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Add documenation for Disaster Recovery which steps to Failover and Failback in case of a planned migration or a Disaster. Signed-off-by: Yug Gupta <yuggupta27@gmail.com>
410 lines
15 KiB
Markdown
410 lines
15 KiB
Markdown
# Failover and Failback In Disaster Recovery
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[RBD mirroring](https://docs.ceph.com/en/latest/rbd/rbd-mirroring/)
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is an asynchronous replication of RBD images between multiple Ceph clusters.
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This capability is available in two modes:
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* Journal-based: Every write to the RBD image is first recorded
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to the associated journal before modifying the actual image.
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The remote cluster will read from this associated journal and
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replay the updates to its local image.
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* Snapshot-based: This mode uses periodically scheduled or
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manually created RBD image mirror-snapshots to replicate
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crash-consistent RBD images between clusters.
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This documentation assumes that `rbd mirroring` is set up between
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two clusters.
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For more information on how to set up rbd mirroring, refer to
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[ceph documentation](https://docs.ceph.com/en/latest/rbd/rbd-mirroring/).
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## Deploy the Volume Replication CRD
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Volume Replication Operator is a kubernetes operator that provides common
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and reusable APIs for storage disaster recovery.
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It is based on [csi-addons/spec](https://github.com/csi-addons/spec)
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specification and can be used by any storage provider.
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Volume Replication Operator follows controller pattern and provides
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extended APIs for storage disaster recovery.
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The extended APIs are provided via Custom Resource Definition (CRD).
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>:bulb: For more information, please refer to the
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> [volume-replication-operator](https://github.com/csi-addons/volume-replication-operator).
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* Deploy the `VolumeReplicationClass` CRD
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```bash
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kubectl create -f https://raw.githubusercontent.com/csi-addons/volume-replication-operator/release-v0.1/config/crd/bases/replication.storage.openshift.io_volumereplicationclasses.yaml
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customresourcedefinition.apiextensions.k8s.io/volumereplicationclasses.replication.storage.openshift.io created
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```
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* Deploy the `VolumeReplication` CRD
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```bash
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kubectl create -f https://raw.githubusercontent.com/csi-addons/volume-replication-operator/release-v0.1/config/crd/bases/replication.storage.openshift.io_volumereplications.yaml
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customresourcedefinition.apiextensions.k8s.io/volumereplications.replication.storage.openshift.io created created
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```
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The VolumeReplicationClass and VolumeReplication CRDs are now created.
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>:bulb: **Note:** Use the latest available release for Volume Replication Operator.
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> See [releases](https://github.com/csi-addons/volume-replication-operator/branches)
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> for more information.
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### Add RBAC rules for Volume Replication Operator
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Add the below mentioned rules to `rbd-external-provisioner-runner`
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ClusterRole in [csi-provisioner-rbac.yaml](https://github.com/ceph/ceph-csi/blob/release-v3.3/deploy/rbd/kubernetes/csi-provisioner-rbac.yaml)
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```yaml
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- apiGroups: ["replication.storage.openshift.io"]
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resources: ["volumereplications", "volumereplicationclasses"]
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verbs: ["create", "delete", "get", "list", "patch", "update", "watch"]
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- apiGroups: ["replication.storage.openshift.io"]
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resources: ["volumereplications/finalizers"]
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verbs: ["update"]
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- apiGroups: ["replication.storage.openshift.io"]
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resources: ["volumereplications/status"]
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verbs: ["get", "patch", "update"]
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- apiGroups: ["replication.storage.openshift.io"]
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resources: ["volumereplicationclasses/status"]
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verbs: ["get"]
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```
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### Deploy the Volume Replication Sidecar
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To deploy `volume-replication` sidecar container in `csi-rbdplugin-provisioner`
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pod, add the following yaml to
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[csi-rbdplugin-provisioner deployment](https://github.com/ceph/ceph-csi/blob/release-v3.3/deploy/rbd/kubernetes/csi-rbdplugin-provisioner.yaml).
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```yaml
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- name: volume-replication
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image: quay.io/csiaddons/volumereplication-operator:v0.1.0
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args :
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- "--metrics-bind-address=0"
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- "--leader-election-namespace=$(NAMESPACE)"
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- "--driver-name=rbd.csi.ceph.com"
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- "--csi-address=$(ADDRESS)"
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- "--rpc-timeout=150s"
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- "--health-probe-bind-address=:9998"
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- "--leader-elect=true"
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env:
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- name: ADDRESS
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value: unix:///csi/csi-provisioner.sock
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- name: NAMESPACE
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valueFrom:
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fieldRef:
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fieldPath: metadata.namespace
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imagePullPolicy: "IfNotPresent"
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volumeMounts:
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- name: socket-dir
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mountPath: /csi
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```
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## VolumeReplicationClass and VolumeReplication
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### VolumeReplicationClass
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*VolumeReplicationClass* is a cluster scoped resource that contains
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driver related configuration parameters. It holds the storage admin
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information required for the volume replication operator.
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### VolumeReplication
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*VolumeReplication* is a namespaced resource that contains references
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to storage object to be replicated and VolumeReplicationClass
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corresponding to the driver providing replication.
