Volumes

On-disk files in a container are ephemeral, which presents some problems for non-trivial applications when running in containers. One problem is the loss of files when a container crashes. The kubelet restarts the container but with a clean state. A second problem occurs when sharing files between containers running together in a Pod. The Kubernetes volume abstraction solves both of these problems. Familiarity with Pods is suggested.

Background

Docker has a concept of volumes, though it is somewhat looser and less managed. A Docker volume is a directory on disk or in another container. Docker provides volume drivers, but the functionality is somewhat limited.

Kubernetes supports many types of volumes. A Pod can use any number of volume types simultaneously. Ephemeral volume types have a lifetime of a pod, but persistent volumes exist beyond the lifetime of a pod. When a pod ceases to exist, Kubernetes destroys ephemeral volumes; however, Kubernetes does not destroy persistent volumes. For any kind of volume in a given pod, data is preserved across container restarts.

At its core, a volume is a directory, possibly with some data in it, which is accessible to the containers in a pod. How that directory comes to be, the medium that backs it, and the contents of it are determined by the particular volume type used.

To use a volume, specify the volumes to provide for the Pod in .spec.volumes and declare where to mount those volumes into containers in .spec.containers[*].volumeMounts. A process in a container sees a filesystem view composed from the initial contents of the container image, plus volumes (if defined) mounted inside the container. The process sees a root filesystem that initially matches the contents of the container image. Any writes to within that filesystem hierarchy, if allowed, affect what that process views when it performs a subsequent filesystem access. Volumes mount at the specified paths within the image. For each container defined within a Pod, you must independently specify where to mount each volume that the container uses.

Volumes cannot mount within other volumes (but see Using subPath for a related mechanism). Also, a volume cannot contain a hard link to anything in a different volume.

Types of Volumes

Kubernetes supports several types of volumes.

awsElasticBlockStore (deprecated)

FEATURE STATE: Kubernetes v1.17 [deprecated]

An awsElasticBlockStore volume mounts an Amazon Web Services (AWS) EBS volume into your pod. Unlike emptyDir, which is erased when a pod is removed, the contents of an EBS volume are persisted and the volume is unmounted. This means that an EBS volume can be pre-populated with data, and that data can be shared between pods.

There are some restrictions when using an awsElasticBlockStore volume:

  • the nodes on which pods are running must be AWS EC2 instances
  • those instances need to be in the same region and availability zone as the EBS volume
  • EBS only supports a single EC2 instance mounting a volume

Creating an AWS EBS volume

Before you can use an EBS volume with a pod, you need to create it.

aws ec2 create-volume --availability-zone=eu-west-1a --size=10 --volume-type=gp2

Make sure the zone matches the zone you brought up your cluster in. Check that the size and EBS volume type are suitable for your use.

AWS EBS configuration example

apiVersion: v1
kind: Pod
metadata:
  name: test-ebs
spec:
  containers:
  - image: k8s.gcr.io/test-webserver
    name: test-container
    volumeMounts:
    - mountPath: /test-ebs
      name: test-volume
  volumes:
  - name: test-volume
    # This AWS EBS volume must already exist.
    awsElasticBlockStore:
      volumeID: "<volume id>"
      fsType: ext4

If the EBS volume is partitioned, you can supply the optional field partition: "<partition number>" to specify which partition to mount on.

AWS EBS CSI migration

FEATURE STATE: Kubernetes v1.17 [beta]

The CSIMigration feature for awsElasticBlockStore, when enabled, redirects all plugin operations from the existing in-tree plugin to the ebs.csi.aws.com Container Storage Interface (CSI) driver. In order to use this feature, the AWS EBS CSI driver must be installed on the cluster and the CSIMigration and CSIMigrationAWS beta features must be enabled.

AWS EBS CSI migration complete

FEATURE STATE: Kubernetes v1.17 [alpha]

To disable the awsElasticBlockStore storage plugin from being loaded by the controller manager and the kubelet, set the InTreePluginAWSUnregister flag to true.

azureDisk (deprecated)

FEATURE STATE: Kubernetes v1.19 [deprecated]

The azureDisk volume type mounts a Microsoft Azure Data Disk into a pod.

For more details, see the azureDisk volume plugin.

azureDisk CSI migration

FEATURE STATE: Kubernetes v1.24 [stable]

The CSIMigration feature for azureDisk, when enabled, redirects all plugin operations from the existing in-tree plugin to the disk.csi.azure.com Container Storage Interface (CSI) Driver. In order to use this feature, the Azure Disk CSI Driver must be installed on the cluster and the CSIMigration feature must be enabled.

azureDisk CSI migration complete

FEATURE STATE: Kubernetes v1.21 [alpha]

To disable the azureDisk storage plugin from being loaded by the controller manager and the kubelet, set the InTreePluginAzureDiskUnregister flag to true.

azureFile (deprecated)

FEATURE STATE: Kubernetes v1.21 [deprecated]

The azureFile volume type mounts a Microsoft Azure File volume (SMB 2.1 and 3.0) into a pod.

