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Snapshotting a Standalone PVC
This guide will show you how to use Stash to snapshot standalone PersistentVolumeClaims and restore that from snapshot using Kubernetes VolumeSnapshot API. In this guide, we are going to backup the volumes in Google Cloud Platform with the help of GCE Persistent Disk CSI Driver.
Before You Begin
- At first, you need to be familiar with the GCE Persistent Disk CSI Driver.
- You need to enable the Kubernetes
VolumeSnapshotDataSource
alpha feature via Kubernetes feature gates--feature-gates=VolumeSnapshotDataSource=true
- Install
Stash
in your cluster following the steps here. - If you don’t know how VolumeSnapshot works in Stash, please visit here.
Prepare for VolumeSnapshot
If you don’t already have a StorageClass that uses the CSI driver that supports VolumeSnapshot feature, create one first. Here, we are going to create StorageClass
that uses GCE Persistent Disk CSI Driver.
Sample StorageClass
YAML are given below,
apiVersion: storage.k8s.io/v1
kind: StorageClass
metadata:
name: standard
parameters:
type: pd-standard
provisioner: pd.csi.storage.gke.io
reclaimPolicy: Delete
volumeBindingMode: Immediate
Let’s create the StorageClass
we have shown above,
$ kubectl apply -f https://github.com/stashed/docs/raw/v2021.06.23/docs/examples/guides/latest/volumesnapshot/storageclass.yaml
storageclass.storage.k8s.io/standard created
We also need a VolumeSnapshotClass
. We are going to use the following VolumeSnapshotClass
for this tutorial,
apiVersion: snapshot.storage.k8s.io/v1beta1
kind: VolumeSnapshotClass
metadata:
name: csi-gce-pd-snapshot-class
driver: pd.csi.storage.gke.io
deletionPolicy: Delete
Here,
metadata.annotations
annotations are used to set default volumeSnapshotClass.snapshotter
field to point to the respective CSI driver that is responsible for taking snapshot. As we are using GCE Persistent Disk CSI Driver, we are going to usepd.csi.storage.gke.io
in this field.
Let’s create the volumeSnapshotClass
crd we have shown above,
$ kubectl apply -f https://github.com/stashed/docs/raw/v2021.06.23/docs/examples/guides/latest/volumesnapshot/default-volumesnapshotclass.yaml
volumesnapshotclass.snapshot.storage.k8s.io/default-snapshot-class created
To keep everything isolated, we are going to use a separate namespace called demo
throughout this tutorial.
$ kubectl create ns demo
namespace/demo created
Note: YAML files used in this tutorial are stored in /docs/examples/guides/latest/volumesnapshot directory of stashed/docs repository.
Take Volume Snapshot
Here, we are going to create a PVC and mount it with a pod and we are going to also generate some sample data on it. Then, we are going to take snapshot of this PVC using Stash.
Create PersistentVolumeClaim :
At first, let’s create a PVC. We are going to mount this PVC in a pod.
Below is the YAML of the sample PVC,
kind: PersistentVolumeClaim
apiVersion: v1
metadata:
name: source-data
namespace: demo
spec:
accessModes:
- ReadWriteOnce
storageClassName: standard
resources:
requests:
storage: 1Gi
Let’s create the PVC we have shown above.
$ kubectl apply -f https://github.com/stashed/docs/raw/v2021.06.23/docs/examples/guides/latest/volumesnapshot/standalone-pvc/source-pvc.yaml
persistentvolumeclaim/source-data created
Create Pod :
Now, we are going to deploy a pod that uses the above PVC. This pod will automatically create data.txt
file in /source/data
directory and write some sample data in it and also mounted the desired PVC in /source/data
directory.
Below is the YAML of the pod that we are going to create,
apiVersion: v1
kind: Pod
metadata:
name: source-pod
namespace: demo
spec:
containers:
- name: busybox
image: busybox
command: ["/bin/sh", "-c"]
args: ["echo sample_data > /source/data/data.txt && sleep 3000"]
volumeMounts:
- name: source-data
mountPath: /source/data
volumes:
- name: source-data
persistentVolumeClaim:
claimName: source-data
readOnly: false
Let’s create the Pod we have shown above.
$ kubectl apply -f https://github.com/stashed/docs/raw/v2021.06.23/docs/examples/guides/latest/volumesnapshot/standalone-pvc/source-pod.yaml
pod/source-pod created
Now, wait for the Pod to go into the Running
state.
$ kubectl get pod -n demo
NAME READY STATUS RESTARTS AGE
source-pod 1/1 Running 0 25s
Verify that the sample data has been created in /source/data
directory for source-pod
pod
using the following command,
$ kubectl exec -n demo source-pod -- cat /source/data/data.txt
sample_data
Create BackupConfiguration :
Now, create a BackupConfiguration
crd to take snapshot of the source-data
PVC.
