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CephObjectStore CRD

Rook allows creation and customization of object stores through the custom resource definitions (CRDs). The following settings are available for Ceph object stores.

Example

Erasure Coded

Erasure coded pools can only be used with dataPools. The metadataPool must use a replicated pool.

Note

This sample requires at least 3 bluestore OSDs, with each OSD located on a different node.

The OSDs must be located on different nodes, because the failureDomain is set to host and the erasureCoded chunk settings require at least 3 different OSDs (2 dataChunks + 1 codingChunks).

apiVersion: ceph.rook.io/v1
kind: CephObjectStore
metadata:
  name: my-store
  namespace: rook-ceph
spec:
  metadataPool:
    failureDomain: host
    replicated:
      size: 3
  dataPool:
    failureDomain: host
    erasureCoded:
      dataChunks: 2
      codingChunks: 1
  preservePoolsOnDelete: true
  gateway:
    # sslCertificateRef:
    # caBundleRef:
    port: 80
    # securePort: 443
    instances: 1
    # A key/value list of annotations
    annotations:
    #  key: value
    placement:
    #  nodeAffinity:
    #    requiredDuringSchedulingIgnoredDuringExecution:
    #      nodeSelectorTerms:
    #      - matchExpressions:
    #        - key: role
    #          operator: In
    #          values:
    #          - rgw-node
    #  tolerations:
    #  - key: rgw-node
    #    operator: Exists
    #  podAffinity:
    #  podAntiAffinity:
    #  topologySpreadConstraints:
    resources:
    #  limits:
    #    cpu: "500m"
    #    memory: "1024Mi"
    #  requests:
    #    cpu: "500m"
    #    memory: "1024Mi"
  #zone:
    #name: zone-a

Object Store Settings

Metadata

  • name: The name of the object store to create, which will be reflected in the pool and other resource names.
  • namespace: The namespace of the Rook cluster where the object store is created.

Pools

The pools allow all of the settings defined in the Block Pool CRD spec. For more details, see the Block Pool CRD settings. In the example above, there must be at least three hosts (size 3) and at least three devices (2 data + 1 coding chunks) in the cluster.

When the zone section is set pools with the object stores name will not be created since the object-store will the using the pools created by the ceph-object-zone.

  • metadataPool: The settings used to create all of the object store metadata pools. Must use replication.
  • dataPool: The settings to create the object store data pool. Can use replication or erasure coding.
  • preservePoolsOnDelete: If it is set to 'true' the pools used to support the object store will remain when the object store will be deleted. This is a security measure to avoid accidental loss of data. It is set to 'false' by default. If not specified is also deemed as 'false'.

Gateway Settings

The gateway settings correspond to the RGW daemon settings.

  • type: S3 is supported
  • sslCertificateRef: If specified, this is the name of the Kubernetes secret(opaque or tls type) that contains the TLS certificate to be used for secure connections to the object store. If it is an opaque Kubernetes Secret, Rook will look in the secret provided at the cert key name. The value of the cert key must be in the format expected by the RGW service: "The server key, server certificate, and any other CA or intermediate certificates be supplied in one file. Each of these items must be in PEM form." They are scenarios where the certificate DNS is set for a particular domain that does not include the local Kubernetes DNS, namely the object store DNS service endpoint. If adding the service DNS name to the certificate is not empty another key can be specified in the secret's data: insecureSkipVerify: true to skip the certificate verification. It is not recommended to enable this option since TLS is susceptible to machine-in-the-middle attacks unless custom verification is used.
  • caBundleRef: If specified, this is the name of the Kubernetes secret (type opaque) that contains additional custom ca-bundle to use. The secret must be in the same namespace as the Rook cluster. Rook will look in the secret provided at the cabundle key name.
  • hostNetwork: Whether host networking is enabled for the rgw daemon. If not set, the network settings from the cluster CR will be applied.
  • port: The port on which the Object service will be reachable. If host networking is enabled, the RGW daemons will also listen on that port. If running on SDN, the RGW daemon listening port will be 8080 internally.
  • securePort: The secure port on which RGW pods will be listening. A TLS certificate must be specified either via sslCerticateRef or service.annotations
  • instances: The number of pods that will be started to load balance this object store.
  • externalRgwEndpoints: A list of IP addresses to connect to external existing Rados Gateways (works with external mode). This setting will be ignored if the CephCluster does not have external spec enabled. Refer to the external cluster section for more details. Multiple endpoints can be given, but for stability of ObjectBucketClaims, we highly recommend that users give only a single external RGW endpoint that is a load balancer that sends requests to the multiple RGWs.
  • annotations: Key value pair list of annotations to add.
  • labels: Key value pair list of labels to add.
  • placement: The Kubernetes placement settings to determine where the RGW pods should be started in the cluster.
  • resources: Set resource requests/limits for the Gateway Pod(s), see Resource Requirements/Limits.
  • priorityClassName: Set priority class name for the Gateway Pod(s)
  • service: The annotations to set on to the Kubernetes Service of RGW. The service serving cert feature supported in Openshift is enabled by the following example:
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gateway:
  service:
    annotations:
      service.beta.openshift.io/serving-cert-secret-name: <name of TLS secret for automatic generation>

Example of external rgw endpoints to connect to:

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gateway:
  port: 80
  externalRgwEndpoints:
    - ip: 192.168.39.182
      # hostname: example.com

This will create a service with the endpoint 192.168.39.182 on port 80, pointing to the Ceph object external gateway. All the other settings from the gateway section will be ignored, except for securePort.

