1. Overview of Strimzi
Strimzi simplifies the process of running Apache Kafka in a Kubernetes cluster.
This guide provides instructions for configuring Kafka components and using Strimzi Operators. Procedures relate to how you might want to modify your deployment and introduce additional features, such as Cruise Control or distributed tracing.
You can configure your deployment using Strimzi custom resources. The Custom resource API reference describes the properties you can use in your configuration.
Note
|
Looking to get started with Strimzi? For step-by-step deployment instructions, see the Deploying and Upgrading Strimzi guide. |
1.1. Kafka capabilities
The underlying data stream-processing capabilities and component architecture of Kafka can deliver:
-
Microservices and other applications to share data with extremely high throughput and low latency
-
Message ordering guarantees
-
Message rewind/replay from data storage to reconstruct an application state
-
Message compaction to remove old records when using a key-value log
-
Horizontal scalability in a cluster configuration
-
Replication of data to control fault tolerance
-
Retention of high volumes of data for immediate access
1.2. Kafka use cases
Kafka’s capabilities make it suitable for:
-
Event-driven architectures
-
Event sourcing to capture changes to the state of an application as a log of events
-
Message brokering
-
Website activity tracking
-
Operational monitoring through metrics
-
Log collection and aggregation
-
Commit logs for distributed systems
-
Stream processing so that applications can respond to data in real time
1.3. How Strimzi supports Kafka
Strimzi provides container images and Operators for running Kafka on Kubernetes. Strimzi Operators are fundamental to the running of Strimzi. The Operators provided with Strimzi are purpose-built with specialist operational knowledge to effectively manage Kafka.
Operators simplify the process of:
-
Deploying and running Kafka clusters
-
Deploying and running Kafka components
-
Configuring access to Kafka
-
Securing access to Kafka
-
Upgrading Kafka
-
Managing brokers
-
Creating and managing topics
-
Creating and managing users
1.4. Strimzi Operators
Strimzi supports Kafka using Operators to deploy and manage the components and dependencies of Kafka to Kubernetes.
Operators are a method of packaging, deploying, and managing a Kubernetes application. Strimzi Operators extend Kubernetes functionality, automating common and complex tasks related to a Kafka deployment. By implementing knowledge of Kafka operations in code, Kafka administration tasks are simplified and require less manual intervention.
Operators
Strimzi provides Operators for managing a Kafka cluster running within a Kubernetes cluster.
- Cluster Operator
-
Deploys and manages Apache Kafka clusters, Kafka Connect, Kafka MirrorMaker, Kafka Bridge, Kafka Exporter, Cruise Control, and the Entity Operator
- Entity Operator
-
Comprises the Topic Operator and User Operator
- Topic Operator
-
Manages Kafka topics
- User Operator
-
Manages Kafka users
The Cluster Operator can deploy the Topic Operator and User Operator as part of an Entity Operator configuration at the same time as a Kafka cluster.
1.4.1. Cluster Operator
Strimzi uses the Cluster Operator to deploy and manage clusters for:
-
Kafka (including ZooKeeper, Entity Operator, Kafka Exporter, and Cruise Control)
-
Kafka Connect
-
Kafka MirrorMaker
-
Kafka Bridge
Custom resources are used to deploy the clusters.
For example, to deploy a Kafka cluster:
-
A
Kafka
resource with the cluster configuration is created within the Kubernetes cluster. -
The Cluster Operator deploys a corresponding Kafka cluster, based on what is declared in the
Kafka
resource.
The Cluster Operator can also deploy (through configuration of the Kafka
resource):
-
A Topic Operator to provide operator-style topic management through
KafkaTopic
custom resources -
A User Operator to provide operator-style user management through
KafkaUser
custom resources
The Topic Operator and User Operator function within the Entity Operator on deployment.
You can use the Cluster Operator with a deployment of Strimzi Drain Cleaner to help with pod evictions. By deploying the Strimzi Drain Cleaner, you can use the Cluster Operator to move Kafka pods instead of Kubernetes. Strimzi Drain Cleaner annotates pods being evicted with a rolling update annotation. The annotation informs the Cluster Operator to perform the rolling update.
1.4.2. Topic Operator
The Topic Operator provides a way of managing topics in a Kafka cluster through Kubernetes resources.
The role of the Topic Operator is to keep a set of KafkaTopic
Kubernetes resources describing Kafka topics in-sync with corresponding Kafka topics.
Specifically, if a KafkaTopic
is:
-
Created, the Topic Operator creates the topic
-
Deleted, the Topic Operator deletes the topic
-
Changed, the Topic Operator updates the topic
Working in the other direction, if a topic is:
-
Created within the Kafka cluster, the Operator creates a
KafkaTopic
-
Deleted from the Kafka cluster, the Operator deletes the
KafkaTopic
-
Changed in the Kafka cluster, the Operator updates the
KafkaTopic
This allows you to declare a KafkaTopic
as part of your application’s deployment and the Topic Operator will take care of creating the topic for you.
Your application just needs to deal with producing or consuming from the necessary topics.
The Topic Operator maintains information about each topic in a topic store, which is continually synchronized with updates from Kafka topics or Kubernetes KafkaTopic
custom resources.
Updates from operations applied to a local in-memory topic store are persisted to a backup topic store on disk.
If a topic is reconfigured or reassigned to other brokers, the KafkaTopic
will always be up to date.
1.4.3. User Operator
The User Operator manages Kafka users for a Kafka cluster by watching for KafkaUser
resources that describe Kafka users,
and ensuring that they are configured properly in the Kafka cluster.
For example, if a KafkaUser
is:
-
Created, the User Operator creates the user it describes
-
Deleted, the User Operator deletes the user it describes
-
Changed, the User Operator updates the user it describes
Unlike the Topic Operator, the User Operator does not sync any changes from the Kafka cluster with the Kubernetes resources. Kafka topics can be created by applications directly in Kafka, but it is not expected that the users will be managed directly in the Kafka cluster in parallel with the User Operator.
The User Operator allows you to declare a KafkaUser
resource as part of your application’s deployment.
You can specify the authentication and authorization mechanism for the user.
You can also configure user quotas that control usage of Kafka resources to ensure, for example, that a user does not monopolize access to a broker.
When the user is created, the user credentials are created in a Secret
.
Your application needs to use the user and its credentials for authentication and to produce or consume messages.
In addition to managing credentials for authentication, the User Operator also manages authorization rules by including a description of the user’s access rights in the KafkaUser
declaration.
1.4.4. Feature gates in Strimzi Operators
You can enable and disable some features of operators using feature gates.
Feature gates are set in the operator configuration and have three stages of maturity: alpha, beta, or General Availability (GA).
For more information, see Feature gates.
1.5. Strimzi custom resources
A deployment of Kafka components to a Kubernetes cluster using Strimzi is highly configurable through the application of custom resources. Custom resources are created as instances of APIs added by Custom resource definitions (CRDs) to extend Kubernetes resources.
CRDs act as configuration instructions to describe the custom resources in a Kubernetes cluster, and are provided with Strimzi for each Kafka component used in a deployment, as well as users and topics. CRDs and custom resources are defined as YAML files. Example YAML files are provided with the Strimzi distribution.
CRDs also allow Strimzi resources to benefit from native Kubernetes features like CLI accessibility and configuration validation.
1.5.1. Strimzi custom resource example
CRDs require a one-time installation in a cluster to define the schemas used to instantiate and manage Strimzi-specific resources.
After a new custom resource type is added to your cluster by installing a CRD, you can create instances of the resource based on its specification.
Depending on the cluster setup, installation typically requires cluster admin privileges.
Note
|
Access to manage custom resources is limited to Strimzi administrators. For more information, see Designating Strimzi administrators. |
A CRD defines a new kind
of resource, such as kind:Kafka
, within a Kubernetes cluster.
The Kubernetes API server allows custom resources to be created based on the kind
and understands from the CRD how to validate and store the custom resource when it is added to the Kubernetes cluster.
Warning
|
When CRDs are deleted, custom resources of that type are also deleted. Additionally, the resources created by the custom resource, such as pods and statefulsets are also deleted. |
Each Strimzi-specific custom resource conforms to the schema defined by the CRD for the resource’s kind
.
The custom resources for Strimzi components have common configuration properties, which are defined under spec
.
To understand the relationship between a CRD and a custom resource, let’s look at a sample of the CRD for a Kafka topic.
apiVersion: kafka.strimzi.io/v1beta2
kind: CustomResourceDefinition
metadata: (1)
name: kafkatopics.kafka.strimzi.io
labels:
app: strimzi
spec: (2)
group: kafka.strimzi.io
versions:
v1beta2
scope: Namespaced
names:
# ...
singular: kafkatopic
plural: kafkatopics
shortNames:
- kt (3)
additionalPrinterColumns: (4)
# ...
subresources:
status: {} (5)
validation: (6)
openAPIV3Schema:
properties:
spec:
type: object
properties:
partitions:
type: integer
minimum: 1
replicas:
type: integer
minimum: 1
maximum: 32767
# ...
-
The metadata for the topic CRD, its name and a label to identify the CRD.
-
The specification for this CRD, including the group (domain) name, the plural name and the supported schema version, which are used in the URL to access the API of the topic. The other names are used to identify instance resources in the CLI. For example,
kubectl get kafkatopic my-topic
orkubectl get kafkatopics
. -
The shortname can be used in CLI commands. For example,
kubectl get kt
can be used as an abbreviation instead ofkubectl get kafkatopic
. -
The information presented when using a
get
command on the custom resource. -
The current status of the CRD as described in the schema reference for the resource.
-
openAPIV3Schema validation provides validation for the creation of topic custom resources. For example, a topic requires at least one partition and one replica.
Note
|
You can identify the CRD YAML files supplied with the Strimzi installation files, because the file names contain an index number followed by ‘Crd’. |
Here is a corresponding example of a KafkaTopic
custom resource.
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaTopic (1)
metadata:
name: my-topic
labels:
strimzi.io/cluster: my-cluster (2)
spec: (3)
partitions: 1
replicas: 1
config:
retention.ms: 7200000
segment.bytes: 1073741824
status:
conditions: (4)
lastTransitionTime: "2019-08-20T11:37:00.706Z"
status: "True"
type: Ready
observedGeneration: 1
/ ...
-
The
kind
andapiVersion
identify the CRD of which the custom resource is an instance. -
A label, applicable only to
KafkaTopic
andKafkaUser
resources, that defines the name of the Kafka cluster (which is same as the name of theKafka
resource) to which a topic or user belongs. -
The spec shows the number of partitions and replicas for the topic as well as the configuration parameters for the topic itself. In this example, the retention period for a message to remain in the topic and the segment file size for the log are specified.
-
Status conditions for the
KafkaTopic
resource. Thetype
condition changed toReady
at thelastTransitionTime
.
Custom resources can be applied to a cluster through the platform CLI. When the custom resource is created, it uses the same validation as the built-in resources of the Kubernetes API.
After a KafkaTopic
custom resource is created, the Topic Operator is notified and corresponding Kafka topics are created in Strimzi.
1.6. Listener configuration
Listeners are used to connect to Kafka brokers.
Strimzi provides a generic GenericKafkaListener
schema with properties to configure listeners through the Kafka
resource.
The GenericKafkaListener
provides a flexible approach to listener configuration.
You can specify properties to configure internal listeners for connecting within the Kubernetes cluster, or external listeners for connecting outside the Kubernetes cluster.
Each listener is defined as an array in the Kafka
resource.
You can configure as many listeners as required, as long as their names and ports are unique.
You might want to configure multiple external listeners, for example, to handle access from networks that require different authentication mechanisms.
Or you might need to join your Kubernetes network to an outside network.
In which case, you can configure internal listeners (using the useServiceDnsDomain
property) so that the Kubernetes service DNS domain (typically .cluster.local
) is not used.
For more information on the configuration options available for listeners,
see the GenericKafkaListener
schema reference.
You can configure listeners for secure connection using authentication. For more information, see Securing access to Kafka brokers.
You can configure external listeners for client access outside a Kubernetes environment using a specified connection mechanism, such as a loadbalancer. For more information on the configuration options for connecting an external client, see Accessing Kafka from external clients outside of the Kubernetes cluster.
You can provide your own server certificates, called Kafka listener certificates, for TLS listeners or external listeners which have TLS encryption enabled. For more information, see Kafka listener certificates.
1.7. Document Conventions
In this document, replaceable text is styled in monospace
, with italics, uppercase, and hyphens.
For example, in the following code, you will want to replace MY-NAMESPACE
with the name of your namespace:
sed -i 's/namespace: .*/namespace: MY-NAMESPACE/' install/cluster-operator/*RoleBinding*.yaml
2. Configuring a Strimzi deployment
This chapter describes how to configure different aspects of the supported deployments using custom resources:
-
Kafka clusters
-
Kafka Connect clusters
-
Kafka MirrorMaker
-
Kafka Bridge
-
Cruise Control
Note
|
Labels applied to a custom resource are also applied to the Kubernetes resources making up its cluster. This provides a convenient mechanism for resources to be labeled as required. |
Strimzi provides example configuration files, which can serve as a starting point when building your own Kafka component configuration for deployment.
You can use Prometheus and Grafana to monitor your Strimzi deployment. For more information, see Introducing metrics to Kafka.
2.1. Kafka cluster configuration
This section describes how to configure a Kafka deployment in your Strimzi cluster. A Kafka cluster is deployed with a ZooKeeper cluster. The deployment can also include the Topic Operator and User Operator, which manage Kafka topics and users.
You configure Kafka using the Kafka
resource.
Configuration options are also available for ZooKeeper and the Entity Operator within the Kafka
resource.
The Entity Operator comprises the Topic Operator and User Operator.
The full schema of the Kafka
resource is described in the Kafka
schema reference.
For more information about Apache Kafka, see the Apache Kafka documentation.
You configure listeners for connecting clients to Kafka brokers. For more information on configuring listeners for connecting brokers, see Listener configuration.
You can configure your Kafka cluster to allow or decline actions executed by users. For more information, see Securing access to Kafka brokers.
When deploying Kafka, the Cluster Operator automatically sets up and renews TLS certificates to enable encryption and authentication within your cluster. If required, you can manually renew the cluster and client CA certificates before their renewal period ends. You can also replace the keys used by the cluster and client CA certificates. For more information, see Renewing CA certificates manually and Replacing private keys.
2.1.1. Configuring Kafka
Use the properties of the Kafka
resource to configure your Kafka deployment.
As well as configuring Kafka, you can add configuration for ZooKeeper and the Strimzi Operators. Common configuration properties, such as logging and healthchecks, are configured independently for each component.
This procedure shows only some of the possible configuration options, but those that are particularly important include:
-
Resource requests (CPU / Memory)
-
JVM options for maximum and minimum memory allocation
-
Listeners (and authentication of clients)
-
Authentication
-
Storage
-
Rack awareness
-
Metrics
-
Cruise Control for cluster rebalancing
The inter.broker.protocol.version
property for the Kafka config
must be the version supported by the specified Kafka version (spec.kafka.version
).
The property represents the version of Kafka protocol used in a Kafka cluster.
From Kafka 3.0.0, when the inter.broker.protocol.version
is set to 3.0
or higher, the log.message.format.version
option is ignored and doesn’t need to be set.
An update to the inter.broker.protocol.version
is required when upgrading your Kafka version.
For more information, see Upgrading Kafka.
-
A Kubernetes cluster
-
A running Cluster Operator
See the Deploying and Upgrading Strimzi guide for instructions on deploying a:
-
Edit the
spec
properties for theKafka
resource.The properties you can configure are shown in this example configuration:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: kafka: replicas: 3 (1) version: 3.0.0 (2) logging: (3) type: inline loggers: kafka.root.logger.level: "INFO" resources: (4) requests: memory: 64Gi cpu: "8" limits: memory: 64Gi cpu: "12" readinessProbe: (5) initialDelaySeconds: 15 timeoutSeconds: 5 livenessProbe: initialDelaySeconds: 15 timeoutSeconds: 5 jvmOptions: (6) -Xms: 8192m -Xmx: 8192m image: my-org/my-image:latest (7) listeners: (8) - name: plain (9) port: 9092 (10) type: internal (11) tls: false (12) configuration: useServiceDnsDomain: true (13) - name: tls port: 9093 type: internal tls: true authentication: (14) type: tls - name: external (15) port: 9094 type: route tls: true configuration: brokerCertChainAndKey: (16) secretName: my-secret certificate: my-certificate.crt key: my-key.key authorization: (17) type: simple config: (18) auto.create.topics.enable: "false" offsets.topic.replication.factor: 3 transaction.state.log.replication.factor: 3 transaction.state.log.min.isr: 2 default.replication.factor: 3 min.insync.replicas: 2 inter.broker.protocol.version: 3.0 ssl.cipher.suites: "TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384" (19) ssl.enabled.protocols: "TLSv1.2" ssl.protocol: "TLSv1.2" storage: (20) type: persistent-claim (21) size: 10000Gi (22) rack: (23) topologyKey: topology.kubernetes.io/zone metricsConfig: (24) type: jmxPrometheusExporter valueFrom: configMapKeyRef: (25) name: my-config-map key: my-key # ... zookeeper: (26) replicas: 3 (27) logging: (28) type: inline loggers: zookeeper.root.logger: "INFO" resources: requests: memory: 8Gi cpu: "2" limits: memory: 8Gi cpu: "2" jvmOptions: -Xms: 4096m -Xmx: 4096m storage: type: persistent-claim size: 1000Gi metricsConfig: # ... entityOperator: (29) tlsSidecar: (30) resources: requests: cpu: 200m memory: 64Mi limits: cpu: 500m memory: 128Mi topicOperator: watchedNamespace: my-topic-namespace reconciliationIntervalSeconds: 60 logging: (31) type: inline loggers: rootLogger.level: "INFO" resources: requests: memory: 512Mi cpu: "1" limits: memory: 512Mi cpu: "1" userOperator: watchedNamespace: my-topic-namespace reconciliationIntervalSeconds: 60 logging: (32) type: inline loggers: rootLogger.level: INFO resources: requests: memory: 512Mi cpu: "1" limits: memory: 512Mi cpu: "1" kafkaExporter: (33) # ... cruiseControl: (34) # ... tlsSidecar: (35) # ...
-
The number of replica nodes. If your cluster already has topics defined, you can scale clusters.
-
Kafka version, which can be changed to a supported version by following the upgrade procedure.
-
Specified Kafka loggers and log levels added directly (
inline
) or indirectly (external
) through a ConfigMap. A custom ConfigMap must be placed under thelog4j.properties
key. For the Kafkakafka.root.logger.level
logger, you can set the log level to INFO, ERROR, WARN, TRACE, DEBUG, FATAL or OFF. -
Requests for reservation of supported resources, currently
cpu
andmemory
, and limits to specify the maximum resources that can be consumed. -
Healthchecks to know when to restart a container (liveness) and when a container can accept traffic (readiness).
-
JVM configuration options to optimize performance for the Virtual Machine (VM) running Kafka.
-
ADVANCED OPTION: Container image configuration, which is recommended only in special situations.
-
Listeners configure how clients connect to the Kafka cluster via bootstrap addresses. Listeners are configured as internal or external listeners for connection from inside or outside the Kubernetes cluster.
-
Name to identify the listener. Must be unique within the Kafka cluster.
-
Port number used by the listener inside Kafka. The port number has to be unique within a given Kafka cluster. Allowed port numbers are 9092 and higher with the exception of ports 9404 and 9999, which are already used for Prometheus and JMX. Depending on the listener type, the port number might not be the same as the port number that connects Kafka clients.
-
Listener type specified as
internal
, or for external listeners, asroute
,loadbalancer
,nodeport
oringress
. -
Enables TLS encryption for each listener. Default is
false
. TLS encryption is not required forroute
listeners. -
Defines whether the fully-qualified DNS names including the cluster service suffix (usually
.cluster.local
) are assigned. -
Listener authentication mechanism specified as mutual TLS, SCRAM-SHA-512 or token-based OAuth 2.0.
-
External listener configuration specifies how the Kafka cluster is exposed outside Kubernetes, such as through a
route
,loadbalancer
ornodeport
. -
Optional configuration for a Kafka listener certificate managed by an external Certificate Authority. The
brokerCertChainAndKey
specifies aSecret
that contains a server certificate and a private key. You can configure Kafka listener certificates on any listener with enabled TLS encryption. -
Authorization enables simple, OAUTH 2.0, or OPA authorization on the Kafka broker. Simple authorization uses the
AclAuthorizer
Kafka plugin. -
The
config
specifies the broker configuration. Standard Apache Kafka configuration may be provided, restricted to those properties not managed directly by Strimzi. -
Storage is configured as
ephemeral
,persistent-claim
orjbod
. -
Storage size for persistent volumes may be increased and additional volumes may be added to JBOD storage.
-
Persistent storage has additional configuration options, such as a storage
id
andclass
for dynamic volume provisioning. -
Rack awareness is configured to spread replicas across different racks. A
topologykey
must match the label of a cluster node. -
Prometheus metrics enabled. In this example, metrics are configured for the Prometheus JMX Exporter (the default metrics exporter).
-
Prometheus rules for exporting metrics to a Grafana dashboard through the Prometheus JMX Exporter, which are enabled by referencing a ConfigMap containing configuration for the Prometheus JMX exporter. You can enable metrics without further configuration using a reference to a ConfigMap containing an empty file under
metricsConfig.valueFrom.configMapKeyRef.key
. -
ZooKeeper-specific configuration, which contains properties similar to the Kafka configuration.
-
The number of ZooKeeper nodes. ZooKeeper clusters or ensembles usually run with an odd number of nodes, typically three, five, or seven. The majority of nodes must be available in order to maintain an effective quorum. If the ZooKeeper cluster loses its quorum, it will stop responding to clients and the Kafka brokers will stop working. Having a stable and highly available ZooKeeper cluster is crucial for Strimzi.
-
Specified ZooKeeper loggers and log levels.
-
Entity Operator configuration, which specifies the configuration for the Topic Operator and User Operator.
-
Entity Operator TLS sidecar configuration. Entity Operator uses the TLS sidecar for secure communication with ZooKeeper.
-
Specified Topic Operator loggers and log levels. This example uses
inline
logging. -
Specified User Operator loggers and log levels.
-
Kafka Exporter configuration. Kafka Exporter is an optional component for extracting metrics data from Kafka brokers, in particular consumer lag data.
-
Optional configuration for Cruise Control, which is used to rebalance the Kafka cluster.
-
Cruise Control TLS sidecar configuration. Cruise Control uses the TLS sidecar for secure communication with ZooKeeper.
-
-
Create or update the resource:
kubectl apply -f KAFKA-CONFIG-FILE
2.1.2. Configuring the Entity Operator
The Entity Operator is responsible for managing Kafka-related entities in a running Kafka cluster.
The Entity Operator comprises the:
-
Topic Operator to manage Kafka topics
-
User Operator to manage Kafka users
Through Kafka
resource configuration, the Cluster Operator can deploy the Entity Operator, including one or both operators, when deploying a Kafka cluster.
Note
|
When deployed, the Entity Operator contains the operators according to the deployment configuration. |
The operators are automatically configured to manage the topics and users of the Kafka cluster.
Entity Operator configuration properties
Use the entityOperator
property in Kafka.spec
to configure the Entity Operator.
The entityOperator
property supports several sub-properties:
-
tlsSidecar
-
topicOperator
-
userOperator
-
template
The tlsSidecar
property contains the configuration of the TLS sidecar container, which is used to communicate with ZooKeeper.
The template
property contains the configuration of the Entity Operator pod, such as labels, annotations, affinity, and tolerations.
For more information on configuring templates, see Customizing Kubernetes resources.
The topicOperator
property contains the configuration of the Topic Operator.
When this option is missing, the Entity Operator is deployed without the Topic Operator.
The userOperator
property contains the configuration of the User Operator.
When this option is missing, the Entity Operator is deployed without the User Operator.
For more information on the properties used to configure the Entity Operator, see the EntityUserOperatorSpec
schema reference.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
kafka:
# ...
zookeeper:
# ...
entityOperator:
topicOperator: {}
userOperator: {}
If an empty object ({}
) is used for the topicOperator
and userOperator
, all properties use their default values.
When both topicOperator
and userOperator
properties are missing, the Entity Operator is not deployed.
Topic Operator configuration properties
Topic Operator deployment can be configured using additional options inside the topicOperator
object.
The following properties are supported:
watchedNamespace
-
The Kubernetes namespace in which the topic operator watches for
KafkaTopics
. Default is the namespace where the Kafka cluster is deployed. reconciliationIntervalSeconds
-
The interval between periodic reconciliations in seconds. Default
120
. zookeeperSessionTimeoutSeconds
-
The ZooKeeper session timeout in seconds. Default
18
. topicMetadataMaxAttempts
-
The number of attempts at getting topic metadata from Kafka. The time between each attempt is defined as an exponential back-off. Consider increasing this value when topic creation might take more time due to the number of partitions or replicas. Default
6
. image
-
The
image
property can be used to configure the container image which will be used. For more details about configuring custom container images, seeimage
. resources
-
The
resources
property configures the amount of resources allocated to the Topic Operator. For more details about resource request and limit configuration, seeresources
. logging
-
The
logging
property configures the logging of the Topic Operator. For more details, seelogging
.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
kafka:
# ...
zookeeper:
# ...
entityOperator:
# ...
topicOperator:
watchedNamespace: my-topic-namespace
reconciliationIntervalSeconds: 60
# ...
User Operator configuration properties
User Operator deployment can be configured using additional options inside the userOperator
object.