For more details, see the azureFile volume plugin.

azureFile CSI migration

FEATURE STATE: Kubernetes v1.21 [beta]

The CSIMigration feature for azureFile, when enabled, redirects all plugin operations from the existing in-tree plugin to the file.csi.azure.com Container Storage Interface (CSI) Driver. In order to use this feature, the Azure File CSI Driver must be installed on the cluster and the CSIMigration and CSIMigrationAzureFile feature gates must be enabled.

Azure File CSI driver does not support using same volume with different fsgroups. If CSIMigrationAzureFile is enabled, using same volume with different fsgroups won't be supported at all.

azureFile CSI migration complete

FEATURE STATE: Kubernetes v1.21 [alpha]

To disable the azureFile storage plugin from being loaded by the controller manager and the kubelet, set the InTreePluginAzureFileUnregister flag to true.

cephfs

A cephfs volume allows an existing CephFS volume to be mounted into your Pod. Unlike emptyDir, which is erased when a pod is removed, the contents of a cephfs volume are preserved and the volume is merely unmounted. This means that a cephfs volume can be pre-populated with data, and that data can be shared between pods. The cephfs volume can be mounted by multiple writers simultaneously.

See the CephFS example for more details.

cinder (deprecated)

FEATURE STATE: Kubernetes v1.18 [deprecated]

The cinder volume type is used to mount the OpenStack Cinder volume into your pod.

Cinder volume configuration example

apiVersion: v1
kind: Pod
metadata:
  name: test-cinder
spec:
  containers:
  - image: k8s.gcr.io/test-webserver
    name: test-cinder-container
    volumeMounts:
    - mountPath: /test-cinder
      name: test-volume
  volumes:
  - name: test-volume
    # This OpenStack volume must already exist.
    cinder:
      volumeID: "<volume id>"
      fsType: ext4

OpenStack CSI migration

FEATURE STATE: Kubernetes v1.24 [stable]

The CSIMigration feature for Cinder is enabled by default since Kubernetes 1.21. It redirects all plugin operations from the existing in-tree plugin to the cinder.csi.openstack.org Container Storage Interface (CSI) Driver. OpenStack Cinder CSI Driver must be installed on the cluster.

To disable the in-tree Cinder plugin from being loaded by the controller manager and the kubelet, you can enable the InTreePluginOpenStackUnregister feature gate.

configMap

A ConfigMap provides a way to inject configuration data into pods. The data stored in a ConfigMap can be referenced in a volume of type configMap and then consumed by containerized applications running in a pod.

When referencing a ConfigMap, you provide the name of the ConfigMap in the volume. You can customize the path to use for a specific entry in the ConfigMap. The following configuration shows how to mount the log-config ConfigMap onto a Pod called configmap-pod:

apiVersion: v1
kind: Pod
metadata:
  name: configmap-pod
spec:
  containers:
    - name: test
      image: busybox:1.28
      volumeMounts:
        - name: config-vol
          mountPath: /etc/config
  volumes:
    - name: config-vol
      configMap:
        name: log-config
        items:
          - key: log_level
            path: log_level

The log-config ConfigMap is mounted as a volume, and all contents stored in its log_level entry are mounted into the Pod at path /etc/config/log_level. Note that this path is derived from the volume's mountPath and the path keyed with log_level.

downwardAPI

A downwardAPI volume makes downward API data available to applications. Within the volume, you can find the exposed data as read-only files in plain text format.

See Expose Pod Information to Containers Through Files to learn more.

emptyDir

An emptyDir volume is first created when a Pod is assigned to a node, and exists as long as that Pod is running on that node. As the name says, the emptyDir volume is initially empty. All containers in the Pod can read and write the same files in the emptyDir volume, though that volume can be mounted at the same or different paths in each container. When a Pod is removed from a node for any reason, the data in the emptyDir is deleted permanently.

