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Combined Cluster
A Kafka combined cluster is a group of kafka brokers where each broker also acts as a controller and participates in leader election as a voter. Combined mode can be used in development environment, but it should be avoided in critical deployment environments.
Before You Begin
At first, you need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. If you do not already have a cluster, you can create one by using kind.
Now, install the KubeDB operator in your cluster following the steps here.
To keep things isolated, this tutorial uses a separate namespace called demo throughout this tutorial.
$ kubectl create namespace demo
namespace/demo created
$ kubectl get namespace
NAME STATUS AGE
demo Active 9s
Note: YAML files used in this tutorial are stored in here in GitHub repository kubedb/docs.
Create Standalone Kafka Cluster
Here, we are going to create a standalone (ie. replicas: 1) Kafka cluster in Kraft mode. For this demo, we are going to provision kafka version 3.3.2. To learn more about Kafka CR, visit here. visit here to learn more about KafkaVersion CR.
apiVersion: kubedb.com/v1alpha2
kind: Kafka
metadata:
name: kafka-standalone
namespace: demo
spec:
replicas: 1
version: 3.3.2
storage:
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 1Gi
storageClassName: standard
storageType: Durable
terminationPolicy: DoNotTerminate
Let’s deploy the above example by the following command:
$ kubectl create -f https://github.com/kubedb/docs/raw/v2023.12.11/docs/examples/kafka/clustering/kf-standalone.yaml
kafka.kubedb.com/kafka-standalone created
Watch the bootstrap progress:
$ kubectl get kf -n demo -w
NAME TYPE VERSION STATUS AGE
kafka-standalone kubedb.com/v1alpha2 3.3.2 Provisioning 8s
kafka-standalone kubedb.com/v1alpha2 3.3.2 Provisioning 14s
kafka-standalone kubedb.com/v1alpha2 3.3.2 Provisioning 35s
kafka-standalone kubedb.com/v1alpha2 3.3.2 Provisioning 35s
kafka-standalone kubedb.com/v1alpha2 3.3.2 Provisioning 36s
kafka-standalone kubedb.com/v1alpha2 3.3.2 Ready 41s
Hence, the cluster is ready to use. Let’s check the k8s resources created by the operator on the deployment of Kafka CRO:
$ kubectl get all,secret,pvc -n demo -l 'app.kubernetes.io/instance=kafka-standalone'
NAME READY STATUS RESTARTS AGE
pod/kafka-standalone-0 1/1 Running 0 8m56s
NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE
service/kafka-standalone-pods ClusterIP None <none> 9092/TCP,9093/TCP,29092/TCP 8m59s
NAME READY AGE
statefulset.apps/kafka-standalone 1/1 8m56s
NAME TYPE VERSION AGE
appbinding.appcatalog.appscode.com/kafka-standalone kubedb.com/kafka 3.3.2 8m56s
NAME TYPE DATA AGE
secret/kafka-standalone-admin-cred kubernetes.io/basic-auth 2 8m59s
secret/kafka-standalone-config Opaque 2 8m59s
NAME STATUS VOLUME CAPACITY ACCESS MODES STORAGECLASS AGE
persistentvolumeclaim/kafka-standalone-data-kafka-standalone-0 Bound pvc-56f8284a-249e-4444-ab3d-31e01662a9a0 1Gi RWO standard 8m56s
Create Multi-Node Combined Kafka Cluster
Here, we are going to create a multi-node (say replicas: 3) Kafka cluster. We will use the KafkaVersion 3.4.0 for this demo. To learn more about kafka CR, visit here.