The following properties are supported:
watchedNamespace
-
The Kubernetes namespace in which the user operator watches for
KafkaUsers
. Default is the namespace where the Kafka cluster is deployed. reconciliationIntervalSeconds
-
The interval between periodic reconciliations in seconds. Default
120
. image
-
The
image
property can be used to configure the container image which will be used. For more details about configuring custom container images, seeimage
. resources
-
The
resources
property configures the amount of resources allocated to the User Operator. For more details about resource request and limit configuration, seeresources
. logging
-
The
logging
property configures the logging of the User Operator. For more details, seelogging
. secretPrefix
-
The
secretPrefix
property adds a prefix to the name of all Secrets created from the KafkaUser resource. For example,STRIMZI_SECRET_PREFIX=kafka-
would prefix all Secret names withkafka-
. So a KafkaUser namedmy-user
would create a Secret namedkafka-my-user
.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
kafka:
# ...
zookeeper:
# ...
entityOperator:
# ...
userOperator:
watchedNamespace: my-user-namespace
reconciliationIntervalSeconds: 60
# ...
2.1.3. Kafka and ZooKeeper storage types
As stateful applications, Kafka and ZooKeeper need to store data on disk. Strimzi supports three storage types for this data:
-
Ephemeral
-
Persistent
-
JBOD storage
Note
|
JBOD storage is supported only for Kafka, not for ZooKeeper. |
When configuring a Kafka
resource, you can specify the type of storage used by the Kafka broker and its corresponding ZooKeeper node. You configure the storage type using the storage
property in the following resources:
-
Kafka.spec.kafka
-
Kafka.spec.zookeeper
The storage type is configured in the type
field.
Refer to the schema reference for more information on storage configuration properties:
Warning
|
The storage type cannot be changed after a Kafka cluster is deployed. |
Data storage considerations
An efficient data storage infrastructure is essential to the optimal performance of Strimzi.
Block storage is required. File storage, such as NFS, does not work with Kafka.
Choose from one of the following options for your block storage:
-
Cloud-based block storage solutions, such as Amazon Elastic Block Store (EBS)
-
Storage Area Network (SAN) volumes accessed by a protocol such as Fibre Channel or iSCSI
Note
|
Strimzi does not require Kubernetes raw block volumes. |
File systems
It is recommended that you configure your storage system to use the XFS file system. Strimzi is also compatible with the ext4 file system, but this might require additional configuration for best results.
Apache Kafka and ZooKeeper storage
Use separate disks for Apache Kafka and ZooKeeper.
Three types of data storage are supported:
-
Ephemeral (Recommended for development only)
-
Persistent
-
JBOD (Just a Bunch of Disks, suitable for Kafka only)
For more information, see Kafka and ZooKeeper storage.
Solid-state drives (SSDs), though not essential, can improve the performance of Kafka in large clusters where data is sent to and received from multiple topics asynchronously. SSDs are particularly effective with ZooKeeper, which requires fast, low latency data access.
Note
|
You do not need to provision replicated storage because Kafka and ZooKeeper both have built-in data replication. |
Ephemeral storage
Ephemeral storage uses emptyDir
volumes to store data.
To use ephemeral storage, set the type
field to ephemeral
.
Important
|
emptyDir volumes are not persistent and the data stored in them is lost when the pod is restarted.
After the new pod is started, it must recover all data from the other nodes of the cluster.
Ephemeral storage is not suitable for use with single-node ZooKeeper clusters or for Kafka topics with a replication factor of 1. This configuration will cause data loss.
|
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
kafka:
# ...
storage:
type: ephemeral
# ...
zookeeper:
# ...
storage:
type: ephemeral
# ...
Log directories
The ephemeral volume is used by the Kafka brokers as log directories mounted into the following path:
/var/lib/kafka/data/kafka-logIDX
Where IDX
is the Kafka broker pod index. For example /var/lib/kafka/data/kafka-log0
.
Persistent storage
Persistent storage uses Persistent Volume Claims to provision persistent volumes for storing data. Persistent Volume Claims can be used to provision volumes of many different types, depending on the Storage Class which will provision the volume. The data types which can be used with persistent volume claims include many types of SAN storage as well as Local persistent volumes.
To use persistent storage, the type
has to be set to persistent-claim
.
Persistent storage supports additional configuration options:
id
(optional)-
Storage identification number. This option is mandatory for storage volumes defined in a JBOD storage declaration. Default is
0
. size
(required)-
Defines the size of the persistent volume claim, for example, "1000Gi".
class
(optional)-
The Kubernetes Storage Class to use for dynamic volume provisioning.
selector
(optional)-
Allows selecting a specific persistent volume to use. It contains key:value pairs representing labels for selecting such a volume.
deleteClaim
(optional)-
Boolean value which specifies if the Persistent Volume Claim has to be deleted when the cluster is undeployed. Default is
false
.
Warning
|
Increasing the size of persistent volumes in an existing Strimzi cluster is only supported in Kubernetes versions that support persistent volume resizing. The persistent volume to be resized must use a storage class that supports volume expansion. For other versions of Kubernetes and storage classes which do not support volume expansion, you must decide the necessary storage size before deploying the cluster. Decreasing the size of existing persistent volumes is not possible. |
size
# ...
storage:
type: persistent-claim
size: 1000Gi
# ...
The following example demonstrates the use of a storage class.
# ...
storage:
type: persistent-claim
size: 1Gi
class: my-storage-class
# ...
Finally, a selector
can be used to select a specific labeled persistent volume to provide needed features such as an SSD.
# ...
storage:
type: persistent-claim
size: 1Gi
selector:
hdd-type: ssd
deleteClaim: true
# ...
Storage class overrides
You can specify a different storage class for one or more Kafka brokers or ZooKeeper nodes, instead of using the default storage class.
This is useful if, for example, storage classes are restricted to different availability zones or data centers.
You can use the overrides
field for this purpose.
In this example, the default storage class is named my-storage-class
:
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
labels:
app: my-cluster
name: my-cluster
namespace: myproject
spec:
# ...
kafka:
replicas: 3
storage:
deleteClaim: true
size: 100Gi
type: persistent-claim
class: my-storage-class
overrides:
- broker: 0
class: my-storage-class-zone-1a
- broker: 1
class: my-storage-class-zone-1b
- broker: 2
class: my-storage-class-zone-1c
# ...
zookeeper:
replicas: 3
storage:
deleteClaim: true
size: 100Gi
type: persistent-claim
class: my-storage-class
overrides:
- broker: 0
class: my-storage-class-zone-1a
- broker: 1
class: my-storage-class-zone-1b
- broker: 2
class: my-storage-class-zone-1c
# ...
As a result of the configured overrides
property, the volumes use the following storage classes:
-
The persistent volumes of ZooKeeper node 0 will use
my-storage-class-zone-1a
. -
The persistent volumes of ZooKeeper node 1 will use
my-storage-class-zone-1b
. -
The persistent volumes of ZooKeeepr node 2 will use
my-storage-class-zone-1c
. -
The persistent volumes of Kafka broker 0 will use
my-storage-class-zone-1a
. -
The persistent volumes of Kafka broker 1 will use
my-storage-class-zone-1b
. -
The persistent volumes of Kafka broker 2 will use
my-storage-class-zone-1c
.
The overrides
property is currently used only to override storage class configurations. Overriding other storage configuration fields is not currently supported.
Other fields from the storage configuration are currently not supported.
Persistent Volume Claim naming
When persistent storage is used, it creates Persistent Volume Claims with the following names:
data-cluster-name-kafka-idx
-
Persistent Volume Claim for the volume used for storing data for the Kafka broker pod
idx
. data-cluster-name-zookeeper-idx
-
Persistent Volume Claim for the volume used for storing data for the ZooKeeper node pod
idx
.
Log directories
The persistent volume is used by the Kafka brokers as log directories mounted into the following path:
/var/lib/kafka/data/kafka-logIDX
Where IDX
is the Kafka broker pod index. For example /var/lib/kafka/data/kafka-log0
.
Resizing persistent volumes
You can provision increased storage capacity by increasing the size of the persistent volumes used by an existing Strimzi cluster. Resizing persistent volumes is supported in clusters that use either a single persistent volume or multiple persistent volumes in a JBOD storage configuration.
Note
|
You can increase but not decrease the size of persistent volumes. Decreasing the size of persistent volumes is not currently supported in Kubernetes. |
-
A Kubernetes cluster with support for volume resizing.
-
The Cluster Operator is running.
-
A Kafka cluster using persistent volumes created using a storage class that supports volume expansion.
-
In a
Kafka
resource, increase the size of the persistent volume allocated to the Kafka cluster, the ZooKeeper cluster, or both.-
To increase the volume size allocated to the Kafka cluster, edit the
spec.kafka.storage
property. -
To increase the volume size allocated to the ZooKeeper cluster, edit the
spec.zookeeper.storage
property.For example, to increase the volume size from
1000Gi
to2000Gi
:apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: kafka: # ... storage: type: persistent-claim size: 2000Gi class: my-storage-class # ... zookeeper: # ...
-
-
Create or update the resource:
kubectl apply -f KAFKA-CONFIG-FILE
Kubernetes increases the capacity of the selected persistent volumes in response to a request from the Cluster Operator. When the resizing is complete, the Cluster Operator restarts all pods that use the resized persistent volumes. This happens automatically.
-
For more information about resizing persistent volumes in Kubernetes, see Resizing Persistent Volumes using Kubernetes.
JBOD storage overview
You can configure Strimzi to use JBOD, a data storage configuration of multiple disks or volumes. JBOD is one approach to providing increased data storage for Kafka brokers. It can also improve performance.
A JBOD configuration is described by one or more volumes, each of which can be either ephemeral or persistent. The rules and constraints for JBOD volume declarations are the same as those for ephemeral and persistent storage. For example, you cannot decrease the size of a persistent storage volume after it has been provisioned, or you cannot change the value of sizeLimit
when type=ephemeral.
JBOD configuration
To use JBOD with Strimzi, the storage type
must be set to jbod
. The volumes
property allows you to describe the disks that make up your JBOD storage array or configuration. The following fragment shows an example JBOD configuration:
# ...
storage:
type: jbod
volumes:
- id: 0
type: persistent-claim
size: 100Gi
deleteClaim: false
- id: 1
type: persistent-claim
size: 100Gi
deleteClaim: false
# ...
The ids cannot be changed once the JBOD volumes are created.
Users can add or remove volumes from the JBOD configuration.
JBOD and Persistent Volume Claims
When persistent storage is used to declare JBOD volumes, the naming scheme of the resulting Persistent Volume Claims is as follows:
data-id-cluster-name-kafka-idx
-
Where
id
is the ID of the volume used for storing data for Kafka broker podidx
.
Log directories
The JBOD volumes will be used by the Kafka brokers as log directories mounted into the following path:
/var/lib/kafka/data-id/kafka-log_idx_
-
Where
id
is the ID of the volume used for storing data for Kafka broker podidx
. For example/var/lib/kafka/data-0/kafka-log0
.
Adding volumes to JBOD storage
This procedure describes how to add volumes to a Kafka cluster configured to use JBOD storage. It cannot be applied to Kafka clusters configured to use any other storage type.
Note
|
When adding a new volume under an id which was already used in the past and removed, you have to make sure that the previously used PersistentVolumeClaims have been deleted.
|
-
A Kubernetes cluster
-
A running Cluster Operator
-
A Kafka cluster with JBOD storage
-
Edit the
spec.kafka.storage.volumes
property in theKafka
resource. Add the new volumes to thevolumes
array. For example, add the new volume with id2
:apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: kafka: # ... storage: type: jbod volumes: - id: 0 type: persistent-claim size: 100Gi deleteClaim: false - id: 1 type: persistent-claim size: 100Gi deleteClaim: false - id: 2 type: persistent-claim size: 100Gi deleteClaim: false # ... zookeeper: # ...
-
Create or update the resource:
kubectl apply -f KAFKA-CONFIG-FILE
-
Create new topics or reassign existing partitions to the new disks.
For more information about reassigning topics, see Partition reassignment tool.
Removing volumes from JBOD storage
This procedure describes how to remove volumes from Kafka cluster configured to use JBOD storage. It cannot be applied to Kafka clusters configured to use any other storage type. The JBOD storage always has to contain at least one volume.
Important
|
To avoid data loss, you have to move all partitions before removing the volumes. |
-
A Kubernetes cluster
-
A running Cluster Operator
-
A Kafka cluster with JBOD storage with two or more volumes
-
Reassign all partitions from the disks which are you going to remove. Any data in partitions still assigned to the disks which are going to be removed might be lost.
-
Edit the
spec.kafka.storage.volumes
property in theKafka
resource. Remove one or more volumes from thevolumes
array. For example, remove the volumes with ids1
and2
:apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: kafka: # ... storage: type: jbod volumes: - id: 0 type: persistent-claim size: 100Gi deleteClaim: false # ... zookeeper: # ...
-
Create or update the resource:
kubectl apply -f KAFKA-CONFIG-FILE
For more information about reassigning topics, see Partition reassignment tool.
2.1.4. Scaling clusters
Scale Kafka clusters by adding or removing brokers. If a cluster already has topics defined, you also have to reassign partitions.
You use the kafka-reassign-partitions.sh
tool to reassign partitions.
The tool uses a reassignment JSON file that specifies the topics to reassign.
You can generate a reassignment JSON file or create a file manually if you want to move specific partitions.
Broker scaling configuration
You configure the Kafka.spec.kafka.replicas
configuration to add or reduce the number of brokers.
Broker addition
The primary way of increasing throughput for a topic is to increase the number of partitions for that topic. That works because the extra partitions allow the load of the topic to be shared between the different brokers in the cluster. However, in situations where every broker is constrained by a particular resource (typically I/O) using more partitions will not result in increased throughput. Instead, you need to add brokers to the cluster.
When you add an extra broker to the cluster, Kafka does not assign any partitions to it automatically. You must decide which partitions to reassign from the existing brokers to the new broker.
Once the partitions have been redistributed between all the brokers, the resource utilization of each broker is reduced.
Broker removal
Because Strimzi uses StatefulSets
to manage broker pods, you cannot remove any pod from the cluster.
You can only remove one or more of the highest numbered pods from the cluster.
For example, in a cluster of 12 brokers the pods are named cluster-name-kafka-0
up to cluster-name-kafka-11
.
If you decide to scale down by one broker, the cluster-name-kafka-11
will be removed.
Before you remove a broker from a cluster, ensure that it is not assigned to any partitions. You should also decide which of the remaining brokers will be responsible for each of the partitions on the broker being decommissioned. Once the broker has no assigned partitions, you can scale the cluster down safely.
Partition reassignment tool
The Topic Operator does not currently support reassigning replicas to different brokers, so it is necessary to connect directly to broker pods to reassign replicas to brokers.
Within a broker pod, the kafka-reassign-partitions.sh
tool allows you to reassign partitions to different brokers.
It has three different modes:
--generate
-
Takes a set of topics and brokers and generates a reassignment JSON file which will result in the partitions of those topics being assigned to those brokers. Because this operates on whole topics, it cannot be used when you only want to reassign some partitions of some topics.
--execute
-
Takes a reassignment JSON file and applies it to the partitions and brokers in the cluster. Brokers that gain partitions as a result become followers of the partition leader. For a given partition, once the new broker has caught up and joined the ISR (in-sync replicas) the old broker will stop being a follower and will delete its replica.
--verify
-
Using the same reassignment JSON file as the
--execute
step,--verify
checks whether all the partitions in the file have been moved to their intended brokers. If the reassignment is complete,--verify
also removes any traffic throttles (--throttle
) that are in effect. Unless removed, throttles will continue to affect the cluster even after the reassignment has finished.
It is only possible to have one reassignment running in a cluster at any given time, and it is not possible to cancel a running reassignment.
If you need to cancel a reassignment, wait for it to complete and then perform another reassignment to revert the effects of the first reassignment.
The kafka-reassign-partitions.sh
will print the reassignment JSON for this reversion as part of its output.
Very large reassignments should be broken down into a number of smaller reassignments in case there is a need to stop in-progress reassignment.
Partition reassignment JSON file
The reassignment JSON file has a specific structure:
{
"version": 1,
"partitions": [
<PartitionObjects>
]
}
Where <PartitionObjects> is a comma-separated list of objects like:
{
"topic": <TopicName>,
"partition": <Partition>,
"replicas": [ <AssignedBrokerIds> ]
}
Note
|
Although Kafka also supports a "log_dirs" property this should not be used in Strimzi.
|
The following is an example reassignment JSON file that assigns partition 4
of topic topic-a
to brokers 2
, 4
and 7
, and partition 2
of topic topic-b
to brokers 1
, 5
and 7
:
{
"version": 1,
"partitions": [
{
"topic": "topic-a",
"partition": 4,
"replicas": [2,4,7]
},
{
"topic": "topic-b",
"partition": 2,
"replicas": [1,5,7]
}
]
}
Partitions not included in the JSON are not changed.
Partition reassignment between JBOD volumes
When using JBOD storage in your Kafka cluster, you can choose to reassign the partitions between specific volumes and their log directories (each volume has a single log directory).
To reassign a partition to a specific volume, add the log_dirs
option to <PartitionObjects> in the reassignment JSON file.
{
"topic": <TopicName>,
"partition": <Partition>,
"replicas": [ <AssignedBrokerIds> ],
"log_dirs": [ <AssignedLogDirs> ]
}
The log_dirs
object should contain the same number of log directories as the number of replicas specified in the replicas
object.
The value should be either an absolute path to the log directory, or the any
keyword.
{
"topic": "topic-a",
"partition": 4,
"replicas": [2,4,7].
"log_dirs": [ "/var/lib/kafka/data-0/kafka-log2", "/var/lib/kafka/data-0/kafka-log4", "/var/lib/kafka/data-0/kafka-log7" ]
}
Partition reassignment throttles
Partition reassignment can be a slow process because it involves transferring large amounts of data between brokers.
To avoid a detrimental impact on clients, you can throttle the reassignment process.
Use the --throttle
parameter with the kafka-reassign-partitions.sh
tool to throttle a reassignment.
You specify a maximum threshold in bytes per second for the movement of partitions between brokers.
For example, --throttle 5000000
sets a maximum threshold for moving partitions of 50 MBps.
Throttling might cause the reassignment to take longer to complete.
-
If the throttle is too low, the newly assigned brokers will not be able to keep up with records being published and the reassignment will never complete.
-
If the throttle is too high, clients will be impacted.
For example, for producers, this could manifest as higher than normal latency waiting for acknowledgment. For consumers, this could manifest as a drop in throughput caused by higher latency between polls.
Generating reassignment JSON files
This procedure describes how to generate a reassignment JSON file.
Use the reassignment file with the kafka-reassign-partitions.sh
tool to reassign partitions after scaling a Kafka cluster.
The steps describe a secure reassignment process that uses TLS. You’ll need a Kafka cluster that uses TLS encryption and authentication.
-
You have a running Cluster Operator.
-
You have a running Kafka cluster based on a
Kafka
resource configured with internal TLS authentication and encryption.Kafka configuration with TLSapiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: kafka: # ... listeners: # ... - name: tls port: 9093 type: internal tls: true (1) authentication: type: tls (2) # ...
-
Enables TLS encryption for the internal listener.
-
Listener authentication mechanism specified as mutual TLS.
-
-
The running Kafka cluster contains a set of topics and partitions to reassign.
Example topic configuration formy-topic
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaTopic metadata: name: my-topic labels: strimzi.io/cluster: my-cluster spec: partitions: 10 replicas: 3 config: retention.ms: 7200000 segment.bytes: 1073741824 # ...
-
You have a
KafkaUser
configured with ACL rules that specify permission to produce and consume topics from the Kafka brokers.Example Kafka user configuration with ACL rules to allow operations onmy-topic
andmy-cluster
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaUser metadata: name: my-user labels: strimzi.io/cluster: my-cluster spec: authentication: (1) type: tls authorization: type: simple (2) acls: - resource: type: topic name: my-topic patternType: literal operation: Write host: "*" - resource: type: topic name: my-topic patternType: literal operation: Create host: "*" - resource: type: topic name: my-topic patternType: literal operation: Describe host: "*" - resource: type: cluster name: my-cluster patternType: literal operation: Alter host: "*" # ... # ...
-
User authentication mechanism defined as mutual
tls
. -
Simple authorization and accompanying list of ACL rules.
NotePermission for a Describe
operation is required as a minimum for TLS access to a topic. -
-
Extract the cluster CA certificate and password from the
<cluster_name>-cluster-ca-cert
Secret of the Kafka cluster.kubectl get secret <cluster_name>-cluster-ca-cert -o jsonpath='{.data.ca\.p12}' | base64 -d > ca.p12
kubectl get secret <cluster_name>-cluster-ca-cert -o jsonpath='{.data.ca\.password}' | base64 -d > ca.password
Replace <cluster_name> with the name of the Kafka cluster. When you deploy Kafka using the
Kafka
resource, a Secret with the cluster CA certificate is created with the Kafka cluster name (<cluster_name>-cluster-ca-cert
). For example,my-cluster-cluster-ca-cert
. -
Run a new interactive pod container using the Strimzi Kafka image to connect to a running Kafka broker.
kubectl run --restart=Never --image=quay.io/strimzi/kafka:0.27.0-kafka-3.0.0 <interactive_pod_name> -- /bin/sh -c "sleep 3600"
Replace <interactive_pod_name> with the name of the pod.
-
Copy the cluster CA certificate to the interactive pod container.
kubectl cp ca.p12 <interactive_pod_name>:/tmp
-
Extract the user CA certificate and password from the Secret of the Kafka user that has permission to access the Kafka brokers.
kubectl get secret <kafka_user> -o jsonpath='{.data.user\.p12}' | base64 -d > user.p12
kubectl get secret <kafka_user> -o jsonpath='{.data.user\.password}' | base64 -d > user.password
Replace <kafka_user> with the name of the Kafka user. When you create a Kafka user using the
KafkaUser
resource, a Secret with the user CA certificate is created with the Kafka user name. For example,my-user
. -
Copy the user CA certificate to the interactive pod container.
kubectl cp user.p12 <interactive_pod_name>:/tmp
The CA certificates allow the interactive pod container to connect to the Kafka broker using TLS.
-
Create a
config.properties
file to specify the truststore and keystore used to authenticate connection to the Kafka cluster.Use the certificates and passwords you extracted in the previous steps.
bootstrap.servers=<kafka_cluster_name>-kafka-bootstrap:9093 (1) security.protocol=SSL (2) ssl.truststore.location=/tmp/ca.p12 (3) ssl.truststore.password=<truststore_password> (4) ssl.keystore.location=/tmp/user.p12 (5) ssl.keystore.password=<keystore_password> (6)
-
The bootstrap server address to connect to the Kafka cluster. Use your own Kafka cluster name to replace <kafka_cluster_name>.
-
The security protocol option when using TLS for encryption.
-
The truststore location contains the public key certificate (
ca.p12
) for the Kafka cluster. -
The password (
ca.password
) for accessing the truststore. -
The keystore location contains the public key certificate (
user.p12
) for the Kafka user. -
The password (
user.password
) for accessing the keystore.
-
-
Copy the
config.properties
file to the interactive pod container.kubectl cp config.properties <interactive_pod_name>:/tmp/config.properties
-
Prepare a JSON file named
topics.json
that specifies the topics to move.Specify topic names as a comma-separated list.
Example JSON file to reassign all the partitions oftopic-a
andtopic-b
{ "version": 1, "topics": [ { "topic": "topic-a"}, { "topic": "topic-b"} ] }
-
Copy the
topics.json
file to the interactive pod container.kubectl cp topics.json <interactive_pod_name>:/tmp/topics.json
-
Start a shell process in the interactive pod container.
kubectl exec -n <namespace> -ti <interactive_pod_name> /bin/bash
Replace <namespace> with the Kubernetes namespace where the pod is running.
-
Use the
kafka-reassign-partitions.sh
command to generate the reassignment JSON.Example command to move all the partitions oftopic-a
andtopic-b
to brokers0
,1
and2
bin/kafka-reassign-partitions.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 \ --command-config /tmp/config.properties \ --topics-to-move-json-file /tmp/topics.json \ --broker-list 0,1,2 \ --generate
Scaling up a Kafka cluster
Use a reassignment file to increase the number of brokers in a Kafka cluster.
The reassignment file should describe how partitions are reassigned to brokers in the enlarged Kafka cluster.
This procedure describes a secure scaling process that uses TLS. You’ll need a Kafka cluster that uses TLS encryption and authentication.
-
You have a running Kafka cluster based on a
Kafka
resource configured with internal TLS authentication and encryption. -
You have generated a reassignment JSON file named
reassignment.json
. -
You are running an interactive pod container that is connected to the running Kafka broker.
-
You are connected as a
KafkaUser
configured with ACL rules that specify permission to manage the Kafka cluster and its topics.
-
Add as many new brokers as you need by increasing the
Kafka.spec.kafka.replicas
configuration option. -
Verify that the new broker pods have started.
-
If you haven’t done so, run an interactive pod container to generate a reassignment JSON file named
reassignment.json
. -
Copy the
reassignment.json
file to the interactive pod container.kubectl cp reassignment.json <interactive_pod_name>:/tmp/reassignment.json
Replace <interactive_pod_name> with the name of the pod.
-
Start a shell process in the interactive pod container.
kubectl exec -n <namespace> -ti <interactive_pod_name> /bin/bash
Replace <namespace> with the Kubernetes namespace where the pod is running.
-
Run the partition reassignment using the
kafka-reassign-partitions.sh
script from the interactive pod container.bin/kafka-reassign-partitions.sh --bootstrap-server <cluster_name>-kafka-bootstrap:9093 \ --command-config /tmp/config.properties \ --reassignment-json-file /tmp/reassignment.json \ --execute
Replace <cluster_name> with the name of your Kafka cluster. For example,
my-cluster-kafka-bootstrap:9093
If you are going to throttle replication, you can also pass the
--throttle
option with an inter-broker throttled rate in bytes per second. For example:bin/kafka-reassign-partitions.sh --bootstrap-server <cluster_name>-kafka-bootstrap:9093 \ --command-config /tmp/config.properties \ --reassignment-json-file /tmp/reassignment.json \ --throttle 5000000 \ --execute
This command will print out two reassignment JSON objects. The first records the current assignment for the partitions being moved. You should save this to a local file (not a file in the pod) in case you need to revert the reassignment later on. The second JSON object is the target reassignment you have passed in your reassignment JSON file.
