============================== Block Devices and Kubernetes ============================== You may use Ceph Block Device images with Kubernetes v1.13 and later through `ceph-csi`_, which dynamically provisions RBD images to back Kubernetes `volumes`_ and maps these RBD images as block devices (optionally mounting a file system contained within the image) on worker nodes running `pods`_ that reference an RBD-backed volume. Ceph stripes block device images as objects across the cluster, which means that large Ceph Block Device images have better performance than a standalone server! To use Ceph Block Devices with Kubernetes v1.13 and higher, you must install and configure ``ceph-csi`` within your Kubernetes environment. The following diagram depicts the Kubernetes/Ceph technology stack. .. ditaa:: +---------------------------------------------------+ | Kubernetes | +---------------------------------------------------+ | ceph--csi | +------------------------+--------------------------+ | | configures v +------------------------+ +------------------------+ | | | rbd--nbd | | Kernel Modules | +------------------------+ | | | librbd | +------------------------+-+------------------------+ | RADOS Protocol | +------------------------+-+------------------------+ | OSDs | | Monitors | +------------------------+ +------------------------+ .. important:: ``ceph-csi`` uses the RBD kernel modules by default which may not support all Ceph `CRUSH tunables`_ or `RBD image features`_. Create a Pool ============= By default, Ceph block devices use the ``rbd`` pool. Create a pool for Kubernetes volume storage. Ensure your Ceph cluster is running, then create the pool. :: $ ceph osd pool create kubernetes See `Create a Pool`_ for details on specifying the number of placement groups for your pools, and `Placement Groups`_ for details on the number of placement groups you should set for your pools. A newly created pool must be initialized prior to use. Use the ``rbd`` tool to initialize the pool:: $ rbd pool init kubernetes Configure ceph-csi ================== Setup Ceph Client Authentication -------------------------------- Create a new user for Kubernetes and `ceph-csi`. Execute the following and record the generated key:: $ ceph auth get-or-create client.kubernetes mon 'profile rbd' osd 'profile rbd pool=kubernetes' mgr 'profile rbd pool=kubernetes' [client.kubernetes] key = AQD9o0Fd6hQRChAAt7fMaSZXduT3NWEqylNpmg== Generate `ceph-csi` `ConfigMap` ------------------------------- The `ceph-csi` requires a `ConfigMap` object stored in Kubernetes to define the the Ceph monitor addresses for the Ceph cluster. Collect both the Ceph cluster unique `fsid` and the monitor addresses:: $ ceph mon dump <...> fsid b9127830-b0cc-4e34-aa47-9d1a2e9949a8 <...> 0: [v2:192.168.1.1:3300/0,v1:192.168.1.1:6789/0] mon.a 1: [v2:192.168.1.2:3300/0,v1:192.168.1.2:6789/0] mon.b 2: [v2:192.168.1.3:3300/0,v1:192.168.1.3:6789/0] mon.c .. note:: ``ceph-csi`` currently only supports the `legacy V1 protocol`_. Generate a `csi-config-map.yaml` file similar to the example below, substituting the `fsid` for "clusterID", and the monitor addresses for "monitors":: $ cat < csi-config-map.yaml --- apiVersion: v1 kind: ConfigMap data: config.json: |- [ { "clusterID": "b9127830-b0cc-4e34-aa47-9d1a2e9949a8", "monitors": [ "192.168.1.1:6789", "192.168.1.2:6789", "192.168.1.3:6789" ] } ] metadata: name: ceph-csi-config EOF Once generated, store the new `ConfigMap` object in Kubernetes:: $ kubectl apply -f csi-config-map.yaml Generate `ceph-csi` cephx `Secret` ---------------------------------- `ceph-csi` requires the cephx credentials for communicating with the Ceph cluster. Generate a `csi-rbd-secret.yaml` file similar to the example below, using the newly created Kubernetes user id and cephx key:: $ cat < csi-rbd-secret.yaml --- apiVersion: v1 kind: Secret metadata: name: csi-rbd-secret namespace: default stringData: userID: kubernetes userKey: AQD9o0Fd6hQRChAAt7fMaSZXduT3NWEqylNpmg== EOF Once generated, store the new `Secret` object in Kubernetes:: $ kubectl apply -f csi-rbd-secret.yaml Configure `ceph-csi` Plugins ---------------------------- Create the required `ServiceAccount` and RBAC `ClusterRole`/`ClusterRoleBinding` Kubernetes objects. These objects do not necessarily need to be customized for your Kubernetes environment and therefore can be used as-is from the `ceph-csi` deployment YAMLs:: $ kubectl apply -f https://raw.githubusercontent.com/ceph/ceph-csi/master/deploy/rbd/kubernetes/csi-provisioner-rbac.yaml $ kubectl apply -f https://raw.githubusercontent.com/ceph/ceph-csi/master/deploy/rbd/kubernetes/csi-nodeplugin-rbac.yaml Finally, create the `ceph-csi` provisioner and node plugins. With the possible exception of the `ceph-csi` container release version, these objects do not