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Using Stash with Rook Managed Ceph Storage
This guide will show you how to use Stash to backup and restore volumes of a Kubernetes workload in Rook managed Ceph storage. Here, we are going to backup a volume of a Deployment into AWS S3 compatible Ceph Object Storage. Then, we are going to show how to restore this volume into a PersistentVolumeClaim of Ceph Object Storage. We are going to also re-deploy deployment using this recovered volume.
Before You Begin
At first, you need to have a Kubernetes cluster. If you don’t already have a cluster, you can create one by using kind.
Install
Stash
in your cluster following the steps here.You should be familiar with the following
Stash
concepts:You will need a Rook deployment with Ceph Object Storage and Ceph Block Storage configured. If you do not already have a Rook Storage Service configured, you can create one by following this quickstart guide.
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/guides/platforms/rook/examples directory of stashed/doc repository.
Choosing StorageClass:
Ceph Block Storage allows mounting Rook storage into pod using a PersistentVolumeClaim. In order to do that, we have to create a PersistentVolumeClaim with rook-ceph-block
StorageClass. Verify the StorageClass exist by the following command:
$ kubectl get storageclass
NAME PROVISIONER AGE
rook-ceph-block ceph.rook.io/block 89m
standard (default) k8s.io/minikube-hostpath 104m
Backup the Volume of a Deployment
Here, we are going to deploy a Deployment with a PVC. This Deployment will automatically generate some sample data into the PVC. Then, we are going to backup this sample data using Stash.
Prepare Workload
At first, let’s deploy the workload whose volumes we are going to backup. Here, we are going create a PVC and deploy a Deployment with this PVC.
Create PVC:
Below is the YAML of the sample PVC that we are going to create,
kind: PersistentVolumeClaim
apiVersion: v1
metadata:
name: source-pvc
namespace: demo
spec:
accessModes:
- ReadWriteOnce
storageClassName: "rook-ceph-block"
resources:
requests:
storage: 1Gi
Let’s create the PVC we have shown above,
$ kubectl apply -f https://github.com/stashed/docs/raw/v2022.06.27/docs/guides/platforms/rook/examples/pvc.yaml
persistentvolumeclaim/source-pvc created
Deploy Deployment:
Now, we are going to deploy a Deployment that uses the above PVC. This Deployment will automatically generate sample data (data.txt
file) in /source/data
directory where we have mounted the PVC.
Below is the YAML of the Deployment that we are going to create,
apiVersion: apps/v1
kind: Deployment
metadata:
labels:
app: stash-demo
name: stash-demo
namespace: demo
spec:
replicas: 1
selector:
matchLabels:
app: stash-demo
template:
metadata:
labels:
app: stash-demo
name: busybox
spec:
containers:
- args: ["echo sample_data > /source/data/data.txt && sleep 3000"]
command: ["/bin/sh", "-c"]
image: busybox
imagePullPolicy: IfNotPresent
name: busybox
volumeMounts:
- mountPath: /source/data
name: source-data
restartPolicy: Always
volumes:
- name: source-data
persistentVolumeClaim:
claimName: source-pvc
strategy:
rollingUpdate:
maxSurge: "0%"
maxUnavailable: "100%"
Let’s create the Deployment we have shown above.
$ kubectl apply -f https://github.com/stashed/docs/raw/v2022.06.27/docs/guides/platforms/rook/examples/deployment.yaml
deployment.apps/stash-demo created
Now, wait for the pods of the Deployment to go into the Running
state.
$ kubectl get pod -n demo
NAME READY STATUS RESTARTS AGE
stash-demo-69f9ffbbf7-98lth 1/1 Running 0 13s
To verify that the sample data has been created in /source/data
directory, use the following command:
$ kubectl exec -n demo stash-demo-69f9ffbbf7-98lth -- cat /source/data/data.txt
sample_data
Prepare Backend
We are going to store our backed up data into an Ceph Storage Bucket. At first, we need to create a secret with the access credentials to our Ceph storage bucket. Then, we have to create a Repository
crd that will hold the information about our backend storage. If you want to use a different backend, please read the respective backend configuration doc from here.