If you need to change the throttle during reassignment, you can use the same command with a different throttled rate. For example:
bin/kafka-reassign-partitions.sh --bootstrap-server <cluster_name>-kafka-bootstrap:9093 \ --command-config /tmp/config.properties \ --reassignment-json-file /tmp/reassignment.json \ --throttle 10000000 \ --execute
-
Verify that the reassignment has completed using the
kafka-reassign-partitions.sh
command line tool from any of the broker pods. This is the same command as the previous step, but with the--verify
option instead of the--execute
option.bin/kafka-reassign-partitions.sh --bootstrap-server <cluster_name>-kafka-bootstrap:9093 \ --command-config /tmp/config.properties \ --reassignment-json-file /tmp/reassignment.json \ --verify
The reassignment has finished when the
--verify
command reports that each of the partitions being moved has completed successfully. This final--verify
will also have the effect of removing any reassignment throttles. -
You can now delete the revert file if you saved the JSON for reverting the assignment to their original brokers.
Scaling down a Kafka cluster
Use a reassignment file to decrease the number of brokers in a Kafka cluster.
The reassignment file must describe how partitions are reassigned to the remaining brokers in the Kafka cluster. Brokers in the highest numbered pods are removed first.
This procedure describes a secure scaling process that uses TLS. You’ll need a Kafka cluster that uses TLS encryption and authentication.
-
You have a running Kafka cluster based on a
Kafka
resource configured with internal TLS authentication and encryption. -
You have generated a reassignment JSON file named
reassignment.json
. -
You are running an interactive pod container that is connected to the running Kafka broker.
-
You are connected as a
KafkaUser
configured with ACL rules that specify permission to manage the Kafka cluster and its topics.
-
If you haven’t done so, run an interactive pod container to generate a reassignment JSON file named
reassignment.json
. -
Copy the
reassignment.json
file to the interactive pod container.kubectl cp reassignment.json <interactive_pod_name>:/tmp/reassignment.json
Replace <interactive_pod_name> with the name of the pod.
-
Start a shell process in the interactive pod container.
kubectl exec -n <namespace> -ti <interactive_pod_name> /bin/bash
Replace <namespace> with the Kubernetes namespace where the pod is running.
-
Run the partition reassignment using the
kafka-reassign-partitions.sh
script from the interactive pod container.bin/kafka-reassign-partitions.sh --bootstrap-server <cluster_name>-kafka-bootstrap:9093 \ --command-config /tmp/config.properties \ --reassignment-json-file /tmp/reassignment.json \ --execute
Replace <cluster_name> with the name of your Kafka cluster. For example,
my-cluster-kafka-bootstrap:9093
If you are going to throttle replication, you can also pass the
--throttle
option with an inter-broker throttled rate in bytes per second. For example:bin/kafka-reassign-partitions.sh --bootstrap-server <cluster_name>-kafka-bootstrap:9093 \ --command-config /tmp/config.properties \ --reassignment-json-file /tmp/reassignment.json \ --throttle 5000000 \ --execute
This command will print out two reassignment JSON objects. The first records the current assignment for the partitions being moved. You should save this to a local file (not a file in the pod) in case you need to revert the reassignment later on. The second JSON object is the target reassignment you have passed in your reassignment JSON file.
If you need to change the throttle during reassignment, you can use the same command with a different throttled rate. For example:
bin/kafka-reassign-partitions.sh --bootstrap-server <cluster_name>-kafka-bootstrap:9093 \ --command-config /tmp/config.properties \ --reassignment-json-file /tmp/reassignment.json \ --throttle 10000000 \ --execute
-
Verify that the reassignment has completed using the
kafka-reassign-partitions.sh
command line tool from any of the broker pods. This is the same command as the previous step, but with the--verify
option instead of the--execute
option.bin/kafka-reassign-partitions.sh --bootstrap-server <cluster_name>-kafka-bootstrap:9093 \ --command-config /tmp/config.properties \ --reassignment-json-file /tmp/reassignment.json \ --verify
The reassignment has finished when the
--verify
command reports that each of the partitions being moved has completed successfully. This final--verify
will also have the effect of removing any reassignment throttles. -
You can now delete the revert file if you saved the JSON for reverting the assignment to their original brokers.
-
When all the partition reassignments have finished, the brokers being removed should not have responsibility for any of the partitions in the cluster. You can verify this by checking that the broker’s data log directory does not contain any live partition logs. If the log directory on the broker contains a directory that does not match the extended regular expression
[a-zA-Z0-9.-]+\.[a-z0-9]+-delete$
, the broker still has live partitions and should not be stopped.You can check this by executing the command:
kubectl exec my-cluster-kafka-0 -c kafka -it -- \ /bin/bash -c \ "ls -l /var/lib/kafka/kafka-log_<n>_ | grep -E '^d' | grep -vE '[a-zA-Z0-9.-]+\.[a-z0-9]+-delete$'"
where n is the number of the pods being deleted.
If the above command prints any output then the broker still has live partitions. In this case, either the reassignment has not finished or the reassignment JSON file was incorrect.
-
When you have confirmed that the broker has no live partitions, you can edit the
Kafka.spec.kafka.replicas
property of yourKafka
resource to reduce the number of brokers.
2.1.5. Retrieving JMX metrics with JmxTrans
JmxTrans is a tool for retrieving JMX metrics data from Java processes and pushing that data, in various formats, to remote sinks inside or outside the cluster. JmxTrans can communicate with a secure JMX port.
Strimzi supports using JmxTrans to read JMX metrics from Kafka brokers.
JmxTrans reads JMX metrics data from secure or insecure Kafka brokers and pushes the data to remote sinks in various data formats. For example, JmxTrans can obtain JMX metrics about the request rate of each Kafka broker’s network and then push the data to a Logstash database outside the Kubernetes cluster.
For more information about JmxTrans, see the JmxTrans GitHub.
Configuring a JmxTrans deployment
-
A running Kubernetes cluster
You can configure a JmxTrans deployment by using the Kafka.spec.jmxTrans
property.
A JmxTrans deployment can read from a secure or insecure Kafka broker.
To configure a JmxTrans deployment, define the following properties:
-
Kafka.spec.jmxTrans.outputDefinitions
-
Kafka.spec.jmxTrans.kafkaQueries
For more information on these properties, see the JmxTransSpec
schema reference.
Note
|
To use JMXTrans, jmxOptions must be configured on the Kafka broker.
|
Configuring JmxTrans output definitions
Output definitions specify where JMX metrics are pushed to, and in which data format.
For information about supported data formats, see Data formats.
How many seconds JmxTrans agent waits for before pushing new data can be configured through the flushDelay
property.
The host
and port
properties define the target host address and target port the data is pushed to.
The name
property is a required property that is referenced by the Kafka.spec.jmxTrans.kafkaQueries
property.
Here is an example configuration pushing JMX data in the Graphite format every 5 seconds to a Logstash database on http://myLogstash:9999, and another pushing to standardOut
(standard output):
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
jmxTrans:
outputDefinitions:
- outputType: "com.googlecode.jmxtrans.model.output.GraphiteWriter"
host: "http://myLogstash"
port: 9999
flushDelay: 5
name: "logstash"
- outputType: "com.googlecode.jmxtrans.model.output.StdOutWriter"
name: "standardOut"
# ...
# ...
zookeeper:
# ...
Configuring JmxTrans queries
JmxTrans queries specify what JMX metrics are read from the Kafka brokers.
Currently JmxTrans queries can only be sent to the Kafka Brokers.
Configure the targetMBean
property to specify which target MBean on the Kafka broker is addressed.
Configuring the attributes
property specifies which MBean attribute is read as JMX metrics from the target MBean.
JmxTrans supports wildcards to read from target MBeans, and filter by specifying the typenames
.
The outputs
property defines where the metrics are pushed to by specifying the name of the output definitions.
The following JmxTrans deployment reads from all MBeans that match the pattern kafka.server:type=BrokerTopicMetrics,name=*
and have name
in the target MBean’s name.
From those Mbeans, it obtains JMX metrics about the Count
attribute and pushes the metrics to standard output as defined by outputs
.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
# ...
jmxTrans:
kafkaQueries:
- targetMBean: "kafka.server:type=BrokerTopicMetrics,*"
typeNames: ["name"]
attributes: ["Count"]
outputs: ["standardOut"]
zookeeper:
# ...
2.1.6. Maintenance time windows for rolling updates
Maintenance time windows allow you to schedule certain rolling updates of your Kafka and ZooKeeper clusters to start at a convenient time.
Maintenance time windows overview
In most cases, the Cluster Operator only updates your Kafka or ZooKeeper clusters in response to changes to the corresponding Kafka
resource.
This enables you to plan when to apply changes to a Kafka
resource to minimize the impact on Kafka client applications.
However, some updates to your Kafka and ZooKeeper clusters can happen without any corresponding change to the Kafka
resource.
For example, the Cluster Operator will need to perform a rolling restart if a CA (Certificate Authority) certificate that it manages is close to expiry.
While a rolling restart of the pods should not affect availability of the service (assuming correct broker and topic configurations), it could affect performance of the Kafka client applications. Maintenance time windows allow you to schedule such spontaneous rolling updates of your Kafka and ZooKeeper clusters to start at a convenient time. If maintenance time windows are not configured for a cluster then it is possible that such spontaneous rolling updates will happen at an inconvenient time, such as during a predictable period of high load.
Maintenance time window definition
You configure maintenance time windows by entering an array of strings in the Kafka.spec.maintenanceTimeWindows
property.
Each string is a cron expression interpreted as being in UTC (Coordinated Universal Time, which for practical purposes is the same as Greenwich Mean Time).
The following example configures a single maintenance time window that starts at midnight and ends at 01:59am (UTC), on Sundays, Mondays, Tuesdays, Wednesdays, and Thursdays:
# ...
maintenanceTimeWindows:
- "* * 0-1 ? * SUN,MON,TUE,WED,THU *"
# ...
In practice, maintenance windows should be set in conjunction with the Kafka.spec.clusterCa.renewalDays
and Kafka.spec.clientsCa.renewalDays
properties of the Kafka
resource, to ensure that the necessary CA certificate renewal can be completed in the configured maintenance time windows.
Note
|
Strimzi does not schedule maintenance operations exactly according to the given windows. Instead, for each reconciliation, it checks whether a maintenance window is currently "open". This means that the start of maintenance operations within a given time window can be delayed by up to the Cluster Operator reconciliation interval. Maintenance time windows must therefore be at least this long. |
-
For more information about the Cluster Operator configuration, see Cluster Operator configuration.
Configuring a maintenance time window
You can configure a maintenance time window for rolling updates triggered by supported processes.
-
A Kubernetes cluster.
-
The Cluster Operator is running.
-
Add or edit the
maintenanceTimeWindows
property in theKafka
resource. For example to allow maintenance between 0800 and 1059 and between 1400 and 1559 you would set themaintenanceTimeWindows
as shown below:apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: kafka: # ... zookeeper: # ... maintenanceTimeWindows: - "* * 8-10 * * ?" - "* * 14-15 * * ?"
-
Create or update the resource:
kubectl apply -f KAFKA-CONFIG-FILE
Performing rolling updates:
2.1.7. Connecting to ZooKeeper from a terminal
Most Kafka CLI tools can connect directly to Kafka, so under normal circumstances you should not need to connect to ZooKeeper. ZooKeeper services are secured with encryption and authentication and are not intended to be used by external applications that are not part of Strimzi.
However, if you want to use Kafka CLI tools that require a connection to ZooKeeper, you can use a terminal inside a ZooKeeper container and connect to localhost:12181
as the ZooKeeper address.
-
A Kubernetes cluster is available.
-
A Kafka cluster is running.
-
The Cluster Operator is running.
-
Open the terminal using the Kubernetes console or run the
exec
command from your CLI.For example:
kubectl exec -ti my-cluster-zookeeper-0 -- bin/kafka-topics.sh --list --zookeeper localhost:12181
Be sure to use
localhost:12181
.You can now run Kafka commands to ZooKeeper.
2.1.8. Deleting Kafka nodes manually
This procedure describes how to delete an existing Kafka node by using a Kubernetes annotation.
Deleting a Kafka node consists of deleting both the Pod
on which the Kafka broker is running and the related PersistentVolumeClaim
(if the cluster was deployed with persistent storage).
After deletion, the Pod
and its related PersistentVolumeClaim
are recreated automatically.
Warning
|
Deleting a PersistentVolumeClaim can cause permanent data loss. The following procedure should only be performed if you have encountered storage issues.
|
See the Deploying and Upgrading Strimzi guide for instructions on running a:
-
Find the name of the
Pod
that you want to delete.Kafka broker pods are named <cluster-name>-kafka-<index>, where <index> starts at zero and ends at the total number of replicas minus one. For example,
my-cluster-kafka-0
. -
Annotate the
Pod
resource in Kubernetes.Use
kubectl annotate
:kubectl annotate pod cluster-name-kafka-index strimzi.io/delete-pod-and-pvc=true
-
Wait for the next reconciliation, when the annotated pod with the underlying persistent volume claim will be deleted and then recreated.
2.1.9. Deleting ZooKeeper nodes manually
This procedure describes how to delete an existing ZooKeeper node by using a Kubernetes annotation.
Deleting a ZooKeeper node consists of deleting both the Pod
on which ZooKeeper is running and the related PersistentVolumeClaim
(if the cluster was deployed with persistent storage).
After deletion, the Pod
and its related PersistentVolumeClaim
are recreated automatically.
Warning
|
Deleting a PersistentVolumeClaim can cause permanent data loss. The following procedure should only be performed if you have encountered storage issues.
|
See the Deploying and Upgrading Strimzi guide for instructions on running a:
-
Find the name of the
Pod
that you want to delete.ZooKeeper pods are named <cluster-name>-zookeeper-<index>, where <index> starts at zero and ends at the total number of replicas minus one. For example,
my-cluster-zookeeper-0
. -
Annotate the
Pod
resource in Kubernetes.Use
kubectl annotate
:kubectl annotate pod cluster-name-zookeeper-index strimzi.io/delete-pod-and-pvc=true
-
Wait for the next reconciliation, when the annotated pod with the underlying persistent volume claim will be deleted and then recreated.
2.1.10. List of Kafka cluster resources
The following resources are created by the Cluster Operator in the Kubernetes cluster:
cluster-name-cluster-ca
-
Secret with the Cluster CA private key used to encrypt the cluster communication.
cluster-name-cluster-ca-cert
-
Secret with the Cluster CA public key. This key can be used to verify the identity of the Kafka brokers.
cluster-name-clients-ca
-
Secret with the Clients CA private key used to sign user certificates
cluster-name-clients-ca-cert
-
Secret with the Clients CA public key. This key can be used to verify the identity of the Kafka users.
cluster-name-cluster-operator-certs
-
Secret with Cluster operators keys for communication with Kafka and ZooKeeper.
cluster-name-zookeeper
-
StatefulSet which is in charge of managing the ZooKeeper node pods.
cluster-name-zookeeper-idx
-
Pods created by the ZooKeeper StatefulSet.
cluster-name-zookeeper-nodes
-
Headless Service needed to have DNS resolve the ZooKeeper pods IP addresses directly.
cluster-name-zookeeper-client
-
Service used by Kafka brokers to connect to ZooKeeper nodes as clients.
cluster-name-zookeeper-config
-
ConfigMap that contains the ZooKeeper ancillary configuration, and is mounted as a volume by the ZooKeeper node pods.
cluster-name-zookeeper-nodes
-
Secret with ZooKeeper node keys.
cluster-name-zookeeper
-
Service account used by the ZooKeeper nodes.
cluster-name-zookeeper
-
Pod Disruption Budget configured for the ZooKeeper nodes.
cluster-name-network-policy-zookeeper
-
Network policy managing access to the ZooKeeper services.
data-cluster-name-zookeeper-idx
-
Persistent Volume Claim for the volume used for storing data for the ZooKeeper node pod
idx
. This resource will be created only if persistent storage is selected for provisioning persistent volumes to store data.
cluster-name-kafka
-
StatefulSet which is in charge of managing the Kafka broker pods.
cluster-name-kafka-idx
-
Pods created by the Kafka StatefulSet.
cluster-name-kafka-brokers
-
Service needed to have DNS resolve the Kafka broker pods IP addresses directly.
cluster-name-kafka-bootstrap
-
Service can be used as bootstrap servers for Kafka clients connecting from within the Kubernetes cluster.
cluster-name-kafka-external-bootstrap
-
Bootstrap service for clients connecting from outside the Kubernetes cluster. This resource is created only when an external listener is enabled. The old service name will be used for backwards compatibility when the listener name is
external
and port is9094
. cluster-name-kafka-pod-id
-
Service used to route traffic from outside the Kubernetes cluster to individual pods. This resource is created only when an external listener is enabled. The old service name will be used for backwards compatibility when the listener name is
external
and port is9094
. cluster-name-kafka-external-bootstrap
-
Bootstrap route for clients connecting from outside the Kubernetes cluster. This resource is created only when an external listener is enabled and set to type
route
. The old route name will be used for backwards compatibility when the listener name isexternal
and port is9094
. cluster-name-kafka-pod-id
-
Route for traffic from outside the Kubernetes cluster to individual pods. This resource is created only when an external listener is enabled and set to type
route
. The old route name will be used for backwards compatibility when the listener name isexternal
and port is9094
. cluster-name-kafka-listener-name-bootstrap
-
Bootstrap service for clients connecting from outside the Kubernetes cluster. This resource is created only when an external listener is enabled. The new service name will be used for all other external listeners.
cluster-name-kafka-listener-name-pod-id
-
Service used to route traffic from outside the Kubernetes cluster to individual pods. This resource is created only when an external listener is enabled. The new service name will be used for all other external listeners.
cluster-name-kafka-listener-name-bootstrap
-
Bootstrap route for clients connecting from outside the Kubernetes cluster. This resource is created only when an external listener is enabled and set to type
route
. The new route name will be used for all other external listeners. cluster-name-kafka-listener-name-pod-id
-
Route for traffic from outside the Kubernetes cluster to individual pods. This resource is created only when an external listener is enabled and set to type
route
. The new route name will be used for all other external listeners. cluster-name-kafka-config
-
ConfigMap which contains the Kafka ancillary configuration and is mounted as a volume by the Kafka broker pods.
cluster-name-kafka-brokers
-
Secret with Kafka broker keys.
cluster-name-kafka
-
Service account used by the Kafka brokers.
cluster-name-kafka
-
Pod Disruption Budget configured for the Kafka brokers.
cluster-name-network-policy-kafka
-
Network policy managing access to the Kafka services.
strimzi-namespace-name-cluster-name-kafka-init
-
Cluster role binding used by the Kafka brokers.
cluster-name-jmx
-
Secret with JMX username and password used to secure the Kafka broker port. This resource is created only when JMX is enabled in Kafka.
data-cluster-name-kafka-idx
-
Persistent Volume Claim for the volume used for storing data for the Kafka broker pod
idx
. This resource is created only if persistent storage is selected for provisioning persistent volumes to store data. data-id-cluster-name-kafka-idx
-
Persistent Volume Claim for the volume
id
used for storing data for the Kafka broker podidx
. This resource is created only if persistent storage is selected for JBOD volumes when provisioning persistent volumes to store data.
These resources are only created if the Entity Operator is deployed using the Cluster Operator.
cluster-name-entity-operator
-
Deployment with Topic and User Operators.
cluster-name-entity-operator-random-string
-
Pod created by the Entity Operator deployment.
cluster-name-entity-topic-operator-config
-
ConfigMap with ancillary configuration for Topic Operators.
cluster-name-entity-user-operator-config
-
ConfigMap with ancillary configuration for User Operators.
cluster-name-entity-operator-certs
-
Secret with Entity Operator keys for communication with Kafka and ZooKeeper.
cluster-name-entity-operator
-
Service account used by the Entity Operator.
strimzi-cluster-name-entity-topic-operator
-
Role binding used by the Entity Topic Operator.
strimzi-cluster-name-entity-user-operator
-
Role binding used by the Entity User Operator.
These resources are only created if the Kafka Exporter is deployed using the Cluster Operator.
cluster-name-kafka-exporter
-
Deployment with Kafka Exporter.
cluster-name-kafka-exporter-random-string
-
Pod created by the Kafka Exporter deployment.
cluster-name-kafka-exporter
-
Service used to collect consumer lag metrics.
cluster-name-kafka-exporter
-
Service account used by the Kafka Exporter.
These resources are only created if Cruise Control was deployed using the Cluster Operator.
cluster-name-cruise-control
-
Deployment with Cruise Control.
cluster-name-cruise-control-random-string
-
Pod created by the Cruise Control deployment.
cluster-name-cruise-control-config
-
ConfigMap that contains the Cruise Control ancillary configuration, and is mounted as a volume by the Cruise Control pods.
cluster-name-cruise-control-certs
-
Secret with Cruise Control keys for communication with Kafka and ZooKeeper.
cluster-name-cruise-control
-
Service used to communicate with Cruise Control.
cluster-name-cruise-control
-
Service account used by Cruise Control.
cluster-name-network-policy-cruise-control
-
Network policy managing access to the Cruise Control service.
These resources are only created if JMXTrans is deployed using the Cluster Operator.
cluster-name-jmxtrans
-
Deployment with JMXTrans.
cluster-name-jmxtrans-random-string
-
Pod created by the JMXTrans deployment.
cluster-name-jmxtrans-config
-
ConfigMap that contains the JMXTrans ancillary configuration, and is mounted as a volume by the JMXTrans pods.
cluster-name-jmxtrans
-
Service account used by JMXTrans.
2.2. Kafka Connect cluster configuration
This section describes how to configure a Kafka Connect deployment in your Strimzi cluster.
Kafka Connect is an integration toolkit for streaming data between Kafka brokers and other systems using connector plugins.
Kafka Connect provides a framework for integrating Kafka with an external data source or target, such as a database, for import or export of data using connectors.
Connectors are plugins that provide the connection configuration needed.
The full schema of the KafkaConnect
resource is described in KafkaConnect
schema reference.
For more information on deploying connector plugins, see Extending Kafka Connect with connector plug-ins.
2.2.1. Configuring Kafka Connect
Use Kafka Connect to set up external data connections to your Kafka cluster.
Use the properties of the KafkaConnect
resource to configure your Kafka Connect deployment.
KafkaConnector resources allow you to create and manage connector instances for Kafka Connect in a Kubernetes-native way.
In your Kafka Connect configuration, you enable KafkaConnectors for a Kafka Connect cluster by adding the strimzi.io/use-connector-resources
annotation.
You can also add a build
configuration so that Strimzi automatically builds a container image with the connector plugins you require for your data connections.
External configuration for Kafka Connect connectors is specified through the externalConfiguration
property.
To manage connectors, you can use the Kafka Connect REST API, or use KafkaConnector custom resources. KafkaConnector resources must be deployed to the same namespace as the Kafka Connect cluster they link to. For more information on using these methods to create, reconfigure, or delete connectors, see Creating and managing connectors in the Deploying and Upgrading Strimzi guide.
Connector configuration is passed to Kafka Connect as part of an HTTP request and stored within Kafka itself. ConfigMaps and Secrets are standard Kubernetes resources used for storing configurations and confidential data. You can use ConfigMaps and Secrets to configure certain elements of a connector. You can then reference the configuration values in HTTP REST commands, which keeps the configuration separate and more secure, if needed. This method applies especially to confidential data, such as usernames, passwords, or certificates.
-
A Kubernetes cluster
-
A running Cluster Operator
See the Deploying and Upgrading Strimzi guide for instructions on running a:
-
Edit the
spec
properties of theKafkaConnect
resource.The properties you can configure are shown in this example configuration:
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaConnect (1) metadata: name: my-connect-cluster annotations: strimzi.io/use-connector-resources: "true" (2) spec: replicas: 3 (3) authentication: (4) type: tls certificateAndKey: certificate: source.crt key: source.key secretName: my-user-source bootstrapServers: my-cluster-kafka-bootstrap:9092 (5) tls: (6) trustedCertificates: - secretName: my-cluster-cluster-cert certificate: ca.crt - secretName: my-cluster-cluster-cert certificate: ca2.crt config: (7) group.id: my-connect-cluster offset.storage.topic: my-connect-cluster-offsets config.storage.topic: my-connect-cluster-configs status.storage.topic: my-connect-cluster-status key.converter: org.apache.kafka.connect.json.JsonConverter value.converter: org.apache.kafka.connect.json.JsonConverter key.converter.schemas.enable: true value.converter.schemas.enable: true config.storage.replication.factor: 3 offset.storage.replication.factor: 3 status.storage.replication.factor: 3 build: (8) output: (9) type: docker image: my-registry.io/my-org/my-connect-cluster:latest pushSecret: my-registry-credentials plugins: (10) - name: debezium-postgres-connector artifacts: - type: tgz url: https://repo1.maven.org/maven2/io/debezium/debezium-connector-postgres/1.3.1.Final/debezium-connector-postgres-1.3.1.Final-plugin.tar.gz sha512sum: 962a12151bdf9a5a30627eebac739955a4fd95a08d373b86bdcea2b4d0c27dd6e1edd5cb548045e115e33a9e69b1b2a352bee24df035a0447cb820077af00c03 - name: camel-telegram artifacts: - type: tgz url: https://repo.maven.apache.org/maven2/org/apache/camel/kafkaconnector/camel-telegram-kafka-connector/0.7.0/camel-telegram-kafka-connector-0.7.0-package.tar.gz sha512sum: a9b1ac63e3284bea7836d7d24d84208c49cdf5600070e6bd1535de654f6920b74ad950d51733e8020bf4187870699819f54ef5859c7846ee4081507f48873479 externalConfiguration: (11) env: - name: AWS_ACCESS_KEY_ID valueFrom: secretKeyRef: name: aws-creds key: awsAccessKey - name: AWS_SECRET_ACCESS_KEY valueFrom: secretKeyRef: name: aws-creds key: awsSecretAccessKey resources: (12) requests: cpu: "1" memory: 2Gi limits: cpu: "2" memory: 2Gi logging: (13) type: inline loggers: log4j.rootLogger: "INFO" readinessProbe: (14) initialDelaySeconds: 15 timeoutSeconds: 5 livenessProbe: initialDelaySeconds: 15 timeoutSeconds: 5 metricsConfig: (15) type: jmxPrometheusExporter valueFrom: configMapKeyRef: name: my-config-map key: my-key jvmOptions: (16) "-Xmx": "1g" "-Xms": "1g" image: my-org/my-image:latest (17) rack: topologyKey: topology.kubernetes.io/zone (18) template: (19) pod: affinity: podAntiAffinity: requiredDuringSchedulingIgnoredDuringExecution: - labelSelector: matchExpressions: - key: application operator: In values: - postgresql - mongodb topologyKey: "kubernetes.io/hostname" connectContainer: (20) env: - name: JAEGER_SERVICE_NAME value: my-jaeger-service - name: JAEGER_AGENT_HOST value: jaeger-agent-name - name: JAEGER_AGENT_PORT value: "6831"
-
Use
KafkaConnect
. -
Enables KafkaConnectors for the Kafka Connect cluster.