Some uses for an emptyDir are:

  • scratch space, such as for a disk-based merge sort
  • checkpointing a long computation for recovery from crashes
  • holding files that a content-manager container fetches while a webserver container serves the data

Depending on your environment, emptyDir volumes are stored on whatever medium that backs the node such as disk or SSD, or network storage. However, if you set the emptyDir.medium field to "Memory", Kubernetes mounts a tmpfs (RAM-backed filesystem) for you instead. While tmpfs is very fast, be aware that unlike disks, tmpfs is cleared on node reboot and any files you write count against your container's memory limit.

emptyDir configuration example

apiVersion: v1
kind: Pod
metadata:
  name: test-pd
spec:
  containers:
  - image: k8s.gcr.io/test-webserver
    name: test-container
    volumeMounts:
    - mountPath: /cache
      name: cache-volume
  volumes:
  - name: cache-volume
    emptyDir: {}

fc (fibre channel)

An fc volume type allows an existing fibre channel block storage volume to mount in a Pod. You can specify single or multiple target world wide names (WWNs) using the parameter targetWWNs in your Volume configuration. If multiple WWNs are specified, targetWWNs expect that those WWNs are from multi-path connections.

See the fibre channel example for more details.

flocker (deprecated)

Flocker is an open-source, clustered container data volume manager. Flocker provides management and orchestration of data volumes backed by a variety of storage backends.

A flocker volume allows a Flocker dataset to be mounted into a Pod. If the dataset does not already exist in Flocker, it needs to be first created with the Flocker CLI or by using the Flocker API. If the dataset already exists it will be reattached by Flocker to the node that the pod is scheduled. This means data can be shared between pods as required.

See the Flocker example for more details.

gcePersistentDisk (deprecated)

FEATURE STATE: Kubernetes v1.17 [deprecated]

A gcePersistentDisk volume mounts a Google Compute Engine (GCE) persistent disk (PD) into your Pod. Unlike emptyDir, which is erased when a pod is removed, the contents of a PD are preserved and the volume is merely unmounted. This means that a PD can be pre-populated with data, and that data can be shared between pods.

There are some restrictions when using a gcePersistentDisk:

  • the nodes on which Pods are running must be GCE VMs
  • those VMs need to be in the same GCE project and zone as the persistent disk

One feature of GCE persistent disk is concurrent read-only access to a persistent disk. A gcePersistentDisk volume permits multiple consumers to simultaneously mount a persistent disk as read-only. This means that you can pre-populate a PD with your dataset and then serve it in parallel from as many Pods as you need. Unfortunately, PDs can only be mounted by a single consumer in read-write mode. Simultaneous writers are not allowed.

Using a GCE persistent disk with a Pod controlled by a ReplicaSet will fail unless the PD is read-only or the replica count is 0 or 1.

Creating a GCE persistent disk

Before you can use a GCE persistent disk with a Pod, you need to create it.

gcloud compute disks create --size=500GB --zone=us-central1-a my-data-disk

GCE persistent disk configuration example

apiVersion: v1
kind: Pod
metadata:
  name: test-pd
spec:
  containers:
  - image: k8s.gcr.io/test-webserver
    name: test-container
    volumeMounts:
    - mountPath: /test-pd
      name: test-volume
  volumes:
  - name: test-volume
    # This GCE PD must already exist.
    gcePersistentDisk:
      pdName: my-data-disk
      fsType: ext4

Regional persistent disks

The Regional persistent disks feature allows the creation of persistent disks that are available in two zones within the same region. In order to use this feature, the volume must be provisioned as a PersistentVolume; referencing the volume directly from a pod is not supported.

Manually provisioning a Regional PD PersistentVolume

Dynamic provisioning is possible using a StorageClass for GCE PD. Before creating a PersistentVolume, you must create the persistent disk:

gcloud compute disks create --size=500GB my-data-disk
  --region us-central1
  --replica-zones us-central1-a,us-central1-b

Regional persistent disk configuration example

apiVersion: v1
kind: PersistentVolume
metadata:
  name: test-volume
spec:
  capacity:
    storage: 400Gi
  accessModes:
  - ReadWriteOnce
  gcePersistentDisk:
    pdName: my-data-disk
    fsType: ext4
  nodeAffinity:
    required:
      nodeSelectorTerms:
      - matchExpressions:
        # failure-domain.beta.kubernetes.io/zone should be used prior to 1.21
        - key: topology.kubernetes.io/zone
          operator: In
          values:
          - us-central1-a
          - us-central1-b

GCE CSI migration

FEATURE STATE: Kubernetes v1.17 [beta]

The CSIMigration feature for GCE PD, when enabled, redirects all plugin operations from the existing in-tree plugin to the pd.csi.storage.gke.io Container Storage Interface (CSI) Driver. In order to use this feature, the GCE PD CSI Driver must be installed on the cluster and the CSIMigration and CSIMigrationGCE beta features must be enabled.