Below is the YAML of the BackupConfiguration
crd that we are going to create,
apiVersion: stash.appscode.com/v1beta1
kind: BackupConfiguration
metadata:
name: pvc-volume-snapshot
namespace: demo
spec:
schedule: "*/5 * * * *"
driver: VolumeSnapshotter
target:
ref:
apiVersion: v1
kind: PersistentVolumeClaim
name: source-data
snapshotClassName: default-snapshot-class
retentionPolicy:
name: 'keep-last-5'
keepLast: 5
prune: true
Here,
spec.schedule
is a cron expression indicates thatBackupSession
will be created at 5 minute interval.spec.driver
indicates the name of the agent to use to back up the target. Currently, Stash supportsRestic
,VolumeSnapshotter
drivers. TheVolumeSnapshotter
is used to backup/restore PVC usingVolumeSnapshot
API.spec.target.ref
refers to the backup target.apiVersion
,kind
andname
refers to theapiVersion
,kind
andname
of the targeted workload respectively. Stash will use this information to create a Volume Snapshotter Job for creating VolumeSnapshot.spec.target.snapshotClassName
indicates the VolumeSnapshotClass to be used for volume snapshotting.
Let’s create the BackupConfiguration
crd we have shown above.
$ kubectl apply -f https://github.com/stashed/docs/raw/v2021.06.23/docs/examples/guides/latest/volumesnapshot/standalone-pvc/backupconfiguration.yaml
backupconfiguration.stash.appscode.com/pvc-volume-snapshot created
Verify CronJob :
If everything goes well, Stash will create a CronJob
to take periodic snapshot of the PVC with the schedule specified in spec.schedule
field of BackupConfiguration
crd.
Check that the CronJob
has been created using the following command,
$ kubectl get cronjob -n demo
NAME SCHEDULE SUSPEND ACTIVE LAST SCHEDULE AGE
pvc-volume-snapshot */1 * * * * False 0 39s 2m41s
Wait for BackupSession :
The pvc-volume-snapshot
CronJob will trigger a backup on each scheduled time slot by creating a BackupSession
crd.
Wait for the next schedule for backup. Run the following command to watch BackupSession
crd,
$ watch -n 1 kubectl get backupsession -n demo
Every 1.0s: kubectl get backupsession -n demo suaas-appscode: Tue Jun 18 18:35:41 2019
NAME INVOKER-TYPE INVOKER-NAME PHASE AGE
pvc-volume-snapshot-1563186667 BackupConfiguration pvc-volume-snapshot Succeeded 1m32s
We can see above that the backup session has succeeded. Now, we are going to verify that the VolumeSnapshot
has been created and the snapshots has been stored in the respective backend.
Verify Volume Snapshot :
Once a BackupSession
crd is created, it creates volume snapshotter Job
. Then the Job
creates VolumeSnapshot
crd for the targeted PVC. The VolumeSnapshot
name follows the following pattern:
<PVC name>-<backup session creation timestamp in Unix epoch seconds>
Check that the VolumeSnapshot
has been created Successfully.
$ kubectl get volumesnapshot -n demo
NAME AGE
source-data-1563186667 1m30s
Let’s find out the actual snapshot name that will be saved in the Google Cloud by the following command,
kubectl get volumesnapshot source-data-1563186667 -n demo -o yaml
apiVersion: snapshot.storage.k8s.io/v1
kind: VolumeSnapshot
metadata:
creationTimestamp: "2019-07-15T10:31:09Z"
finalizers:
- snapshot.storage.kubernetes.io/volumesnapshot-protection
generation: 4
name: source-data-1563186667
namespace: demo
resourceVersion: "32098"
selfLink: /apis/snapshot.storage.k8s.io/v1/namespaces/demo/volumesnapshots/source-data-1563186667
uid: a8e8faeb-a6eb-11e9-9f3a-42010a800050
spec:
source:
persistentVolumeClaimName: source-data
volumeSnapshotClassName: default-snapshot-class
status:
boundVolumeSnapshotContentName: snapcontent-a8e8faeb-a6eb-11e9-9f3a-42010a800050
creationTime: "2019-07-15T10:31:10Z"
readyToUse: true
restoreSize: 1Gi
Here, spec.snapshotContentName
field specifies the name of the VolumeSnapshotContent
crd. It also represents the actual snapshot name that has been saved in Google Cloud. If we navigate to the Snapshots
tab in the GCP console, we are going to see snapshot snapcontent-a8e8faeb-a6eb-11e9-9f3a-42010a800050
has been stored successfully.
Restore PVC from VolumeSnapshot
This section will show you how to restore the PVC from the snapshot we have taken in the earlier section.
Stop Taking Backup of the Old PVC:
At first, let’s stop taking any further backup of the old PVC so that no backup is taken during the restore process. We are going to pause the BackupConfiguration
that we created to backup the source-data
PVC. Then, Stash will stop taking any further backup for this PVC. You can learn more how to pause a scheduled backup here
Let’s pause the pvc-volume-snapshot
BackupConfiguration,
$ kubectl patch backupconfiguration -n demo pvc-volume-snapshot --type="merge" --patch='{"spec": {"paused": true}}'
backupconfiguration.stash.appscode.com/pvc-volume-snapshot patched
Now, wait for a moment. Stash will pause the BackupConfiguration. Verify that the BackupConfiguration has been paused,
$ kubectl get backupconfiguration -n demo
NAME TASK SCHEDULE PAUSED AGE
pvc-volume-snapshot */1 * * * * true 22m
Notice the PAUSED
column. Value true
for this field means that the BackupConfiguration has been paused.