-
Authentication for the Kafka Connect cluster, using the TLS mechanism, as shown here, using OAuth bearer tokens, or a SASL-based SCRAM-SHA-256/SCRAM-SHA-512 or PLAIN mechanism. By default, Kafka Connect connects to Kafka brokers using a plain text connection.
-
Bootstrap server for connection to the Kafka Connect cluster.
-
TLS encryption with key names under which TLS certificates are stored in X.509 format for the cluster. If certificates are stored in the same secret, it can be listed multiple times.
-
Kafka Connect configuration of workers (not connectors). Standard Apache Kafka configuration may be provided, restricted to those properties not managed directly by Strimzi.
-
Build configuration properties for building a container image with connector plugins automatically.
-
(Required) Configuration of the container registry where new images are pushed.
-
(Required) List of connector plugins and their artifacts to add to the new container image. Each plugin must be configured with at least one
artifact
. -
External configuration for Kafka connectors using environment variables, as shown here, or volumes. You can also use the Kubernetes Configuration Provider to load configuration values from external sources.
-
Requests for reservation of supported resources, currently
cpu
andmemory
, and limits to specify the maximum resources that can be consumed. -
Specified Kafka Connect loggers and log levels added directly (
inline
) or indirectly (external
) through a ConfigMap. A custom ConfigMap must be placed under thelog4j.properties
orlog4j2.properties
key. For the Kafka Connectlog4j.rootLogger
logger, you can set the log level to INFO, ERROR, WARN, TRACE, DEBUG, FATAL or OFF. -
Healthchecks to know when to restart a container (liveness) and when a container can accept traffic (readiness).
-
Prometheus metrics, which are enabled by referencing a ConfigMap containing configuration for the Prometheus JMX exporter in this example. You can enable metrics without further configuration using a reference to a ConfigMap containing an empty file under
metricsConfig.valueFrom.configMapKeyRef.key
. -
JVM configuration options to optimize performance for the Virtual Machine (VM) running Kafka Connect.
-
ADVANCED OPTION: Container image configuration, which is recommended only in special situations.
-
Rack awareness is configured to spread replicas across different racks. A
topologykey
must match the label of a cluster node. -
Template customization. Here a pod is scheduled with anti-affinity, so the pod is not scheduled on nodes with the same hostname.
-
Environment variables are also set for distributed tracing using Jaeger.
-
-
Create or update the resource:
kubectl apply -f KAFKA-CONNECT-CONFIG-FILE
-
If authorization is enabled for Kafka Connect, configure Kafka Connect users to enable access to the Kafka Connect consumer group and topics.
2.2.2. Kafka Connect configuration for multiple instances
If you are running multiple instances of Kafka Connect, you have to change the default configuration of the following config
properties:
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaConnect
metadata:
name: my-connect
spec:
# ...
config:
group.id: connect-cluster (1)
offset.storage.topic: connect-cluster-offsets (2)
config.storage.topic: connect-cluster-configs (3)
status.storage.topic: connect-cluster-status (4)
# ...
# ...
-
The Kafka Connect cluster ID within Kafka.
-
Kafka topic that stores connector offsets.
-
Kafka topic that stores connector and task status configurations.
-
Kafka topic that stores connector and task status updates.
Note
|
Values for the three topics must be the same for all Kafka Connect instances with the same group.id .
|
Unless you change the default settings, each Kafka Connect instance connecting to the same Kafka cluster is deployed with the same values. What happens, in effect, is all instances are coupled to run in a cluster and use the same topics.
If multiple Kafka Connect clusters try to use the same topics, Kafka Connect will not work as expected and generate errors.
If you wish to run multiple Kafka Connect instances, change the values of these properties for each instance.
2.2.3. Configuring Kafka Connect user authorization
This procedure describes how to authorize user access to Kafka Connect.
When any type of authorization is being used in Kafka, a Kafka Connect user requires read/write access rights to the consumer group and the internal topics of Kafka Connect.
The properties for the consumer group and internal topics are automatically configured by Strimzi,
or they can be specified explicitly in the spec
of the KafkaConnect
resource.
KafkaConnect
resourceapiVersion: kafka.strimzi.io/v1beta2
kind: KafkaConnect
metadata:
name: my-connect
spec:
# ...
config:
group.id: my-connect-cluster (1)
offset.storage.topic: my-connect-cluster-offsets (2)
config.storage.topic: my-connect-cluster-configs (3)
status.storage.topic: my-connect-cluster-status (4)
# ...
# ...
-
The Kafka Connect cluster ID within Kafka.
-
Kafka topic that stores connector offsets.
-
Kafka topic that stores connector and task status configurations.
-
Kafka topic that stores connector and task status updates.
This procedure shows how access is provided when simple
authorization is being used.
Simple authorization uses ACL rules, handled by the Kafka AclAuthorizer
plugin, to provide the right level of access.
For more information on configuring a KafkaUser
resource to use simple authorization, see the AclRule
schema reference.
Note
|
The default values for the consumer group and topics will differ when running multiple instances. |
-
A Kubernetes cluster
-
A running Cluster Operator
-
Edit the
authorization
property in theKafkaUser
resource to provide access rights to the user.In the following example, access rights are configured for the Kafka Connect topics and consumer group using
literal
name values:Property Name offset.storage.topic
connect-cluster-offsets
status.storage.topic
connect-cluster-status
config.storage.topic
connect-cluster-configs
group
connect-cluster
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaUser metadata: name: my-user labels: strimzi.io/cluster: my-cluster spec: # ... authorization: type: simple acls: # access to offset.storage.topic - resource: type: topic name: connect-cluster-offsets patternType: literal operation: Write host: "*" - resource: type: topic name: connect-cluster-offsets patternType: literal operation: Create host: "*" - resource: type: topic name: connect-cluster-offsets patternType: literal operation: Describe host: "*" - resource: type: topic name: connect-cluster-offsets patternType: literal operation: Read host: "*" # access to status.storage.topic - resource: type: topic name: connect-cluster-status patternType: literal operation: Write host: "*" - resource: type: topic name: connect-cluster-status patternType: literal operation: Create host: "*" - resource: type: topic name: connect-cluster-status patternType: literal operation: Describe host: "*" - resource: type: topic name: connect-cluster-status patternType: literal operation: Read host: "*" # access to config.storage.topic - resource: type: topic name: connect-cluster-configs patternType: literal operation: Write host: "*" - resource: type: topic name: connect-cluster-configs patternType: literal operation: Create host: "*" - resource: type: topic name: connect-cluster-configs patternType: literal operation: Describe host: "*" - resource: type: topic name: connect-cluster-configs patternType: literal operation: Read host: "*" # consumer group - resource: type: group name: connect-cluster patternType: literal operation: Read host: "*"
-
Create or update the resource.
kubectl apply -f KAFKA-USER-CONFIG-FILE
2.2.4. Performing a restart of a Kafka connector
This procedure describes how to manually trigger a restart of a Kafka connector by using a Kubernetes annotation.
-
The Cluster Operator is running.
-
Find the name of the
KafkaConnector
custom resource that controls the Kafka connector you want to restart:kubectl get KafkaConnector
-
To restart the connector, annotate the
KafkaConnector
resource in Kubernetes. For example, usingkubectl annotate
:kubectl annotate KafkaConnector KAFKACONNECTOR-NAME strimzi.io/restart=true
-
Wait for the next reconciliation to occur (every two minutes by default).
The Kafka connector is restarted, as long as the annotation was detected by the reconciliation process. When Kafka Connect accepts the restart request, the annotation is removed from the
KafkaConnector
custom resource.
2.2.5. Performing a restart of a Kafka connector task
This procedure describes how to manually trigger a restart of a Kafka connector task by using a Kubernetes annotation.
-
The Cluster Operator is running.
-
Find the name of the
KafkaConnector
custom resource that controls the Kafka connector task you want to restart:kubectl get KafkaConnector
-
Find the ID of the task to be restarted from the
KafkaConnector
custom resource. Task IDs are non-negative integers, starting from 0.kubectl describe KafkaConnector KAFKACONNECTOR-NAME
-
To restart the connector task, annotate the
KafkaConnector
resource in Kubernetes. For example, usingkubectl annotate
to restart task 0:kubectl annotate KafkaConnector KAFKACONNECTOR-NAME strimzi.io/restart-task=0
-
Wait for the next reconciliation to occur (every two minutes by default).
The Kafka connector task is restarted, as long as the annotation was detected by the reconciliation process. When Kafka Connect accepts the restart request, the annotation is removed from the
KafkaConnector
custom resource.
2.2.6. Exposing the Kafka Connect API
Use the Kafka Connect REST API as an alternative to using KafkaConnector
resources to manage connectors.
The Kafka Connect REST API is available as a service running on <connect_cluster_name>-connect-api:8083
, where <connect_cluster_name> is the name of your Kafka Connect cluster.
The service is created when you create a Kafka Connect instance.
Note
|
The strimzi.io/use-connector-resources annotation enables KafkaConnectors.
If you applied the annotation to your KafkaConnect resource configuration, you need to remove it to use the Kafka Connect API.
Otherwise, manual changes made directly using the Kafka Connect REST API are reverted by the Cluster Operator.
|
You can add the connector configuration as a JSON object.
curl -X POST \
http://my-connect-cluster-connect-api:8083/connectors \
-H 'Content-Type: application/json' \
-d '{ "name": "my-source-connector",
"config":
{
"connector.class":"org.apache.kafka.connect.file.FileStreamSourceConnector",
"file": "/opt/kafka/LICENSE",
"topic":"my-topic",
"tasksMax": "4",
"type": "source"
}
}'
The API is only accessible within the Kubernetes cluster. If you want to make the Kafka Connect API accessible to applications running outside of the Kubernetes cluster, you can expose it manually by creating one of the following features:
-
LoadBalancer
orNodePort
type services -
Ingress
resources -
OpenShift routes
Note
|
The connection is insecure, so allow external access advisedly. |
If you decide to create services, use the labels from the selector
of the <connect_cluster_name>-connect-api
service to configure the pods to which the service will route the traffic:
# ...
selector:
strimzi.io/cluster: my-connect-cluster (1)
strimzi.io/kind: KafkaConnect
strimzi.io/name: my-connect-cluster-connect (2)
#...
-
Name of the Kafka Connect custom resource in your Kubernetes cluster.
-
Name of the Kafka Connect deployment created by the Cluster Operator.
You must also create a NetworkPolicy
that allows HTTP requests from external clients.
apiVersion: networking.k8s.io/v1
kind: NetworkPolicy
metadata:
name: my-custom-connect-network-policy
spec:
ingress:
- from:
- podSelector: (1)
matchLabels:
app: my-connector-manager
ports:
- port: 8083
protocol: TCP
podSelector:
matchLabels:
strimzi.io/cluster: my-connect-cluster
strimzi.io/kind: KafkaConnect
strimzi.io/name: my-connect-cluster-connect
policyTypes:
- Ingress
-
The label of the pod that is allowed to connect to the API.
To add the connector configuration outside the cluster, use the URL of the resource that exposes the API in the curl command.
-
The operations supported by the REST API are described in the Apache Kafka documentation.
2.2.7. List of Kafka Connect cluster resources
The following resources are created by the Cluster Operator in the Kubernetes cluster:
- connect-cluster-name-connect
-
Deployment which is in charge to create the Kafka Connect worker node pods.
- connect-cluster-name-connect-api
-
Service which exposes the REST interface for managing the Kafka Connect cluster.
- connect-cluster-name-config
-
ConfigMap which contains the Kafka Connect ancillary configuration and is mounted as a volume by the Kafka broker pods.
- connect-cluster-name-connect
-
Pod Disruption Budget configured for the Kafka Connect worker nodes.
2.3. Kafka MirrorMaker cluster configuration
This chapter describes how to configure a Kafka MirrorMaker deployment in your Strimzi cluster to replicate data between Kafka clusters.
You can use Strimzi with MirrorMaker or MirrorMaker 2.0. MirrorMaker 2.0 is the latest version, and offers a more efficient way to mirror data between Kafka clusters.
If you are using MirrorMaker, you configure the KafkaMirrorMaker
resource.
Important
|
Kafka MirrorMaker 1 (referred to as just MirrorMaker in the documentation) has been deprecated in Apache Kafka 3.0.0 and will be removed in Apache Kafka 4.0.0.
As a result, the KafkaMirrorMaker custom resource which is used to deploy Kafka MirrorMaker 1 has been deprecated in Strimzi as well.
The KafkaMirrorMaker resource will be removed from Strimzi when we adopt Apache Kafka 4.0.0.
As a replacement, use the KafkaMirrorMaker2 custom resource with the IdentityReplicationPolicy .
|
The following procedure shows how the resource is configured:
The full schema of the KafkaMirrorMaker
resource is described in the KafkaMirrorMaker schema reference.
2.3.1. Configuring Kafka MirrorMaker
Use the properties of the KafkaMirrorMaker
resource to configure your Kafka MirrorMaker deployment.
You can configure access control for producers and consumers using TLS or SASL authentication. This procedure shows a configuration that uses TLS encryption and authentication on the consumer and producer side.
-
See the Deploying and Upgrading Strimzi guide for instructions on running a:
-
Source and target Kafka clusters must be available
-
Edit the
spec
properties for theKafkaMirrorMaker
resource.The properties you can configure are shown in this example configuration:
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaMirrorMaker metadata: name: my-mirror-maker spec: replicas: 3 (1) consumer: bootstrapServers: my-source-cluster-kafka-bootstrap:9092 (2) groupId: "my-group" (3) numStreams: 2 (4) offsetCommitInterval: 120000 (5) tls: (6) trustedCertificates: - secretName: my-source-cluster-ca-cert certificate: ca.crt authentication: (7) type: tls certificateAndKey: secretName: my-source-secret certificate: public.crt key: private.key config: (8) max.poll.records: 100 receive.buffer.bytes: 32768 ssl.cipher.suites: "TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384" (9) ssl.enabled.protocols: "TLSv1.2" ssl.protocol: "TLSv1.2" ssl.endpoint.identification.algorithm: HTTPS (10) producer: bootstrapServers: my-target-cluster-kafka-bootstrap:9092 abortOnSendFailure: false (11) tls: trustedCertificates: - secretName: my-target-cluster-ca-cert certificate: ca.crt authentication: type: tls certificateAndKey: secretName: my-target-secret certificate: public.crt key: private.key config: compression.type: gzip batch.size: 8192 ssl.cipher.suites: "TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384" (12) ssl.enabled.protocols: "TLSv1.2" ssl.protocol: "TLSv1.2" ssl.endpoint.identification.algorithm: HTTPS (13) include: "my-topic|other-topic" (14) resources: (15) requests: cpu: "1" memory: 2Gi limits: cpu: "2" memory: 2Gi logging: (16) type: inline loggers: mirrormaker.root.logger: "INFO" readinessProbe: (17) initialDelaySeconds: 15 timeoutSeconds: 5 livenessProbe: initialDelaySeconds: 15 timeoutSeconds: 5 metricsConfig: (18) type: jmxPrometheusExporter valueFrom: configMapKeyRef: name: my-config-map key: my-key jvmOptions: (19) "-Xmx": "1g" "-Xms": "1g" image: my-org/my-image:latest (20) template: (21) pod: affinity: podAntiAffinity: requiredDuringSchedulingIgnoredDuringExecution: - labelSelector: matchExpressions: - key: application operator: In values: - postgresql - mongodb topologyKey: "kubernetes.io/hostname" connectContainer: (22) env: - name: JAEGER_SERVICE_NAME value: my-jaeger-service - name: JAEGER_AGENT_HOST value: jaeger-agent-name - name: JAEGER_AGENT_PORT value: "6831" tracing: (23) type: jaeger
-
Bootstrap servers for consumer and producer.
-
TLS encryption with key names under which TLS certificates are stored in X.509 format for consumer or producer. If certificates are stored in the same secret, it can be listed multiple times.
-
Authentication for consumer or producer, using the TLS mechanism, as shown here, using OAuth bearer tokens, or a SASL-based SCRAM-SHA-256/SCRAM-SHA-512 or PLAIN mechanism.
-
SSL properties for external listeners to run with a specific cipher suite for a TLS version.
-
Hostname verification is enabled by setting to
HTTPS
. An empty string disables the verification. -
If the
abortOnSendFailure
property is set totrue
, Kafka MirrorMaker will exit and the container will restart following a send failure for a message. -
SSL properties for external listeners to run with a specific cipher suite for a TLS version.
-
Hostname verification is enabled by setting to
HTTPS
. An empty string disables the verification. -
A included topics mirrored from source to target Kafka cluster.
-
Requests for reservation of supported resources, currently
cpu
andmemory
, and limits to specify the maximum resources that can be consumed. -
Specified loggers and log levels added directly (
inline
) or indirectly (external
) through a ConfigMap. A custom ConfigMap must be placed under thelog4j.properties
orlog4j2.properties
key. MirrorMaker has a single logger calledmirrormaker.root.logger
. You can set the log level to INFO, ERROR, WARN, TRACE, DEBUG, FATAL or OFF. -
Healthchecks to know when to restart a container (liveness) and when a container can accept traffic (readiness).
-
Prometheus metrics, which are enabled by referencing a ConfigMap containing configuration for the Prometheus JMX exporter in this example. You can enable metrics without further configuration using a reference to a ConfigMap containing an empty file under
metricsConfig.valueFrom.configMapKeyRef.key
. -
JVM configuration options to optimize performance for the Virtual Machine (VM) running Kafka MirrorMaker.
-
ADVANCED OPTION: Container image configuration, which is recommended only in special situations.
-
Template customization. Here a pod is scheduled with anti-affinity, so the pod is not scheduled on nodes with the same hostname.
-
Environment variables are also set for distributed tracing using Jaeger.
WarningWith the abortOnSendFailure
property set tofalse
, the producer attempts to send the next message in a topic. The original message might be lost, as there is no attempt to resend a failed message. -
Create or update the resource:
kubectl apply -f <your-file>
2.3.2. List of Kafka MirrorMaker cluster resources
The following resources are created by the Cluster Operator in the Kubernetes cluster:
- <mirror-maker-name>-mirror-maker
-
Deployment which is responsible for creating the Kafka MirrorMaker pods.
- <mirror-maker-name>-config
-
ConfigMap which contains ancillary configuration for the Kafka MirrorMaker, and is mounted as a volume by the Kafka broker pods.
- <mirror-maker-name>-mirror-maker
-
Pod Disruption Budget configured for the Kafka MirrorMaker worker nodes.
2.4. Kafka MirrorMaker 2.0 cluster configuration
This section describes how to configure a Kafka MirrorMaker 2.0 deployment in your Strimzi cluster.
MirrorMaker 2.0 is used to replicate data between two or more active Kafka clusters, within or across data centers.
Data replication across clusters supports scenarios that require:
-
Recovery of data in the event of a system failure
-
Aggregation of data for analysis
-
Restriction of data access to a specific cluster
-
Provision of data at a specific location to improve latency
If you are using MirrorMaker 2.0, you configure the KafkaMirrorMaker2
resource.
MirrorMaker 2.0 introduces an entirely new way of replicating data between clusters.
As a result, the resource configuration differs from the previous version of MirrorMaker. If you choose to use MirrorMaker 2.0, there is currently no legacy support, so any resources must be manually converted into the new format.
How MirrorMaker 2.0 replicates data is described here:
The following procedure shows how the resource is configured for MirrorMaker 2.0:
The full schema of the KafkaMirrorMaker2
resource is described in the KafkaMirrorMaker2 schema reference.
2.4.1. MirrorMaker 2.0 data replication
MirrorMaker 2.0 consumes messages from a source Kafka cluster and writes them to a target Kafka cluster.
MirrorMaker 2.0 uses:
-
Source cluster configuration to consume data from the source cluster
-
Target cluster configuration to output data to the target cluster
MirrorMaker 2.0 is based on the Kafka Connect framework, connectors managing the transfer of data between clusters.
A MirrorMaker 2.0 MirrorSourceConnector
replicates topics from a source cluster to a target cluster.
The process of mirroring data from one cluster to another cluster is asynchronous. The recommended pattern is for messages to be produced locally alongside the source Kafka cluster, then consumed remotely close to the target Kafka cluster.
MirrorMaker 2.0 can be used with more than one source cluster.
By default, a check for new topics in the source cluster is made every 10 minutes.
You can change the frequency by adding refresh.topics.interval.seconds
to the source connector configuration.
However, increasing the frequency of the operation might affect overall performance.
2.4.2. Cluster configuration
You can use MirrorMaker 2.0 in active/passive or active/active cluster configurations.
-
In an active/active configuration, both clusters are active and provide the same data simultaneously, which is useful if you want to make the same data available locally in different geographical locations.
-
In an active/passive configuration, the data from an active cluster is replicated in a passive cluster, which remains on standby, for example, for data recovery in the event of system failure.
The expectation is that producers and consumers connect to active clusters only.
A MirrorMaker 2.0 cluster is required at each target destination.
Bidirectional replication (active/active)
The MirrorMaker 2.0 architecture supports bidirectional replication in an active/active cluster configuration.
Each cluster replicates the data of the other cluster using the concept of source and remote topics. As the same topics are stored in each cluster, remote topics are automatically renamed by MirrorMaker 2.0 to represent the source cluster. The name of the originating cluster is prepended to the name of the topic.
By flagging the originating cluster, topics are not replicated back to that cluster.
The concept of replication through remote topics is useful when configuring an architecture that requires data aggregation. Consumers can subscribe to source and remote topics within the same cluster, without the need for a separate aggregation cluster.
Unidirectional replication (active/passive)
The MirrorMaker 2.0 architecture supports unidirectional replication in an active/passive cluster configuration.
You can use an active/passive cluster configuration to make backups or migrate data to another cluster. In this situation, you might not want automatic renaming of remote topics.
You can override automatic renaming by adding IdentityReplicationPolicy
to the source connector configuration.
With this configuration applied, topics retain their original names.
Topic configuration synchronization
Topic configuration is automatically synchronized between source and target clusters. By synchronizing configuration properties, the need for rebalancing is reduced.
Data integrity
MirrorMaker 2.0 monitors source topics and propagates any configuration changes to remote topics, checking for and creating missing partitions. Only MirrorMaker 2.0 can write to remote topics.
Offset tracking
MirrorMaker 2.0 tracks offsets for consumer groups using internal topics.
-
The offset sync topic maps the source and target offsets for replicated topic partitions from record metadata
-
The checkpoint topic maps the last committed offset in the source and target cluster for replicated topic partitions in each consumer group
Offsets for the checkpoint topic are tracked at predetermined intervals through configuration. Both topics enable replication to be fully restored from the correct offset position on failover.
MirrorMaker 2.0 uses its MirrorCheckpointConnector
to emit checkpoints for offset tracking.
Synchronizing consumer group offsets
The __consumer_offsets
topic stores information on committed offsets, for each consumer group.
Offset synchronization periodically transfers the consumer offsets for the consumer groups of a source cluster into the consumer offsets topic of a target cluster.
Offset synchronization is particularly useful in an active/passive configuration. If the active cluster goes down, consumer applications can switch to the passive (standby) cluster and pick up from the last transferred offset position.
To use topic offset synchronization, enable the synchronization by adding sync.group.offsets.enabled
to the checkpoint connector configuration, and setting the property to true
.
Synchronization is disabled by default.
When using the IdentityReplicationPolicy
in the source connector, it also has to be configured in the checkpoint connector configuration.
This ensures that the mirrored consumer offsets will be applied for the correct topics.
The consumer offsets are only synchronized for consumer groups that are not active in the target cluster.
If enabled, the synchronization of offsets from the source cluster is made periodically.
You can change the frequency by adding sync.group.offsets.interval.seconds
and emit.checkpoints.interval.seconds
to the checkpoint connector configuration.
The properties specify the frequency in seconds that the consumer group offsets are synchronized, and the frequency of checkpoints emitted for offset tracking.
The default for both properties is 60 seconds.
You can also change the frequency of checks for new consumer groups using the refresh.groups.interval.seconds
property, which is performed every 10 minutes by default.
Because the synchronization is time-based, any switchover by consumers to a passive cluster will likely result in some duplication of messages.
Connectivity checks
A heartbeat internal topic checks connectivity between clusters.
The heartbeat topic is replicated from the source cluster.
