Kubernetes NFS Subdir External Provisioner
NFS subdir external provisioner is an automatic provisioner that use your existing and already configured NFS server to support dynamic provisioning of Kubernetes Persistent Volumes via Persistent Volume Claims. Persistent volumes are provisioned as ${namespace}-${pvcName}-${pvName}
.
Note: This repository is migrated from https://github.com/kubernetes-incubator/external-storage/tree/master/nfs-client. As part of the migration:
- The container image name and repository has changed to
k8s.gcr.io/sig-storage
andnfs-subdir-external-provisioner
respectively. - To maintain backward compatibility with earlier deployment files, the naming of NFS Client Provisioner is retained as
nfs-client-provisioner
in the deployment YAMLs. - One of the pending areas for development on this repository is to add automated e2e tests. If you would like to contribute, please raise an issue or reach us on the Kubernetes slack #sig-storage channel.
How to deploy NFS Subdir External Provisioner to your cluster
To note again, you must already have an NFS Server.
With Helm
Follow the instructions from the helm chart README.
The tl;dr is
$ helm repo add nfs-subdir-external-provisioner https://kubernetes-sigs.github.io/nfs-subdir-external-provisioner/
$ helm install nfs-subdir-external-provisioner nfs-subdir-external-provisioner/nfs-subdir-external-provisioner \
--set nfs.server=x.x.x.x \
--set nfs.path=/exported/path
Without Helm
Step 1: Get connection information for your NFS server
Make sure your NFS server is accessible from your Kubernetes cluster and get the information you need to connect to it. At a minimum you will need its hostname.
Step 2: Get the NFS Subdir External Provisioner files
To setup the provisioner you will download a set of YAML files, edit them to add your NFS server's connection information and then apply each with the kubectl
/ oc
command.
Get all of the files in the deploy directory of this repository. These instructions assume that you have cloned the kubernetes-sigs/nfs-subdir-external-provisioner repository and have a bash-shell open in the root directory.
Step 3: Setup authorization
If your cluster has RBAC enabled or you are running OpenShift you must authorize the provisioner. If you are in a namespace/project other than "default" edit deploy/rbac.yaml
.
Kubernetes:
# Set the subject of the RBAC objects to the current namespace where the provisioner is being deployed
$ NS=$(kubectl config get-contexts|grep -e "^\*" |awk '{print $5}')
$ NAMESPACE=${NS:-default}
$ sed -i'' "s/namespace:.*/namespace: $NAMESPACE/g" ./deploy/rbac.yaml ./deploy/deployment.yaml
$ kubectl create -f deploy/rbac.yaml
OpenShift:
On some installations of OpenShift the default admin user does not have cluster-admin permissions. If these commands fail refer to the OpenShift documentation for User and Role Management or contact your OpenShift provider to help you grant the right permissions to your admin user.
On OpenShift the service account used to bind volumes does not have the necessary permissions required to use the hostmount-anyuid
SCC. See also Role based access to SCC for more information. If these commands fail refer to the OpenShift documentation for User and Role Management or contact your OpenShift provider to help you grant the right permissions to your admin user.
# Set the subject of the RBAC objects to the current namespace where the provisioner is being deployed
$ NAMESPACE=`oc project -q`
$ sed -i'' "s/namespace:.*/namespace: $NAMESPACE/g" ./deploy/rbac.yaml
$ oc create -f deploy/rbac.yaml
$ oc adm policy add-scc-to-user hostmount-anyuid system:serviceaccount:$NAMESPACE:nfs-client-provisioner
Step 4: Configure the NFS subdir external provisioner
If you would like to use a custom built nfs-subdir-external-provisioner image, you must edit the provisioner's deployment file to specify the correct location of your nfs-client-provisioner
container image.
Next you must edit the provisioner's deployment file to add connection information for your NFS server. Edit deploy/deployment.yaml
and replace the two occurences of with your server's hostname.
kind: Deployment
apiVersion: apps/v1
metadata:
name: nfs-client-provisioner
spec:
replicas: 1
selector:
matchLabels:
app: nfs-client-provisioner
strategy:
type: Recreate
template:
metadata:
labels:
app: nfs-client-provisioner
spec:
serviceAccountName: nfs-client-provisioner
containers:
- name: nfs-client-provisioner
image: k8s.gcr.io/sig-storage/nfs-subdir-external-provisioner:v4.0.2
volumeMounts:
- name: nfs-client-root
mountPath: /persistentvolumes
env:
- name: PROVISIONER_NAME
value: k8s-sigs.io/nfs-subdir-external-provisioner
- name: NFS_SERVER
value: <YOUR NFS SERVER HOSTNAME>
- name: NFS_PATH
value: /var/nfs
volumes:
- name: nfs-client-root
nfs:
server: <YOUR NFS SERVER HOSTNAME>
path: /var/nfs
Note: If you want to change the PROVISIONER_NAME above from k8s-sigs.io/nfs-subdir-external-provisioner
to something else like myorg/nfs-storage
, remember to also change the PROVISIONER_NAME in the storage class definition below.
