This is a cache of https://docs.openshift.com/container-platform/4.17/storage/container_storage_interface/persistent-storage-csi-smb-cifs.html. It is a snapshot of the page at 2024-11-24T06:53:35.351+0000.
CIFS/SMB CSI Driver Operator - Using Container Storage Interface (CSI) | Storage | OpenShift Container Platform 4.17
×

OpenShift Container Platform is capable of provisioning persistent volumes (PVs) with a Container Storage Interface (CSI) driver for Common Internet File System (CIFS) dialect/Server Message Block (SMB) protocol.

CIFS/SMB CSI Driver Operator is a Technology Preview feature only. Technology Preview features are not supported with Red Hat production service level agreements (SLAs) and might not be functionally complete. Red Hat does not recommend using them in production. These features provide early access to upcoming product features, enabling customers to test functionality and provide feedback during the development process.

For more information about the support scope of Red Hat Technology Preview features, see Technology Preview Features Support Scope.

Familiarity with persistent storage and configuring CSI volumes is recommended when working with a CSI Operator and driver.

After installing the CIFS/SMB CSI Driver Operator, OpenShift Container Platform installs corresponding pods for the Operator and driver in the openshift-cluster-csi-drivers namespace by default. This allows the CIFS/SMB CSI Driver to create CSI-provisioned persistent volumes (PVs) that mount to CIFS/SMB shares.

  • The CIFS/SMB CSI Driver Operator, after being installed, does not create a storage class by default to use to create persistent volume claims (PVCs). However, you can manually create the CIFS/SMB StorageClass for dynamic provisioning. The CIFS/SMB CSI Driver Operator supports dynamic volume provisioning by allowing storage volumes to be created on-demand. This eliminates the need for cluster administrators to pre-provision storage.

  • The CIFS/SMB CSI driver enables you to create and mount CIFS/SMB PVs.

About CSI

Storage vendors have traditionally provided storage drivers as part of Kubernetes. With the implementation of the Container Storage Interface (CSI), third-party providers can instead deliver storage plugins using a standard interface without ever having to change the core Kubernetes code.

CSI Operators give OpenShift Container Platform users storage options, such as volume snapshots, that are not possible with in-tree volume plugins.

Limitations

The following limitations apply to the Common Internet File System (CIFS)/Server Message Block (SMB) Container Storage Interface (CSI) Driver Operator:

  • FIPS mode is not supported:

    When Federal Information Processing Standards (FIPS) mode is enabled, the use of md4 and md5 are disabled, which prevents users from using ntlm, ntlmv2, or ntlmssp authentication. Also, signing cannot be used because it uses md5. Any CIFS mount that uses these methods fails when FIPS mode is enabled.

  • Using HTTP proxy configuration to connect to outside of the cluster SMB servers is not supported by the CSI driver.

    Since CIFS/SMB is a LAN protocol, and though it can be routed to subnets, it is not designed to be extended over the WAN, and does not support HTTP proxy settings.

Installing the CIFS/SMB CSI Driver Operator

The CIFS/SMB CSI Driver Operator (a Red Hat Operator) is not installed in OpenShift Container Platform by default. Use the following procedure to install and configure the CIFS/SMB CSI Driver Operator in your cluster.

Prerequisites
  • Access to the OpenShift Container Platform web console.

Procedure

To install the CIFS/SMB CSI Driver Operator from the web console:

  1. Log in to the web console.

  2. Install the CIFS/SMB CSI Operator:

    1. Click OperatorsOperatorHub.

    2. Locate the CIFS/SMB CSI Operator by typing CIFS/SMB CSI in the filter box.

    3. Click the CIFS/SMB CSI Driver Operator button.

    4. On the CIFS/SMB CSI Driver Operator page, click Install.

    5. On the Install Operator page, ensure that:

      • All namespaces on the cluster (default) is selected.

      • Installed Namespace is set to openshift-cluster-csi-drivers.

    6. Click Install.

      After the installation finishes, the CIFS/SMB CSI Operator is listed in the Installed Operators section of the web console.

Installing the CIFS/SMB CSI Driver

After installing the CIFS/SMB Container Storage Interface (CSI) Driver Operator, install the CIFS/SMB CSI driver.

Prerequisites
  • Access to the OpenShift Container Platform web console.

  • CIFS/SMB CSI Driver Operator installed.

Procedure
  1. Click AdministrationCustomResourceDefinitionsClusterCSIDriver.

