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Operator for managing the Spark clusters on Kubernetes and OpenShift.

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spark-operator

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{CRD|ConfigMap}-based approach for managing the Spark clusters in Kubernetes and OpenShift.

This operator uses abstract-operator library.

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How does it work

UML diagram

Quick Start

Run the spark-operator deployment: Remember to change the namespace variable for the ClusterRoleBinding before doing this step

kubectl apply -f manifest/operator.yaml

Create new cluster from the prepared example:

kubectl apply -f examples/cluster.yaml

After issuing the commands above, you should be able to see a new Spark cluster running in the current namespace.

kubectl get pods
NAME                               READY     STATUS    RESTARTS   AGE
my-spark-cluster-m-5kjtj           1/1       Running   0          10s
my-spark-cluster-w-m8knz           1/1       Running   0          10s
my-spark-cluster-w-vg9k2           1/1       Running   0          10s
spark-operator-510388731-852b2     1/1       Running   0          27s

Once you don't need the cluster anymore, you can delete it by deleting the custom resource by:

kubectl delete sparkcluster my-spark-cluster

Very Quick Start

# create operator
kubectl apply -f http://bit.ly/sparkop

# create cluster
cat <<EOF | kubectl apply -f -
apiVersion: v1
kind: SparkCluster
metadata:
  name: my-cluster
spec:
  worker:
    instances: "2"
EOF

Limits and requests for cpu and memory in SparkCluster pods

The operator supports multiple fields for setting limit and request values for master and worker pods. You can see these being used in the examples/test directory.

  • cpu and memory specify both limit and request values for cpu and memory (that is, limits and requests will be equal) This was the first mechanism provided for setting limits and requests and has been retained for backward compatibility. However, a need was found to be able to set the requests and limits individually.

  • cpuRequest and memoryRequest set request values and take precedence over values from cpu and memory respectively

  • cpuLimit and memoryLimit set limit values and take precedence over values taken from cpu and memory respectively

Spark Applications

Apart from managing clusters with Apache Spark, this operator can also manage Spark applications similarly as the GoogleCloudPlatform/spark-on-k8s-operator. These applications spawn their own Spark cluster for their needs and it uses the Kubernetes as the native scheduling mechanism for Spark. For more details, consult the Spark docs.

# create spark application
cat <<EOF | kubectl apply -f -
apiVersion: v1
kind: SparkApplication
metadata:
  name: my-cluster
spec:
  mainApplicationFile: local:///opt/spark/examples/jars/spark-examples_2.11-2.3.0.jar
  mainClass: org.apache.spark.examples.SparkPi
EOF

OpenShift

For deployment on OpenShift use the same commands as above (with oc instead of kubectl if kubectl is not installed) and make sure the logged user can create CRDs: oc login -u system:admin && oc project default

Config Map approach

This operator can also work with Config Maps instead of CRDs. This can be useful in situations when user is not allowed to create CRDs or ClusterRoleBinding resources. The schema for config maps is almost identical to custom resources and you can check the examples.

kubectl apply -f manifest/operator-cm.yaml

The manifest above is almost the same as the operator.yaml. If the environmental variable CRD is set to false, the operator will watch on config maps with certain labels.

You can then create the Spark clusters as usual by creating the config map (CM).

kubectl apply -f examples/cluster-cm.yaml
kubectl get cm -l radanalytics.io/kind=SparkCluster

or Spark applications that are natively scheduled on Spark clusters by:

kubectl apply -f examples/test/cm/app.yaml
kubectl get cm -l radanalytics.io/kind=SparkApplication

Images

Image name Description Layers quay.io docker.io
:latest-released represents the latest released version Layers info quay.io repo docker.io repo
:latest represents the master branch Layers info
:x.y.z one particular released version Layers info

For each variant there is also available an image with -alpine suffix based on Alpine for instance Layers info

Configuring the operator

The spark-operator contains several defaults that are implicit to the creation of Spark clusters and applications. Here are a list of environment variables that can be set to adjust the default behaviors of the operator.

  • CRD set to true if the operator should respond to Custom Resources, and set to false if it should respond to ConfigMaps.
  • DEFAULT_SPARK_CLUSTER_IMAGE a container image reference that will be used as a default for all pods in a SparkCluster deployment when the image is not specified in the cluster manifest.
  • DEFAULT_SPARK_APP_IMAGE a container image reference that will be used as a default for all executor pods in a SparkApplication deployment when the image is not specified in the application manifest.

Please note that these environment variables must be set in the operator's container, see operator.yaml and operator-cm.yaml for operator deployment information.

Related projects

If you are looking for tooling to make interacting with the spark-operator more convenient, please see the following.

  • Ansible role is a simple way to deploy the Spark operator using Ansible ecosystem. The role is available also in the Ansible Galaxy.

  • oshinko-temaki is a shell application for generating SparkCluster manifest definitions. It can produce full schema manifests from a few simple command line flags.

For checking and verifying that your own container image will work smoothly with the operator use the following tool.

  • soit is a CLI tool that runs a set of tests against the given image to verify if it contains the right files on the file system, if worker can register with master, etc. Check the code in the repository.

The radanalyticsio/spark-operator is not the only Kubernetes operator service that targets Apache Spark.

  • GoogleCloudPlatform/spark-on-k8s-operator is an operator which shares a similar schema for the Spark cluster and application resources. One major difference between it and the radanalyticsio/spark-operator is that the latter has been designed to work well in environments where a user has a limited role-based access to Kubernetes, such as on OpenShift and also that radanalyticsio/spark-operator can deploy standalone Spark clusters.

Operator Marketplace

If you would like to install the operator into OpenShift (since 4.1) using the Operator Marketplace, simply run:

cat <<EOF | kubectl apply -f -
apiVersion: operators.coreos.com/v1
kind: OperatorSource
metadata:
  name: radanalyticsio-operators
  namespace: openshift-marketplace
spec:
  type: appregistry
  endpoint: https://quay.io/cnr
  registryNamespace: radanalyticsio
  displayName: "Operators from radanalytics.io"
  publisher: "Jirka Kremser"
EOF

You will find the operator in the OpenShift web console under Catalog > OperatorHub (make sure the namespace is set to openshift-marketplace).

Troubleshooting

Show the log:

# last 25 log entries
kubectl logs --tail 25 -l app.kubernetes.io/name=spark-operator
# follow logs
kubectl logs -f `kubectl get pod -l app.kubernetes.io/name=spark-operator -o='jsonpath="{.items[0].metadata.name}"' | sed 's/"//g'`

Run the operator from your host (also possible with the debugger/profiler):

java -jar target/spark-operator-*.jar

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