3s.foo.zone tls keypair www.vault.f3s.foo.zone tls keypair standby.vault.f3s.foo.zone tls keypair syncthing.f3s.foo.zone tls keypair www.syncthing.f3s.foo.zone tls keypair standby.syncthing.f3s.foo.zone tls keypair uprecords.f3s.foo.zone tls keypair www.uprecords.f3s.foo.zone tls keypair standby.uprecords.f3s.foo.zone match request quick header "Host" value "f3s.foo.zone" forward to match request quick header "Host" value "www.f3s.foo.zone" forward to match request quick header "Host" value "standby.f3s.foo.zone" forward to match request quick header "Host" value "anki.f3s.foo.zone" forward to match request quick header "Host" value "www.anki.f3s.foo.zone" forward to match request quick header "Host" value "standby.anki.f3s.foo.zone" forward to match request quick header "Host" value "bag.f3s.foo.zone" forward to match request quick header "Host" value "www.bag.f3s.foo.zone" forward to match request quick header "Host" value "standby.bag.f3s.foo.zone" forward to match request quick header "Host" value "flux.f3s.foo.zone" forward to match request quick header "Host" value "www.flux.f3s.foo.zone" forward to match request quick header "Host" value "standby.flux.f3s.foo.zone" forward to match request quick header "Host" value "audiobookshelf.f3s.foo.zone" forward to match request quick header "Host" value "www.audiobookshelf.f3s.foo.zone" forward to match request quick header "Host" value "standby.audiobookshelf.f3s.foo.zone" forward to match request quick header "Host" value "gpodder.f3s.foo.zone" forward to match request quick header "Host" value "www.gpodder.f3s.foo.zone" forward to match request quick header "Host" value "standby.gpodder.f3s.foo.zone" forward to match request quick header "Host" value "radicale.f3s.foo.zone" forward to match request quick header "Host" value "www.radicale.f3s.foo.zone" forward to match request quick header "Host" value "standby.radicale.f3s.foo.zone" forward to match request quick header "Host" value "vault.f3s.foo.zone" forward to match request quick header "Host" value "www.vault.f3s.foo.zone" forward to match request quick header "Host" value "standby.vault.f3s.foo.zone" forward to match request quick header "Host" value "syncthing.f3s.foo.zone" forward to match request quick header "Host" value "www.syncthing.f3s.foo.zone" forward to match request quick header "Host" value "standby.syncthing.f3s.foo.zone" forward to match request quick header "Host" value "uprecords.f3s.foo.zone" forward to match request quick header "Host" value "www.uprecords.f3s.foo.zone" forward to match request quick header "Host" value "standby.uprecords.f3s.foo.zone" forward to } ``` Both IPv4 and IPv6 listeners reuse the same protocol definition, making the relay transparent for dual-stack clients while still health checking every k3s backend before forwarding traffic over WireGuard: ``` relay "https4" { listen on 46.23.94.99 port 443 tls protocol "https" forward to port 80 check tcp } relay "https6" { listen on 2a03:6000:6f67:624::99 port 443 tls protocol "https" forward to port 80 check tcp } ``` In practice, that means relayd terminates TLS with the correct certificate, keeps the three WireGuard-connected backends in rotation, and ships each request to whichever bhyve VM answers first. ## Deploying the private Docker image registry As not all Docker images I want to deploy are available on public Docker registries and as I also build some of them by myself, there is the need of a private registry. All manifests for the f3s stack live in my configuration repository: => https://codeberg.org/snonux/conf/src/branch/master/f3s codeberg.org/snonux/conf/f3s Within that repo, the `examples/conf/f3s/registry/` directory contains the Helm chart, a `Justfile`, and a detailed `README`. Here's the condensed walkthrough I used to roll out the registry with Helm. ### Prepare the NFS-backed storage Create the directory that will hold the registry blobs on the NFS share (I ran this on `r0`, but any node that exports `/data/nfs/k3svolumes` works): ```sh [root@r0 ~]# mkdir -p /data/nfs/k3svolumes/registry ``` ### Install (or upgrade) the chart Clone the repo (or pull the latest changes) on a workstation that has `helm` configured for the cluster, then deploy the chart. The Justfile wraps the commands, but the raw Helm invocation looks like this: ```sh $ git clone https://codeberg.org/snonux/conf/f3s.git $ cd conf/f3s/examples/conf/f3s/registry $ helm upgrade --install registry ./helm-chart --namespace infra --create-namespace ``` Helm creates the `infra` namespace if it does not exist, provisions a `PersistentVolume`/`PersistentVolumeClaim` pair that points at `/data/nfs/k3svolumes/registry`, and spins up a single registry pod exposed via the `docker-registry-service` NodePort (`30001`). Verify everything is up before continuing: ```sh $ kubectl get pods --namespace infra NAME READY STATUS RESTARTS AGE docker-registry-6bc9bb46bb-6grkr 1/1 Running 6 (53d