Zone Settings

The zone settings allow the object store to join custom created ceph-object-zone.

  • name: the name of the ceph-object-zone the object store will be in.

Runtime settings

MIME types

Rook provides a default mime.types file for each Ceph object store. This file is stored in a Kubernetes ConfigMap with the name rook-ceph-rgw-<STORE-NAME>-mime-types. For most users, the default file should suffice, however, the option is available to users to edit the mime.types file in the ConfigMap as they desire. Users may have their own special file types, and particularly security conscious users may wish to pare down the file to reduce the possibility of a file type execution attack.

Rook will not overwrite an existing mime.types ConfigMap so that user modifications will not be destroyed. If the object store is destroyed and recreated, the ConfigMap will also be destroyed and created anew.

Health settings

Rook will be default monitor the state of the object store endpoints. The following CRD settings are available:

  • healthCheck: main object store health monitoring section
    • startupProbe: Disable, or override timing and threshold values of the object gateway startup probe.
    • readinessProbe: Disable, or override timing and threshold values of the object gateway readiness probe.

Here is a complete example:

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healthCheck:
  startupProbe:
    disabled: false
  readinessProbe:
    disabled: false
    periodSeconds: 5
    failureThreshold: 2

You can monitor the health of a CephObjectStore by monitoring the gateway deployments it creates. The primary deployment created is named rook-ceph-rgw-<store-name>-a where store-name is the name of the CephObjectStore (don't forget the -a at the end).

Security settings

Ceph RGW supports Server Side Encryption as defined in AWS S3 protocol with three different modes: AWS-SSE:C, AWS-SSE:KMS and AWS-SSE:S3. The last two modes require a Key Management System (KMS) like HashiCorp Vault. Currently, Vault is the only supported KMS backend for CephObjectStore.

Refer to the Vault KMS section for details about Vault. If these settings are defined, then RGW will establish a connection between Vault and whenever S3 client sends request with Server Side Encryption. Ceph's Vault documentation has more details.

The security section contains settings related to KMS encryption of the RGW.

security:
  kms:
    connectionDetails:
      KMS_PROVIDER: vault
      VAULT_ADDR: http://vault.default.svc.cluster.local:8200
      VAULT_BACKEND_PATH: rgw
      VAULT_SECRET_ENGINE: kv
      VAULT_BACKEND: v2
    # name of the k8s secret containing the kms authentication token
    tokenSecretName: rgw-vault-kms-token
  s3:
    connectionDetails:
      KMS_PROVIDER: vault
      VAULT_ADDR: http://vault.default.svc.cluster.local:8200
      VAULT_BACKEND_PATH: rgw
      VAULT_SECRET_ENGINE: transit
    # name of the k8s secret containing the kms authentication token
    tokenSecretName: rgw-vault-s3-token

For RGW, please note the following:

  • VAULT_SECRET_ENGINE: the secret engine which Vault should use. Currently supports kv and transit. AWS-SSE:KMS supports transit engine and kv engine version 2. AWS-SSE:S3 only supports transit engine.
  • The Storage administrator needs to create a secret in the Vault server so that S3 clients use that key for encryption for AWS-SSE:KMS
vault kv put rook/<mybucketkey> key=$(openssl rand -base64 32) # kv engine
vault write -f transit/keys/<mybucketkey> exportable=true # transit engine
  • TLS authentication with custom certificates between Vault and CephObjectStore RGWs are supported from ceph v16.2.6 onwards
  • tokenSecretName can be (and often will be) the same for both kms and s3 configurations.
  • AWS-SSE:S3 requires Ceph Quincy (v17.2.3) and later.

Deleting a CephObjectStore

During deletion of a CephObjectStore resource, Rook protects against accidental or premature destruction of user data by blocking deletion if there are any object buckets in the object store being deleted. Buckets may have been created by users or by ObjectBucketClaims.

For deletion to be successful, all buckets in the object store must be removed. This may require manual deletion or removal of all ObjectBucketClaims. Alternately, the cephobjectstore.ceph.rook.io finalizer on the CephObjectStore can be removed to remove the Kubernetes Custom Resource, but the Ceph pools which store the data will not be removed in this case.

Rook will warn about which buckets are blocking deletion in three ways:

  1. An event will be registered on the CephObjectStore resource
  2. A status condition will be added to the CephObjectStore resource
  3. An error will be added to the Rook Ceph Operator log

If the CephObjectStore is configured in a multisite setup the above conditions are applicable only to stores that belong to a single master zone. Otherwise the conditions are ignored. Even if the store is removed the user can access the data from a peer object store.