Target clusters use the topic to check:
-
The connector managing connectivity between clusters is running
-
The source cluster is available
MirrorMaker 2.0 uses its MirrorHeartbeatConnector
to emit heartbeats that perform these checks.
2.4.3. ACL rules synchronization
ACL access to remote topics is possible if you are not using the User Operator.
If AclAuthorizer
is being used, without the User Operator, ACL rules that manage access to brokers also apply to remote topics.
Users that can read a source topic can read its remote equivalent.
Note
|
OAuth 2.0 authorization does not support access to remote topics in this way. |
2.4.4. Synchronizing data between Kafka clusters using MirrorMaker 2.0
Use MirrorMaker 2.0 to synchronize data between Kafka clusters through configuration.
The configuration must specify:
-
Each Kafka cluster
-
Connection information for each cluster, including TLS authentication
-
The replication flow and direction
-
Cluster to cluster
-
Topic to topic
-
Use the properties of the KafkaMirrorMaker2
resource to configure your Kafka MirrorMaker 2.0 deployment.
Note
|
The previous version of MirrorMaker continues to be supported. If you wish to use the resources configured for the previous version, they must be updated to the format supported by MirrorMaker 2.0. |
MirrorMaker 2.0 provides default configuration values for properties such as replication factors. A minimal configuration, with defaults left unchanged, would be something like this example:
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaMirrorMaker2
metadata:
name: my-mirror-maker2
spec:
version: 3.0.0
connectCluster: "my-cluster-target"
clusters:
- alias: "my-cluster-source"
bootstrapServers: my-cluster-source-kafka-bootstrap:9092
- alias: "my-cluster-target"
bootstrapServers: my-cluster-target-kafka-bootstrap:9092
mirrors:
- sourceCluster: "my-cluster-source"
targetCluster: "my-cluster-target"
sourceConnector: {}
You can configure access control for source and target clusters using TLS or SASL authentication. This procedure shows a configuration that uses TLS encryption and authentication for the source and target cluster.
-
See the Deploying and Upgrading Strimzi guide for instructions on running a:
-
Source and target Kafka clusters must be available
-
Edit the
spec
properties for theKafkaMirrorMaker2
resource.The properties you can configure are shown in this example configuration:
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaMirrorMaker2 metadata: name: my-mirror-maker2 spec: version: 3.0.0 (1) replicas: 3 (2) connectCluster: "my-cluster-target" (3) clusters: (4) - alias: "my-cluster-source" (5) authentication: (6) certificateAndKey: certificate: source.crt key: source.key secretName: my-user-source type: tls bootstrapServers: my-cluster-source-kafka-bootstrap:9092 (7) tls: (8) trustedCertificates: - certificate: ca.crt secretName: my-cluster-source-cluster-ca-cert - alias: "my-cluster-target" (9) authentication: (10) certificateAndKey: certificate: target.crt key: target.key secretName: my-user-target type: tls bootstrapServers: my-cluster-target-kafka-bootstrap:9092 (11) config: (12) config.storage.replication.factor: 1 offset.storage.replication.factor: 1 status.storage.replication.factor: 1 ssl.cipher.suites: "TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384" (13) ssl.enabled.protocols: "TLSv1.2" ssl.protocol: "TLSv1.2" ssl.endpoint.identification.algorithm: HTTPS (14) tls: (15) trustedCertificates: - certificate: ca.crt secretName: my-cluster-target-cluster-ca-cert mirrors: (16) - sourceCluster: "my-cluster-source" (17) targetCluster: "my-cluster-target" (18) sourceConnector: (19) tasksMax: 10 (20) config: replication.factor: 1 (21) offset-syncs.topic.replication.factor: 1 (22) sync.topic.acls.enabled: "false" (23) refresh.topics.interval.seconds: 60 (24) replication.policy.separator: "" (25) replication.policy.class: "io.strimzi.kafka.connect.mirror.IdentityReplicationPolicy" (26) heartbeatConnector: (27) config: heartbeats.topic.replication.factor: 1 (28) checkpointConnector: (29) config: checkpoints.topic.replication.factor: 1 (30) refresh.groups.interval.seconds: 600 (31) sync.group.offsets.enabled: true (32) sync.group.offsets.interval.seconds: 60 (33) emit.checkpoints.interval.seconds: 60 (34) replication.policy.class: "io.strimzi.kafka.connect.mirror.IdentityReplicationPolicy" topicsPattern: ".*" (35) groupsPattern: "group1|group2|group3" (36) resources: (37) requests: cpu: "1" memory: 2Gi limits: cpu: "2" memory: 2Gi logging: (38) type: inline loggers: connect.root.logger.level: "INFO" readinessProbe: (39) initialDelaySeconds: 15 timeoutSeconds: 5 livenessProbe: initialDelaySeconds: 15 timeoutSeconds: 5 jvmOptions: (40) "-Xmx": "1g" "-Xms": "1g" image: my-org/my-image:latest (41) template: (42) pod: affinity: podAntiAffinity: requiredDuringSchedulingIgnoredDuringExecution: - labelSelector: matchExpressions: - key: application operator: In values: - postgresql - mongodb topologyKey: "kubernetes.io/hostname" connectContainer: (43) env: - name: JAEGER_SERVICE_NAME value: my-jaeger-service - name: JAEGER_AGENT_HOST value: jaeger-agent-name - name: JAEGER_AGENT_PORT value: "6831" tracing: type: jaeger (44) externalConfiguration: (45) env: - name: AWS_ACCESS_KEY_ID valueFrom: secretKeyRef: name: aws-creds key: awsAccessKey - name: AWS_SECRET_ACCESS_KEY valueFrom: secretKeyRef: name: aws-creds key: awsSecretAccessKey
-
The Kafka Connect and Mirror Maker 2.0 version, which will always be the same.
-
Kafka cluster alias for Kafka Connect, which must specify the target Kafka cluster. The Kafka cluster is used by Kafka Connect for its internal topics.
-
Specification for the Kafka clusters being synchronized.
-
Cluster alias for the source Kafka cluster.
-
Authentication for the source cluster, using the TLS mechanism, as shown here, using OAuth bearer tokens, or a SASL-based SCRAM-SHA-256/SCRAM-SHA-512 or PLAIN mechanism.
-
Bootstrap server for connection to the source Kafka cluster.
-
TLS encryption with key names under which TLS certificates are stored in X.509 format for the source Kafka cluster. If certificates are stored in the same secret, it can be listed multiple times.
-
Cluster alias for the target Kafka cluster.
-
Authentication for the target Kafka cluster is configured in the same way as for the source Kafka cluster.
-
Bootstrap server for connection to the target Kafka cluster.
-
Kafka Connect configuration. Standard Apache Kafka configuration may be provided, restricted to those properties not managed directly by Strimzi.
-
SSL properties for external listeners to run with a specific cipher suite for a TLS version.
-
Hostname verification is enabled by setting to
HTTPS
. An empty string disables the verification. -
TLS encryption for the target Kafka cluster is configured in the same way as for the source Kafka cluster.
-
Cluster alias for the source cluster used by the MirrorMaker 2.0 connectors.
-
Cluster alias for the target cluster used by the MirrorMaker 2.0 connectors.
-
Configuration for the
MirrorSourceConnector
that creates remote topics. Theconfig
overrides the default configuration options. -
The maximum number of tasks that the connector may create. Tasks handle the data replication and run in parallel. If the infrastructure supports the processing overhead, increasing this value can improve throughput. Kafka Connect distributes the tasks between members of the cluster. If there are more tasks than workers, workers are assigned multiple tasks. For sink connectors, aim to have one task for each topic partition consumed. For source connectors, the number of tasks that can run in parallel may also depend on the external system. The connector creates fewer than the maximum number of tasks if it cannot achieve the parallelism.
-
Replication factor for mirrored topics created at the target cluster.
-
Replication factor for the
MirrorSourceConnector
offset-syncs
internal topic that maps the offsets of the source and target clusters. -
When ACL rules synchronization is enabled, ACLs are applied to synchronized topics. The default is
true
. -
Optional setting to change the frequency of checks for new topics. The default is for a check every 10 minutes.
-
Defines the separator used for the renaming of remote topics.
-
Adds a policy that overrides the automatic renaming of remote topics. Instead of prepending the name with the name of the source cluster, the topic retains its original name. This optional setting is useful for active/passive backups and data migration. To configure topic offset synchronization, this property must also be set for the
checkpointConnector.config
. -
Configuration for the
MirrorHeartbeatConnector
that performs connectivity checks. Theconfig
overrides the default configuration options. -
Replication factor for the heartbeat topic created at the target cluster.
-
Configuration for the
MirrorCheckpointConnector
that tracks offsets. Theconfig
overrides the default configuration options. -
Replication factor for the checkpoints topic created at the target cluster.
-
Optional setting to change the frequency of checks for new consumer groups. The default is for a check every 10 minutes.
-
Optional setting to synchronize consumer group offsets, which is useful for recovery in an active/passive configuration. Synchronization is not enabled by default.
-
If the synchronization of consumer group offsets is enabled, you can adjust the frequency of the synchronization.
-
Adjusts the frequency of checks for offset tracking. If you change the frequency of offset synchronization, you might also need to adjust the frequency of these checks.
-
Topic replication from the source cluster defined as regular expression patterns. Here we request all topics.
-
Consumer group replication from the source cluster defined as regular expression patterns. Here we request three consumer groups by name. You can use comma-separated lists.
-
Requests for reservation of supported resources, currently
cpu
andmemory
, and limits to specify the maximum resources that can be consumed. -
Specified Kafka Connect loggers and log levels added directly (
inline
) or indirectly (external
) through a ConfigMap. A custom ConfigMap must be placed under thelog4j.properties
orlog4j2.properties
key. For the Kafka Connectlog4j.rootLogger
logger, you can set the log level to INFO, ERROR, WARN, TRACE, DEBUG, FATAL or OFF. -
Healthchecks to know when to restart a container (liveness) and when a container can accept traffic (readiness).
-
JVM configuration options to optimize performance for the Virtual Machine (VM) running Kafka MirrorMaker.
-
ADVANCED OPTION: Container image configuration, which is recommended only in special situations.
-
Template customization. Here a pod is scheduled with anti-affinity, so the pod is not scheduled on nodes with the same hostname.
-
Environment variables are also set for distributed tracing using Jaeger.
-
External configuration for a Kubernetes Secret mounted to Kafka MirrorMaker as an environment variable. You can also use the Kubernetes Configuration Provider to load configuration values from external sources.
-
-
Create or update the resource:
kubectl apply -f MIRRORMAKER-CONFIGURATION-FILE
2.4.5. Performing a restart of a Kafka MirrorMaker 2.0 connector
This procedure describes how to manually trigger a restart of a Kafka MirrorMaker 2.0 connector by using a Kubernetes annotation.
-
The Cluster Operator is running.
-
Find the name of the
KafkaMirrorMaker2
custom resource that controls the Kafka MirrorMaker 2.0 connector you want to restart:kubectl get KafkaMirrorMaker2
-
Find the name of the Kafka MirrorMaker 2.0 connector to be restarted from the
KafkaMirrorMaker2
custom resource.kubectl describe KafkaMirrorMaker2 KAFKAMIRRORMAKER-2-NAME
-
To restart the connector, annotate the
KafkaMirrorMaker2
resource in Kubernetes. In this example,kubectl annotate
restarts a connector namedmy-source->my-target.MirrorSourceConnector
:kubectl annotate KafkaMirrorMaker2 KAFKAMIRRORMAKER-2-NAME "strimzi.io/restart-connector=my-source->my-target.MirrorSourceConnector"
-
Wait for the next reconciliation to occur (every two minutes by default).
The Kafka MirrorMaker 2.0 connector is restarted, as long as the annotation was detected by the reconciliation process. When the restart request is accepted, the annotation is removed from the
KafkaMirrorMaker2
custom resource.
2.4.6. Performing a restart of a Kafka MirrorMaker 2.0 connector task
This procedure describes how to manually trigger a restart of a Kafka MirrorMaker 2.0 connector task by using a Kubernetes annotation.
-
The Cluster Operator is running.
-
Find the name of the
KafkaMirrorMaker2
custom resource that controls the Kafka MirrorMaker 2.0 connector you want to restart:kubectl get KafkaMirrorMaker2
-
Find the name of the Kafka MirrorMaker 2.0 connector and the ID of the task to be restarted from the
KafkaMirrorMaker2
custom resource. Task IDs are non-negative integers, starting from 0.kubectl describe KafkaMirrorMaker2 KAFKAMIRRORMAKER-2-NAME
-
To restart the connector task, annotate the
KafkaMirrorMaker2
resource in Kubernetes. In this example,kubectl annotate
restarts task 0 of a connector namedmy-source->my-target.MirrorSourceConnector
:kubectl annotate KafkaMirrorMaker2 KAFKAMIRRORMAKER-2-NAME "strimzi.io/restart-connector-task=my-source->my-target.MirrorSourceConnector:0"
-
Wait for the next reconciliation to occur (every two minutes by default).
The Kafka MirrorMaker 2.0 connector task is restarted, as long as the annotation was detected by the reconciliation process. When the restart task request is accepted, the annotation is removed from the
KafkaMirrorMaker2
custom resource.
2.5. Kafka Bridge cluster configuration
This section describes how to configure a Kafka Bridge deployment in your Strimzi cluster.
Kafka Bridge provides an API for integrating HTTP-based clients with a Kafka cluster.
If you are using the Kafka Bridge, you configure the KafkaBridge
resource.
The full schema of the KafkaBridge
resource is described in KafkaBridge
schema reference.
2.5.1. Configuring the Kafka Bridge
Use the Kafka Bridge to make HTTP-based requests to the Kafka cluster.
Use the properties of the KafkaBridge
resource to configure your Kafka Bridge deployment.
In order to prevent issues arising when client consumer requests are processed by different Kafka Bridge instances, address-based routing must be employed to ensure that requests are routed to the right Kafka Bridge instance. Additionally, each independent Kafka Bridge instance must have a replica. A Kafka Bridge instance has its own state which is not shared with another instances.
-
A Kubernetes cluster
-
A running Cluster Operator
See the Deploying and Upgrading Strimzi guide for instructions on running a:
-
Edit the
spec
properties for theKafkaBridge
resource.The properties you can configure are shown in this example configuration:
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaBridge metadata: name: my-bridge spec: replicas: 3 (1) bootstrapServers: my-cluster-kafka-bootstrap:9092 (2) tls: (3) trustedCertificates: - secretName: my-cluster-cluster-cert certificate: ca.crt - secretName: my-cluster-cluster-cert certificate: ca2.crt authentication: (4) type: tls certificateAndKey: secretName: my-secret certificate: public.crt key: private.key http: (5) port: 8080 cors: (6) allowedOrigins: "https://strimzi.io" allowedMethods: "GET,POST,PUT,DELETE,OPTIONS,PATCH" consumer: (7) config: auto.offset.reset: earliest producer: (8) config: delivery.timeout.ms: 300000 resources: (9) requests: cpu: "1" memory: 2Gi limits: cpu: "2" memory: 2Gi logging: (10) type: inline loggers: logger.bridge.level: "INFO" # enabling DEBUG just for send operation logger.send.name: "http.openapi.operation.send" logger.send.level: "DEBUG" jvmOptions: (11) "-Xmx": "1g" "-Xms": "1g" readinessProbe: (12) initialDelaySeconds: 15 timeoutSeconds: 5 livenessProbe: initialDelaySeconds: 15 timeoutSeconds: 5 image: my-org/my-image:latest (13) template: (14) pod: affinity: podAntiAffinity: requiredDuringSchedulingIgnoredDuringExecution: - labelSelector: matchExpressions: - key: application operator: In values: - postgresql - mongodb topologyKey: "kubernetes.io/hostname" bridgeContainer: (15) env: - name: JAEGER_SERVICE_NAME value: my-jaeger-service - name: JAEGER_AGENT_HOST value: jaeger-agent-name - name: JAEGER_AGENT_PORT value: "6831"
-
Bootstrap server for connection to the target Kafka cluster.
-
TLS encryption with key names under which TLS certificates are stored in X.509 format for the source Kafka cluster. If certificates are stored in the same secret, it can be listed multiple times.
-
Authentication for the Kafka Bridge cluster, using the TLS mechanism, as shown here, using OAuth bearer tokens, or a SASL-based SCRAM-SHA-256/SCRAM-SHA-512 or PLAIN mechanism. By default, the Kafka Bridge connects to Kafka brokers without authentication.
-
HTTP access to Kafka brokers.
-
CORS access specifying selected resources and access methods. Additional HTTP headers in requests describe the origins that are permitted access to the Kafka cluster.
-
Consumer configuration options.
-
Producer configuration options.
-
Requests for reservation of supported resources, currently
cpu
andmemory
, and limits to specify the maximum resources that can be consumed. -
Specified Kafka Bridge loggers and log levels added directly (
inline
) or indirectly (external
) through a ConfigMap. A custom ConfigMap must be placed under thelog4j.properties
orlog4j2.properties
key. For the Kafka Bridge loggers, you can set the log level to INFO, ERROR, WARN, TRACE, DEBUG, FATAL or OFF. -
JVM configuration options to optimize performance for the Virtual Machine (VM) running the Kafka Bridge.
-
Healthchecks to know when to restart a container (liveness) and when a container can accept traffic (readiness).
-
Optional: Container image configuration, which is recommended only in special situations.
-
Template customization. Here a pod is scheduled with anti-affinity, so the pod is not scheduled on nodes with the same hostname.
-
Environment variables are also set for distributed tracing using Jaeger.
-
Create or update the resource:
kubectl apply -f KAFKA-BRIDGE-CONFIG-FILE
2.5.2. List of Kafka Bridge cluster resources
The following resources are created by the Cluster Operator in the Kubernetes cluster:
- bridge-cluster-name-bridge
-
Deployment which is in charge to create the Kafka Bridge worker node pods.
- bridge-cluster-name-bridge-service
-
Service which exposes the REST interface of the Kafka Bridge cluster.
- bridge-cluster-name-bridge-config
-
ConfigMap which contains the Kafka Bridge ancillary configuration and is mounted as a volume by the Kafka broker pods.
- bridge-cluster-name-bridge
-
Pod Disruption Budget configured for the Kafka Bridge worker nodes.
2.6. Customizing Kubernetes resources
Strimzi creates several Kubernetes resources, such as Deployments
, StatefulSets
, Pods
, and Services
, which are managed by Strimzi operators.
Only the operator that is responsible for managing a particular Kubernetes resource can change that resource.
If you try to manually change an operator-managed Kubernetes resource, the operator will revert your changes back.
However, changing an operator-managed Kubernetes resource can be useful if you want to perform certain tasks, such as:
-
Adding custom labels or annotations that control how
Pods
are treated by Istio or other services -
Managing how
Loadbalancer
-type Services are created by the cluster
You can make such changes using the template
property in the Strimzi custom resources.
The template
property is supported in the following resources.
The API reference provides more details about the customizable fields.
Kafka.spec.kafka
Kafka.spec.zookeeper
Kafka.spec.entityOperator
Kafka.spec.kafkaExporter
Kafka.spec.cruiseControl
Kafka.spec.jmxTrans
KafkaConnect.spec
KafkaMirrorMaker.spec
KafkaMirrorMaker2.spec
KafkaBridge.spec
KafkaUser.spec
In the following example, the template
property is used to modify the labels in a Kafka broker’s StatefulSet
:
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
labels:
app: my-cluster
spec:
kafka:
# ...
template:
statefulset:
metadata:
labels:
mylabel: myvalue
# ...
2.6.1. Customizing the image pull policy
Strimzi allows you to customize the image pull policy for containers in all pods deployed by the Cluster Operator.
The image pull policy is configured using the environment variable STRIMZI_IMAGE_PULL_POLICY
in the Cluster Operator deployment.
The STRIMZI_IMAGE_PULL_POLICY
environment variable can be set to three different values:
Always
-
Container images are pulled from the registry every time the pod is started or restarted.
IfNotPresent
-
Container images are pulled from the registry only when they were not pulled before.
Never
-
Container images are never pulled from the registry.
The image pull policy can be currently customized only for all Kafka, Kafka Connect, and Kafka MirrorMaker clusters at once. Changing the policy will result in a rolling update of all your Kafka, Kafka Connect, and Kafka MirrorMaker clusters.
-
For more information about Cluster Operator configuration, see Using the Cluster Operator.
-
For more information about Image Pull Policies, see Disruptions.
2.7. Configuring pod scheduling
When two applications are scheduled to the same Kubernetes node, both applications might use the same resources like disk I/O and impact performance. That can lead to performance degradation. Scheduling Kafka pods in a way that avoids sharing nodes with other critical workloads, using the right nodes or dedicated a set of nodes only for Kafka are the best ways how to avoid such problems.
2.7.1. Specifying affinity, tolerations, and topology spread constraints
Use affinity, tolerations and topology spread constraints to schedule the pods of kafka resources onto nodes.
Affinity, tolerations and topology spread constraints are configured using the affinity
, tolerations
, and topologySpreadConstraint
properties in following resources:
-
Kafka.spec.kafka.template.pod
-
Kafka.spec.zookeeper.template.pod
-
Kafka.spec.entityOperator.template.pod
-
KafkaConnect.spec.template.pod
-
KafkaBridge.spec.template.pod
-
KafkaMirrorMaker.spec.template.pod
-
KafkaMirrorMaker2.spec.template.pod
The format of the affinity
, tolerations
, and topologySpreadConstraint
properties follows the Kubernetes specification.
The affinity configuration can include different types of affinity:
-
Pod affinity and anti-affinity
-
Node affinity
Note
|
On Kubernetes 1.16 and 1.17, the support for topologySpreadConstraint is disabled by default.
In order to use topologySpreadConstraint , you have to enable the EvenPodsSpread feature gate in Kubernetes API server and scheduler.
|
Use pod anti-affinity to avoid critical applications sharing nodes
Use pod anti-affinity to ensure that critical applications are never scheduled on the same disk. When running a Kafka cluster, it is recommended to use pod anti-affinity to ensure that the Kafka brokers do not share nodes with other workloads, such as databases.
Use node affinity to schedule workloads onto specific nodes
The Kubernetes cluster usually consists of many different types of worker nodes. Some are optimized for CPU heavy workloads, some for memory, while other might be optimized for storage (fast local SSDs) or network. Using different nodes helps to optimize both costs and performance. To achieve the best possible performance, it is important to allow scheduling of Strimzi components to use the right nodes.
Kubernetes uses node affinity to schedule workloads onto specific nodes.
Node affinity allows you to create a scheduling constraint for the node on which the pod will be scheduled.
The constraint is specified as a label selector.
You can specify the label using either the built-in node label like beta.kubernetes.io/instance-type
or custom labels to select the right node.
Use node affinity and tolerations for dedicated nodes
Use taints to create dedicated nodes, then schedule Kafka pods on the dedicated nodes by configuring node affinity and tolerations.
Cluster administrators can mark selected Kubernetes nodes as tainted. Nodes with taints are excluded from regular scheduling and normal pods will not be scheduled to run on them. Only services which can tolerate the taint set on the node can be scheduled on it. The only other services running on such nodes will be system services such as log collectors or software defined networks.
Running Kafka and its components on dedicated nodes can have many advantages. There will be no other applications running on the same nodes which could cause disturbance or consume the resources needed for Kafka. That can lead to improved performance and stability.
2.7.2. Configuring pod anti-affinity to schedule each Kafka broker on a different worker node
Many Kafka brokers or ZooKeeper nodes can run on the same Kubernetes worker node.
If the worker node fails, they will all become unavailable at the same time.
To improve reliability, you can use podAntiAffinity
configuration to schedule each Kafka broker or ZooKeeper node on a different Kubernetes worker node.
-
A Kubernetes cluster
-
A running Cluster Operator
-
Edit the
affinity
property in the resource specifying the cluster deployment. To make sure that no worker nodes are shared by Kafka brokers or ZooKeeper nodes, use thestrimzi.io/name
label. Set thetopologyKey
tokubernetes.io/hostname
to specify that the selected pods are not scheduled on nodes with the same hostname. This will still allow the same worker node to be shared by a single Kafka broker and a single ZooKeeper node. For example:apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... template: pod: affinity: podAntiAffinity: requiredDuringSchedulingIgnoredDuringExecution: - labelSelector: matchExpressions: - key: strimzi.io/name operator: In values: - CLUSTER-NAME-kafka topologyKey: "kubernetes.io/hostname" # ... zookeeper: # ... template: pod: affinity: podAntiAffinity: requiredDuringSchedulingIgnoredDuringExecution: - labelSelector: matchExpressions: - key: strimzi.io/name operator: In values: - CLUSTER-NAME-zookeeper topologyKey: "kubernetes.io/hostname" # ...
Where
CLUSTER-NAME
is the name of your Kafka custom resource. -
If you even want to make sure that a Kafka broker and ZooKeeper node do not share the same worker node, use the
strimzi.io/cluster
label. For example:apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... template: pod: affinity: podAntiAffinity: requiredDuringSchedulingIgnoredDuringExecution: - labelSelector: matchExpressions: - key: strimzi.io/cluster operator: In values: - CLUSTER-NAME topologyKey: "kubernetes.io/hostname" # ... zookeeper: # ... template: pod: affinity: podAntiAffinity: requiredDuringSchedulingIgnoredDuringExecution: - labelSelector: matchExpressions: - key: strimzi.io/cluster operator: In values: - CLUSTER-NAME topologyKey: "kubernetes.io/hostname" # ...
Where
CLUSTER-NAME
is the name of your Kafka custom resource. -
Create or update the resource.
kubectl apply -f KAFKA-CONFIG-FILE
2.7.3. Configuring pod anti-affinity in Kafka components
Pod anti-affinity configuration helps with the stability and performance of Kafka brokers. By using podAntiAffinity
, Kubernetes will not schedule Kafka brokers on the same nodes as other workloads.