ago) 54d $ kubectl get svc docker-registry-service -n infra NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE docker-registry-service NodePort 10.43.141.56 5000:30001/TCP 54d ``` ### Allow nodes and workstations to trust the registry The registry listens on plain HTTP, so both Docker daemons on workstations and the k3s nodes need to treat it as an insecure registry. That's fine for my personal needs, as: * I don't store any secrets in the images * I access the registry this way only via my LAN * I may will change it later on... On my Fedora workstation where I build images: ```sh $ cat <<"EOF" | sudo tee /etc/docker/daemon.json >/dev/null { "insecure-registries": [ "r0.lan.buetow.org:30001", "r1.lan.buetow.org:30001", "r2.lan.buetow.org:30001" ] } EOF $ sudo systemctl restart docker ``` On each k3s node, make `registry.lan.buetow.org` resolve locally and point k3s at the NodePort: ```sh $ for node in r0 r1 r2; do > ssh root@$node "echo '127.0.0.1 registry.lan.buetow.org' >> /etc/hosts" > done $ for node in r0 r1 r2; do > ssh root@$node "cat <<'EOF' > /etc/rancher/k3s/registries.yaml mirrors: "registry.lan.buetow.org:30001": endpoint: - "http://localhost:30001" EOF systemctl restart k3s" > done ``` Thanks to the relayd configuration earlier in the post, the external hostnames (`f3s.foo.zone`, etc.) can already reach NodePort `30001`, so publishing the registry later to the outside world is just a matter of wiring the DNS the same way as the ingress hosts. But by default, that's not enabled for now due to security reasons. ### Pushing and pulling images Tag any locally built image with one of the node IPs on port `30001`, then push it. I usually target whichever node is closest to me, but any of the three will do: ```sh $ docker tag my-app:latest r0.lan.buetow.org:30001/my-app:latest $ docker push r0.lan.buetow.org:30001/my-app:latest ``` Inside the cluster (or from other nodes), reference the image via the service name that Helm created: ``` image: docker-registry-service:5000/my-app:latest ``` You can test the pull path straight away: ```sh $ kubectl run registry-test \ > --image=docker-registry-service:5000/my-app:latest \ > --restart=Never -n test --command -- sleep 300 ``` If the pod pulls successfully, the private registry is ready for use by the rest of the workloads. Note, that the commands above actually don't work, they are only for illustration purpose mentioned here. ## Example: Anki Sync Server from the private registry One of the first workloads I migrated onto the k3s cluster after standing up the registry was my Anki sync server. The configuration repo ships everything in `examples/conf/f3s/anki-sync-server/`: a Docker build context plus a Helm chart that references the freshly built image. ### Build and push the image The Dockerfile lives under `docker-image/` and takes the Anki release to compile as an `ANKI_VERSION` build argument. The accompanying `Justfile` wraps the steps, but the raw commands look like this: ```sh $ cd conf/f3s/examples/conf/f3s/anki-sync-server/docker-image $ docker build -t anki-sync-server:25.07.5b --build-arg ANKI_VERSION=25.07.5 . $ docker tag anki-sync-server:25.07.5b \ r0.lan.buetow.org:30001/anki-sync-server:25.07.5b $ docker push r0.lan.buetow.org:30001/anki-sync-server:25.07.5b ``` Because every k3s node treats `registry.lan.buetow.org:30001` as an insecure mirror (see above), the push succeeds regardless of which node answers. If you prefer the shortcut, `just f3s` in that directory performs the same build/tag/push sequence. ### Create the Anki secret and storage on the cluster The Helm chart expects the `services` namespace, a pre-created NFS directory, and a Kubernetes secret that holds the credentials the upstream container understands: ```sh $ ssh root@r0 "mkdir -p /data/nfs/k3svolumes/anki-sync-server/anki_data" $ kubectl create namespace services $ kubectl create secret generic anki-sync-server-secret \ --from-literal=SYNC_USER1='paul:SECRETPASSWORD' \ -n services ``` If the `services` namespace already exists, you can skip that line or let Kubernetes tell you the namespace is unchanged. ### Deploy the chart With the prerequisites in place, install (or upgrade) the chart. It pins the container image to the tag we just pushed and mounts the NFS export via a `PersistentVolume/PersistentVolumeClaim` pair: ```sh $ cd ../helm-chart $ helm upgrade --install anki-sync-server . -n services ``` Helm provisions everything referenced in the templates: ``` containers: - name: anki-sync-server image: registry.lan.buetow.org:30001/anki-sync-server:25.07.5b volumeMounts: - name: anki-data mountPath: /anki_data ``` Once the release comes up, verify that the pod pulled the freshly pushed image and that the ingress we configured earlier resolves through relayd just like the Apache example. ```sh $ kubectl get pods -n services $ kubectl get ingress anki-sync-server-ingress -n services $ curl