GCE CSI migration complete

FEATURE STATE: Kubernetes v1.21 [alpha]

To disable the gcePersistentDisk storage plugin from being loaded by the controller manager and the kubelet, set the InTreePluginGCEUnregister flag to true.

gitRepo (deprecated)

A gitRepo volume is an example of a volume plugin. This plugin mounts an empty directory and clones a git repository into this directory for your Pod to use.

Here is an example of a gitRepo volume:

apiVersion: v1
kind: Pod
metadata:
  name: server
spec:
  containers:
  - image: nginx
    name: nginx
    volumeMounts:
    - mountPath: /mypath
      name: git-volume
  volumes:
  - name: git-volume
    gitRepo:
      repository: "git@somewhere:me/my-git-repository.git"
      revision: "22f1d8406d464b0c0874075539c1f2e96c253775"

glusterfs

A glusterfs volume allows a Glusterfs (an open source networked filesystem) volume to be mounted into your Pod. Unlike emptyDir, which is erased when a Pod is removed, the contents of a glusterfs volume are preserved and the volume is merely unmounted. This means that a glusterfs volume can be pre-populated with data, and that data can be shared between pods. GlusterFS can be mounted by multiple writers simultaneously.

See the GlusterFS example for more details.

hostPath

A hostPath volume mounts a file or directory from the host node's filesystem into your Pod. This is not something that most Pods will need, but it offers a powerful escape hatch for some applications.

For example, some uses for a hostPath are:

  • running a container that needs access to Docker internals; use a hostPath of /var/lib/docker
  • running cAdvisor in a container; use a hostPath of /sys
  • allowing a Pod to specify whether a given hostPath should exist prior to the Pod running, whether it should be created, and what it should exist as

In addition to the required path property, you can optionally specify a type for a hostPath volume.

The supported values for field type are:

ValueBehavior
Empty string (default) is for backward compatibility, which means that no checks will be performed before mounting the hostPath volume.
DirectoryOrCreateIf nothing exists at the given path, an empty directory will be created there as needed with permission set to 0755, having the same group and ownership with Kubelet.
DirectoryA directory must exist at the given path
FileOrCreateIf nothing exists at the given path, an empty file will be created there as needed with permission set to 0644, having the same group and ownership with Kubelet.
FileA file must exist at the given path
SocketA UNIX socket must exist at the given path
CharDeviceA character device must exist at the given path
BlockDeviceA block device must exist at the given path

Watch out when using this type of volume, because:

  • HostPaths can expose privileged system credentials (such as for the Kubelet) or privileged APIs (such as container runtime socket), which can be used for container escape or to attack other parts of the cluster.
  • Pods with identical configuration (such as created from a PodTemplate) may behave differently on different nodes due to different files on the nodes
  • The files or directories created on the underlying hosts are only writable by root. You either need to run your process as root in a privileged Container or modify the file permissions on the host to be able to write to a hostPath volume

hostPath configuration example

apiVersion: v1
kind: Pod
metadata:
  name: test-pd
spec:
  containers:
  - image: k8s.gcr.io/test-webserver
    name: test-container
    volumeMounts:
    - mountPath: /test-pd
      name: test-volume
  volumes:
  - name: test-volume
    hostPath:
      # directory location on host
      path: /data
      # this field is optional
      type: Directory

hostPath FileOrCreate configuration example

apiVersion: v1
kind: Pod
metadata:
  name: test-webserver
spec:
  containers:
  - name: test-webserver
    image: k8s.gcr.io/test-webserver:latest
    volumeMounts:
    - mountPath: /var/local/aaa
      name: mydir
    - mountPath: /var/local/aaa/1.txt
      name: myfile
  volumes:
  - name: mydir
    hostPath:
      # Ensure the file directory is created.
      path: /var/local/aaa
      type: DirectoryOrCreate
  - name: myfile
    hostPath:
      path: /var/local/aaa/1.txt
      type: FileOrCreate

iscsi

An iscsi volume allows an existing iSCSI (SCSI over IP) volume to be mounted into your Pod. Unlike emptyDir, which is erased when a Pod is removed, the contents of an iscsi volume are preserved and the volume is merely unmounted. This means that an iscsi volume can be pre-populated with data, and that data can be shared between pods.

A feature of iSCSI is that it can be mounted as read-only by multiple consumers simultaneously. This means that you can pre-populate a volume with your dataset and then serve it in parallel from as many Pods as you need. Unfortunately, iSCSI volumes can only be mounted by a single consumer in read-write mode. Simultaneous writers are not allowed.

See the iSCSI example for more details.

local

A local volume represents a mounted local storage device such as a disk, partition or directory.

Local volumes can only be used as a statically created PersistentVolume. Dynamic provisioning is not supported.