necessarily need to be customized for your Kubernetes environment and therefore can be used as-is from the `ceph-csi` deployment YAMLs:: $ wget https://raw.githubusercontent.com/ceph/ceph-csi/master/deploy/rbd/kubernetes/csi-rbdplugin-provisioner.yaml $ kubectl apply -f csi-rbdplugin-provisioner.yaml $ wget https://raw.githubusercontent.com/ceph/ceph-csi/master/deploy/rbd/kubernetes/csi-rbdplugin.yaml $ kubectl apply -f csi-rbdplugin.yaml .. important:: The provisioner and node plugin YAMLs will, by default, pull the development release of the `ceph-csi` container (quay.io/cephcsi/cephcsi:canary). The YAMLs should be updated to use a release version container for production workloads. Using Ceph Block Devices ======================== Create a `StorageClass` ----------------------- The Kubernetes `StorageClass` defines a class of storage. Multiple `StorageClass` objects can be created to map to different quality-of-service levels (i.e. NVMe vs HDD-based pools) and features. For example, to create a `ceph-csi` `StorageClass` that maps to the `kubernetes` pool created above, the following YAML file can be used after ensuring that the "clusterID" property matches your Ceph cluster's `fsid`:: $ cat < csi-rbd-sc.yaml --- apiVersion: storage.k8s.io/v1 kind: StorageClass metadata: name: csi-rbd-sc provisioner: rbd.csi.ceph.com parameters: clusterID: b9127830-b0cc-4e34-aa47-9d1a2e9949a8 pool: kubernetes csi.storage.k8s.io/provisioner-secret-name: csi-rbd-secret csi.storage.k8s.io/provisioner-secret-namespace: default csi.storage.k8s.io/node-stage-secret-name: csi-rbd-secret csi.storage.k8s.io/node-stage-secret-namespace: default reclaimPolicy: Delete mountOptions: - discard EOF $ kubectl apply -f csi-rbd-sc.yaml Create a `PersistentVolumeClaim` -------------------------------- A `PersistentVolumeClaim` is a request for abstract storage resources by a user. The `PersistentVolumeClaim` would then be associated to a `Pod` resource to provision a `PersistentVolume`, which would be backed by a Ceph block image. An optional `volumeMode` can be included to select between a mounted file system (default) or raw block device-based volume. Using `ceph-csi`, specifying `Filesystem` for `volumeMode` can support both `ReadWriteOnce` and `ReadOnlyMany` `accessMode` claims, and specifying `Block` for `volumeMode` can support `ReadWriteOnce`, `ReadWriteMany`, and `ReadOnlyMany` `accessMode` claims. For example, to create a block-based `PersistentVolumeClaim` that utilizes the `ceph-csi`-based `StorageClass` created above, the following YAML can be used to request raw block storage from the `csi-rbd-sc` `StorageClass`:: $ cat < raw-block-pvc.yaml --- apiVersion: v1 kind: PersistentVolumeClaim metadata: name: raw-block-pvc spec: accessModes: - ReadWriteOnce volumeMode: Block resources: requests: storage: 1Gi storageClassName: csi-rbd-sc EOF $ kubectl apply -f raw-block-pvc.yaml The following demonstrates and example of binding the above `PersistentVolumeClaim` to a `Pod` resource as a raw block device:: $ cat < raw-block-pod.yaml --- apiVersion: v1 kind: Pod metadata: name: pod-with-raw-block-volume spec: containers: - name: fc-container image: fedora:26 command: ["/bin/sh", "-c"] args: ["tail -f /dev/null"] volumeDevices: - name: data devicePath: /dev/xvda volumes: - name: data persistentVolumeClaim: claimName: raw-block-pvc EOF $ kubectl apply -f raw-block-pod.yaml To create a file-system-based `PersistentVolumeClaim` that utilizes the `ceph-csi`-based `StorageClass` created above, the following YAML can be used to request a mounted file system (backed by an RBD image) from the `csi-rbd-sc` `StorageClass`:: $ cat < pvc.yaml --- apiVersion: v1 kind: PersistentVolumeClaim metadata: name: rbd-pvc spec: accessModes: - ReadWriteOnce volumeMode: Filesystem resources: requests: storage: 1Gi storageClassName: csi-rbd-sc EOF $ kubectl apply -f pvc.yaml The following demonstrates and example of binding the above `PersistentVolumeClaim` to a `Pod` resource as a mounted file system:: $ cat < pod.yaml --- apiVersion: v1 kind: Pod metadata: name: csi-rbd-demo-pod spec: containers: - name: web-server image: nginx volumeMounts: - name: mypvc mountPath: /var/lib/www/html volumes: - name: mypvc persistentVolumeClaim: claimName: rbd-pvc readOnly: false EOF $ kubectl apply -f pod.yaml .. _ceph-csi: https://github.com/ceph/ceph-csi/ .. _volumes: https://kubernetes.io/docs/concepts/storage/volumes/ .. _pods: https://kubernetes.io/docs/concepts/workloads/pods/pod-overview/ .. _Create a Pool: ../../rados/operations/pools#createpool .. _Placement Groups: ../../rados/operations/placement-groups .. _CRUSH tunables: ../../rados/operations/crush-map/#tunables .. _RBD image features: ../rbd-config-ref/#image-features .. _legacy V1 protocol: ../../rados/configuration/msgr2/#address-formats