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>:bulb: For more information, please refer to the
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> [volume-replication-operator](https://github.com/csi-addons/volume-replication-operator).
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Let's say we have a *PVC* (rbd-pvc) in BOUND state; created using
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*StorageClass* with `Retain` reclaimPolicy.
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```bash
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kubectl get pvc --context=cluster-1
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NAME STATUS VOLUME CAPACITY ACCESS MODES STORAGECLASS AGE
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rbd-pvc Bound pvc-65dc0aac-5e15-4474-90f4-7a3532c621ec 1Gi RWO csi-rbd-sc 44s
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```
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* Create Volume Replication Class on cluster-1
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```yaml
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$cat <<EOF | kubectl --context=cluster1 apply -f -
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apiVersion: replication.storage.openshift.io/v1alpha1
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kind: VolumeReplicationClass
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metadata:
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name: rbd-volumereplicationclass
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spec:
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provisioner: rbd.csi.ceph.com
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parameters:
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mirroringMode: snapshot
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schedulingInterval: "12m"
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schedulingStartTime: "16:18:43"
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replication.storage.openshift.io/replication-secret-name: csi-rbd-secret
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replication.storage.openshift.io/replication-secret-namespace: default
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EOF
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```
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>:bulb: **Note:** The `schedulingInterval` can be specified in formats of
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> minutes, hours or days using suffix `m`,`h` and `d` respectively.
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> The optional schedulingStartTime can be specified using the ISO 8601
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> time format.
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* Once VolumeReplicationClass is created,create a Volume Replication for
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the PVC which we intend to replicate to secondary cluster.
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```yaml
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$cat <<EOF | kubectl --context=cluster-1 apply -f -
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apiVersion: replication.storage.openshift.io/v1alpha1
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kind: VolumeReplication
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metadata:
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name: pvc-volumereplication
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spec:
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volumeReplicationClass: rbd-volumereplicationclass
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replicationState: primary
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dataSource:
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apiGroup: ""
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kind: PersistentVolumeClaim
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name: rbd-pvc # Name of the PVC to which mirroring to be enabled.
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EOF
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```
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>:memo: *VolumeReplication* is a namespace scoped object. Thus,
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> it should be created in the same namespace as of PVC.
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`replicationState` is the state of the volume being referenced.
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Possible values are primary, secondary, and resync.
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* `primary` denotes that the volume is primary.
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* `secondary` denotes that the volume is secondary.
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* `resync` denotes that the volume needs to be resynced.
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To check VolumeReplication CR status:
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```yaml
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kubectl get volumereplication pvc-volumereplication --context=cluster-1 -oyaml
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...
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spec:
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dataSource:
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apiGroup: ""
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kind: PersistentVolumeClaim
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name: rbd-pvc
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replicationState: primary
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volumeReplicationClass: rbd-volumereplicationclass
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status:
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conditions:
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- lastTransitionTime: "2021-05-04T07:39:00Z"
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message: ""
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observedGeneration: 1
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reason: Promoted
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status: "True"
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type: Completed
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- lastTransitionTime: "2021-05-04T07:39:00Z"
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message: ""
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observedGeneration: 1
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reason: Healthy
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status: "False"
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type: Degraded
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- lastTransitionTime: "2021-05-04T07:39:00Z"
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message: ""
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observedGeneration: 1
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reason: NotResyncing
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status: "False"
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type: Resyncing
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lastCompletionTime: "2021-05-04T07:39:00Z"
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lastStartTime: "2021-05-04T07:38:59Z"
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message: volume is marked primary
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observedGeneration: 1
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state: Primary
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```
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* Take a backup of PVC and PV object on primary cluster(cluster-1)
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* Take backup of the PVC `rbd-pvc`
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```bash
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kubectl get pvc rbd-pvc -oyaml >pvc-backup.yaml
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```
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* Take a backup of the PV, corresponding to the PVC
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```bash
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kubectl get pv/pvc-65dc0aac-5e15-4474-90f4-7a3532c621ec -oyaml >pv_backup.yaml
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```
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>:bulb: We can also take backup using external tools like **Velero**.
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> Refer [velero documentation]((https://velero.io/docs/main/)) for more information.
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* Restoring on the secondary cluster(cluster-2)
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* Create storageclass on the secondary cluster
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```bash
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kubectl create -f examples/rbd/storageclass.yaml --context=cluster-2
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storageclass.storage.k8s.io/csi-rbd-sc created
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```
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* Create VolumeReplicationClass on the secondary cluster
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```bash
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cat <<EOF | kubectl --context=cluster-2 apply -f -
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apiVersion: replication.storage.openshift.io/v1alpha1
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kind: VolumeReplicationClass
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metadata:
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name: rbd-volumereplicationclass
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spec:
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provisioner: rbd.csi.ceph.com
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parameters:
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mirroringMode: snapshot
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replication.storage.openshift.io/replication-secret-name: csi-rbd-secret
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replication.storage.openshift.io/replication-secret-namespace: default
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EOF
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volumereplicationclass.replication.storage.openshift.io/rbd-volumereplicationclass created
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```
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* If Persistent Volumes and Claims are created manually
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on the secondary cluster, remove the `claimRef` on the
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backed up PV objects in yaml files; so that the PV can
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get bound to the new claim on the secondary cluster.