  2. On the Instances tab, click Create ClusterCSIDriver.

  3. Use the following YAML file:

    apiVersion: operator.openshift.io/v1
    kind: ClusterCSIDriver
    metadata:
        name: smb.csi.k8s.io
    spec:
      managementState: Managed
  4. Click Create.

  5. Wait for the following Conditions to change to a "True" status:

    • SambaDriverControllerServiceControllerAvailable

    • SambaDriverNodeServiceControllerAvailable

Dynamic provisioning

You can create a storage class for dynamic provisioning of Common Internet File System (CIFS) dialect/Server Message Block (SMB) protocol volumes. Provisioning volumes creates a subdirectory with the persistent volume (PV) name under source defined in the storage class.

Prerequisites
  • CIFS/SMB CSI Driver Operator and driver installed.

  • You are logged in to the running OpenShift Container Platform cluster.

  • You have installed the SMB server and know the following information about the server:

    • Hostname

    • Share name

    • Username and password

Procedure

To set up dynamic provisioning:

  1. Create a secret for access to the Samba server using the following command with the following example YAML file:

    $ oc create -f <file_name>.yaml
    secret example YAML file
    apiVersion: v1
    kind: secret
    metadata:
      name: smbcreds (1)
      namespace: samba-server (2)
    stringData:
      username: <username> (3)
      password: <password> (4)
    1 Name of the secret for the Samba server.
    2 Namespace for the secret for the Samba server.
    3 Username for the secret for the Samba server.
    4 Password for the secret for the Samba server.
  2. Create a storage class by running the following command with the following example YAML file:

    $ oc create -f <sc_file_name>.yaml (1)
    1 Name of the storage class YAML file.
    Storage class example YAML file
    apiVersion: storage.k8s.io/v1
    kind: StorageClass
    metadata:
      name: <sc_name> (1)
    provisioner: smb.csi.k8s.io
    parameters:
      source: //<hostname>/<shares> (2)
      csi.storage.k8s.io/provisioner-secret-name: smbcreds (3)
      csi.storage.k8s.io/provisioner-secret-namespace: samba-server (4)
      csi.storage.k8s.io/node-stage-secret-name: smbcreds (3)
      csi.storage.k8s.io/node-stage-secret-namespace: samba-server (4)
    reclaimPolicy: Delete
    volumeBindingMode: Immediate
    mountOptions:
      - dir_mode=0777
      - file_mode=0777
      - uid=1001
      - gid=1001
    1 The name of the storage class.
    2 The Samba server must be installed somewhere and reachable from the cluster with <`hostname>` being the hostname for the Samba server and <shares> the path the server is configured to have among the exported shares.
    3 Name of the secret for the Samba server that was set in the previous step. If the csi.storage.k8s.io/provisioner-secret is provided, a subdirectory is created with the PV name under source.
    4 Namespace for the secret for the Samba server that was set in the previous step.
  3. Create a PVC:

    1. Create a PVC by running the following command with the following example YAML file:

      $ oc create -f <pv_file_name>.yaml (1)
      1 The name of the PVC YAML file.
      Example PVC YAML file
      kind: PersistentVolumeClaim
      apiVersion: v1
      metadata:
        name: <pvc_name> (1)
      spec:
        accessModes:
          - ReadWriteMany
        resources:
          requests:
            storage: <storage_amount> (2)
        storageClassName: <sc_name> (3)
      1 The name of the PVC.
      2 Storage request amount.
      3 The name of the CIFS/SMB storage class that you created in the previous step.
    2. Ensure that the PVC was created and is in the "Bound" status by running the following command:

      $ oc describe pvc <pvc_name> (1)
      1 The name of the PVC that you created in the preceding step.
      Example output
      Name:          pvc-test
      Namespace:     default
      StorageClass:  samba
      Status:        Bound (1)
      ...
      1 PVC is in Bound status.

Static provisioning

You can use static provisioning to create a persistent volume (PV) and persistent volume claim (PVC) to consume existing Server Message Block protocol (SMB) shares:

Prerequisites
  • Access to the OpenShift Container Platform web console.

  • CIFS/SMB CSI Driver Operator and driver installed.