apiVersion: kubedb.com/v1alpha2
kind: Kafka
metadata:
name: kafka-multinode
namespace: demo
spec:
replicas: 3
version: 3.3.2
storage:
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 1Gi
storageClassName: standard
storageType: Durable
terminationPolicy: DoNotTerminate
Let’s deploy the above example by the following command:
$ kubectl create -f https://github.com/kubedb/docs/raw/v2023.12.11/docs/examples/kafka/clustering/kf-multinode.yaml
kafka.kubedb.com/kafka-multinode created
Watch the bootstrap progress:
$ kubectl get kf -n demo -w
kafka-multinode kubedb.com/v1alpha2 3.3.2 Provisioning 9s
kafka-multinode kubedb.com/v1alpha2 3.3.2 Provisioning 14s
kafka-multinode kubedb.com/v1alpha2 3.3.2 Provisioning 18s
kafka-multinode kubedb.com/v1alpha2 3.3.2 Provisioning 2m6s
kafka-multinode kubedb.com/v1alpha2 3.3.2 Provisioning 2m8s
kafka-multinode kubedb.com/v1alpha2 3.3.2 Ready 2m14s
Hence, the cluster is ready to use. Let’s check the k8s resources created by the operator on the deployment of Kafka CRO:
$ kubectl get all,secret,pvc -n demo -l 'app.kubernetes.io/instance=kafka-multinode'
NAME READY STATUS RESTARTS AGE
pod/kafka-multinode-0 1/1 Running 0 6m2s
pod/kafka-multinode-1 1/1 Running 0 5m56s
pod/kafka-multinode-2 1/1 Running 0 5m51s
NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE
service/kafka-multinode-pods ClusterIP None <none> 9092/TCP,9093/TCP,29092/TCP 6m7s
NAME READY AGE
statefulset.apps/kafka-multinode 3/3 6m2s
NAME TYPE VERSION AGE
appbinding.appcatalog.appscode.com/kafka-multinode kubedb.com/kafka 3.3.2 6m2s
NAME TYPE DATA AGE
secret/kafka-multinode-admin-cred kubernetes.io/basic-auth 2 6m7s
secret/kafka-multinode-config Opaque 2 6m7s
NAME STATUS VOLUME CAPACITY ACCESS MODES STORAGECLASS AGE
persistentvolumeclaim/kafka-multinode-data-kafka-multinode-0 Bound pvc-15cc2329-15ba-4781-8b7f-f0fe6cf81614 1Gi RWO standard 6m2s
persistentvolumeclaim/kafka-multinode-data-kafka-multinode-1 Bound pvc-bc3773cc-dff0-458c-b71a-7ef6aa877549 1Gi RWO standard 5m56s
persistentvolumeclaim/kafka-multinode-data-kafka-multinode-2 Bound pvc-e4829946-b2bb-473e-84d9-c5f9c360f3f0 1Gi RWO standard 5m51s
Publish & Consume messages with Kafka
We will create a Kafka topic using kafka-topics.sh script which is provided by kafka container itself. We will use kafka console producer and kafka console consumer as clients for publishing messages to the topic and then consume those messages. Exec into one of the kafka brokers in interactive mode first.
$ kubectl exec -it -n demo kafka-multinode-0 -- bash
root@kafka-multinode-0:~# pwd
/opt/kafka
You will find a file named clientauth.properties in the config directory. This file is generated by the operator which contains necessary authentication/authorization configurations that are required during publishing or subscribing messages to a kafka topic.
root@kafka-multinode-0:~# cat config/clientauth.properties
security.protocol=SASL_PLAINTEXT
sasl.mechanism=PLAIN
sasl.jaas.config=org.apache.kafka.common.security.plain.PlainLoginModule required username="admin" password="************";
Now, we have to use a bootstrap server to perform operations in a kafka broker. For this demo, we are going to use the http endpoint of the headless service kafka-multinode-pods as bootstrap server for publishing & consuming messages to kafka brokers. These endpoints are pointing to all the kafka broker pods. We will set an environment variable for the clientauth.properties filepath as well. At first, describe the service to get the http endpoints.
$ kubectl describe svc -n demo kafka-multinode-pods
Name: kafka-multinode-pods
Namespace: demo
Labels: app.kubernetes.io/component=database
app.kubernetes.io/instance=kafka-multinode
app.kubernetes.io/managed-by=kubedb.com
app.kubernetes.io/name=kafkas.kubedb.com
Annotations: <none>
Selector: app.kubernetes.io/instance=kafka-multinode,app.kubernetes.io/managed-by=kubedb.com,app.kubernetes.io/name=kafkas.kubedb.com
Type: ClusterIP
IP Family Policy: SingleStack
IP Families: IPv4
IP: None
IPs: None
Port: http 9092/TCP
TargetPort: http/TCP
Endpoints: 10.244.0.69:9092,10.244.0.71:9092,10.244.0.73:9092
Port: controller 9093/TCP
TargetPort: controller/TCP
Endpoints: 10.244.0.69:9093,10.244.0.71:9093,10.244.0.73:9093
Port: internal 29092/TCP
TargetPort: internal/TCP
Endpoints: 10.244.0.69:29092,10.244.0.71:29092,10.244.0.73:29092
Session Affinity: None
Events: <none>
Use the http endpoints and clientauth.properties file to set environment variables. These environment variables will be useful for handling console command operations easily.