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```yaml
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...
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spec:
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accessModes:
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- ReadWriteOnce
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capacity:
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storage: 1Gi
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claimRef:
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apiVersion: v1
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kind: PersistentVolumeClaim
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name: rbd-pvc
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namespace: default
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resourceVersion: "64252"
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uid: 65dc0aac-5e15-4474-90f4-7a3532c621ec
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csi:
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...
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```
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* Apply the Persistent Volume backup from the primary cluster
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```bash
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kubectl create -f pv-backup.yaml --context=cluster-2
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persistentvolume/pvc-65dc0aac-5e15-4474-90f4-7a3532c621ec created
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```
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* Apply the Persistent Volume claim from the restored backup
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```bash
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kubectl create -f pvc-backup.yaml --context=cluster-2
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persistentvolumeclaim/rbd-pvc created
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```
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```bash
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kubectl get pvc --context=cluster-2
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NAME STATUS VOLUME CAPACITY ACCESS MODES STORAGECLASS AGE
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rbd-pvc Bound pvc-65dc0aac-5e15-4474-90f4-7a3532c621ec 1Gi RWO csi-rbd-sc 44s
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```
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## Planned Migration
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> Use cases: Datacenter maintenance, Technology refresh, Disaster avoidance, etc.
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### Failover
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The failover operation is the process of switching production to a
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backup facility (normally your recovery site). In the case of Failover,
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access to the image on the primary site should be stopped.
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The image should now be made *primary* on the secondary cluster so that
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the access can be resumed there.
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:memo: As mentioned in the pre-requisites, periodic or one time backup of
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the application should be available for restore on the secondary site (cluster-b).
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Follow the below steps for planned migration of workload from primary
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cluster to secondary cluster:
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* Scale down all the application pods which are using the
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mirrored PVC on the Primary Cluster
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* Take a back up of PVC and PV object from the primary cluster.
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This can be done using some backup tools like
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[velero](https://velero.io/docs/main/).
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* Update `replicationState` to `secondary` in VolumeReplication CR at Primary Site.
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When the operator sees this change, it will pass the information down to the
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driver via GRPC request to mark the dataSource as `secondary`.
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* If you are manually recreating the PVC and PV on the secondary cluster,
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remove the `claimRef` section in the PV objects.
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* Recreate the storageclass, PVC, and PV objects on the secondary site.
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* As you are creating the static binding between PVC and PV, a new PV won’t
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be created here, the PVC will get bind to the existing PV.
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* Create the VolumeReplicationClass on the secondary site.
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* Create the VolumeReplications for all the PVC’s for which mirroring
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is enabled
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* `replicationState` should be `primary` for all the PVC’s on
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the secondary site.
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* Check whether the image is marked `primary` on the secondary site
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by verifying it in VolumeReplication CR status.
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* Once the Image is marked as `primary`, the PVC is now ready
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to be used. Now, we can scale up the applications to use the PVC.
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>:memo: **WARNING**: In Async Disaster recovery use case, we don't
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> get the complete data. We will only get the crash-consistent data
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> based on the snapshot interval time.
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### Failback
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To perform a failback operation to primary cluster in case of planned migration
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, just repeat the Failback steps in vice-versa.
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>:memo: **Remember**: We can skip the backup-restore operations
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> in case of failback if the required yamls are already present on
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> the primary cluster. Any new PVCs will still need to be restored on the
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> primary site.
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## Disaster Recovery
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> Use cases: Natural disasters, Power failures, System failures, and crashes, etc.
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### Failover (abrupt shutdown)
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In case of Disaster recovery, create VolumeReplication CR at the Secondary Site.
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Since the connection to the Primary Site is lost, the operator automatically
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sends a GRPC request down to the driver to forcefully mark the dataSource as `primary`.
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* If you are manually creating the PVC and PV on the secondary cluster, remove
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the claimRef section in the PV objects.
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* Create the storageclass, PVC, and PV objects on the secondary site.
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* As you are creating the static binding between PVC and PV, a new PV won’t be
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created here, the PVC will get bind to the existing PV.
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* Create the VolumeReplicationClass and VolumeReplication CR on the secondary site.
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* Check whether the image is `primary` on secondary site, by verifying in
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the VolumeReplication CR status.
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* Once the Image is marked as `primary`, the PVC is now ready to be used. Now,
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we can scale up the applications to use the PVC.
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### Failback (post-disaster recovery)
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Once the failed cluster is recovered on the primary site and you want to failback
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from secondary site, follow the below steps:
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* Update the VolumeReplication CR replicationState
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from `primary` to `secondary` on the primary site.
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* Scale down the applications on the secondary site.
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* Update the VolumeReplication CR replicationState from `primary` to
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`secondary` in secondary site.
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* On the primary site, verify that the VolumeReplication status is marked as
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volume ready to use
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* Once the volume is marked to ready to use, change the replicationState state
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from `secondary` to `primary` in primary site.
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* Scale up the applications again on the primary site.
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