Typically, you want to avoid Kafka running on the same worker node as other network or storage intensive applications such as databases, storage or other messaging platforms.
-
A Kubernetes cluster
-
A running Cluster Operator
-
Edit the
affinity
property in the resource specifying the cluster deployment. Use labels to specify the pods which should not be scheduled on the same nodes. ThetopologyKey
should be set tokubernetes.io/hostname
to specify that the selected pods should not be scheduled on nodes with the same hostname. For example:apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... template: pod: affinity: podAntiAffinity: requiredDuringSchedulingIgnoredDuringExecution: - labelSelector: matchExpressions: - key: application operator: In values: - postgresql - mongodb topologyKey: "kubernetes.io/hostname" # ... zookeeper: # ...
-
Create or update the resource.
This can be done using
kubectl apply
:kubectl apply -f KAFKA-CONFIG-FILE
2.7.4. Configuring node affinity in Kafka components
-
A Kubernetes cluster
-
A running Cluster Operator
-
Label the nodes where Strimzi components should be scheduled.
This can be done using
kubectl label
:kubectl label node NAME-OF-NODE node-type=fast-network
Alternatively, some of the existing labels might be reused.
-
Edit the
affinity
property in the resource specifying the cluster deployment. For example:apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... template: pod: affinity: nodeAffinity: requiredDuringSchedulingIgnoredDuringExecution: nodeSelectorTerms: - matchExpressions: - key: node-type operator: In values: - fast-network # ... zookeeper: # ...
-
Create or update the resource.
This can be done using
kubectl apply
:kubectl apply -f KAFKA-CONFIG-FILE
2.7.5. Setting up dedicated nodes and scheduling pods on them
-
A Kubernetes cluster
-
A running Cluster Operator
-
Select the nodes which should be used as dedicated.
-
Make sure there are no workloads scheduled on these nodes.
-
Set the taints on the selected nodes:
This can be done using
kubectl taint
:kubectl taint node NAME-OF-NODE dedicated=Kafka:NoSchedule
-
Additionally, add a label to the selected nodes as well.
This can be done using
kubectl label
:kubectl label node NAME-OF-NODE dedicated=Kafka
-
Edit the
affinity
andtolerations
properties in the resource specifying the cluster deployment.For example:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... template: pod: tolerations: - key: "dedicated" operator: "Equal" value: "Kafka" effect: "NoSchedule" affinity: nodeAffinity: requiredDuringSchedulingIgnoredDuringExecution: nodeSelectorTerms: - matchExpressions: - key: dedicated operator: In values: - Kafka # ... zookeeper: # ...
-
Create or update the resource.
This can be done using
kubectl apply
:kubectl apply -f KAFKA-CONFIG-FILE
2.8. Logging configuration
Configure logging levels in the custom resources of Kafka components and Strimzi Operators.
You can specify the logging levels directly in the spec.logging
property of the custom resource.
Or you can define the logging properties in a ConfigMap that’s referenced in the custom resource using the configMapKeyRef
property.
The advantages of using a ConfigMap are that the logging properties are maintained in one place and are accessible to more than one resource. You can also reuse the ConfigMap for more than one resource. If you are using a ConfigMap to specify loggers for Strimzi Operators, you can also append the logging specification to add filters.
You specify a logging type
in your logging specification:
-
inline
when specifying logging levels directly -
external
when referencing a ConfigMap
inline
logging configurationspec:
# ...
logging:
type: inline
loggers:
kafka.root.logger.level: "INFO"
external
logging configurationspec:
# ...
logging:
type: external
valueFrom:
configMapKeyRef:
name: my-config-map
key: my-config-map-key
Values for the name
and key
of the ConfigMap are mandatory.
Default logging is used if the name
or key
is not set.
2.8.1. Logging options for Kafka components and operators
For more information on configuring logging for specific Kafka components or operators, see the following sections.
2.8.2. Creating a ConfigMap for logging
To use a ConfigMap to define logging properties, you create the ConfigMap and then reference it as part of the logging definition in the spec
of a resource.
The ConfigMap must contain the appropriate logging configuration.
-
log4j.properties
for Kafka components, ZooKeeper, and the Kafka Bridge -
log4j2.properties
for the Topic Operator and User Operator
The configuration must be placed under these properties.
In this procedure a ConfigMap defines a root logger for a Kafka resource.
-
Create the ConfigMap.
You can create the ConfigMap as a YAML file or from a properties file.
ConfigMap example with a root logger definition for Kafka:
kind: ConfigMap apiVersion: v1 metadata: name: logging-configmap data: log4j.properties: kafka.root.logger.level="INFO"
If you are using a properties file, specify the file at the command line:
kubectl create configmap logging-configmap --from-file=log4j.properties
The properties file defines the logging configuration:
# Define the logger kafka.root.logger.level="INFO" # ...
-
Define external logging in the
spec
of the resource, setting thelogging.valueFrom.configMapKeyRef.name
to the name of the ConfigMap andlogging.valueFrom.configMapKeyRef.key
to the key in this ConfigMap.spec: # ... logging: type: external valueFrom: configMapKeyRef: name: logging-configmap key: log4j.properties
-
Create or update the resource.
kubectl apply -f KAFKA-CONFIG-FILE
2.8.3. Adding logging filters to Operators
If you are using a ConfigMap to configure the (log4j2) logging levels for Strimzi Operators, you can also define logging filters to limit what’s returned in the log.
Logging filters are useful when you have a large number of logging messages.
Suppose you set the log level for the logger as DEBUG (rootLogger.level="DEBUG"
).
Logging filters reduce the number of logs returned for the logger at that level, so you can focus on a specific resource.
When the filter is set, only log messages matching the filter are logged.
Filters use markers to specify what to include in the log.
You specify a kind, namespace and name for the marker.
For example, if a Kafka cluster is failing, you can isolate the logs by specifying the kind as Kafka
, and use the namespace and name of the failing cluster.
This example shows a marker filter for a Kafka cluster named my-kafka-cluster
.
rootLogger.level="INFO"
appender.console.filter.filter1.type=MarkerFilter (1)
appender.console.filter.filter1.onMatch=ACCEPT (2)
appender.console.filter.filter1.onMismatch=DENY (3)
appender.console.filter.filter1.marker=Kafka(my-namespace/my-kafka-cluster) (4)
-
The
MarkerFilter
type compares a specified marker for filtering. -
The
onMatch
property accepts the log if the marker matches. -
The
onMismatch
property rejects the log if the marker does not match. -
The marker used for filtering is in the format KIND(NAMESPACE/NAME-OF-RESOURCE).
You can create one or more filters. Here, the log is filtered for two Kafka clusters.
appender.console.filter.filter1.type=MarkerFilter
appender.console.filter.filter1.onMatch=ACCEPT
appender.console.filter.filter1.onMismatch=DENY
appender.console.filter.filter1.marker=Kafka(my-namespace/my-kafka-cluster-1)
appender.console.filter.filter2.type=MarkerFilter
appender.console.filter.filter2.onMatch=ACCEPT
appender.console.filter.filter2.onMismatch=DENY
appender.console.filter.filter2.marker=Kafka(my-namespace/my-kafka-cluster-2)
To add filters to the Cluster Operator, update its logging ConfigMap YAML file (install/cluster-operator/050-ConfigMap-strimzi-cluster-operator.yaml
).
-
Update the
050-ConfigMap-strimzi-cluster-operator.yaml
file to add the filter properties to the ConfigMap.In this example, the filter properties return logs only for the
my-kafka-cluster
Kafka cluster:kind: ConfigMap apiVersion: v1 metadata: name: strimzi-cluster-operator data: log4j2.properties: #... appender.console.filter.filter1.type=MarkerFilter appender.console.filter.filter1.onMatch=ACCEPT appender.console.filter.filter1.onMismatch=DENY appender.console.filter.filter1.marker=Kafka(my-namespace/my-kafka-cluster)
Alternatively, edit the
ConfigMap
directly:kubectl edit configmap strimzi-cluster-operator
-
If you updated the YAML file instead of editing the
ConfigMap
directly, apply the changes by deploying the ConfigMap:kubectl create -f install/cluster-operator/050-ConfigMap-strimzi-cluster-operator.yaml
To add filters to the Topic Operator or User Operator, create or edit a logging ConfigMap.
In this procedure a logging ConfigMap is created with filters for the Topic Operator. The same approach is used for the User Operator.
-
Create the ConfigMap.
You can create the ConfigMap as a YAML file or from a properties file.
In this example, the filter properties return logs only for the
my-topic
topic:kind: ConfigMap apiVersion: v1 metadata: name: logging-configmap data: log4j2.properties: rootLogger.level="INFO" appender.console.filter.filter1.type=MarkerFilter appender.console.filter.filter1.onMatch=ACCEPT appender.console.filter.filter1.onMismatch=DENY appender.console.filter.filter1.marker=KafkaTopic(my-namespace/my-topic)
If you are using a properties file, specify the file at the command line:
kubectl create configmap logging-configmap --from-file=log4j2.properties
The properties file defines the logging configuration:
# Define the logger rootLogger.level="INFO" # Set the filters appender.console.filter.filter1.type=MarkerFilter appender.console.filter.filter1.onMatch=ACCEPT appender.console.filter.filter1.onMismatch=DENY appender.console.filter.filter1.marker=KafkaTopic(my-namespace/my-topic) # ...
-
Define external logging in the
spec
of the resource, setting thelogging.valueFrom.configMapKeyRef.name
to the name of the ConfigMap andlogging.valueFrom.configMapKeyRef.key
to the key in this ConfigMap.For the Topic Operator, logging is specified in the
topicOperator
configuration of theKafka
resource.spec: # ... entityOperator: topicOperator: logging: type: external valueFrom: configMapKeyRef: name: logging-configmap key: log4j2.properties
-
Apply the changes by deploying the Cluster Operator:
create -f install/cluster-operator -n my-cluster-operator-namespace
2.9. Loading configuration values from external sources
Use the Kubernetes Configuration Provider plugin to load configuration data from external sources. Load data from Kubernetes Secrets or ConfigMaps.
Suppose you have a Secret that’s managed outside the Kafka namespace, or outside the Kafka cluster. The provider allows you to reference the values of the Secret in your configuration without extracting the files. You just need to tell the provider what Secret to use and provide access rights. The provider loads the data without needing to restart the Kafka component, even when using a new Secret or ConfigMap. This capability avoids disruption when a Kafka Connect instance hosts multiple connectors.
The provider operates independently of Strimzi. You can use it to load configuration data for all Kafka components, including producers and consumers. Use it, for example, to provide the credentials for Kafka Connect connector configuration.
In this procedure, an external ConfigMap provides configuration properties for a connector.
Note
|
Kubernetes Configuration Provider can’t use mounted files.
For example, it can’t load values that need the location of a truststore or keystore.
Instead, you can mount ConfigMaps or Secrets into a Kafka Connect pod as environment variables or volumes.
You add configuration using the externalConfiguration property in KafkaConnect.spec .
You don’t need to set up access rights with this approach.
However, Kafka Connect will need a restart when using a new Secret or ConfigMap for a connector.
This will cause disruption to all the Kafka Connect instance’s connectors.
|
-
A Kubernetes cluster is available.
-
A Kafka cluster is running.
-
The Cluster Operator is running.
-
Create a ConfigMap or Secret that contains the configuration properties.
In this example, a ConfigMap named
my-connector-configuration
contains connector properties:Example ConfigMap with connector propertiesapiVersion: v1 kind: ConfigMap metadata: name: my-connector-configuration data: option1: value1 option2: value2
-
Specify the Kubernetes Configuration Provider in the Kafka Connect configuration.
The specification shown here can support loading values from Secrets and ConfigMaps.
Example external volumes set to values from a ConfigMapapiVersion: kafka.strimzi.io/v1beta2 kind: KafkaConnect metadata: name: my-connect annotations: strimzi.io/use-connector-resources: "true" spec: # ... config: # ... config.providers: secrets,configmaps (1) config.providers.secrets.class: io.strimzi.kafka.KubernetesSecretConfigProvider (2) config.providers.configmaps.class: io.strimzi.kafka.KubernetesConfigMapConfigProvider (3) # ...
-
The alias for the configuration provider is used to define other configuration parameters. The provider parameters use the alias from
config.providers
, taking the formconfig.providers.${alias}.class
. -
KubernetesSecretConfigProvider
provides values from Secrets. -
KubernetesConfigMapConfigProvider
provides values from ConfigMaps.
-
-
Create or update the resource to enable the provider.
kubectl apply -f KAFKA-CONNECT-CONFIG-FILE
-
Create a role that permits access to the values in the external ConfigMap.
Example role to access values from a ConfigMapapiVersion: rbac.authorization.k8s.io/v1 kind: Role metadata: name: connector-configuration-role rules: - apiGroups: [""] resources: ["configmaps"] resourceNames: ["my-connector-configuration"] verbs: ["get"] # ...
The rule gives the role permission to access the
my-connector-configuration
ConfigMap. -
Create a role binding to permit access to the namespace that contains the ConfigMap.
Example role binding to access the namespace that contains the ConfigMapapiVersion: rbac.authorization.k8s.io/v1 kind: RoleBinding metadata: name: connector-configuration-role-binding subjects: - kind: ServiceAccount name: my-connect-connect namespace: my-project roleRef: kind: Role name: connector-configuration-role apiGroup: rbac.authorization.k8s.io # ...
The role binding gives the role permission to access the
my-project
namespace.The service account must be the same one used by the Kafka Connect deployment. The service account name format is CLUSTER_NAME-connect, where CLUSTER_NAME is the name of the
KafkaConnect
custom resource. -
Reference the ConfigMap in the connector configuration.
Example connector configuration referencing the ConfigMapapiVersion: kafka.strimzi.io/v1beta2 kind: KafkaConnector metadata: name: my-connector labels: strimzi.io/cluster: my-connect spec: # ... config: option: ${configmaps:my-project/my-connector-configuration:option1} # ... # ...
Placeholders for the property values in the ConfigMap are referenced in the connector configuration. The placeholder structure is
configmaps:PATH-AND-FILE-NAME:PROPERTY
.KubernetesConfigMapConfigProvider
reads and extracts the option1 property value from the external ConfigMap.
3. Accessing Kafka outside of the Kubernetes cluster
Use an external listener to expose your Strimzi Kafka cluster to a client outside a Kubernetes environment.
Specify the connection type
to expose Kafka in the external listener configuration.
-
nodeport
usesNodePort
typeServices
-
loadbalancer
usesLoadbalancer
typeServices
-
ingress
uses KubernetesIngress
and the NGINX Ingress Controller for Kubernetes -
route
uses OpenShiftRoutes
and the HAProxy router
For more information on listener configuration, see GenericKafkaListener
schema reference.
If you want to know more about the pros and cons of each connection type, refer to Accessing Apache Kafka in Strimzi.
Note
|
route is only supported on OpenShift
|
3.1. Accessing Kafka using node ports
This procedure describes how to access a Strimzi Kafka cluster from an external client using node ports.
To connect to a broker, you need a hostname and port number for the Kafka bootstrap address, as well as the certificate used for authentication.
-
A Kubernetes cluster
-
A running Cluster Operator
-
Configure a
Kafka
resource with an external listener set to thenodeport
type.For example:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... listeners: - name: external port: 9094 type: nodeport tls: true authentication: type: tls # ... # ... zookeeper: # ...
-
Create or update the resource.
kubectl apply -f KAFKA-CONFIG-FILE
NodePort
type services are created for each Kafka broker, as well as an external bootstrap service. The bootstrap service routes external traffic to the Kafka brokers. Node addresses used for connection are propagated to thestatus
of the Kafka custom resource.The cluster CA certificate to verify the identity of the kafka brokers is also created with the same name as the
Kafka
resource. -
Retrieve the bootstrap address you can use to access the Kafka cluster from the status of the
Kafka
resource.kubectl get kafka KAFKA-CLUSTER-NAME -o=jsonpath='{.status.listeners[?(@.type=="external")].bootstrapServers}{"\n"}'
-
If TLS encryption is enabled, extract the public certificate of the broker certification authority.
kubectl get secret KAFKA-CLUSTER-NAME-cluster-ca-cert -o jsonpath='{.data.ca\.crt}' | base64 -d > ca.crt
Use the extracted certificate in your Kafka client to configure TLS connection. If you enabled any authentication, you will also need to configure SASL or TLS authentication.
3.2. Accessing Kafka using loadbalancers
This procedure describes how to access a Strimzi Kafka cluster from an external client using loadbalancers.
To connect to a broker, you need the address of the bootstrap loadbalancer, as well as the certificate used for TLS encryption.
-
A Kubernetes cluster
-
A running Cluster Operator
-
Configure a
Kafka
resource with an external listener set to theloadbalancer
type.For example:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... listeners: - name: external port: 9094 type: loadbalancer tls: true # ... # ... zookeeper: # ...
-
Create or update the resource.
kubectl apply -f KAFKA-CONFIG-FILE
loadbalancer
type services and loadbalancers are created for each Kafka broker, as well as an external bootstrap service. The bootstrap service routes external traffic to all Kafka brokers. DNS names and IP addresses used for connection are propagated to thestatus
of each service.The cluster CA certificate to verify the identity of the kafka brokers is also created with the same name as the
Kafka
resource. -
Retrieve the address of the bootstrap service you can use to access the Kafka cluster from the status of the
Kafka
resource.kubectl get kafka KAFKA-CLUSTER-NAME -o=jsonpath='{.status.listeners[?(@.type=="external")].bootstrapServers}{"\n"}'
-
If TLS encryption is enabled, extract the public certificate of the broker certification authority.
kubectl get secret KAFKA-CLUSTER-NAME-cluster-ca-cert -o jsonpath='{.data.ca\.crt}' | base64 -d > ca.crt
Use the extracted certificate in your Kafka client to configure TLS connection. If you enabled any authentication, you will also need to configure SASL or TLS authentication.
3.3. Accessing Kafka using ingress
This procedure shows how to access a Strimzi Kafka cluster from an external client outside of Kubernetes using Nginx Ingress.
To connect to a broker, you need a hostname (advertised address) for the Ingress bootstrap address, as well as the certificate used for authentication.
For access using Ingress, the port is always 443.
Kafka uses a binary protocol over TCP, but the NGINX Ingress Controller for Kubernetes is designed to work with the HTTP protocol. To be able to pass the Kafka connections through the Ingress, Strimzi uses the TLS passthrough feature of the NGINX Ingress Controller for Kubernetes. Ensure TLS passthrough is enabled in your NGINX Ingress Controller for Kubernetes deployment.
Because it is using the TLS passthrough functionality, TLS encryption cannot be disabled when exposing Kafka using Ingress
.
For more information about enabling TLS passthrough, see TLS passthrough documentation.
-
Kubernetes cluster
-
Deployed NGINX Ingress Controller for Kubernetes with TLS passthrough enabled
-
A running Cluster Operator
-
Configure a
Kafka
resource with an external listener set to theingress
type.Specify the Ingress hosts for the bootstrap service and Kafka brokers.
For example:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... listeners: - name: external port: 9094 type: ingress tls: true authentication: type: tls configuration: (1) bootstrap: host: bootstrap.myingress.com brokers: - broker: 0 host: broker-0.myingress.com - broker: 1 host: broker-1.myingress.com - broker: 2 host: broker-2.myingress.com # ... zookeeper: # ...
-
Ingress hosts for the bootstrap service and Kafka brokers.
-
-
Create or update the resource.
kubectl apply -f KAFKA-CONFIG-FILE
ClusterIP
type services are created for each Kafka broker, as well as an additional bootstrap service. These services are used by the Ingress controller to route traffic to the Kafka brokers. AnIngress
resource is also created for each service to expose them using the Ingress controller. The Ingress hosts are propagated to thestatus
of each service.The cluster CA certificate to verify the identity of the kafka brokers is also created with the same name as the
Kafka
resource.Use the address for the bootstrap host you specified in the
configuration
and port 443 (BOOTSTRAP-HOST:443) in your Kafka client as the bootstrap address to connect to the Kafka cluster. -
Extract the public certificate of the broker certificate authority.
kubectl get secret KAFKA-CLUSTER-NAME-cluster-ca-cert -o jsonpath='{.data.ca\.crt}' | base64 -d > ca.crt
Use the extracted certificate in your Kafka client to configure the TLS connection. If you enabled any authentication, you will also need to configure SASL or TLS authentication.
3.4. Accessing Kafka using OpenShift routes
This procedure describes how to access a Strimzi Kafka cluster from an external client outside of OpenShift using routes.
To connect to a broker, you need a hostname for the route bootstrap address, as well as the certificate used for TLS encryption.
For access using routes, the port is always 443.
-
An OpenShift cluster
-
A running Cluster Operator
-
Configure a
Kafka
resource with an external listener set to theroute
type.For example:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: labels: app: my-cluster name: my-cluster namespace: myproject spec: kafka: # ... listeners: - name: listener1 port: 9094 type: route tls: true # ... # ... zookeeper: # ...
WarningAn OpenShift Route address comprises the name of the Kafka cluster, the name of the listener, and the name of the namespace it is created in. For example, my-cluster-kafka-listener1-bootstrap-myproject
(CLUSTER-NAME-kafka-LISTENER-NAME-bootstrap-NAMESPACE). Be careful that the whole length of the address does not exceed a maximum limit of 63 characters. -
Create or update the resource.
kubectl apply -f KAFKA-CONFIG-FILE
ClusterIP
type services are created for each Kafka broker, as well as an external bootstrap service. The services route the traffic from the OpenShift Routes to the Kafka brokers. An OpenShiftRoute
resource is also created for each service to expose them using the HAProxy load balancer. DNS addresses used for connection are propagated to thestatus
of each service.The cluster CA certificate to verify the identity of the kafka brokers is also created with the same name as the
Kafka
resource. -
Retrieve the address of the bootstrap service you can use to access the Kafka cluster from the status of the
Kafka
resource.kubectl get kafka KAFKA-CLUSTER-NAME -o=jsonpath='{.status.listeners[?(@.type=="external")].bootstrapServers}{"\n"}'
-
Extract the public certificate of the broker certification authority.
kubectl get secret KAFKA-CLUSTER-NAME-cluster-ca-cert -o jsonpath='{.data.ca\.crt}' | base64 -d > ca.crt
Use the extracted certificate in your Kafka client to configure TLS connection. If you enabled any authentication, you will also need to configure SASL or TLS authentication.
4. Managing secure access to Kafka
You can secure your Kafka cluster by managing the access each client has to the Kafka brokers.
A secure connection between Kafka brokers and clients can encompass:
-
Encryption for data exchange
-
Authentication to prove identity
-
Authorization to allow or decline actions executed by users
This chapter explains how to set up secure connections between Kafka brokers and clients, with sections describing:
-
Security options for Kafka clusters and clients
-
How to secure Kafka brokers
-
How to use an authorization server for OAuth 2.0 token-based authentication and authorization
4.1. Security options for Kafka
Use the Kafka
resource to configure the mechanisms used for Kafka authentication and authorization.
4.1.1. Listener authentication
For clients inside the Kubernetes cluster, you can create plain
(without encryption) or tls
internal listeners.
For clients outside the Kubernetes cluster, you create external listeners and specify a connection mechanism,
which can be nodeport
, loadbalancer
, ingress
or route
(on OpenShift).
For more information on the configuration options for connecting an external client, see Accessing Kafka outside of the Kubernetes cluster.
Supported authentication options:
-
Mutual TLS authentication (only on the listeners with TLS enabled encryption)
-
SCRAM-SHA-512 authentication
The authentication option you choose depends on how you wish to authenticate client access to Kafka brokers.
The listener authentication
property is used to specify an authentication mechanism specific to that listener.
If no authentication
property is specified then the listener does not authenticate clients which connect through that listener.
The listener will accept all connections without authentication.
Authentication must be configured when using the User Operator to manage KafkaUsers
.
The following example shows:
-
A
plain
listener configured for SCRAM-SHA-512 authentication -
A
tls
listener with mutual TLS authentication -
An
external
listener with mutual TLS authentication
Each listener is configured with a unique name and port within a Kafka cluster.
Note
|
Listeners cannot be configured to use the ports reserved for inter-broker communication (9091 or 9090) and metrics (9404). |
# ...
listeners:
- name: plain
port: 9092
type: internal
tls: true
authentication:
type: scram-sha-512
- name: tls
port: 9093
type: internal
tls: true
authentication:
type: tls
- name: external
port: 9094
type: loadbalancer
tls: true
authentication:
type: tls
# ...
Mutual TLS authentication
Mutual TLS authentication is always used for the communication between Kafka brokers and ZooKeeper pods.
Strimzi can configure Kafka to use TLS (Transport Layer Security) to provide encrypted communication between Kafka brokers and clients either with or without mutual authentication. For mutual, or two-way, authentication, both the server and the client present certificates. When you configure mutual authentication, the broker authenticates the client (client authentication) and the client authenticates the broker (server authentication).
Note
|
TLS authentication is more commonly one-way, with one party authenticating the identity of another. For example, when HTTPS is used between a web browser and a web server, the browser obtains proof of the identity of the web server. |
SCRAM-SHA-512 authentication
SCRAM (Salted Challenge Response Authentication Mechanism) is an authentication protocol that can establish mutual authentication using passwords. Strimzi can configure Kafka to use SASL (Simple Authentication and Security Layer) SCRAM-SHA-512 to provide authentication on both unencrypted and encrypted client connections.
When SCRAM-SHA-512 authentication is used with a TLS client connection, the TLS protocol provides the encryption, but is not used for authentication.
The following properties of SCRAM make it safe to use SCRAM-SHA-512 even on unencrypted connections:
-
The passwords are not sent in the clear over the communication channel. Instead the client and the server are each challenged by the other to offer proof that they know the password of the authenticating user.