root@kafka-multinode-0:~# export SERVER="10.244.0.69:9092,10.244.0.71:9092,10.244.0.73:9092"
root@kafka-multinode-0:~# export CLIENTAUTHCONFIG="$HOME/config/clientauth.properties"
Let’s describe the broker metadata for the quorum.
root@kafka-multinode-0:~# kafka-metadata-quorum.sh --command-config $CLIENTAUTHCONFIG --bootstrap-server $SERVER describe --status
ClusterId: 11ed-957c-625c6a5f47bw
LeaderId: 0
LeaderEpoch: 19
HighWatermark: 2601
MaxFollowerLag: 0
MaxFollowerLagTimeMs: 0
CurrentVoters: [0,1,2]
CurrentObservers: []
It will show you important metadata information like clusterID, current leader ID, broker IDs which are participating in leader election voting and IDs of those brokers who are observers. It is important to mention that each broker is assigned a numeric ID which is called its broker ID. The ID is assigned sequentially with respect to the host pod name. In this case, The pods assigned broker IDs are as follows:
| Pods | Broker ID |
|---|---|
| kafka-multinode-0 | 0 |
| kafka-multinode-1 | 1 |
| kafka-multinode-2 | 2 |
Let’s create a topic named sample with 1 partitions and a replication factor of 1. Describe the topic once it’s created. You will see the leader ID for each partition and their replica IDs along with in-sync-replicas(ISR).
root@kafka-multinode-0:~# kafka-topics.sh --command-config $CLIENTAUTHCONFIG --create --topic sample --partitions 1 --replication-factor 1 --bootstrap-server $SERVER
Created topic sample.
root@kafka-multinode-0:~# kafka-topics.sh --command-config $CLIENTAUTHCONFIG --describe --topic sample --bootstrap-server $SERVER
Topic: sample TopicId: KVpw_JXfRjaeUHfoXLPBvQ PartitionCount: 1 ReplicationFactor: 1 Configs: segment.bytes=1073741824
Topic: sample Partition: 0 Leader: 0 Replicas: 0 Isr: 0
Now, we are going to start a producer and a consumer for topic sample using console. Let’s use this current terminal for producing messages and open a new terminal for consuming messages. Let’s set the environment variables for bootstrap server and the configuration file in consumer terminal also.
From the topic description we can see that the leader partition for partition 0 is 0 (the broker that we are on). If we produce messages to kafka-multinode-0 broker(brokerID=0) it will store those messages in partition 0. Let’s produce messages in the producer terminal and consume them from the consumer terminal.
root@kafka-quickstart-0:~# kafka-console-producer.sh --producer.config $CLIENTAUTHCONFIG --topic sample --request-required-acks all --bootstrap-server $SERVER
>message one
>message two
>message three
>
root@kafka-quickstart-0:/# kafka-console-consumer.sh --consumer.config $CLIENTAUTHCONFIG --topic sample --from-beginning --bootstrap-server $SERVER --partition 0
message one
message two
message three
Notice that, messages are coming to the consumer as you continue sending messages via producer. So, we have created a kafka topic and used kafka console producer and consumer to test message publishing and consuming successfully.
Cleaning Up
TO clean up the k8s resources created by this tutorial, run:
# standalone cluster
$ kubectl patch -n demo kf kafka-standalone -p '{"spec":{"terminationPolicy":"WipeOut"}}' --type="merge"
$ kubectl delete kf -n demo kafka-standalone
# multinode cluster
$ kubectl patch -n demo kf kafka-multinode -p '{"spec":{"terminationPolicy":"WipeOut"}}' --type="merge"
$ kubectl delete kf -n demo kafka-multinode
# delete namespace
$ kubectl delete namespace demo
Next Steps
- Deploy dedicated topology cluster for Apache Kafka
- Monitor your Kafka cluster with KubeDB using
out-of-the-boxPrometheus operator. - Detail concepts of Kafka object.
- Detail concepts of KafkaVersion object.
- Learn to use KubeDB managed Kafka objects using CLIs.
- Want to hack on KubeDB? Check our contribution guidelines.