https://anki.f3s.foo.zone/health ``` All of this runs solely on first-party images that now live in the private registry, proving the full flow from local bild to WireGuard-exposed service. ## NFSv4 UID mapping for Postgres-backed (and other) apps NFSv4 only sees numeric user and group IDs, so the `postgres` account created inside the container must exist with the same UID/GID on the Kubernetes worker and on the FreeBSD NFS servers. Otherwise the pod starts with UID 999, the export sees it as an unknown anonymous user, and Postgres fails to initialise its data directory. To verify things line up end-to-end I run `id` in the container and on the hosts: ```sh > ~ kubectl exec -n services deploy/miniflux-postgres -- id postgres uid=999(postgres) gid=999(postgres) groups=999(postgres) [root@r0 ~]# id postgres uid=999(postgres) gid=999(postgres) groups=999(postgres) paul@f0:~ % doas id postgres uid=999(postgres) gid=99(postgres) groups=999(postgres) ``` The Rocky Linux workers get their matching user with plain `useradd`/`groupadd` (repeat on `r0`, `r1`, and `r2`): ```sh [root@r0 ~]# groupadd --gid 999 postgres [root@r0 ~]# useradd --uid 999 --gid 999 \ --home-dir /var/lib/pgsql \ --shell /sbin/nologin postgres ``` FreeBSD uses `pw`, so on each NFS server (`f0`, `f1`, `f2`) I created the same account and disabled shell access: ```sh paul@f0:~ % doas pw groupadd postgres -g 999 paul@f0:~ % doas pw useradd postgres -u 999 -g postgres \ -d /var/db/postgres -s /usr/sbin/nologin ``` Once the UID/GID exist everywhere, the Miniflux chart in `examples/conf/f3s/miniflux` deploys cleanly. The chart provisions both the application and its bundled Postgres database, mounts the exported directory, and builds the DSN at runtime. The important bits live in `helm-chart/templates/persistent-volumes.yaml` and `deployment.yaml`: ``` # Persistent volume lives on the NFS export hostPath: path: /data/nfs/k3svolumes/miniflux/data type: Directory ... containers: - name: miniflux-postgres image: postgres:17 volumeMounts: - name: miniflux-postgres-data mountPath: /var/lib/postgresql/data ``` Follow the `README` beside the chart to create the secrets and the target directory: ```sh $ cd examples/conf/f3s/miniflux/helm-chart $ mkdir -p /data/nfs/k3svolumes/miniflux/data $ kubectl create secret generic miniflux-db-password \ --from-literal=fluxdb_password='YOUR_PASSWORD' -n services $ kubectl create secret generic miniflux-admin-password \ --from-literal=admin_password='YOUR_ADMIN_PASSWORD' -n services $ helm upgrade --install miniflux . -n services --create-namespace ``` And to verify it's all up: ``` $ kubectl get all --namespace=services | grep mini pod/miniflux-postgres-556444cb8d-xvv2p 1/1 Running 0 54d pod/miniflux-server-85d7c64664-stmt9 1/1 Running 0 54d service/miniflux ClusterIP 10.43.47.80 8080/TCP 54d service/miniflux-postgres ClusterIP 10.43.139.50 5432/TCP 54d deployment.apps/miniflux-postgres 1/1 1 1 54d deployment.apps/miniflux-server 1/1 1 1 54d replicaset.apps/miniflux-postgres-556444cb8d 1 1 1 54d replicaset.apps/miniflux-server-85d7c64664 1 1 1 54d ``` Or from the repository root I simply run: ### Helm charts currently in service These are the charts that already live under `examples/conf/f3s` and run on the cluster today (and I'll keep adding more as new services graduate into production): * `anki-sync-server` — custom-built image served from the private registry, stores decks on `/data/nfs/k3svolumes/anki-sync-server/anki_data`, and authenticates through the `anki-sync-server-secret`. * `koreade-sync-server` — Sync server for KOReader. * `audiobookshelf` — media streaming stack with three hostPath mounts (`config`, `audiobooks`, `podcasts`) so the library survives node rebuilds. * `example-apache` — minimal HTTP service I use for smoke-testing ingress and relayd rules. * `example-apache-volume-claim` — Apache plus PVC variant that exercises NFS-backed storage for walkthroughs like the one earlier in this post. * `miniflux` — the Postgres-backed feed reader described above, wired for NFSv4 UID mapping and per-release secrets. * `opodsync` — podsync deployment with its data directory under `/data/nfs/k3svolumes/opodsync/data`. * `radicale` — CalDAV/CardDAV (and gpodder) backend with separate `collections` and `auth` volumes. * `registry` — the plain-HTTP Docker registry exposed on NodePort 30001 and mirrored internally as `registry.lan.buetow.org:30001`. * `syncthing` — two-volume setup for config and shared data, fronted by the `syncthing.f3s.foo.zone` ingress. * `wallabag` — read-it-later service with persistent `data` and `images` directories on the NFS export. I hope you enjoyed this walkthrough. Read the next post of this series: => ./2025-12-07-f3s-kubernetes-with-freebsd-part-8.gmi f3s: Kubernetes with FreeBSD - Part 8: Observability Other *BSD-related posts: << template::inline::rindex bsd E-Mail your comments to `paul@nospam.buetow.org` => ../ Back to the main site