OpenEBS for MongoDB

OpenEBS and MongoDB

Introduction

MongoDB is a cross-platform document-oriented database. Classified as a NoSQL database, MongoDB eschews the traditional table-based relational database structure in favour of JSON-like documents with dynamic schemas, making the integration of data in certain types of applications easier and faster. MongoDB is deployed usually as a statefulset on Kubernetes and requires persistent storage for each instance of MongoDB StorageManager instance. OpenEBS provides persistent volumes on the fly when StorageManagers are scaled up.

Advantages of using OpenEBS for MongoDB:

  • No need to manage the local disks, they are managed by OpenEBS
  • Large size PVs can be provisioned by OpenEBS and MongoDB
  • Start with small storage and add disks as needed on the fly. Sometimes MongoDB instances are scaled up because of capacity on the nodes. With OpenEBS persistent volumes, capacity can be thin provisioned and disks can be added to OpenEBS on the fly without disruption of service
  • MongoDB sometimes need highly available storage, in such cases OpenEBS volumes can be configured with 3 replicas.
  • If required, take backup of the MongoDB data periodically and back them up to S3 or any object storage so that restoration of the same data is possible to the same or any other Kubernetes cluster

Note: MongoDB can be deployed both as deployment or as statefulset. When MongoDB deployed as statefulset, you don’t need to replicate the data again at OpenEBS level. When MongoDB is deployed as deployment, consider 3 OpenEBS replicas, choose the StorageClass accordingly.

Deployment model

OpenEBS and Mongo

Configuration workflow

  1. Install OpenEBS

    If OpenEBS is not installed in your K8s cluster, this can done from here. If OpenEBS is already installed, go to the next step.

  2. Connect to Kubera (Optional) : Connecting the Kubernetes cluster to Kubera provides good visibility of storage resources. Kubera has various support options for enterprise customers.

  3. Configure cStor Pool

    After OpenEBS installation, cStor pool has to be configured. If cStor Pool is not configured in your OpenEBS cluster, this can be done from here. During cStor Pool creation, make sure that the maxPools parameter is set to >=3. Sample YAML named openebs-config.yaml for configuring cStor Pool is provided in the Configuration details below. If cStor pool is already configured, go to the next step.

  4. Create Storage Class

    You must configure a StorageClass to provision cStor volume on given cStor pool. StorageClass is the interface through which most of the OpenEBS storage policies are defined. In this solution we are using a StorageClass to consume the cStor Pool which is created using external disks attached on the Nodes. In this solution, MongoDB is installed as a Deployment. So it requires replication at the storage level. So cStor volume replicaCount is 3. Sample YAML named openebs-sc-disk.yaml to consume cStor pool with cStoveVolume Replica count as 3 is provided in the configuration details below.

  5. Launch and test MongoDB

    Use stable MongoDB chart with helm to install MongoDB deployment in your cluster using the following command. In the following command, it will create a PVC with 8Gi size with a storage replication factor 3.

    1. helm install --name my-release --set persistence.storageClass=openebs-cstor-disk stable/mongodb

    For more information on installation, see MongoDB documentation.

Reference at openebs.ci

A live deployment of MongoDB using OpenEBS volumes can be seen at the website www.openebs.ci

Deployment YAML spec files for MongoDB and OpenEBS resources are found here

OpenEBS-CI dashboard of MongoDB

Post deployment Operations

Monitor OpenEBS Volume size

It is not seamless to increase the cStor volume size (refer to the roadmap item). Hence, it is recommended that sufficient size is allocated during the initial configuration. However, an alert can be setup for volume size threshold using Kubera.

Monitor cStor Pool size

As in most cases, cStor pool may not be dedicated to just Mongo database alone. It is recommended to watch the pool capacity and add more disks to the pool before it hits 80% threshold. See cStorPool metrics.

Configuration details

openebs-config.yaml

  1. #Use the following YAMLs to create a cStor Storage Pool.
  2. # and associated storage class.
  3. apiVersion: openebs.io/v1alpha1
  4. kind: StoragePoolClaim
  5. metadata:
  6. name: cstor-disk
  7. spec:
  8. name: cstor-disk
  9. type: disk
  10. poolSpec:
  11. poolType: striped
  12. # NOTE - Appropriate disks need to be fetched using `kubectl get disks`
  13. #
  14. # `Disk` is a custom resource supported by OpenEBS with `node-disk-manager`
  15. # as the disk operator
  16. # Replace the following with actual disk CRs from your cluster `kubectl get disks`
  17. # Uncomment the below lines after updating the actual disk names.
  18. disks:
  19. diskList:
  20. # Replace the following with actual disk CRs from your cluster from `kubectl get disks`
  21. # - disk-184d99015253054c48c4aa3f17d137b1
  22. # - disk-2f6bced7ba9b2be230ca5138fd0b07f1
  23. # - disk-806d3e77dd2e38f188fdaf9c46020bdc
  24. # - disk-8b6fb58d0c4e0ff3ed74a5183556424d
  25. # - disk-bad1863742ce905e67978d082a721d61
  26. # - disk-d172a48ad8b0fb536b9984609b7ee653
  27. ---

openebs-sc-disk.yaml

  1. apiVersion: storage.k8s.io/v1
  2. kind: StorageClass
  3. metadata:
  4. name: openebs-cstor-disk
  5. annotations:
  6. openebs.io/cas-type: cstor
  7. cas.openebs.io/config: |
  8. - name: StoragePoolClaim
  9. value: "cstor-disk"
  10. - name: ReplicaCount
  11. value: "3"
  12. provisioner: openebs.io/provisioner-iscsi
  13. reclaimPolicy: Delete
  14. ---

See Also:

OpenEBS architecture

OpenEBS use cases

cStor pools overview