a10dedbd5e
This is an initial scheduler implementation for ZFS Local PV.
* adding scheduler as a configurable option
* adding volumeWeightedScheduler as scheduling logic
The volumeWeightedScheduler will go through all the nodes as per
topology information and it will pick the node which has less
volume provisioned in the given pool.
lets say there are 2 nodes node1 and node2 with below pool configuration :-
```
node1
|
|-----> pool1
| |
| |------> pvc1
| |------> pvc2
|-----> pool2
|------> pvc3
node2
|
|-----> pool1
| |
| |------> pvc4
|-----> pool2
|------> pvc5
|------> pvc6
```
So if application is using pool1 as shown in the below storage class, then ZFS driver will schedule it on node2 as it has one volume as compared to node1 which has 2 volumes in pool1.
```yaml
kind: StorageClass
apiVersion: storage.k8s.io/v1
metadata:
name: openebs-zfspv
provisioner: zfs.csi.openebs.io
parameters:
blocksize: "4k"
compression: "on"
dedup: "on"
thinprovision: "yes"
poolname: "pool1"
```
So if application is using pool2 as shown in the below storage class, then ZFS driver will schedule it on node1 as it has one volume only as compared node2 which has 2 volumes in pool2.
```yaml
kind: StorageClass
apiVersion: storage.k8s.io/v1
metadata:
name: openebs-zfspv
provisioner: zfs.csi.openebs.io
parameters:
blocksize: "4k"
compression: "on"
dedup: "on"
thinprovision: "yes"
poolname: "pool2"
```
In case of same number of volumes on all the nodes for the given pool, it can pick any node and schedule the PV on that.
Signed-off-by: Pawan <pawan@mayadata.io>
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| pkg | ||
| vendor | ||
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| Gopkg.lock | ||
| Gopkg.toml | ||
| LICENSE | ||
| Makefile | ||
| README.md | ||
| VERSION | ||
OpenEBS ZFS CSI Driver
CSI driver for provisioning Local PVs backed by ZFS and more.
Project Status
This project is under active development and considered to be in Alpha state. The current implementation only supports provisioning and de-provisioning of ZFS Volumes.
Usage
Prerequisites
Before installing ZFS driver please make sure your Kubernetes Cluster must meet the following prerequisites:
- all the nodes must have zfs utils installed
- ZPOOL has been setup for provisioning the volume
- You have access to install RBAC components into kube-system namespace. The OpenEBS ZFS driver components are installed in kube-system namespace to allow them to be flagged as system critical components.
Supported System
K8S : 1.14+
OS : ubuntu 18.04
ZFS : 0.7, 0.8
Setup
All the node should have zfsutils-linux installed. We should go to the each node of the cluster and install zfs utils
$ apt-get install zfsutils-linux
Installation
OpenEBS ZFS driver components can be installed by running the following command.
kubectl apply -f https://raw.githubusercontent.com/openebs/zfs-localpv/master/deploy/zfs-operator.yaml
Verify that the ZFS driver Components are installed and running using below command :
$ kubectl get pods -n kube-system -l role=openebs-zfs
Depending on number of nodes, you will see one zfs-controller pod and zfs-node daemonset running on the nodes.
NAME READY STATUS RESTARTS AGE
openebs-zfs-controller-0 4/4 Running 0 5h28m
openebs-zfs-node-4d94n 2/2 Running 0 5h28m
openebs-zfs-node-gssh8 2/2 Running 0 5h28m
openebs-zfs-node-twmx8 2/2 Running 0 5h28m
Once ZFS driver is installed we can provision a volume.
Deployment
- create a Storage class
$ cat sc.yaml
```yaml
apiVersion: storage.k8s.io/v1
kind: StorageClass
metadata:
name: openebs-zfspv
parameters:
blocksize: "4k"
compression: "off"
dedup: "off"
thinprovision: "no"
poolname: "zfspv-pool"
provisioner: openebs.io/zfs
The storage class contains the volume paramaters like blocksize, compression, dedup and thinprovision. You can select what are all parameters you want. The above yaml shows the default values in case paramenters are not provided or wrong value has been provided. The poolname is the must argument. There must be a ZPOOL running on the node with the name given in this storage class.
Here we have to give the provisioner as "openebs.io/zfs" which is the provisioner name of the ZFS driver.