Compared to hostPath volumes, local volumes are used in a durable and portable manner without manually scheduling pods to nodes. The system is aware of the volume's node constraints by looking at the node affinity on the PersistentVolume.

However, local volumes are subject to the availability of the underlying node and are not suitable for all applications. If a node becomes unhealthy, then the local volume becomes inaccessible by the pod. The pod using this volume is unable to run. Applications using local volumes must be able to tolerate this reduced availability, as well as potential data loss, depending on the durability characteristics of the underlying disk.

The following example shows a PersistentVolume using a local volume and nodeAffinity:

apiVersion: v1
kind: PersistentVolume
metadata:
  name: example-pv
spec:
  capacity:
    storage: 100Gi
  volumeMode: Filesystem
  accessModes:
  - ReadWriteOnce
  persistentVolumeReclaimPolicy: Delete
  storageClassName: local-storage
  local:
    path: /mnt/disks/ssd1
  nodeAffinity:
    required:
      nodeSelectorTerms:
      - matchExpressions:
        - key: kubernetes.io/hostname
          operator: In
          values:
          - example-node

You must set a PersistentVolume nodeAffinity when using local volumes. The Kubernetes scheduler uses the PersistentVolume nodeAffinity to schedule these Pods to the correct node.

PersistentVolume volumeMode can be set to "Block" (instead of the default value "Filesystem") to expose the local volume as a raw block device.

When using local volumes, it is recommended to create a StorageClass with volumeBindingMode set to WaitForFirstConsumer. For more details, see the local StorageClass example. Delaying volume binding ensures that the PersistentVolumeClaim binding decision will also be evaluated with any other node constraints the Pod may have, such as node resource requirements, node selectors, Pod affinity, and Pod anti-affinity.

An external static provisioner can be run separately for improved management of the local volume lifecycle. Note that this provisioner does not support dynamic provisioning yet. For an example on how to run an external local provisioner, see the local volume provisioner user guide.

nfs

An nfs volume allows an existing NFS (Network File System) share to be mounted into a Pod. Unlike emptyDir, which is erased when a Pod is removed, the contents of an nfs volume are preserved and the volume is merely unmounted. This means that an NFS volume can be pre-populated with data, and that data can be shared between pods. NFS can be mounted by multiple writers simultaneously.

See the NFS example for more details.

persistentVolumeClaim

A persistentVolumeClaim volume is used to mount a PersistentVolume into a Pod. PersistentVolumeClaims are a way for users to "claim" durable storage (such as a GCE PersistentDisk or an iSCSI volume) without knowing the details of the particular cloud environment.

See the information about PersistentVolumes for more details.

portworxVolume

A portworxVolume is an elastic block storage layer that runs hyperconverged with Kubernetes. Portworx fingerprints storage in a server, tiers based on capabilities, and aggregates capacity across multiple servers. Portworx runs in-guest in virtual machines or on bare metal Linux nodes.

A portworxVolume can be dynamically created through Kubernetes or it can also be pre-provisioned and referenced inside a Pod. Here is an example Pod referencing a pre-provisioned Portworx volume:

apiVersion: v1
kind: Pod
metadata:
  name: test-portworx-volume-pod
spec:
  containers:
  - image: k8s.gcr.io/test-webserver
    name: test-container
    volumeMounts:
    - mountPath: /mnt
      name: pxvol
  volumes:
  - name: pxvol
    # This Portworx volume must already exist.
    portworxVolume:
      volumeID: "pxvol"
      fsType: "<fs-type>"

For more details, see the Portworx volume examples.

projected

A projected volume maps several existing volume sources into the same directory. For more details, see projected volumes.

quobyte (deprecated)

A quobyte volume allows an existing Quobyte volume to be mounted into your Pod.

Quobyte supports the Container Storage Interface. CSI is the recommended plugin to use Quobyte volumes inside Kubernetes. Quobyte's GitHub project has instructions for deploying Quobyte using CSI, along with examples.

rbd

An rbd volume allows a Rados Block Device (RBD) volume to mount into your Pod. Unlike emptyDir, which is erased when a pod is removed, the contents of an rbd volume are preserved and the volume is unmounted. This means that a RBD volume can be pre-populated with data, and that data can be shared between pods.

A feature of RBD is that it can be mounted as read-only by multiple consumers simultaneously. This means that you can pre-populate a volume with your dataset and then serve it in parallel from as many pods as you need. Unfortunately, RBD volumes can only be mounted by a single consumer in read-write mode. Simultaneous writers are not allowed.

See the RBD example for more details.