Create Secret:
Let’s create a secret called rook-secret
with access credentials to our desired Ceph Storage Bucket,
$ echo -n 'changeit' > RESTIC_PASSWORD
$ echo -n '<your-rook-access-key-here>' > AWS_ACCESS_KEY_ID
$ echo -n '<your-rook-secret-key-here>' > AWS_SECRET_ACCESS_KEY
$ kubectl create secret generic -n demo rook-secret \
--from-file=./RESTIC_PASSWORD \
--from-file=./AWS_ACCESS_KEY_ID \
--from-file=./AWS_SECRET_ACCESS_KEY
secret/rook-secret created
Verify that the secret has been created successfully,
$ kubectl get secret -n demo rook-secret -o yaml
apiVersion: v1
data:
AWS_ACCESS_KEY_ID: Tk5HTkcwUVowS1lVOEhKMEFQVEQ=
AWS_SECRET_ACCESS_KEY: alExVHJFNU9oa2QzUEk0QzlQbkYwTjVaV0hvd2Yycm9BS2U1MEVsdA==
RESTIC_PASSWORD: Y2hhbmdlaXQ=
kind: Secret
metadata:
creationTimestamp: "2019-07-25T10:34:25Z"
name: rook-secret
namespace: demo
resourceVersion: "43037"
selfLink: /api/v1/namespaces/demo/secrets/rook-secret
uid: 49f412a4-f1e7-4eb1-92f5-49c0a96cc18d
type: Opaque
Create Repository:
Now, let’s create a Repository
with the information of our desired Ceph storage bucket. Below is the YAML of Repository
crd we are going to create,
apiVersion: stash.appscode.com/v1alpha1
kind: Repository
metadata:
name: rook-repo
namespace: demo
spec:
backend:
s3:
endpoint: 'http://rook-ceph-rgw-my-store-external.rook-ceph.svc'
bucket: rook-bucket
prefix: /source/data
storageSecretName: rook-secret
Let’s create the Repository
we have shown above,
$ kubectl apply -f https://github.com/stashed/docs/raw/v2022.06.27/docs/guides/platforms/rook/examples/repository.yaml
repository.stash.appscode.com/rook-repo created
Now, we are ready to backup our sample data into this backend.
Backup
We have to create a BackupConfiguration
crd targeting the stash-demo
Deployment that we have deployed earlier. Stash will inject a sidecar container into the target. It will also create a CronJob
to take a periodic backup of /source/data
directory of the target.
Create BackupConfiguration:
Below is the YAML of the BackupConfiguration
crd that we are going to create,
apiVersion: stash.appscode.com/v1beta1
kind: BackupConfiguration
metadata:
name: deployment-backup
namespace: demo
spec:
repository:
name: rook-repo
schedule: "*/5 * * * *"
target:
ref:
apiVersion: apps/v1
kind: Deployment
name: stash-demo
volumeMounts:
- name: source-data
mountPath: /source/data
paths:
- /source/data
retentionPolicy:
name: 'keep-last-5'
keepLast: 5
prune: true
Here,
spec.repository
refers to theRepository
objectrook-repo
that holds backend information.spec.target.ref
refers to thestash-demo
Deployment for backup target.spec.target.volumeMounts
specifies a list of volumes and their mountPath that contain the target paths.spec.target.paths
specifies list of file paths to backup.
Let’s create the BackupConfiguration
crd we have shown above,
$ kubectl apply -f https://github.com/stashed/docs/raw/v2022.06.27/docs/guides/platforms/rook/examples/backupconfiguration.yaml
backupconfiguration.stash.appscode.com/deployment-backup created
Verify Sidecar:
If everything goes well, Stash will inject a sidecar container into the stash-demo
Deployment to take backup of /source/data
directory. Let’s check that the sidecar has been injected successfully,
$ kubectl get pod -n demo
NAME READY STATUS RESTARTS AGE
stash-demo-76d78d8966-nbkrl 2/2 Running 0 39s
Look at the pod. It now has 2 containers. If you view the resource definition of this pod, you will see that there is a container named stash
which is running run-backup
command.