Create RestoreSession :
At first, we have to create a RestoreSession
crd to restore the PVC from respective snapshot.
Below is the YAML of the RestoreSesion crd that we are going to create,
apiVersion: stash.appscode.com/v1beta1
kind: RestoreSession
metadata:
name: restore-pvc
namespace: demo
spec:
driver: VolumeSnapshotter
target:
volumeClaimTemplates:
- metadata:
name: restore-data
spec:
accessModes: [ "ReadWriteOnce" ]
storageClassName: "standard"
resources:
requests:
storage: 1Gi
dataSource:
kind: VolumeSnapshot
name: source-data-1563186667
apiGroup: snapshot.storage.k8s.io
Here,
spec.target.volumeClaimTemplates
:metadata.name
is the name of the restoredPVC
or prefix of theVolumeSnapshot
name.spec.dataSource
:spec.dataSource
specifies the source of the data from where the newly created PVC will be initialized. It requires following fields to be set:apiGroup
is the group for resource being referenced. Now, Kubernetes supports onlysnapshot.storage.k8s.io
.kind
is resource of the kind being referenced. Now, Kubernetes supports onlyVolumeSnapshot
.name
is theVolumeSnapshot
resource name. InRestoreSession
crd, You must set the VolumeSnapshot name directly.
Let’s create the RestoreSession
crd we have shown above.
$ kubectl create -f ./docs/examples/guides/latest/volumesnapshot/standalone-pvc/restoresession.yaml
restoresession.stash.appscode.com/restore-pvc created
Once, you have created the RestoreSession
crd, Stash will create a job to restore. We can watch the RestoreSession
phase to check if the restore process has succeeded or not.
Run the following command to watch RestoreSession phase,
$ watch -n 1 kubectl get restore -n demo
Every 1.0s: kubectl get restore -n demo suaas-appscode: Tue Jun 18 19:32:35 2019
NAME REPOSITORY-NAME PHASE AGE
restore-pvc Running 10s
restore-pvc Succeeded 1m
Verify Restored PVC :
Once the restore process is complete, we are going to see that new PVC with the name restore-data
has been created.
To verify that the PVC has been created, run by the following command,
$ kubectl get pvc -n demo
NAME STATUS VOLUME CAPACITY ACCESS MODES STORAGECLASS AGE
restore-data Bound pvc-c5f0e7f5-a6ec-11e9-9f3a-42010a800050 1Gi RWO standard 52s
Notice the STATUS
field. It indicates that the respective PV has been provisioned and initialized from the respective VolumeSnapshot by CSI driver and the PVC has been bound with the PV.
The volumeBindingMode field controls when volume binding and dynamic provisioning should occur. Kubernetes allows
Immediate
andWaitForFirstConsumer
modes for binding volumes. TheImmediate
mode indicates that volume binding and dynamic provisioning occurs once the PVC is created andWaitForFirstConsumer
mode indicates that volume binding and provisioning does not occur until a pod is created that uses this PVC. By defaultvolumeBindingMode
isImmediate
.
If you use
volumeBindingMode: WaitForFirstConsumer
, respective PVC will be initialized from respective VolumeSnapshot after you create a workload with that PVC. In this case, Stash will mark the restore session as completed with phaseUnknown
.
Verify Restored Data :
We are going to create a new pod with the restored PVC to verify whether the backed up data has been restored.
Below, the YAML for the Pod we are going to create.
apiVersion: v1
kind: Pod
metadata:
name: restored-pod
namespace: demo
spec:
containers:
- name: busybox
image: busybox
args:
- sleep
- "3600"
volumeMounts:
- name: restore-data
mountPath: /restore/data
volumes:
- name: restore-data
persistentVolumeClaim:
claimName: restore-data
readOnly: false
Let’s create the Pod we have shown above.
$ kubectl apply -f https://github.com/stashed/docs/raw/v2021.06.23/docs/examples/guides/latest/volumesnapshot/standalone-pvc/restored-pod.yaml
pod/restored-pod created
Now, wait for the Pod to go into the Running
state.
$ kubectl get pod -n demo
NAME READY STATUS RESTARTS AGE
restored-pod 1/1 Running 0 34s
Verify that the backed up data has been restored in /restore/data
directory for restored-pod
pod using the following command,
$ kubectl exec -n demo restored-pod -- cat /restore/data/data.txt
sample_data
Cleaning Up
To clean up the Kubernetes resources created by this tutorial, run:
kubectl delete -n demo pod source-pod
kubectl delete -n demo pod restored-pod
kubectl delete -n demo backupconfiguration pvc-volume-snapshot
kubectl delete -n demo restoresession restore-pvc
kubectl delete -n demo storageclass standard
kubectl delete -n demo volumesnapshotclass default-snapshot-class
kubectl delete -n demo pvc --all