RBD CSI migration

FEATURE STATE: Kubernetes v1.23 [alpha]

The CSIMigration feature for RBD, when enabled, redirects all plugin operations from the existing in-tree plugin to the rbd.csi.ceph.com CSI driver. In order to use this feature, the Ceph CSI driver must be installed on the cluster and the CSIMigration and csiMigrationRBD feature gates must be enabled.

secret

A secret volume is used to pass sensitive information, such as passwords, to Pods. You can store secrets in the Kubernetes API and mount them as files for use by pods without coupling to Kubernetes directly. secret volumes are backed by tmpfs (a RAM-backed filesystem) so they are never written to non-volatile storage.

For more details, see Configuring Secrets.

storageOS (deprecated)

A storageos volume allows an existing StorageOS volume to mount into your Pod.

StorageOS runs as a container within your Kubernetes environment, making local or attached storage accessible from any node within the Kubernetes cluster. Data can be replicated to protect against node failure. Thin provisioning and compression can improve utilization and reduce cost.

At its core, StorageOS provides block storage to containers, accessible from a file system.

The StorageOS Container requires 64-bit Linux and has no additional dependencies. A free developer license is available.

The following example is a Pod configuration with StorageOS:

apiVersion: v1
kind: Pod
metadata:
  labels:
    name: redis
    role: master
  name: test-storageos-redis
spec:
  containers:
    - name: master
      image: kubernetes/redis:v1
      env:
        - name: MASTER
          value: "true"
      ports:
        - containerPort: 6379
      volumeMounts:
        - mountPath: /redis-master-data
          name: redis-data
  volumes:
    - name: redis-data
      storageos:
        # The `redis-vol01` volume must already exist within StorageOS in the `default` namespace.
        volumeName: redis-vol01
        fsType: ext4

For more information about StorageOS, dynamic provisioning, and PersistentVolumeClaims, see the StorageOS examples.

vsphereVolume (deprecated)

A vsphereVolume is used to mount a vSphere VMDK volume into your Pod. The contents of a volume are preserved when it is unmounted. It supports both VMFS and VSAN datastore.

For more information, see the vSphere volume examples.

vSphere CSI migration

FEATURE STATE: Kubernetes v1.19 [beta]

The CSIMigration feature for vsphereVolume, when enabled, redirects all plugin operations from the existing in-tree plugin to the csi.vsphere.vmware.com CSI driver. In order to use this feature, the vSphere CSI driver must be installed on the cluster and the CSIMigration and CSIMigrationvSphere feature gates must be enabled. You can find additional advice on how to migrate in VMware's documentation page Migrating In-Tree vSphere Volumes to vSphere Container Storage Plug-in.

Kubernetes v1.24 requires that you are using vSphere 7.0u2 or later in order to migrate to the out-of-tree CSI driver. If you are running a version of Kubernetes other than v1.24, consult the documentation for that version of Kubernetes. If you are running Kubernetes v1.24 and an older version of vSphere, consider upgrading to at least vSphere 7.0u2.

vSphere CSI migration complete

FEATURE STATE: Kubernetes v1.19 [beta]

To turn off the vsphereVolume plugin from being loaded by the controller manager and the kubelet, you need to set InTreePluginvSphereUnregister feature flag to true. You must install a csi.vsphere.vmware.com CSI driver on all worker nodes.

Portworx CSI migration

FEATURE STATE: Kubernetes v1.23 [alpha]

The CSIMigration feature for Portworx has been added but disabled by default in Kubernetes 1.23 since it's in alpha state. It redirects all plugin operations from the existing in-tree plugin to the pxd.portworx.com Container Storage Interface (CSI) Driver. Portworx CSI Driver must be installed on the cluster. To enable the feature, set CSIMigrationPortworx=true in kube-controller-manager and kubelet.

Using subPath

Sometimes, it is useful to share one volume for multiple uses in a single pod. The volumeMounts.subPath property specifies a sub-path inside the referenced volume instead of its root.

The following example shows how to configure a Pod with a LAMP stack (Linux Apache MySQL PHP) using a single, shared volume. This sample subPath configuration is not recommended for production use.

The PHP application's code and assets map to the volume's html folder and the MySQL database is stored in the volume's mysql folder. For example:

apiVersion: v1
kind: Pod
metadata:
  name: my-lamp-site
spec:
    containers:
    - name: mysql
      image: mysql
      env:
      - name: MYSQL_ROOT_PASSWORD
        value: "rootpasswd"
      volumeMounts:
      - mountPath: /var/lib/mysql
        name: site-data
        subPath: mysql
    - name: php
      image: php:7.0-apache
      volumeMounts:
      - mountPath: /var/www/html
        name: site-data
        subPath: html
    volumes:
    - name: site-data
      persistentVolumeClaim:
        claimName: my-lamp-site-data

Using subPath with expanded environment variables

FEATURE STATE: Kubernetes v1.17 [stable]

Use the subPathExpr field to construct subPath directory names from downward API environment variables. The subPath and subPathExpr properties are mutually exclusive.