$ kubectl get pod -n demo stash-demo-76d78d8966-nbkrl -o yaml
apiVersion: v1
kind: Pod
metadata:
generateName: stash-demo-76d78d8966-
labels:
app: stash-demo
pod-template-hash: 76d78d8966
name: stash-demo-76d78d8966-nbkrl
namespace: demo
...
spec:
containers:
- args:
- echo sample_data > /source/data/data.txt && sleep 3000
command:
- /bin/sh
- -c
image: busybox
imagePullPolicy: IfNotPresent
name: busybox
resources: {}
terminationMessagePath: /dev/termination-log
terminationMessagePolicy: File
volumeMounts:
- mountPath: /source/data
name: source-data
- mountPath: /var/run/secrets/kubernetes.io/serviceaccount
name: default-token-2njxz
readOnly: true
- args:
- run-backup
- --backup-configuration=deployment-backup
- --secret-dir=/etc/stash/repository/secret
- --enable-cache=true
- --max-connections=0
- --metrics-enabled=true
- --pushgateway-url=http://stash-operator.kube-system.svc:56789
- --enable-status-subresource=true
- --use-kubeapiserver-fqdn-for-aks=true
- --logtostderr=true
- --alsologtostderr=false
- --v=3
- --stderrthreshold=0
env:
- name: NODE_NAME
valueFrom:
fieldRef:
apiVersion: v1
fieldPath: spec.nodeName
- name: POD_NAME
valueFrom:
fieldRef:
apiVersion: v1
fieldPath: metadata.name
image: suaas21/stash:volumeTemp_linux_amd64
imagePullPolicy: IfNotPresent
name: stash
resources: {}
terminationMessagePath: /dev/termination-log
terminationMessagePolicy: File
volumeMounts:
- mountPath: /etc/stash
name: stash-podinfo
- mountPath: /etc/stash/repository/secret
name: stash-secret-volume
- mountPath: /tmp
name: tmp-dir
- mountPath: /source/data
name: source-data
- mountPath: /var/run/secrets/kubernetes.io/serviceaccount
name: default-token-2njxz
readOnly: true
dnsPolicy: ClusterFirst
enableServiceLinks: true
nodeName: minikube
priority: 0
restartPolicy: Always
schedulerName: default-scheduler
securityContext: {}
serviceAccount: default
serviceAccountName: default
terminationGracePeriodSeconds: 30
tolerations:
- effect: NoExecute
key: node.kubernetes.io/not-ready
operator: Exists
tolerationSeconds: 300
- effect: NoExecute
key: node.kubernetes.io/unreachable
operator: Exists
tolerationSeconds: 300
volumes:
- name: source-data
persistentVolumeClaim:
claimName: source-pvc
- emptyDir: {}
name: tmp-dir
- downwardAPI:
defaultMode: 420
items:
- fieldRef:
apiVersion: v1
fieldPath: metadata.labels
path: labels
name: stash-podinfo
- name: stash-secret-volume
secret:
defaultMode: 420
secretName: rook-secret
- name: default-token-2njxz
secret:
defaultMode: 420
secretName: default-token-2njxz
...
...
Verify CronJob:
It will also create a CronJob
with the schedule specified in spec.schedule
field of BackupConfiguration
crd.
Verify that the CronJob
has been created using the following command,
$ kubectl get cronjob -n demo
NAME SCHEDULE SUSPEND ACTIVE LAST SCHEDULE AGE
deployment-backup */1 * * * * False 0 13s 1m50s
Wait for BackupSession:
The deployment-backup
CronJob will trigger a backup on each schedule by creating a BackupSession
crd. The sidecar container will watch for the BackupSession
crd. When it finds one, it will take backup immediately.
Wait for the next schedule for backup. Run the following command to watch BackupSession
crd,
$ watch -n 3 kubectl get backupsession -n demo
Every 3.0s: kubectl get backupsession -n demo suaas-appscode: Mon Jul 22 15:01:21 2019
NAME INVOKER-TYPE INVOKER-NAME PHASE AGE
deployment-backup-1663786062 BackupConfiguration deployment-backup Succeeded 21s
We can see from the above output that the backup session has succeeded. Now, we are going to verify whether the backed up data has been stored in the backend.
