# CSI RBD Plugin The RBD CSI plugin is able to provision new RBD images and attach and mount those to workloads. ## Building CSI RBD plugin can be compiled in a form of a binary file or in a form of a Docker image. When compiled as a binary file, the result is stored in `_output/` directory with the name `rbdplugin`. When compiled as an image, it's stored in the local Docker image store. Building binary: ```bash make rbdplugin ``` Building Docker image: ```bash make image-rbdplugin ``` ## Configuration **Available command line arguments:** Option | Default value | Description ------ | ------------- | ----------- `--endpoint` | `unix://tmp/csi.sock` | CSI endpoint, must be a UNIX socket `--drivername` | `csi-cephfsplugin` | name of the driver (Kubernetes: `provisioner` field in StorageClass must correspond to this value) `--nodeid` | _empty_ | This node's ID `--containerized` | true | Whether running in containerized mode `--metadatastorage` | _empty_ | Whether should metadata be kept on node as file or in a k8s configmap (`node` or `k8s_configmap`) **Available environmental variables:** `HOST_ROOTFS`: rbdplugin searches `/proc` directory under the directory set by `HOST_ROOTFS`. `KUBERNETES_CONFIG_PATH`: if you use `k8s_configmap` as metadata store, specify the path of your k8s config file (if not specified, the plugin will assume you're running it inside a k8s cluster and find the config itself). `POD_NAMESPACE`: if you use `k8s_configmap` as metadata store, `POD_NAMESPACE` is used to define in which namespace you want the configmaps to be stored **Available volume parameters:** Parameter | Required | Description --------- | -------- | ----------- `monitors` | one of `monitors` and `monValueFromSecret` must be set | Comma separated list of Ceph monitors (e.g. `192.168.100.1:6789,192.168.100.2:6789,192.168.100.3:6789`) `monValueFromSecret` | one of `monitors` and `monValueFromSecret` must be set | a string pointing the key in the credential secret, whose value is the mon. This is used for the case when the monitors' IP or hostnames are changed, the secret can be updated to pick up the new monitors. `pool` | yes | Ceph pool into which the RBD image shall be created `imageFormat` | no | RBD image format. Defaults to `2`. See [man pages](http://docs.ceph.com/docs/mimic/man/8/rbd/#cmdoption-rbd-image-format) `imageFeatures` | no | RBD image features. Available for `imageFormat=2`. CSI RBD currently supports only `layering` feature. See [man pages](http://docs.ceph.com/docs/mimic/man/8/rbd/#cmdoption-rbd-image-feature) `csi.storage.k8s.io/provisioner-secret-name`, `csi.storage.k8s.io/node-publish-secret-name` | for Kubernetes | name of the Kubernetes Secret object containing Ceph client credentials. Both parameters should have the same value `csi.storage.k8s.io/provisioner-secret-namespace`, `csi.storage.k8s.io/node-publish-secret-namespace` | for Kubernetes | namespaces of the above Secret objects `mounter`| no | if set to `rbd-nbd`, use `rbd-nbd` on nodes that have `rbd-nbd` and `nbd` kernel modules to map rbd images **Required secrets:** Admin credentials are required for provisioning new RBD images `ADMIN_NAME`: `ADMIN_PASSWORD` - note that the key of the key-value pair is the name of the client with admin privileges, and the value is its password Also note that CSI RBD expects admin keyring and Ceph config file in `/etc/ceph`. ## Deployment with Kubernetes Requires Kubernetes 1.11 Your Kubernetes cluster must allow privileged pods (i.e. `--allow-privileged` flag must be set to true for both the API server and the kubelet). Moreover, as stated in the [mount propagation docs](https://kubernetes.io/docs/concepts/storage/volumes/#mount-propagation), the Docker daemon of the cluster nodes must allow shared mounts. YAML manifests are located in `deploy/rbd/kubernetes`. **Deploy RBACs for sidecar containers and node plugins:** ```bash kubectl create -f csi-attacher-rbac.yaml kubectl create -f csi-provisioner-rbac.yaml kubectl create -f csi-nodeplugin-rbac.yaml ``` Those manifests deploy service accounts, cluster roles and cluster role bindings. These are shared for both RBD and CephFS CSI plugins, as they require the same permissions. **Deploy CSI sidecar containers:** ```bash kubectl create -f csi-rbdplugin-attacher.yaml kubectl create -f csi-rbdplugin-provisioner.yaml ``` Deploys stateful sets for external-attacher and external-provisioner sidecar containers for CSI RBD. **Deploy RBD CSI driver:** ```bash kubectl create -f csi-rbdplugin.yaml ``` Deploys a daemon set with two containers: CSI driver-registrar and the CSI RBD driver. ## Verifying the deployment in Kubernetes After successfully completing the steps above, you should see output similar to this: ```bash $ kubectl get all NAME READY STATUS RESTARTS AGE pod/csi-rbdplugin-attacher-0 1/1 Running 0 23s pod/csi-rbdplugin-fptqr 2/2 Running 0 21s pod/csi-rbdplugin-provisioner-0 1/1 Running 0 22s NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE service/csi-rbdplugin-attacher ClusterIP 10.109.15.54 12345/TCP 26s service/csi-rbdplugin-provisioner ClusterIP 10.104.2.130 12345/TCP 23s ... ``` You can try deploying a demo pod from `examples/rbd` to test the deployment further. ## Deployment with Helm The same requirements from the Kubernetes section apply here, i.e. Kubernetes version, privileged flag and shared mounts. The Helm chart is located in `deploy/rbd/helm`. **Deploy Helm Chart:** ```bash helm install ./deploy/rbd/helm ``` The Helm chart deploys all of the required resources to use the CSI RBD driver. After deploying the chart you can verify the deployment using the instructions above for verifying the deployment with Kubernetes