-
The server and client each generate a new challenge for each authentication exchange. This means that the exchange is resilient against replay attacks.
When a KafkaUser.spec.authentication.type
is configured with scram-sha-512
the User Operator will generate a random 12-character password consisting of upper and lowercase ASCII letters and numbers.
Network policies
By default, Strimzi automatically creates a NetworkPolicy
resource for every listener that is enabled on a Kafka broker.
This NetworkPolicy
allows applications to connect to listeners in all namespaces.
Use network policies as part of the listener configuration.
If you want to restrict access to a listener at the network level to only selected applications or namespaces, use the networkPolicyPeers
property.
Each listener can have a different networkPolicyPeers
configuration.
For more information on network policy peers, refer to the NetworkPolicyPeer API reference.
If you want to use custom network policies, you can set the STRIMZI_NETWORK_POLICY_GENERATION
environment variable to false
in the Cluster Operator configuration.
For more information, see Cluster Operator configuration.
Note
|
Your configuration of Kubernetes must support ingress NetworkPolicies in order to use network policies in Strimzi.
|
Additional listener configuration options
You can use the properties of the GenericKafkaListenerConfiguration schema to add further configuration to listeners.
4.1.2. Kafka authorization
You can configure authorization for Kafka brokers using the authorization
property in the Kafka.spec.kafka
resource.
If the authorization
property is missing, no authorization is enabled and clients have no restrictions.
When enabled, authorization is applied to all enabled listeners.
The authorization method is defined in the type
field.
Supported authorization options:
-
OAuth 2.0 authorization (if you are using OAuth 2.0 token based authentication)
Super users
Super users can access all resources in your Kafka cluster regardless of any access restrictions, and are supported by all authorization mechanisms.
To designate super users for a Kafka cluster, add a list of user principals to the superUsers
property.
If a user uses TLS client authentication, their username is the common name from their certificate subject prefixed with CN=
.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
namespace: myproject
spec:
kafka:
# ...
authorization:
type: simple
superUsers:
- CN=client_1
- user_2
- CN=client_3
# ...
4.2. Security options for Kafka clients
Use the KafkaUser
resource to configure the authentication mechanism, authorization mechanism, and access rights for Kafka clients.
In terms of configuring security, clients are represented as users.
You can authenticate and authorize user access to Kafka brokers. Authentication permits access, and authorization constrains the access to permissible actions.
You can also create super users that have unconstrained access to Kafka brokers.
The authentication and authorization mechanisms must match the specification for the listener used to access the Kafka brokers.
For more information on configuring a KafkaUser
resource to access Kafka brokers securely, see the following sections:
4.2.1. Identifying a Kafka cluster for user handling
A KafkaUser
resource includes a label that defines the appropriate name of the Kafka cluster (derived from the name of the Kafka
resource) to which it belongs.
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaUser
metadata:
name: my-user
labels:
strimzi.io/cluster: my-cluster
The label is used by the User Operator to identify the KafkaUser
resource and create a new user, and also in subsequent handling of the user.
If the label does not match the Kafka cluster, the User Operator cannot identify the KafkaUser
and the user is not created.
If the status of the KafkaUser
resource remains empty, check your label.
4.2.2. User authentication
User authentication is configured using the authentication
property in KafkaUser.spec
.
The authentication mechanism enabled for the user is specified using the type
field.
Supported authentication types:
-
tls
for TLS client authentication -
tls-external
for TLS client authentication using external certificates -
scram-sha-512
for SCRAM-SHA-512 authentication
If tls
or scram-sha-512
is specified, the User Operator creates authentication credentials when it creates the user.
If tls-external
is specified, the user still uses TLS client authentication, but no authentication credentials are created.
Use this option when you’re providing your own certificates.
When no authentication type is specified, the User Operator does not create the user or its credentials.
You can use tls-external
to authenticate with TLS client authentication using a certificate issued outside the User Operator.
The User Operator does not generate a TLS certificate or a secret.
You can still manage ACL rules and quotas through the User Operator in the same way as when you’re using the tls
mechanism.
This means that you use the CN=USER-NAME
format when specifying ACL rules and quotas.
USER-NAME is the common name given in a TLS certificate.
TLS client authentication
To use TLS client authentication, you set the type
field in the KafkaUser
resource to tls
.
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaUser
metadata:
name: my-user
labels:
strimzi.io/cluster: my-cluster
spec:
authentication:
type: tls
# ...
When the user is created by the User Operator, it creates a new secret with the same name as the KafkaUser
resource.
The secret contains a private and public key for TLS client authentication.
The public key is contained in a user certificate, which is signed by the client Certificate Authority (CA).
All keys are in X.509 format.
Secrets provide private keys and certificates in PEM and PKCS #12 formats.
For more information on securing Kafka communication with secrets, see Managing TLS certificates.
apiVersion: v1
kind: Secret
metadata:
name: my-user
labels:
strimzi.io/kind: KafkaUser
strimzi.io/cluster: my-cluster
type: Opaque
data:
ca.crt: # Public key of the client CA
user.crt: # User certificate that contains the public key of the user
user.key: # Private key of the user
user.p12: # PKCS #12 archive file for storing certificates and keys
user.password: # Password for protecting the PKCS #12 archive file
TLS client authentication using a certificate issued outside the User Operator
To use TLS client authentication using a certificate issued outside the User Operator, you set the type
field in the KafkaUser
resource to tls-external
.
A secret and credentials are not created for the user.
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaUser
metadata:
name: my-user
labels:
strimzi.io/cluster: my-cluster
spec:
authentication:
type: tls-external
# ...
SCRAM-SHA-512 authentication
To use the SCRAM-SHA-512 authentication mechanism, you set the type
field in the KafkaUser
resource to scram-sha-512
.
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaUser
metadata:
name: my-user
labels:
strimzi.io/cluster: my-cluster
spec:
authentication:
type: scram-sha-512
# ...
When the user is created by the User Operator, it creates a new secret with the same name as the KafkaUser
resource.
The secret contains the generated password in the password
key, which is encoded with base64.
In order to use the password, it must be decoded.
apiVersion: v1
kind: Secret
metadata:
name: my-user
labels:
strimzi.io/kind: KafkaUser
strimzi.io/cluster: my-cluster
type: Opaque
data:
password: Z2VuZXJhdGVkcGFzc3dvcmQ= (1)
sasl.jaas.config: b3JnLmFwYWNoZS5rYWZrYS5jb21tb24uc2VjdXJpdHkuc2NyYW0uU2NyYW1Mb2dpbk1vZHVsZSByZXF1aXJlZCB1c2VybmFtZT0ibXktdXNlciIgcGFzc3dvcmQ9ImdlbmVyYXRlZHBhc3N3b3JkIjsK (2)
-
The generated password, base64 encoded.
-
The JAAS configuration string for SASL SCRAM-SHA-512 authentication, base64 encoded.
Decoding the generated password:
echo "Z2VuZXJhdGVkcGFzc3dvcmQ=" | base64 --decode
Custom password configuration
When a user is created, Strimzi generates a random password.
You can use your own password instead of the one generated by Strimzi. To do so, create a secret with the password and reference it in the KafkaUser
resource.
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaUser
metadata:
name: my-user
labels:
strimzi.io/cluster: my-cluster
spec:
authentication:
type: scram-sha-512
password:
valueFrom:
secretKeyRef:
name: my-secret (1)
key: my-password (2)
# ...
-
The name of the secret containing the predefined password.
-
The key for the password stored inside the secret.
4.2.3. User authorization
User authorization is configured using the authorization
property in KafkaUser.spec
.
The authorization type enabled for a user is specified using the type
field.
To use simple authorization, you set the type
property to simple
in KafkaUser.spec.authorization
.
The simple authorization will use the Kafka Admin API to manage the ACL rules inside your Kafka cluster.
Whether ACL management in the User Operator is enabled or not depends on your authorization configuration in the Kafka cluster.
-
For simple authorization, ACL management is always enabled.
-
For OPA authorization, ACL management is always disabled. Authorization rules are configured in the OPA server.
-
For Keycloak authorization, you can manage the ACL rules directly in Keycloak. You can also delegate authorization to the simple authorizer as a fallback option in the configuration. When delegation to the simple authorizer is enabled, the User Operator will enable management of ACL rules as well.
-
For custom authorization using a custom authorization plugin, use the
supportsAdminApi
property in the.spec.kafka.authorization
configuration of theKafka
custom resource to enable or disable the support.
If ACL managment is not enabled, Strimzi rejects a resource if it contains any ACL rules.
If you’re using a standalone deployment of the User Operator, ACL management is enabled by default.
You can disable it using the STRIMZI_ACLS_ADMIN_API_SUPPORTED
environment variable.
If no authorization is specified, the User Operator does not provision any access rights for the user.
Whether such a KafkaUser
can still access resources depends on the authorizer being used.
For example, for the AclAuthorizer
this is determined by its allow.everyone.if.no.acl.found
configuration.
ACL rules
AclAuthorizer
uses ACL rules to manage access to Kafka brokers.
ACL rules grant access rights to the user, which you specify in the acls
property.
For more information about the AclRule
object, see the AclRule
schema reference.
Super user access to Kafka brokers
If a user is added to a list of super users in a Kafka broker configuration,
the user is allowed unlimited access to the cluster regardless of any authorization constraints defined in ACLs in KafkaUser
.
For more information on configuring super user access to brokers, see Kafka authorization.
User quotas
You can configure the spec
for the KafkaUser
resource to enforce quotas so that a user does not exceed a configured level of access to Kafka brokers.
You can set size-based network usage and time-based CPU utilization thresholds.
You can also add a partition mutation quota to control the rate at which requests to change partitions are accepted for user requests.
KafkaUser
with user quotasapiVersion: kafka.strimzi.io/v1beta2
kind: KafkaUser
metadata:
name: my-user
labels:
strimzi.io/cluster: my-cluster
spec:
# ...
quotas:
producerByteRate: 1048576 (1)
consumerByteRate: 2097152 (2)
requestPercentage: 55 (3)
controllerMutationRate: 10 (4)
-
Byte-per-second quota on the amount of data the user can push to a Kafka broker
-
Byte-per-second quota on the amount of data the user can fetch from a Kafka broker
-
CPU utilization limit as a percentage of time for a client group
-
Number of concurrent partition creation and deletion operations (mutations) allowed per second
For more information on these properties, see the KafkaUserQuotas
schema reference.
4.3. Securing access to Kafka brokers
To establish secure access to Kafka brokers, you configure and apply:
-
A
Kafka
resource to:-
Create listeners with a specified authentication type
-
Configure authorization for the whole Kafka cluster
-
-
A
KafkaUser
resource to access the Kafka brokers securely through the listeners
Configure the Kafka
resource to set up:
-
Listener authentication
-
Network policies that restrict access to Kafka listeners
-
Kafka authorization
-
Super users for unconstrained access to brokers
Authentication is configured independently for each listener. Authorization is always configured for the whole Kafka cluster.
The Cluster Operator creates the listeners and sets up the cluster and client certificate authority (CA) certificates to enable authentication within the Kafka cluster.
You can replace the certificates generated by the Cluster Operator by installing your own certificates. You can also configure your listener to use a Kafka listener certificate managed by an external Certificate Authority. Certificates are available in PKCS #12 format (.p12) and PEM (.crt) formats.
Use KafkaUser
to enable the authentication and authorization mechanisms that a specific client uses to access Kafka.
Configure the KafkaUser
resource to set up:
-
Authentication to match the enabled listener authentication
-
Authorization to match the enabled Kafka authorization
-
Quotas to control the use of resources by clients
The User Operator creates the user representing the client and the security credentials used for client authentication, based on the chosen authentication type.
Refer to the schema reference for more information on access configuration properties:
4.3.1. Securing Kafka brokers
This procedure shows the steps involved in securing Kafka brokers when running Strimzi.
The security implemented for Kafka brokers must be compatible with the security implemented for the clients requiring access.
-
Kafka.spec.kafka.listeners[*].authentication
matchesKafkaUser.spec.authentication
-
Kafka.spec.kafka.authorization
matchesKafkaUser.spec.authorization
The steps show the configuration for simple authorization and a listener using TLS authentication.
For more information on listener configuration, see GenericKafkaListener
schema reference.
Alternatively, you can use SCRAM-SHA or OAuth 2.0 for listener authentication, and OAuth 2.0 or OPA for Kafka authorization.
-
Configure the
Kafka
resource.-
Configure the
authorization
property for authorization. -
Configure the
listeners
property to create a listener with authentication.For example:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... authorization: (1) type: simple superUsers: (2) - CN=client_1 - user_2 - CN=client_3 listeners: - name: tls port: 9093 type: internal tls: true authentication: type: tls (3) # ... zookeeper: # ...
-
Authorization enables
simple
authorization on the Kafka broker using theAclAuthorizer
Kafka plugin. -
List of user principals with unlimited access to Kafka. CN is the common name from the client certificate when TLS authentication is used.
-
Listener authentication mechanisms may be configured for each listener, and specified as mutual TLS, SCRAM-SHA-512 or token-based OAuth 2.0.
If you are configuring an external listener, the configuration is dependent on the chosen connection mechanism.
-
-
-
Create or update the
Kafka
resource.kubectl apply -f KAFKA-CONFIG-FILE
The Kafka cluster is configured with a Kafka broker listener using TLS authentication.
A service is created for each Kafka broker pod.
A service is created to serve as the bootstrap address for connection to the Kafka cluster.
The cluster CA certificate to verify the identity of the kafka brokers is also created with the same name as the
Kafka
resource.
4.3.2. Securing user access to Kafka
Use the properties of the KafkaUser
resource to configure a Kafka user.
You can use kubectl apply
to create or modify users, and kubectl delete
to delete existing users.
For example:
-
kubectl apply -f USER-CONFIG-FILE
-
kubectl delete KafkaUser USER-NAME
When you configure the KafkaUser
authentication and authorization mechanisms, ensure they match the equivalent Kafka
configuration:
-
KafkaUser.spec.authentication
matchesKafka.spec.kafka.listeners[*].authentication
-
KafkaUser.spec.authorization
matchesKafka.spec.kafka.authorization
This procedure shows how a user is created with TLS authentication. You can also create a user with SCRAM-SHA authentication.
The authentication required depends on the type of authentication configured for the Kafka broker listener.
Note
|
Authentication between Kafka users and Kafka brokers depends on the authentication settings for each. For example, it is not possible to authenticate a user with TLS if it is not also enabled in the Kafka configuration. |
-
A running Kafka cluster configured with a Kafka broker listener using TLS authentication and encryption.
-
A running User Operator (typically deployed with the Entity Operator).
The authentication type in KafkaUser
should match the authentication configured in Kafka
brokers.
-
Configure the
KafkaUser
resource.For example:
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaUser metadata: name: my-user labels: strimzi.io/cluster: my-cluster spec: authentication: (1) type: tls authorization: type: simple (2) acls: - resource: type: topic name: my-topic patternType: literal operation: Read - resource: type: topic name: my-topic patternType: literal operation: Describe - resource: type: group name: my-group patternType: literal operation: Read
-
User authentication mechanism, defined as mutual
tls
orscram-sha-512
. -
Simple authorization, which requires an accompanying list of ACL rules.
-
-
Create or update the
KafkaUser
resource.kubectl apply -f USER-CONFIG-FILE
The user is created, as well as a Secret with the same name as the
KafkaUser
resource. The Secret contains a private and public key for TLS client authentication.
For information on configuring a Kafka client with properties for secure connection to Kafka brokers, see Setting up access for clients outside of Kubernetes in the Deploying and Upgrading Strimzi guide.
4.3.3. Restricting access to Kafka listeners using network policies
You can restrict access to a listener to only selected applications by using the networkPolicyPeers
property.
-
A Kubernetes cluster with support for Ingress NetworkPolicies.
-
The Cluster Operator is running.
-
Open the
Kafka
resource. -
In the
networkPolicyPeers
property, define the application pods or namespaces that will be allowed to access the Kafka cluster.For example, to configure a
tls
listener to allow connections only from application pods with the labelapp
set tokafka-client
:apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: kafka: # ... listeners: - name: tls port: 9093 type: internal tls: true authentication: type: tls networkPolicyPeers: - podSelector: matchLabels: app: kafka-client # ... zookeeper: # ...
-
Create or update the resource.
Use
kubectl apply
:kubectl apply -f your-file
4.4. Using OAuth 2.0 token-based authentication
Strimzi supports the use of OAuth 2.0 authentication using the OAUTHBEARER and PLAIN mechanisms.
OAuth 2.0 enables standardized token-based authentication and authorization between applications, using a central authorization server to issue tokens that grant limited access to resources.
Kafka brokers and clients both need to be configured to use OAuth 2.0. You can configure OAuth 2.0 authentication, then OAuth 2.0 authorization.
Note
|
OAuth 2.0 authentication can be used in conjunction with Kafka authorization. |
Using OAuth 2.0 authentication, application clients can access resources on application servers (called resource servers) without exposing account credentials.
The application client passes an access token as a means of authenticating, which application servers can also use to determine the level of access to grant. The authorization server handles the granting of access and inquiries about access.
In the context of Strimzi:
-
Kafka brokers act as OAuth 2.0 resource servers
-
Kafka clients act as OAuth 2.0 application clients
Kafka clients authenticate to Kafka brokers. The brokers and clients communicate with the OAuth 2.0 authorization server, as necessary, to obtain or validate access tokens.
For a deployment of Strimzi, OAuth 2.0 integration provides:
-
Server-side OAuth 2.0 support for Kafka brokers
-
Client-side OAuth 2.0 support for Kafka MirrorMaker, Kafka Connect and the Kafka Bridge
4.4.1. OAuth 2.0 authentication mechanisms
Strimzi supports the OAUTHBEARER and PLAIN mechanisms for OAuth 2.0 authentication. Both mechanisms allow Kafka clients to establish authenticated sessions with Kafka brokers. The authentication flow between clients, the authorization server, and Kafka brokers is different for each mechanism.
We recommend that you configure clients to use OAUTHBEARER whenever possible. OAUTHBEARER provides a higher level of security than PLAIN because client credentials are never shared with Kafka brokers. Consider using PLAIN only with Kafka clients that do not support OAUTHBEARER.
If necessary, OAUTHBEARER and PLAIN can be enabled together, on the same oauth
listener.
Kafka supports the OAUTHBEARER authentication mechanism, however it must be explicitly configured. Also, many Kafka client tools use libraries that provide basic support for OAUTHBEARER at the protocol level.
To ease application development, Strimzi provides an OAuth callback handler for the upstream Kafka Client Java libraries (but not for other libraries). Therefore, you do not need to write your own callback handlers for such clients. An application client can use the callback handler to provide the access token. Clients written in other languages, such as Go, must use custom code to connect to the authorization server and obtain the access token.
With OAUTHBEARER, the client initiates a session with the Kafka broker for credentials exchange, where credentials take the form of a bearer token provided by the callback handler. Using the callbacks, you can configure token provision in one of three ways:
-
Client ID and Secret (by using the OAuth 2.0 client credentials mechanism)
-
A long-lived access token, obtained manually at configuration time
-
A long-lived refresh token, obtained manually at configuration time
OAUTHBEARER is automatically enabled in the oauth
listener configuration for the Kafka broker.
You can set the enableOauthBearer
property to true
, though this is not required.
# ...
authentication:
type: oauth
# ...
enableOauthBearer: true
Note
|
OAUTHBEARER authentication can only be used by Kafka clients that support the OAUTHBEARER mechanism at the protocol level. |
PLAIN is a simple authentication mechanism used by all Kafka client tools. To enable PLAIN to be used together with OAuth 2.0 authentication, Strimzi includes server-side callbacks and calls this OAuth 2.0 over PLAIN.
With the Strimzi implementation of PLAIN, the client credentials are not stored in ZooKeeper. Instead, client credentials are handled centrally behind a compliant authorization server, similar to when OAUTHBEARER authentication is used.
When used with the OAuth 2.0 over PLAIN callbacks, Kafka clients authenticate with Kafka brokers using either of the following methods:
-
Client ID and secret (by using the OAuth 2.0 client credentials mechanism)
-
A long-lived access token, obtained manually at configuration time
The client must be enabled to use PLAIN authentication, and provide a username
and password
.
If the password is prefixed with $accessToken:
followed by the value of the access token, the Kafka broker will interpret the password as the access token.
Otherwise, the Kafka broker will interpret the username
as the client ID and the password
as the client secret.
If the password
is set as the access token, the username
must be set to the same principal name that the Kafka broker obtains from the access token.
The process depends on how you configure username extraction using userNameClaim
, fallbackUserNameClaim
, fallbackUsernamePrefix
, or userInfoEndpointUri
.
It also depends on your authorization server; in particular, how it maps client IDs to account names.
To use PLAIN, you must enable it in the oauth
listener configuration for the Kafka broker.
In the following example, PLAIN is enabled in addition to OAUTHBEARER, which is enabled by default.
If you want to use PLAIN only, you can disable OAUTHBEARER by setting enableOauthBearer
to false
.
# ...
authentication:
type: oauth
# ...
enablePlain: true
tokenEndpointUri: https://OAUTH-SERVER-ADDRESS/auth/realms/external/protocol/openid-connect/token
4.4.2. OAuth 2.0 Kafka broker configuration
Kafka broker configuration for OAuth 2.0 involves:
-
Creating the OAuth 2.0 client in the authorization server
-
Configuring OAuth 2.0 authentication in the Kafka custom resource
Note
|
In relation to the authorization server, Kafka brokers and Kafka clients are both regarded as OAuth 2.0 clients. |
OAuth 2.0 client configuration on an authorization server
To configure a Kafka broker to validate the token received during session initiation, the recommended approach is to create an OAuth 2.0 client definition in an authorization server, configured as confidential, with the following client credentials enabled:
-
Client ID of
kafka
(for example) -
Client ID and Secret as the authentication mechanism
Note
|
You only need to use a client ID and secret when using a non-public introspection endpoint of the authorization server. The credentials are not typically required when using public authorization server endpoints, as with fast local JWT token validation. |
OAuth 2.0 authentication configuration in the Kafka cluster
To use OAuth 2.0 authentication in the Kafka cluster, you specify, for example, a TLS listener configuration for your Kafka cluster custom resource with the authentication method oauth
:
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
spec:
kafka:
# ...
listeners:
- name: tls
port: 9093
type: internal
tls: true
authentication:
type: oauth
#...
You can configure plain
, tls
and external
listeners,
but it is recommended not to use plain
listeners or external
listeners with disabled TLS encryption with OAuth 2.0 as this creates a vulnerability to network eavesdropping and unauthorized access through token theft.
You configure an external
listener with type: oauth
for a secure transport layer to communicate with the client.
# ...
listeners:
- name: external
port: 9094
type: loadbalancer
tls: true
authentication:
type: oauth
#...
The tls
property is false by default, so it must be enabled.
When you have defined the type of authentication as OAuth 2.0, you add configuration based on the type of validation, either as fast local JWT validation or token validation using an introspection endpoint.
The procedure to configure OAuth 2.0 for listeners, with descriptions and examples, is described in Configuring OAuth 2.0 support for Kafka brokers.
Fast local JWT token validation configuration
Fast local JWT token validation checks a JWT token signature locally.
The local check ensures that a token:
-
Conforms to type by containing a (typ) claim value of
Bearer
for an access token -
Is valid (not expired)
-
Has an issuer that matches a
validIssuerURI
You specify a validIssuerURI
attribute when you configure the listener, so that any tokens not issued by the authorization server are rejected.
The authorization server does not need to be contacted during fast local JWT token validation.
You activate fast local JWT token validation by specifying a jwksEndpointUri
attribute, the endpoint exposed by the OAuth 2.0 authorization server.
The endpoint contains the public keys used to validate signed JWT tokens, which are sent as credentials by Kafka clients.
Note
|
All communication with the authorization server should be performed using TLS encryption. |
You can configure a certificate truststore as a Kubernetes Secret in your Strimzi project namespace, and use a tlsTrustedCertificates
attribute to point to the Kubernetes Secret containing the truststore file.
You might want to configure a userNameClaim
to properly extract a username from the JWT token.
If you want to use Kafka ACL authorization, you need to identify the user by their username during authentication.
(The sub
claim in JWT tokens is typically a unique ID, not a username.)
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
spec:
kafka:
#...
listeners:
- name: tls
port: 9093
type: internal
tls: true
authentication:
type: oauth
validIssuerUri: <https://<auth-server-address>/auth/realms/tls>
jwksEndpointUri: <https://<auth-server-address>/auth/realms/tls/protocol/openid-connect/certs>
userNameClaim: preferred_username
maxSecondsWithoutReauthentication: 3600
tlsTrustedCertificates:
- secretName: oauth-server-cert
certificate: ca.crt
#...
OAuth 2.0 introspection endpoint configuration
Token validation using an OAuth 2.0 introspection endpoint treats a received access token as opaque. The Kafka broker sends an access token to the introspection endpoint, which responds with the token information necessary for validation. Importantly, it returns up-to-date information if the specific access token is valid, and also information about when the token expires.
To configure OAuth 2.0 introspection-based validation, you specify an introspectionEndpointUri
attribute rather than the jwksEndpointUri
attribute specified for fast local JWT token validation.
Depending on the authorization server, you typically have to specify a clientId
and clientSecret
, because the introspection endpoint is usually protected.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
spec:
kafka:
listeners:
- name: tls
port: 9093
type: internal
tls: true
authentication:
type: oauth
clientId: kafka-broker
clientSecret:
secretName: my-cluster-oauth
key: clientSecret
validIssuerUri: <https://<auth-server-address>/auth/realms/tls>
introspectionEndpointUri: <https://<auth-server-address>/auth/realms/tls/protocol/openid-connect/token/introspect>
userNameClaim: preferred_username
maxSecondsWithoutReauthentication: 3600
tlsTrustedCertificates:
- secretName: oauth-server-cert
certificate: ca.crt
4.4.3. Session re-authentication for Kafka brokers
You can configure oauth
listeners to use Kafka session re-authentication for OAuth 2.0 sessions between Kafka clients and Kafka brokers.
