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Container Storage Interface (CSI) for SeaweedFS

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Container storage interface is an industry standard that enables storage vendors to develop a plugin once and have it work across a number of container orchestration systems.

SeaweedFS is a simple and highly scalable distributed file system, to store and serve billions of files fast!



Deployment

Kubernetes (kubectl)

Prerequisites:

  • Already have a working Kubernetes cluster (includes kubectl)
  • Already have a working SeaweedFS cluster

Install

Helm

  1. Add the helm repo;
helm repo add seaweedfs-csi-driver https://seaweedfs.github.io/seaweedfs-csi-driver/helm
"seaweedfs-csi-driver" has been added to your repositories
  1. Check versions by helm repo update seaweedfs-csi-driver and helm search repo seaweedfs-csi-driver

Source

  1. Clone this repository
git clone https://github.com/seaweedfs/seaweedfs-csi-driver.git
  1. Adjust your SeaweedFS Filer address via variable SEAWEEDFS_FILER in deploy/kubernetes/seaweedfs-csi.yaml (2 places)

  2. Apply the container storage interface for SeaweedFS for your cluster. Use the '-pre-1.17' version for any cluster pre kubernetes version 1.17.


To generate an up to date manifest from the helm chart, do:

$ helm template seaweedfs ./deploy/helm/seaweedfs-csi-driver > deploy/kubernetes/seaweedfs-csi.yaml

Then apply the manifest.

$ kubectl apply -f deploy/kubernetes/seaweedfs-csi.yaml
  1. Ensure all the containers are ready and running
$ kubectl get po -n kube-system

Uninstall

$ kubectl delete -f deploy/kubernetes/sample-busybox-pod.yaml
$ kubectl delete -f deploy/kubernetes/sample-seaweedfs-pvc.yaml
$ kubectl delete -f deploy/kubernetes/seaweedfs-csi.yaml

Kubernetes (helm)

Install

  1. Clone project
git clone https://github.com/seaweedfs/seaweedfs-csi-driver.git
  1. Edit ./seaweedfs-csi-driver/deploy/helm/values.yaml if required and Install
helm install --set seaweedfsFiler=<filerHost:port> seaweedfs-csi-driver ./seaweedfs-csi-driver/deploy/helm/seaweedfs-csi-driver

Uninstall

helm uninstall seaweedfs-csi-driver

Update (Safe rollout)

Updating seaweed-csi-driver DaemonSet (DS) will break processeses who implement fuse mount: newly created pods will not remount net device.

For safe update set node.updateStrategy.type: OnDelete for manual update. Steps:

  1. delete DS pods on the node where there is no seaweedfs PV
  2. cordon or taint node
  3. evict or delete pods with seaweedfs PV
  4. delete DS pod on node
  5. uncordon or remove taint on node
  6. repeat all steps on [all nodes]

Testing

  1. Create a persistant volume claim for 5GiB with name seaweedfs-csi-pvc with storage class seaweedfs-storage. The value, 5Gib does not have any significance as for SeaweedFS the whole filesystem is mounted into the container.
$ kubectl apply -f deploy/kubernetes/sample-seaweedfs-pvc.yaml
  1. Verify if the persistant volume claim exists and wait until its the STATUS is Bound
$ kubectl get pvc
  1. After its in Bound state, create a sample workload mounting that volume
$ kubectl apply -f deploy/kubernetes/sample-busybox-pod.yaml
  1. Verify the storage mount of the busybox pod
$ kubectl exec my-csi-app -- df -h

Static and dynamic provisioning

By default, driver will create separate folder (/buckets/<volume-id>) and will use separate collection (volume-id) for each request. Sometimes we need to use exact collection name or change replication options. It can be done via creating separate storage class with options:

kind: StorageClass
apiVersion: storage.k8s.io/v1
metadata:
  name: seaweedfs-special
provisioner: seaweedfs-csi-driver
parameters:
  collection: mycollection
  replication: "011"
  diskType: "ssd"

There is another use case when we need to access one folder from different pods with ro/rw access. In this case we do not need additional StorageClass. We need to create PersistentVolume:

apiVersion: v1
kind: PersistentVolume
metadata:
  name: seaweedfs-static
spec:
  accessModes:
  - ReadWriteMany
  capacity:
    storage: 1Gi
  csi:
    driver: seaweedfs-csi-driver
    volumeHandle: dfs-test
    volumeAttributes:
      collection: default
      replication: "011"
      path: /path/to/files
      diskType: "ssd"
    readOnly: true
  persistentVolumeReclaimPolicy: Retain
  volumeMode: Filesystem

and bind PersistentVolumeClaim(s) to it:

apiVersion: v1
kind: PersistentVolumeClaim
metadata:
  name: seaweedfs-static
spec:
  storageClassName: ""
  volumeName: seaweedfs-static
  accessModes:
  - ReadWriteMany
  resources:
    requests:
      storage: 1Gi

DataLocality

DataLocality (inspired by Longhorn) allows instructing the storage-driver which volume-locations will be used or preferred in Pods to read & write.

It auto-sets mount-options based on the location a pod is scheduled in and the locality-option wanted. The option can be set and overridden in Driver, StorageClass and PersistentVolume.


Setup

Change the type of locality

Level Location
Driver Helm: values.yaml -> dataLocality
Or DaemonSet -> Container csi-seaweedfs-plugin -> args --dataLocality=
StorageClass parameter.dataLocality
PersistentVolume spec.csi.volumeAttributes.dataLocality

Driver < StorageClass < PersistentVolume


Available options

Option Effect
none* Changes nothing
write_preferLocalDc Sets the DataCenter-mount-option to the current Node-DataCenter, making writes local and allowing reads to occur wherever read data is stored. More Details

* Default


Requirements

Volume-Servers and the CSI-Driver-Node need to have the locality-option DataCenter correctly set (currently only this option is required).

This can be done manually (although quite tedious) or injected by the Container-Orchestration.


Automatic injection

Kubernetes

Unfortunately Kubernetes doesnt allow grabbing node-labels, which contain well-known region-labels, and setting them as environment-variables. The DownwardAPI is very limited in that regard. (see #40610)

Therefore a workaround must be used. KubeMod can be used based on this comment. This of course requires KubeMod to be installed.

You can activate it in the Helm-Chart values.yaml -> node.injectTopologyInfoFromNodeLabel.enabled. node.injectTopologyInfoFromNodeLabel.labels decides which labels are grabbed from the node.

It is recommended to use well-known labels to avoid confusion.


License

Apache v2 license


Code of conduct

Participation in this project is governed by Kubernetes/CNCF code of conduct

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