- create a PVC
$ cat pvc.yaml
```yaml
kind: PersistentVolumeClaim
apiVersion: v1
metadata:
name: csi-zfspv
spec:
storageClassName: openebs-zfspv
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 4Gi
Create a PVC using the storage class created with the openebs.io/zfs provisioner.
- Check the kubernetes resource is created for the corresponding zfs volume
$ kubectl get zv -n openebs
NAME NODE SIZE
pvc-37b07ad6-db68-11e9-bbb6-000c296e38d9 4294967296
Here note that NODE field will be empty as application POD has not yet deployed. When application will be deployed, as a part of deploying the application the ZFS driver will create the zfs volume of name pvc-37b07ad6-db68-11e9-bbb6-000c296e38d9 in the pool mentioned in the storage class.
- Deploy the application using this PVC
$ cat fio.yaml
```yaml
apiVersion: v1
kind: Pod
metadata:
name: fio
spec:
affinity:
nodeAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
nodeSelectorTerms:
- matchExpressions:
- key: kubernetes.io/hostname
operator: In
values:
- k8s-virtual-machine
restartPolicy: Never
containers:
- name: perfrunner
image: openebs/tests-fio
command: ["/bin/bash"]
args: ["-c", "while true ;do sleep 50; done"]
volumeMounts:
- mountPath: /datadir
name: fio-vol
tty: true
volumes:
- name: fio-vol
persistentVolumeClaim:
claimName: csi-zfspv
Here in alpha version of the ZFS driver we have to make use of node selector or node affinity to make the application pod stick to the node as the application pod should not move to the other node because the data will be there on one node only.
After the deployment of the application we can go to the node and see that a zfs volume has been created in the pool mentioned in the storage class and application is using that volume for writting the data. This is in effect working like waitforFirstConsumer so the actual ZFS volume will be create when application is deployed to the node.
$ zfs list
NAME USED AVAIL REFER MOUNTPOINT
zfspv-pool 4.25G 92.1G 96K /zfspv-pool
zfspv-pool/pvc-37b07ad6-db68-11e9-bbb6-000c296e38d9 4.25G 96.4G 5.69M -
Also we can check the kubernetes resource for the corresponding zfs volume
$ kubectl get zv -n openebs
NAME NODE SIZE
pvc-37b07ad6-db68-11e9-bbb6-000c296e38d9 k8s-virtual-machine 4294967296
$ kubectl describe zv pvc-37b07ad6-db68-11e9-bbb6-000c296e38d9 -n openebs
```yaml
Name: pvc-37b07ad6-db68-11e9-bbb6-000c296e38d9
Namespace: openebs
Labels: kubernetes.io/nodename=k8s-virtual-machine
Annotations: <none>
API Version: openebs.io/v1alpha1
Kind: ZFSVolume
Metadata:
Creation Timestamp: 2019-09-20T05:33:52Z
Finalizers:
zfs.openebs.io/finalizer
Generation: 2
Resource Version: 20029636
Self Link: /apis/openebs.io/v1alpha1/namespaces/openebs/zfsvolumes/pvc-37b07ad6-db68-11e9-bbb6-000c296e38d9
UID: 3b20990a-db68-11e9-bbb6-000c296e38d9
Spec:
Blocksize: 4k
Capacity: 4294967296
Compression: off
Dedup: off
Owner Node ID: k8s-virtual-machine
Pool Name: zfspv-pool
Thin Provison: no
Events: <none>
- ZFS Volume Property Change like compression on/off can be done by just simply editing the kubernetes resource for the corresponding zfs volume by using below command :
kubectl edit zv pvc-37b07ad6-db68-11e9-bbb6-000c296e38d9 -n openebs
You can edit the relevant property like make compression on or make dedup on and save it. This property will be applied to the corresponding volume and can be verified using below command on the node:
zfs get all zfspv-pool/pvc-37b07ad6-db68-11e9-bbb6-000c296e38d9
- for deprovisioning the volume we can delete the application which is using the volume and then we can go ahead and delete the pv, as part of deletion of pv this volume will also be deleted from the ZFS pool and data will be freed.
$ kubectl delete -f fio.yaml
pod "fio" deleted
$ kubectl delete -f pvc.yaml
persistentvolumeclaim "csi-zfspv" deleted
License