Verify Backup:
Once a backup is complete, Stash will update the respective Repository
crd to reflect the backup. Check that the repository rook-repo
has been updated by the following command,
$ kubectl get repository -n demo
NAME INTEGRITY SIZE SNAPSHOT-COUNT LAST-SUCCESSFUL-BACKUP AGE
rook-repo true 30 B 2 3m10s 5m20s
Here, BACKUPCOUNT
field indicates the number of backup snapshots has taken in this repository.
Restore the Backed up Data
This section will show you how to restore the backed up data from Ceph Storage Bucket we have taken in the earlier section.
Stop Taking Backup of the Old Deployment:
At first, let’s stop taking any further backup of the old Deployment so that no backup is taken during the restore process. We are going to pause the BackupConfiguration
that we created to backup the stash-demo
Deployment. Then, Stash will stop taking any further backup for this Deployment. You can learn more how to pause a scheduled backup here
Let’s pause the deployment-backup
BackupConfiguration,
$ kubectl patch backupconfiguration -n demo deployment-backup --type="merge" --patch='{"spec": {"paused": true}}'
backupconfiguration.stash.appscode.com/deployment-backup 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
deployment-backup */1 * * * * true 26m
Notice the PAUSED
column. Value true
for this field means that the BackupConfiguration has been paused.
Deploy Deployment:
We are going to create a new Deployment named stash-recovered
with a new PVC and restore the backed up data inside it.
Below are the YAMLs of the Deployment and PVC that we are going to create,
apiVersion: v1
kind: PersistentVolumeClaim
metadata:
name: restore-pvc
namespace: demo
spec:
accessModes:
- ReadWriteOnce
storageClassName: "rook-ceph-block"
resources:
requests:
storage: 1Gi
---
apiVersion: apps/v1
kind: Deployment
metadata:
labels:
app: stash-recovered
name: stash-recovered
namespace: demo
spec:
replicas: 1
selector:
matchLabels:
app: stash-recovered
template:
metadata:
labels:
app: stash-recovered
name: busybox
spec:
containers:
- args:
- sleep
- "3600"
image: busybox
imagePullPolicy: IfNotPresent
name: busybox
volumeMounts:
- mountPath: /restore/data
name: restore-data
restartPolicy: Always
volumes:
- name: restore-data
persistentVolumeClaim:
claimName: restore-pvc
strategy:
rollingUpdate:
maxSurge: "0%"
maxUnavailable: "100%"
Let’s create the Deployment and PVC we have shown above.
$ kubectl apply -f https://github.com/stashed/docs/raw/v2022.06.27/docs/guides/platforms/rook/examples/recovered_deployment.yaml
persistentvolumeclaim/restore-pvc created
deployment.apps/stash-recovered created
Create RestoreSession:
Now, we need to create a RestoreSession
crd targeting the stash-recovered
Deployment.
Below is the YAML of the RestoreSesion
crd that we are going to create,
apiVersion: stash.appscode.com/v1beta1
kind: RestoreSession
metadata:
name: deployment-restore
namespace: demo
spec:
repository:
name: rook-repo
target: # target indicates where the recovered data will be stored
ref:
apiVersion: apps/v1
kind: Deployment
name: stash-recovered
volumeMounts:
- name: restore-data
mountPath: /source/data
rules:
- paths:
- /source/data/
Here,
spec.repository.name
specifies theRepository
crd that holds the backend information where our backed up data has been stored.spec.target.ref
refers to the target workload where the recovered data will be stored.spec.target.volumeMounts
specifies a list of volumes and their mountPath where the data will be restored.mountPath
must be samemountPath
as the original volume because Stash stores absolute path of the backed up files. If you use differentmountPath
for the restored volume the backed up files will not be restored into your desired volume.
Let’s create the RestoreSession
crd we have shown above,
$ kubectl apply -f https://github.com/stashed/docs/raw/v2022.06.27/docs/guides/platforms/rook/examples/restoresession.yaml
restoresession.stash.appscode.com/deployment-restore created
Once, you have created the RestoreSession
crd, Stash will inject init-container
into stash-recovered
Deployment. The Deployment will restart and the init-container
will restore the desired data on start-up.
