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EKS on Amazon Web Services Deployment

OpenMetadata supports the Installation and Running of Application on Elastic Kubernetes Services (EKS) through Helm Charts. However, there are some additional configurations which needs to be done as prerequisites for the same.

It is recommended to use Amazon RDS and Amazon OpenSearch Service for Production Deployments.

We support

  • Amazon RDS (MySQL) engine version 8 or higher
  • Amazon RDS (PostgreSQL) engine version 12 or higher
  • Amazon OpenSearch engine version 2.X (upto 2.7)

We recommend

  • Amazon RDS to be in Multiple Availability Zones.
  • Amazon OpenSearch (or ElasticSearch) Service with Multiple Availability Zones with minimum 2 Nodes.

Once you have the RDS and OpenSearch Services Setup, you can update the environment variables below for OpenMetadata kubernetes deployments to connect with Database and ElasticSearch.

Make sure to create RDS and OpenSearch credentials as Kubernetes Secrets mentioned here.

Also, disable MySQL and ElasticSearch from OpenMetadata Dependencies Helm Charts as mentioned in the FAQs here.

You can follow official AWS Guides here to provision EFS File System in the same VPC which is associated with your EKS Cluster.

OpenMetadata helm chart depends on Airflow and Airflow expects a persistent disk that support ReadWriteMany (the volume can be mounted as read-write by many nodes).

In AWS, this is achieved by Elastic File System (EFS) service. AWS Elastic Block Store (EBS) does not provide ReadWriteMany Volume access mode as EBS will only be attached to one Kubernetes Node at any given point of time.

In order to provision persistent volumes from AWS EFS, you will need to setup and install aws-efs-csi-driver. Note that this is required for Airflow as One OpenMetadata Dependencies.

Also, aws-ebs-csi-driver might be required for Persistent Volumes that are to be used for MySQL and ElasticSearch as OpenMetadata Dependencies.

The below guide provides Persistent Volumes provisioning as static volumes (meaning you will be responsible to create, maintain and destroy Persistent Volumes).

Please note that we are using one AWS Elastic File System (EFS) service with subdirectories as airflow-dags and airflow-logs with the reference in this documentation. Also, it is presumed that airflow-dags and airflow-logs directories are already available on that file system.

In order to create directories inside the AWS Elastic File System (EFS) you would need to follow these steps.

Create Persistent Volumes and Persistent Volume claims with the below command.

Create Persistent Volumes and Persistent Volume claims with the below command.

Since airflow pods run as non root users, they would not have write access on the nfs server volumes. In order to fix the permission here, spin up a pod with persistent volumes attached and run it once.

You can find more reference on AWS EFS permissions in docs here.

Run the below command to create the pod and fix the permissions

Override openmetadata dependencies airflow helm values to bind the efs persistent volumes for DAGs and logs.

For more information on airflow helm chart values, please refer to airflow-helm.

When deploying openmetadata dependencies helm chart, use the below command -

Once the openmetadata dependencies helm chart deployed, you can then run the below command to install the openmetadata helm chart -

Again, this uses the values defined here. Use the --values flag to point to your own YAML configuration if needed.

FAQs

If you are facing the below issue -

This error is typically related to EKS Cluster not able to reach to EFS File systems. You can check the security groups associated between the connectivity EFS and EKS. Here is an article which further describes the steps required to create Security Group Rules for EKS to use EFS over port 2049.

It can also happen if the mount targets are already available for EKS Nodes but the Nodes do not pick that up. In such cases, you can do an AWS AutoScaling Group instance refresh in order for EKS nodes to get the available mount targets.

If your openmetadata pods are not in ready state at any point in time and the openmetadata pod logs speaks about the below issue -

This is due to the default JVM Heap Space configuration (1 GiB) being not enough for your workloads. In order to resolve this issue, head over to your custom openmetadata helm values and append the below environment variable

The flag Xmx specifies the maximum memory allocation pool for a Java virtual machine (JVM), while Xms specifies the initial memory allocation pool.