  • You have installed the SMB server and know the following information about the server:

    • Hostname

    • Share name

    • Username and password

Procedure

To set up static provisioning:

  1. Create a secret for access to the Samba server using the following command with the following example YAML file:

    $ oc create -f <file_name>.yaml
    secret example YAML file
    apiVersion: v1
    kind: secret
    metadata:
      name: smbcreds (1)
      namespace: samba-server (2)
    stringData:
      username: <username> (3)
      password: <password> (4)
    1 Name of the secret for the Samba server.
    2 Namespace for the secret for the Samba server.
    3 Username for the secret for the Samba server.
    4 Password for the secret for the Samba server.
  2. Create a PV by running the following command with the following example YAML file:

    $ oc create -f <pv_file_name>.yaml (1)
    1 The name of the PV YAML file.
    Example PV YAML file
    apiVersion: v1
    kind: PersistentVolume
    metadata:
      annotations:
        pv.kubernetes.io/provisioned-by: smb.csi.k8s.io
      name: <pv_name> (1)
    spec:
      capacity:
        storage: 100Gi
      accessModes:
        - ReadWriteMany
      persistentVolumeReclaimPolicy: Retain
      storageClassName: ""
      mountOptions:
        - dir_mode=0777
        - file_mode=0777
      csi:
        driver: smb.csi.k8s.io
        volumeHandle: smb-server.default.svc.cluster.local/share/ (2)
        volumeAttributes:
          source: //<hostname>/<shares> (3)
        nodeStagesecretRef:
          name: <secret_name_shares> (4)
          namespace: <namespace> (5)
    1 The name of the PV.
    2 volumeHandle format: {smb-server-address}.{sub-dir-name}.{share-name}. Ensure that this value is unique for every share in the cluster.
    3 The Samba server must be installed somewhere and reachable from the cluster with <hostname> being the hostname for the Samba server and <shares> the path the server is configured to have among the exported shares.
    4 The name of the secret for the shares.
    5 The applicable namespace.
  3. Create a PVC:

    1. Create a PVC by running the following command with the following example YAML file:

      $ oc create -f <pv_file_name>.yaml (1)
      1 The name of the PVC YAML file.
      Example PVC YAML file
      kind: PersistentVolumeClaim
      apiVersion: v1
      metadata:
        name: <pvc_name> (1)
      spec:
        accessModes:
          - ReadWriteMany
        resources:
          requests:
            storage: <storage_amount> (2)
        storageClassName: ""
        volumeName: <pv_name> (3)
      1 The name of the PVC.
      2 Storage request amount.
      3 The name of the PV from the first step.
    2. Ensure that the PVC was created and is in the "Bound" status by running the following command:

      $ oc describe pvc <pvc_name> (1)
      1 The name of the PVC that you created in the preceding step.
      Example output
      Name:          pvc-test
      Namespace:     default
      StorageClass:
      Status:        Bound (1)
      ...
      1 PVC is in Bound status.
  4. Create a deployment on Linux by running the following command with the following example YAML file:

    The following deployment is not mandatory for using the PV and PVC created in the previous steps. It is example of how they can be used.

    $ oc create -f <deployment_file_name>.yaml (1)
    1 The name of the deployment YAML file.
    Example deployment YAML file
    apiVersion: apps/v1
    kind: Deployment
    metadata:
      labels:
        app: nginx
      name: <deployment_name> (1)
    spec:
      replicas: 1
      selector:
        matchLabels:
          app: nginx
      template:
        metadata:
          labels:
            app: nginx
          name: <deployment_name> (1)
        spec:
          nodeSelector:
            "kubernetes.io/os": linux
          containers:
            - name: <deployment_name> (1)
              image: quay.io/centos/centos:stream8
              command:
                - "/bin/bash"
                - "-c"
                - set -euo pipefail; while true; do echo $(date) >> <mount_path>/outfile; sleep 1; done (2)
              volumeMounts:
                - name: <vol_mount_name> (3)
                  mountPath: <mount_path> (2)
                  readOnly: false
          volumes:
            - name: <vol_mount_name> (3)
              persistentVolumeClaim:
                claimName: <pvc_name> (4)
      strategy:
        rollingUpdate:
          maxSurge: 0
          maxUnavailable: 1
        type: RollingUpdate
    1 The name of the deployment.
    2 The volume mount path.
    3 The name of the volume mount.
    4 The name of the PVC created in the preceding step.
  5. Check the setup by running the df -h command in the container:

    $ oc exec -it <pod_name> -- df -h (1)
    1 The name of the pod.
    Example output
    Filesystem            Size  Used Avail Use% Mounted on
    ...
    /dev/sda1              97G   21G   77G  22% /etc/hosts
    //20.43.191.64/share   97G   21G   77G  22% /mnt/smb
    ...

    In this example, there is a /mnt/smb directory mounted as a Common Internet File System (CIFS) filesystem.

Additional resources