Verify Init-Container:
Wait until the init-container
has been injected into the stash-recovered
Deployment. Let’s describe the Deployment to verify that init-container
has been injected successfully.
$ kubectl describe deployment -n demo stash-recovered
Name: stash-recovered
Namespace: demo
CreationTimestamp: Thu, 25 Jul 2019 19:14:18 +0600
Labels: app=stash-recovered
Selector: app=stash-recovered
Replicas: 1 desired | 1 updated | 1 total | 1 available | 0 unavailable
StrategyType: RollingUpdate
MinReadySeconds: 0
RollingUpdateStrategy: 100% max unavailable, 0% max surge
...
Pod Template:
Labels: app=stash-recovered
Annotations: stash.appscode.com/last-applied-restoresession-hash: 10604314699482840900
Init Containers:
stash-init:
Image: suaas21/stash:volumeTemp_linux_amd64
Port: <none>
Host Port: <none>
Args:
restore
--restore-session=deployment-restore
--secret-dir=/etc/stash/repository/secret
--enable-cache=true
--max-connections=0
--metrics-enabled=true
--pushgateway-url=http://stash-operator.kube-system.svc:56789
--enable-status-subresource=true
--use-kubeapiserver-fqdn-for-aks=true
--logtostderr=true
--alsologtostderr=false
--v=3
--stderrthreshold=0
Environment:
NODE_NAME: (v1:spec.nodeName)
POD_NAME: (v1:metadata.name)
Mounts:
/etc/stash/repository/secret from stash-secret-volume (rw)
/source/data from restore-data (rw)
/tmp from tmp-dir (rw)
Containers:
busybox:
Image: busybox
Port: <none>
Host Port: <none>
Args:
sleep
3600
Environment: <none>
Mounts:
/restore/data from restore-data (rw)
Volumes:
restore-data:
Type: PersistentVolumeClaim (a reference to a PersistentVolumeClaim in the same namespace)
ClaimName: restore-pvc
ReadOnly: false
tmp-dir:
Type: EmptyDir (a temporary directory that shares a pod's lifetime)
Medium:
SizeLimit: <unset>
stash-podinfo:
Type: DownwardAPI (a volume populated by information about the pod)
Items:
metadata.labels -> labels
stash-secret-volume:
Type: Secret (a volume populated by a Secret)
SecretName: rook-secret
Optional: false
...
Notice the Init-Containers
section. We can see that the init-container stash-init
has been injected which is running restore
command.
Wait for RestoreSession to Succeeded:
Now, wait for the restore process to complete. You can watch the RestoreSession
phase using the following command,
$ watch -n 2 kubectl get restoresession -n demo
Every 3.0s: kubectl get restoresession --all-namespaces suaas-appscode: Mon Jul 28 18:17:22 2019
NAMESPACE NAME REPOSITORY-NAME PHASE AGE
demo deployment-restore rook-repo Succeeded 100s
So, we can see from the output of the above command that the restore process has succeeded.
Note: If you want to restore the backed up data inside the same Deployment whose volumes were backed up, you have to remove the corrupted data from the Deployment. Then, you have to create a RestoreSession targeting the Deployment.
Verify Restored Data:
In this section, we are going to verify that the desired data has been restored successfully. At first, check if the stash-recovered
pod of the Deployment has gone into Running
state by the following command,
$ kubectl get pod -n demo
NAME READY STATUS RESTARTS AGE
stash-recovered-5c59587895-76tsx 1/1 Running 0 73s
Verify that the sample data has been restored in /restore/data
directory of the stash-recovered
pod of the Deployment using the following command,
$ kubectl exec -n demo stash-recovered-5c59587895-76tsx -- cat /restore/data/data.txt
sample_data
Cleaning Up
To clean up the Kubernetes resources created by this tutorial, run:
kubectl delete -n demo deployment stash-demo
kubectl delete -n demo deployment stash-recovered
kubectl delete -n demo backupconfiguration deployment-backup
kubectl delete -n demo restoresession deployment-restore
kubectl delete -n demo repository rook-repo
kubectl delete -n demo secret rook-secret
kubectl delete -n demo pvc --all