Upgrade the helm charts with the above changes using the following command helm upgrade --install openmetadata open-metadata/openmetadata --values <values.yml> --namespace <namespaceName>. Update this command your values.yml filename and namespaceName where you have deployed OpenMetadata in Kubernetes.

If you are facing the below issue with PostgreSQL as Database Backend for OpenMetadata Application,

It seems the Database User does not have sufficient privileges. In order to resolve the above issue, grant usage permissions to the PSQL User.

OpenMetadata helm charts uses official published docker images from DockerHub. A typical scenario will be to install organization certificates for connecting with inhouse systems.

For Example -

where docker.getcollate.io/openmetadata/server:x.y.z needs to point to the same version of the OpenMetadata server, for example docker.getcollate.io/openmetadata/server:1.3.1. This image needs to be built and published to the container registry of your choice.

The OpenMetadata Application gets installed as part of openmetadata helm chart. In this step, update the custom helm values using YAML file to point the image created in the previous step. For example, create a helm values file named values.yaml with the following contents -

Upgrade/Install your openmetadata helm charts with the below single command:

One possible use case where you would need to use a custom image for the ingestion is because you have developed your own custom connectors. You can find a complete working example of this here. After you have your code ready, the steps would be the following:

For example -

where docker.getcollate.io/openmetadata/ingestion:x.y.z needs to point to the same version of the OpenMetadata server, for example docker.getcollate.io/openmetadata/ingestion:1.3.1. This image needs to be built and published to the container registry of your choice.

The ingestion containers (which is the one shipping Airflow) gets installed in the openmetadata-dependencies helm chart. In this step, we use our own custom values YAML file to point to the image we just created on the previous step. You can create a file named values.deps.yaml with the following contents:

Upgrade/Install your openmetadata-dependencies helm charts with the below single command:

If you are using MySQL and ElasticSearch externally, you would want to disable the local installation of mysql and elasticsearch while installing OpenMetadata Dependencies Helm Chart. You can disable the MySQL and ElasticSearch Helm Dependencies by setting enabled: false value for each dependency. Below is the command to set helm values from Helm CLI -

Alternatively, you can create a custom YAML file named values.deps.yaml to disable installation of MySQL and Elasticsearch .

OpenMetadata Supports PostgreSQL as one of the Database Dependencies. OpenMetadata Helm Charts by default does not include PostgreSQL as Database Dependencies. In order to configure Helm Charts with External Database like PostgreSQL, follow the below guide to make the helm values change and upgrade / install OpenMetadata helm charts with the same.

We ship airflow-helm as one of OpenMetadata Dependencies with default values to connect to MySQL Database as part of externalDatabase configurations.

You can find more information on setting the externalDatabase as part of helm values here.

With OpenMetadata Dependencies Helm Charts, your helm values would look something like below -

For the above code, it is assumed you are creating a kubernetes secret for storing Airflow Database login Credentials. A sample command to create the secret will be kubectl create secret generic airflow-postgresql-secrets --from-literal=airflow-postgresql-password=<password>.

Update the openmetadata.config.database.* helm values for OpenMetadata Application to connect to External Database like PostgreSQL.

With OpenMetadata Helm Charts, your helm values would look something like below -

For the above code, it is assumed you are creating a kubernetes secret for storing OpenMetadata Database login Credentials. A sample command to create the secret will be kubectl create secret generic openmetadata-postgresql-secrets --from-literal=openmetadata-postgresql-password=<password>.

Once you make the above changes to your helm values, run the below command to install/upgrade helm charts -

Our OpenMetadata Dependencies Helm Charts are internally depends on three sub-charts -

If you are looking to customize the deployments of any of the above dependencies, please refer to the above links for customizations of helm values for further references.

By default, OpenMetadata Dependencies helm chart provides initial generic customization of these helm values in order to get you started quickly. You can refer to the openmetadata-dependencies helm charts default values here.