To disable leader election, define an env variable named ENABLE_LEADER_ELECTION and set its value to false.
Step 5: Deploying your storage class
Parameters:
Name | Description | Default |
---|---|---|
onDelete | If it exists and has a delete value, delete the directory, if it exists and has a retain value, save the directory. | will be archived with name on the share: archived-<volume.Name> |
archiveOnDelete | If it exists and has a false value, delete the directory. if onDelete exists, archiveOnDelete will be ignored. |
will be archived with name on the share: archived-<volume.Name> |
pathPattern | Specifies a template for creating a directory path via PVC metadata's such as labels, annotations, name or namespace. To specify metadata use ${.PVC.<metadata>} . Example: If folder should be named like <pvc-namespace>-<pvc-name> , use ${.PVC.namespace}-${.PVC.name} as pathPattern. |
n/a |
This is deploy/class.yaml
which defines the NFS subdir external provisioner's Kubernetes Storage Class:
apiVersion: storage.k8s.io/v1
kind: StorageClass
metadata:
name: managed-nfs-storage
provisioner: k8s-sigs.io/nfs-subdir-external-provisioner # or choose another name, must match deployment's env PROVISIONER_NAME'
parameters:
pathPattern: "${.PVC.namespace}/${.PVC.annotations.nfs.io/storage-path}" # waits for nfs.io/storage-path annotation, if not specified will accept as empty string.
onDelete: delete
Step 6: Finally, test your environment!
Now we'll test your NFS subdir external provisioner.
Deploy:
$ kubectl create -f deploy/test-claim.yaml -f deploy/test-pod.yaml
Now check your NFS Server for the file SUCCESS
.
kubectl delete -f deploy/test-pod.yaml -f deploy/test-claim.yaml
Now check the folder has been deleted.
Step 7: Deploying your own PersistentVolumeClaims
To deploy your own PVC, make sure that you have the correct storageClassName
as indicated by your deploy/class.yaml
file.
For example:
kind: PersistentVolumeClaim
apiVersion: v1
metadata:
name: test-claim
annotations:
nfs.io/storage-path: "test-path" # not required, depending on whether this annotation was shown in the storage class description
spec:
storageClassName: managed-nfs-storage
accessModes:
- ReadWriteMany
resources:
requests:
storage: 1Mi
Build and publish your own container image
To build your own custom container image from this repository, you will have to build and push the nfs-subdir-external-provisioner image using the following instructions.
make build
make container
# `nfs-subdir-external-provisioner:latest` will be created.
# Note: This will build a single-arch image that matches the machine on which container is built.
# To upload this to your custom registry, say `quay.io/myorg` and arch as amd64, you can use
# docker tag nfs-subdir-external-provisioner:latest quay.io/myorg/nfs-subdir-external-provisioner-amd64:latest
# docker push quay.io/myorg/nfs-subdir-external-provisioner-amd64:latest
Build and publish with GitHub Actions
In a forked repository you can use GitHub Actions pipeline defined in .github/workflows/release.yml. The pipeline builds Docker images for linux/amd64
, linux/arm64
, and linux/arm/v7
platforms and publishes them using a multi-arch manifest. The pipeline is triggered when you add a tag like gh-v{major}.{minor}.{patch}
to your commit and push it to GitHub. The tag is used for generating Docker image tags: latest
, {major}
, {major}:{minor}
, {major}:{minor}:{patch}
.
The pipeline adds several labels:
org.opencontainers.image.title=${{ github.event.repository.name }}
org.opencontainers.image.description=${{ github.event.repository.description }}
org.opencontainers.image.url=${{ github.event.repository.html_url }}
org.opencontainers.image.source=${{ github.event.repository.clone_url }}
org.opencontainers.image.created=${{ steps.prep.outputs.created }}
org.opencontainers.image.revision=${{ github.sha }}
org.opencontainers.image.licenses=${{ github.event.repository.license.spdx_id }}
Important:
- The pipeline performs the docker login command using
REGISTRY_USERNAME
andREGISTRY_TOKEN
secrets, which have to be provided. - You also need to provide the
DOCKER_IMAGE
secret specifying your Docker image name, e.g.,quay.io/[username]/nfs-subdir-external-provisioner
.