In this example, a Pod uses subPathExpr to create a directory pod1 within the hostPath volume /var/log/pods. The hostPath volume takes the Pod name from the downwardAPI. The host directory /var/log/pods/pod1 is mounted at /logs in the container.

apiVersion: v1
kind: Pod
metadata:
  name: pod1
spec:
  containers:
  - name: container1
    env:
    - name: POD_NAME
      valueFrom:
        fieldRef:
          apiVersion: v1
          fieldPath: metadata.name
    image: busybox:1.28
    command: [ "sh", "-c", "while [ true ]; do echo 'Hello'; sleep 10; done | tee -a /logs/hello.txt" ]
    volumeMounts:
    - name: workdir1
      mountPath: /logs
      # The variable expansion uses round brackets (not curly brackets).
      subPathExpr: $(POD_NAME)
  restartPolicy: Never
  volumes:
  - name: workdir1
    hostPath:
      path: /var/log/pods

Resources

The storage media (such as Disk or SSD) of an emptyDir volume is determined by the medium of the filesystem holding the kubelet root dir (typically /var/lib/kubelet). There is no limit on how much space an emptyDir or hostPath volume can consume, and no isolation between containers or between pods.

To learn about requesting space using a resource specification, see how to manage resources.

Out-of-tree volume plugins

The out-of-tree volume plugins include Container Storage Interface (CSI), and also FlexVolume (which is deprecated). These plugins enable storage vendors to create custom storage plugins without adding their plugin source code to the Kubernetes repository.

Previously, all volume plugins were "in-tree". The "in-tree" plugins were built, linked, compiled, and shipped with the core Kubernetes binaries. This meant that adding a new storage system to Kubernetes (a volume plugin) required checking code into the core Kubernetes code repository.

Both CSI and FlexVolume allow volume plugins to be developed independent of the Kubernetes code base, and deployed (installed) on Kubernetes clusters as extensions.

For storage vendors looking to create an out-of-tree volume plugin, please refer to the volume plugin FAQ.

csi

Container Storage Interface (CSI) defines a standard interface for container orchestration systems (like Kubernetes) to expose arbitrary storage systems to their container workloads.

Please read the CSI design proposal for more information.

Once a CSI compatible volume driver is deployed on a Kubernetes cluster, users may use the csi volume type to attach or mount the volumes exposed by the CSI driver.

A csi volume can be used in a Pod in three different ways:

The following fields are available to storage administrators to configure a CSI persistent volume:

  • driver: A string value that specifies the name of the volume driver to use. This value must correspond to the value returned in the GetPluginInfoResponse by the CSI driver as defined in the CSI spec. It is used by Kubernetes to identify which CSI driver to call out to, and by CSI driver components to identify which PV objects belong to the CSI driver.
  • volumeHandle: A string value that uniquely identifies the volume. This value must correspond to the value returned in the volume.id field of the CreateVolumeResponse by the CSI driver as defined in the CSI spec. The value is passed as volume_id on all calls to the CSI volume driver when referencing the volume.
  • readOnly: An optional boolean value indicating whether the volume is to be "ControllerPublished" (attached) as read only. Default is false. This value is passed to the CSI driver via the readonly field in the ControllerPublishVolumeRequest.
  • fsType: If the PV's VolumeMode is Filesystem then this field may be used to specify the filesystem that should be used to mount the volume. If the volume has not been formatted and formatting is supported, this value will be used to format the volume. This value is passed to the CSI driver via the VolumeCapability field of ControllerPublishVolumeRequest, NodeStageVolumeRequest, and NodePublishVolumeRequest.
  • volumeAttributes: A map of string to string that specifies static properties of a volume. This map must correspond to the map returned in the volume.attributes field of the CreateVolumeResponse by the CSI driver as defined in the CSI spec. The map is passed to the CSI driver via the volume_context field in the ControllerPublishVolumeRequest, NodeStageVolumeRequest, and NodePublishVolumeRequest.
  • controllerPublishSecretRef: A reference to the secret object containing sensitive information to pass to the CSI driver to complete the CSI ControllerPublishVolume and ControllerUnpublishVolume calls. This field is optional, and may be empty if no secret is required. If the Secret contains more than one secret, all secrets are passed.
  • nodeStageSecretRef: A reference to the secret object containing sensitive information to pass to the CSI driver to complete the CSI NodeStageVolume call. This field is optional, and may be empty if no secret is required. If the Secret contains more than one secret, all secrets are passed.
  • nodePublishSecretRef: A reference to the secret object containing sensitive information to pass to the CSI driver to complete the CSI NodePublishVolume call. This field is optional, and may be empty if no secret is required. If the secret object contains more than one secret, all secrets are passed.

CSI raw block volume support

FEATURE STATE: Kubernetes v1.18 [stable]

Vendors with external CSI drivers can implement raw block volume support in Kubernetes workloads.

You can set up your PersistentVolume/PersistentVolumeClaim with raw block volume support as usual, without any CSI specific changes.

CSI ephemeral volumes

FEATURE STATE: Kubernetes v1.16 [beta]

You can directly configure CSI volumes within the Pod specification. Volumes specified in this way are ephemeral and do not persist across pod restarts. See Ephemeral Volumes for more information.

For more information on how to develop a CSI driver, refer to the kubernetes-csi documentation

Windows CSI proxy

FEATURE STATE: Kubernetes v1.22 [stable]

CSI node plugins need to perform various privileged operations like scanning of disk devices and mounting of file systems. These operations differ for each host operating system. For Linux worker nodes, containerized CSI node node plugins are typically deployed as privileged containers. For Windows worker nodes, privileged operations for containerized CSI node plugins is supported using csi-proxy, a community-managed, stand-alone binary that needs to be pre-installed on each Windows node.

For more details, refer to the deployment guide of the CSI plugin you wish to deploy.

Migrating to CSI drivers from in-tree plugins

FEATURE STATE: Kubernetes v1.17 [beta]

The CSIMigration feature, when enabled, directs operations against existing in-tree plugins to corresponding CSI plugins (which are expected to be installed and configured). As a result, operators do not have to make any configuration changes to existing Storage Classes, PersistentVolumes or PersistentVolumeClaims (referring to in-tree plugins) when transitioning to a CSI driver that supersedes an in-tree plugin.

The operations and features that are supported include: provisioning/delete, attach/detach, mount/unmount and resizing of volumes.

In-tree plugins that support CSIMigration and have a corresponding CSI driver implemented are listed in Types of Volumes.

The following in-tree plugins support persistent storage on Windows nodes:

flexVolume

FEATURE STATE: Kubernetes v1.23 [deprecated]

FlexVolume is an out-of-tree plugin interface that uses an exec-based model to interface with storage drivers. The FlexVolume driver binaries must be installed in a pre-defined volume plugin path on each node and in some cases the control plane nodes as well.

Pods interact with FlexVolume drivers through the flexVolume in-tree volume plugin. For more details, see the FlexVolume README document.

The following FlexVolume plugins, deployed as PowerShell scripts on the host, support Windows nodes:

Mount propagation

Mount propagation allows for sharing volumes mounted by a container to other containers in the same pod, or even to other pods on the same node.

Mount propagation of a volume is controlled by the mountPropagation field in Container.volumeMounts. Its values are:

  • None - This volume mount will not receive any subsequent mounts that are mounted to this volume or any of its subdirectories by the host. In similar fashion, no mounts created by the container will be visible on the host. This is the default mode.

    This mode is equal to private mount propagation as described in the Linux kernel documentation

  • HostToContainer - This volume mount will receive all subsequent mounts that are mounted to this volume or any of its subdirectories.

    In other words, if the host mounts anything inside the volume mount, the container will see it mounted there.

    Similarly, if any Pod with Bidirectional mount propagation to the same volume mounts anything there, the container with HostToContainer mount propagation will see it.

    This mode is equal to rslave mount propagation as described in the Linux kernel documentation

  • Bidirectional - This volume mount behaves the same the HostToContainer mount. In addition, all volume mounts created by the container will be propagated back to the host and to all containers of all pods that use the same volume.

    A typical use case for this mode is a Pod with a FlexVolume or CSI driver or a Pod that needs to mount something on the host using a hostPath volume.

    This mode is equal to rshared mount propagation as described in the Linux kernel documentation

Configuration

Before mount propagation can work properly on some deployments (CoreOS, RedHat/Centos, Ubuntu) mount share must be configured correctly in Docker as shown below.

Edit your Docker's systemd service file. Set MountFlags as follows:

MountFlags=shared

Or, remove MountFlags=slave if present. Then restart the Docker daemon:

sudo systemctl daemon-reload
sudo systemctl restart docker

What's next

Follow an example of deploying WordPress and MySQL with Persistent Volumes.

Last modified June 19, 2022 at 10:43 AM PST: Fix typo (2d2ae604dd)