This mechanism enforces the expiry of an authenticated session between the client and the broker after a defined period of time.
When a session expires, the client immediately starts a new session by reusing the existing connection rather than dropping it.
Session re-authentication is disabled by default.
To enable it, you set a time value for maxSecondsWithoutReauthentication
in the oauth
listener configuration.
The same property is used to configure session re-authentication for OAUTHBEARER and PLAIN authentication.
For an example configuration, see Configuring OAuth 2.0 support for Kafka brokers.
Session re-authentication must be supported by the Kafka client libraries used by the client.
Session re-authentication can be used with fast local JWT or introspection endpoint token validation.
When the broker’s authenticated session expires, the client must re-authenticate to the existing session by sending a new, valid access token to the broker, without dropping the connection.
If token validation is successful, a new client session is started using the existing connection. If the client fails to re-authenticate, the broker will close the connection if further attempts are made to send or receive messages. Java clients that use Kafka client library 2.2 or later automatically re-authenticate if the re-authentication mechanism is enabled on the broker.
Session re-authentication also applies to refresh tokens, if used. When the session expires, the client refreshes the access token by using its refresh token. The client then uses the new access token to re-authenticate to the existing session.
When session re-authentication is configured, session expiry works differently for OAUTHBEARER and PLAIN authentication.
For OAUTHBEARER and PLAIN, using the client ID and secret method:
-
The broker’s authenticated session will expire at the configured
maxSecondsWithoutReauthentication
. -
The session will expire earlier if the access token expires before the configured time.
For PLAIN using the long-lived access token method:
-
The broker’s authenticated session will expire at the configured
maxSecondsWithoutReauthentication
. -
Re-authentication will fail if the access token expires before the configured time. Although session re-authentication is attempted, PLAIN has no mechanism for refreshing tokens.
If maxSecondsWithoutReauthentication
is not configured, OAUTHBEARER and PLAIN clients can remain connected to brokers indefinitely, without needing to re-authenticate.
Authenticated sessions do not end with access token expiry.
However, this can be considered when configuring authorization, for example, by using keycloak
authorization or installing a custom authorizer.
4.4.4. OAuth 2.0 Kafka client configuration
A Kafka client is configured with either:
-
The credentials required to obtain a valid access token from an authorization server (client ID and Secret)
-
A valid long-lived access token or refresh token, obtained using tools provided by an authorization server
The only information ever sent to the Kafka broker is an access token. The credentials used to authenticate with the authorization server to obtain the access token are never sent to the broker.
When a client obtains an access token, no further communication with the authorization server is needed.
The simplest mechanism is authentication with a client ID and Secret. Using a long-lived access token, or a long-lived refresh token, adds more complexity because there is an additional dependency on authorization server tools.
Note
|
If you are using long-lived access tokens, you may need to configure the client in the authorization server to increase the maximum lifetime of the token. |
If the Kafka client is not configured with an access token directly, the client exchanges credentials for an access token during Kafka session initiation by contacting the authorization server. The Kafka client exchanges either:
-
Client ID and Secret
-
Client ID, refresh token, and (optionally) a Secret
4.4.5. OAuth 2.0 client authentication flow
In this section, we explain and visualize the communication flow between Kafka client, Kafka broker, and authorization server during Kafka session initiation. The flow depends on the client and server configuration.
When a Kafka client sends an access token as credentials to a Kafka broker, the token needs to be validated.
Depending on the authorization server used, and the configuration options available, you may prefer to use:
-
Fast local token validation based on JWT signature checking and local token introspection, without contacting the authorization server
-
An OAuth 2.0 introspection endpoint provided by the authorization server
Using fast local token validation requires the authorization server to provide a JWKS endpoint with public certificates that are used to validate signatures on the tokens.
Another option is to use an OAuth 2.0 introspection endpoint on the authorization server. Each time a new Kafka broker connection is established, the broker passes the access token received from the client to the authorization server, and checks the response to confirm whether or not the token is valid.
Kafka client credentials can also be configured for:
-
Direct local access using a previously generated long-lived access token
-
Contact with the authorization server for a new access token to be issued
Note
|
An authorization server might only allow the use of opaque access tokens, which means that local token validation is not possible. |
Example client authentication flows
Here you can see the communication flows, for different configurations of Kafka clients and brokers, during Kafka session authentication.
-
Client using client ID and secret, with broker delegating validation to authorization server
-
Client using client ID and secret, with broker performing fast local token validation
-
Client using long-lived access token, with broker delegating validation to authorization server
-
Client using long-lived access token, with broker performing fast local validation
-
Kafka client requests access token from authorization server, using client ID and secret, and optionally a refresh token.
-
Authorization server generates a new access token.
-
Kafka client authenticates with the Kafka broker using the SASL OAUTHBEARER mechanism to pass the access token.
-
Kafka broker validates the access token by calling a token introspection endpoint on authorization server, using its own client ID and secret.
-
Kafka client session is established if the token is valid.
-
Kafka client authenticates with authorization server from the token endpoint, using a client ID and secret, and optionally a refresh token.
-
Authorization server generates a new access token.
-
Kafka client authenticates with the Kafka broker using the SASL OAUTHBEARER mechanism to pass the access token.
-
Kafka broker validates the access token locally using a JWT token signature check, and local token introspection.
-
Kafka client authenticates with the Kafka broker using the SASL OAUTHBEARER mechanism to pass the long-lived access token.
-
Kafka broker validates the access token by calling a token introspection endpoint on authorization server, using its own client ID and secret.
-
Kafka client session is established if the token is valid.
-
Kafka client authenticates with the Kafka broker using the SASL OAUTHBEARER mechanism to pass the long-lived access token.
-
Kafka broker validates the access token locally using JWT token signature check, and local token introspection.
Warning
|
Fast local JWT token signature validation is suitable only for short-lived tokens as there is no check with the authorization server if a token has been revoked. Token expiration is written into the token, but revocation can happen at any time, so cannot be accounted for without contacting the authorization server. Any issued token would be considered valid until it expires. |
4.4.6. Configuring OAuth 2.0 authentication
OAuth 2.0 is used for interaction between Kafka clients and Strimzi components.
In order to use OAuth 2.0 for Strimzi, you must:
Configuring an OAuth 2.0 authorization server
This procedure describes in general what you need to do to configure an authorization server for integration with Strimzi.
These instructions are not product specific.
The steps are dependent on the chosen authorization server. Consult the product documentation for the authorization server for information on how to set up OAuth 2.0 access.
Note
|
If you already have an authorization server deployed, you can skip the deployment step and use your current deployment. |
-
Deploy the authorization server to your cluster.
-
Access the CLI or admin console for the authorization server to configure OAuth 2.0 for Strimzi.
Now prepare the authorization server to work with Strimzi.
-
Configure a
kafka-broker
client. -
Configure clients for each Kafka client component of your application.
After deploying and configuring the authorization server, configure the Kafka brokers to use OAuth 2.0.
Configuring OAuth 2.0 support for Kafka brokers
This procedure describes how to configure Kafka brokers so that the broker listeners are enabled to use OAuth 2.0 authentication using an authorization server.
We advise use of OAuth 2.0 over an encrypted interface through configuration of TLS listeners. Plain listeners are not recommended.
If the authorization server is using certificates signed by the trusted CA and matching the OAuth 2.0 server hostname, TLS connection works using the default settings. Otherwise, you may need to configure the truststore with prober certificates or disable the certificate hostname validation.
When configuring the Kafka broker you have two options for the mechanism used to validate the access token during OAuth 2.0 authentication of the newly connected Kafka client:
For more information on the configuration of OAuth 2.0 authentication for Kafka broker listeners, see:
-
Strimzi and Kafka are running
-
An OAuth 2.0 authorization server is deployed
-
Update the Kafka broker configuration (
Kafka.spec.kafka
) of yourKafka
resource in an editor.kubectl edit kafka my-cluster
-
Configure the Kafka broker
listeners
configuration.The configuration for each type of listener does not have to be the same, as they are independent.
The examples here show the configuration options as configured for external listeners.
Example 1: Configuring fast local JWT token validation#... - name: external port: 9094 type: loadbalancer tls: true authentication: type: oauth (1) validIssuerUri: <https://<auth-server-address>/auth/realms/external> (2) jwksEndpointUri: <https://<auth-server-address>/auth/realms/external/protocol/openid-connect/certs> (3) userNameClaim: preferred_username (4) maxSecondsWithoutReauthentication: 3600 (5) tlsTrustedCertificates: (6) - secretName: oauth-server-cert certificate: ca.crt disableTlsHostnameVerification: true (7) jwksExpirySeconds: 360 (8) jwksRefreshSeconds: 300 (9) jwksMinRefreshPauseSeconds: 1 (10)
-
Listener type set to
oauth
. -
URI of the token issuer used for authentication.
-
URI of the JWKS certificate endpoint used for local JWT validation.
-
The token claim (or key) that contains the actual user name in the token. The user name is the principal used to identify the user. The
userNameClaim
value will depend on the authentication flow and the authorization server used. -
(Optional) Activates the Kafka re-authentication mechanism that enforces session expiry to the same length of time as the access token. If the specified value is less than the time left for the access token to expire, then the client will have to re-authenticate before the actual token expiry. By default, the session does not expire when the access token expires, and the client does not attempt re-authentication.
-
(Optional) Trusted certificates for TLS connection to the authorization server.
-
(Optional) Disable TLS hostname verification. Default is
false
. -
The duration the JWKS certificates are considered valid before they expire. Default is
360
seconds. If you specify a longer time, consider the risk of allowing access to revoked certificates. -
The period between refreshes of JWKS certificates. The interval must be at least 60 seconds shorter than the expiry interval. Default is
300
seconds. -
The minimum pause in seconds between consecutive attempts to refresh JWKS public keys. When an unknown signing key is encountered, the JWKS keys refresh is scheduled outside the regular periodic schedule with at least the specified pause since the last refresh attempt. The refreshing of keys follows the rule of exponential backoff, retrying on unsuccessful refreshes with ever increasing pause, until it reaches
jwksRefreshSeconds
. The default value is 1.
Example 2: Configuring token validation using an introspection endpoint- name: external port: 9094 type: loadbalancer tls: true authentication: type: oauth validIssuerUri: <https://<auth-server-address>/auth/realms/external> introspectionEndpointUri: <https://<auth-server-address>/auth/realms/external/protocol/openid-connect/token/introspect> (1) clientId: kafka-broker (2) clientSecret: (3) secretName: my-cluster-oauth key: clientSecret userNameClaim: preferred_username (4) maxSecondsWithoutReauthentication: 3600 (5)
-
URI of the token introspection endpoint.
-
Client ID to identify the client.
-
Client Secret and client ID is used for authentication.
-
The token claim (or key) that contains the actual user name in the token. The user name is the principal used to identify the user. The
userNameClaim
value will depend on the authorization server used. -
(Optional) Activates the Kafka re-authentication mechanism that enforces session expiry to the same length of time as the access token. If the specified value is less than the time left for the access token to expire, then the client will have to re-authenticate before the actual token expiry. By default, the session does not expire when the access token expires, and the client does not attempt re-authentication.
Depending on how you apply OAuth 2.0 authentication, and the type of authorization server, there are additional (optional) configuration settings you can use:
# ... authentication: type: oauth # ... checkIssuer: false (1) checkAudience: true (2) fallbackUserNameClaim: client_id (3) fallbackUserNamePrefix: client-account- (4) validTokenType: bearer (5) userInfoEndpointUri: https://OAUTH-SERVER-ADDRESS/auth/realms/external/protocol/openid-connect/userinfo (6) enableOauthBearer: false (7) enablePlain: true (8) tokenEndpointUri: https://OAUTH-SERVER-ADDRESS/auth/realms/external/protocol/openid-connect/token (9) customClaimCheck: "@.custom == 'custom-value'" (10) clientAudience: AUDIENCE (11) clientScope: SCOPE (12)
-
If your authorization server does not provide an
iss
claim, it is not possible to perform an issuer check. In this situation, setcheckIssuer
tofalse
and do not specify avalidIssuerUri
. Default istrue
. -
If your authorization server provides an
aud
(audience) claim, and you want to enforce an audience check, setcheckAudience
totrue
. Audience checks identify the intended recipients of tokens. As a result, the Kafka broker will reject tokens that do not have itsclientId
in theiraud
claim. Default isfalse
. -
An authorization server may not provide a single attribute to identify both regular users and clients. When a client authenticates in its own name, the server might provide a client ID. When a user authenticates using a username and password, to obtain a refresh token or an access token, the server might provide a username attribute in addition to a client ID. Use this fallback option to specify the username claim (attribute) to use if a primary user ID attribute is not available.
-
In situations where
fallbackUserNameClaim
is applicable, it may also be necessary to prevent name collisions between the values of the username claim, and those of the fallback username claim. Consider a situation where a client calledproducer
exists, but also a regular user calledproducer
exists. In order to differentiate between the two, you can use this property to add a prefix to the user ID of the client. -
(Only applicable when using
introspectionEndpointUri
) Depending on the authorization server you are using, the introspection endpoint may or may not return the token type attribute, or it may contain different values. You can specify a valid token type value that the response from the introspection endpoint has to contain. -
(Only applicable when using
introspectionEndpointUri
) The authorization server may be configured or implemented in such a way to not provide any identifiable information in an Introspection Endpoint response. In order to obtain the user ID, you can configure the URI of theuserinfo
endpoint as a fallback. TheuserNameClaim
,fallbackUserNameClaim
, andfallbackUserNamePrefix
settings are applied to the response ofuserinfo
endpoint. -
Set this to
false`to disable the OAUTHBEARER mechanism on the listener. At least one of PLAIN or OAUTHBEARER has to be enabled. Default is `true
. -
Set to
true
to enable PLAIN authentication on the listener, which is supported by all clients on all platforms. The Kafka client must enable the PLAIN mechanism and set theusername
andpassword
. PLAIN can be used to authenticate either by using the OAuth access token, or the OAuthclientId
andsecret
(the client credentials). The behavior is additionally controlled by whethertokenEndpointUri
is specified or not. Default isfalse
. IftokenEndpointUri
is specified and the client setspassword
to start with the string$accessToken:
, the server interprets the password as the access token and theusername
as the account username. Otherwise, theusername
is interpreted as theclientId
and thepassword
as the clientsecret
, which the broker uses to obtain the access token in the client’s name. IftokenEndpointUri
is not specified, thepassword
is always interpreted as an access token and theusername
is always interpreted as the account username, which must match the principal id extracted from the token. This is known as 'no-client-credentials' mode because the client must always obtain the access token by itself, and can’t useclientId
andsecret
. -
Additional configuration for PLAIN mechanism to allow clients to authenticate by passing
clientId
andsecret
asusername
andpassword
as described in the previous point. If not specified the clients can authenticate over PLAIN only by passing an access token aspassword
parameter. -
Additional custom rules can be imposed on the JWT access token during validation by setting this to a JsonPath filter query. If the access token does not contain the necessary data, it is rejected. When using the
introspectionEndpointUri
, the custom check is applied to the introspection endpoint response JSON. -
(Optional) An
audience
parameter passed to the token endpoint. An audience is used when obtaining an access token for inter-broker authentication. It is also used in the name of a client for OAuth 2.0 over PLAIN client authentication using aclientId
andsecret
. This only affects the ability to obtain the token, and the content of the token, depending on the authorization server. It does not affect token validation rules by the listener. -
(Optional) A
scope
parameter passed to the token endpoint. A scope is used when obtaining an access token for inter-broker authentication. It is also used in the name of a client for OAuth 2.0 over PLAIN client authentication using aclientId
andsecret
. This only affects the ability to obtain the token, and the content of the token, depending on the authorization server. It does not affect token validation rules by the listener.
-
-
Save and exit the editor, then wait for rolling updates to complete.
-
Check the update in the logs or by watching the pod state transitions:
kubectl logs -f ${POD_NAME} -c ${CONTAINER_NAME} kubectl get pod -w
The rolling update configures the brokers to use OAuth 2.0 authentication.
Configuring Kafka Java clients to use OAuth 2.0
This procedure describes how to configure Kafka producer and consumer APIs to use OAuth 2.0 for interaction with Kafka brokers.
Add a client callback plugin to your pom.xml file, and configure the system properties.
-
Strimzi and Kafka are running
-
An OAuth 2.0 authorization server is deployed and configured for OAuth access to Kafka brokers
-
Kafka brokers are configured for OAuth 2.0
-
Add the client library with OAuth 2.0 support to the
pom.xml
file for the Kafka client:<dependency> <groupId>io.strimzi</groupId> <artifactId>kafka-oauth-client</artifactId> <version>{oauth-version}</version> </dependency>
-
Configure the system properties for the callback:
For example:
System.setProperty(ClientConfig.OAUTH_TOKEN_ENDPOINT_URI, “https://<auth-server-address>/auth/realms/master/protocol/openid-connect/token”); (1) System.setProperty(ClientConfig.OAUTH_CLIENT_ID, "<client-name>"); (2) System.setProperty(ClientConfig.OAUTH_CLIENT_SECRET, "<client-secret>"); (3)
-
URI of the authorization server token endpoint.
-
Client ID, which is the name used when creating the client in the authorization server.
-
Client secret created when creating the client in the authorization server.
-
-
Enable the SASL OAUTHBEARER mechanism on a TLS encrypted connection in the Kafka client configuration:
For example:
props.put("sasl.jaas.config", "org.apache.kafka.common.security.oauthbearer.OAuthBearerLoginModule required;"); props.put("security.protocol", "SASL_SSL"); (1) props.put("sasl.mechanism", "OAUTHBEARER"); props.put("sasl.login.callback.handler.class", "io.strimzi.kafka.oauth.client.JaasClientOauthLoginCallbackHandler");
-
Here we use
SASL_SSL
for use over TLS connections. UseSASL_PLAINTEXT
over unencrypted connections.
-
-
Verify that the Kafka client can access the Kafka brokers.
Configuring OAuth 2.0 for Kafka components
This procedure describes how to configure Kafka components to use OAuth 2.0 authentication using an authorization server.
You can configure authentication for:
-
Kafka Connect
-
Kafka MirrorMaker
-
Kafka Bridge
In this scenario, the Kafka component and the authorization server are running in the same cluster.
For more information on the configuration of OAuth 2.0 authentication for Kafka components, see:
-
Strimzi and Kafka are running
-
An OAuth 2.0 authorization server is deployed and configured for OAuth access to Kafka brokers
-
Kafka brokers are configured for OAuth 2.0
-
Create a client secret and mount it to the component as an environment variable.
For example, here we are creating a client
Secret
for the Kafka Bridge:apiVersion: kafka.strimzi.io/v1beta2 kind: Secret metadata: name: my-bridge-oauth type: Opaque data: clientSecret: MGQ1OTRmMzYtZTllZS00MDY2LWI5OGEtMTM5MzM2NjdlZjQw (1)
-
The
clientSecret
key must be in base64 format.
-
-
Create or edit the resource for the Kafka component so that OAuth 2.0 authentication is configured for the authentication property.
For OAuth 2.0 authentication, you can use:
-
Client ID and secret
-
Client ID and refresh token
-
Access token
-
TLS
For example, here OAuth 2.0 is assigned to the Kafka Bridge client using a client ID and secret, and TLS:
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaBridge metadata: name: my-bridge spec: # ... authentication: type: oauth (1) tokenEndpointUri: https://<auth-server-address>/auth/realms/master/protocol/openid-connect/token (2) clientId: kafka-bridge clientSecret: secretName: my-bridge-oauth key: clientSecret tlsTrustedCertificates: (3) - secretName: oauth-server-cert certificate: tls.crt
-
Authentication type set to
oauth
. -
URI of the token endpoint for authentication.
-
Trusted certificates for TLS connection to the authorization server.
Depending on how you apply OAuth 2.0 authentication, and the type of authorization server, there are additional configuration options you can use:
# ... spec: # ... authentication: # ... disableTlsHostnameVerification: true (1) checkAccessTokenType: false (2) accessTokenIsJwt: false (3) scope: any (4) audience: kafka (5)
-
(Optional) Disable TLS hostname verification. Default is
false
. -
If the authorization server does not return a
typ
(type) claim inside the JWT token, you can applycheckAccessTokenType: false
to skip the token type check. Default istrue
. -
If you are using opaque tokens, you can apply
accessTokenIsJwt: false
so that access tokens are not treated as JWT tokens. -
(Optional) The
scope
for requesting the token from the token endpoint. An authorization server may require a client to specify the scope. In this case it isany
. -
(Optional) The
audience
for requesting the token from the token endpoint. An authorization server may require a client to specify the audience. In this case it iskafka
.
-
-
Apply the changes to the deployment of your Kafka resource.
kubectl apply -f your-file
-
Check the update in the logs or by watching the pod state transitions:
kubectl logs -f ${POD_NAME} -c ${CONTAINER_NAME} kubectl get pod -w
The rolling updates configure the component for interaction with Kafka brokers using OAuth 2.0 authentication.
4.4.7. Authorization server examples
When choosing an authorization server, consider the features that best support configuration of your chosen authentication flow.
For the purposes of testing OAuth 2.0 with Strimzi, Keycloak and ORY Hydra were implemented as the OAuth 2.0 authorization server.
For more information, see:
4.5. Using OAuth 2.0 token-based authorization
Strimzi supports the use of OAuth 2.0 token-based authorization through Keycloak Keycloak Authorization Services, which allows you to manage security policies and permissions centrally.
Security policies and permissions defined in Keycloak are used to grant access to resources on Kafka brokers. Users and clients are matched against policies that permit access to perform specific actions on Kafka brokers.
Kafka allows all users full access to brokers by default,
and also provides the AclAuthorizer
plugin to configure authorization based on Access Control Lists (ACLs).
ZooKeeper stores ACL rules that grant or deny access to resources based on username. However, OAuth 2.0 token-based authorization with Keycloak offers far greater flexibility on how you wish to implement access control to Kafka brokers. In addition, you can configure your Kafka brokers to use OAuth 2.0 authorization and ACLs.
4.5.1. OAuth 2.0 authorization mechanism
OAuth 2.0 authorization in Strimzi uses Keycloak server Authorization Services REST endpoints to extend token-based authentication with Keycloak by applying defined security policies on a particular user, and providing a list of permissions granted on different resources for that user. Policies use roles and groups to match permissions to users. OAuth 2.0 authorization enforces permissions locally based on the received list of grants for the user from Keycloak Authorization Services.
Kafka broker custom authorizer
A Keycloak authorizer (KeycloakRBACAuthorizer
) is provided with Strimzi.
To be able to use the Keycloak REST endpoints for Authorization Services provided by Keycloak,
you configure a custom authorizer on the Kafka broker.
The authorizer fetches a list of granted permissions from the authorization server as needed, and enforces authorization locally on the Kafka Broker, making rapid authorization decisions for each client request.
4.5.2. Configuring OAuth 2.0 authorization support
This procedure describes how to configure Kafka brokers to use OAuth 2.0 authorization using Keycloak Authorization Services.
Consider the access you require or want to limit for certain users. You can use a combination of Keycloak groups, roles, clients, and users to configure access in Keycloak.
Typically, groups are used to match users based on organizational departments or geographical locations. And roles are used to match users based on their function.
With Keycloak, you can store users and groups in LDAP, whereas clients and roles cannot be stored this way. Storage and access to user data may be a factor in how you choose to configure authorization policies.
Note
|
Super users always have unconstrained access to a Kafka broker regardless of the authorization implemented on the Kafka broker. |
-
Strimzi must be configured to use OAuth 2.0 with Keycloak for token-based authentication. You use the same Keycloak server endpoint when you set up authorization.
-
OAuth 2.0 authentication must be configured with the
maxSecondsWithoutReauthentication
option to enable re-authentication.
-
Access the Keycloak Admin Console or use the Keycloak Admin CLI to enable Authorization Services for the Kafka broker client you created when setting up OAuth 2.0 authentication.
-
Use Authorization Services to define resources, authorization scopes, policies, and permissions for the client.
-
Bind the permissions to users and clients by assigning them roles and groups.
-
Configure the Kafka brokers to use Keycloak authorization by updating the Kafka broker configuration (
Kafka.spec.kafka
) of yourKafka
resource in an editor.kubectl edit kafka my-cluster
-
Configure the Kafka broker
kafka
configuration to usekeycloak
authorization, and to be able to access the authorization server and Authorization Services.For example:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: kafka: # ... authorization: type: keycloak (1) tokenEndpointUri: <https://<auth-server-address>/auth/realms/external/protocol/openid-connect/token> (2) clientId: kafka (3) delegateToKafkaAcls: false (4) disableTlsHostnameVerification: false (5) superUsers: (6) - CN=fred - sam - CN=edward tlsTrustedCertificates: (7) - secretName: oauth-server-cert certificate: ca.crt grantsRefreshPeriodSeconds: 60 (8) grantsRefreshPoolSize: 5 (9) #...
-
Type
keycloak
enables Keycloak authorization. -
URI of the Keycloak token endpoint. For production, always use HTTPs. When you configure token-based
oauth
authentication, you specify ajwksEndpointUri
as the URI for local JWT validation. The hostname for thetokenEndpointUri
URI must be the same. -
The client ID of the OAuth 2.0 client definition in Keycloak that has Authorization Services enabled. Typically,
kafka
is used as the ID. -
(Optional) Delegate authorization to Kafka
AclAuthorizer
if access is denied by Keycloak Authorization Services policies. Default isfalse
. -
(Optional) Disable TLS hostname verification. Default is
false
. -
(Optional) Designated super users.
-
(Optional) Trusted certificates for TLS connection to the authorization server.
-
(Optional) The time between two consecutive grants refresh runs. That is the maximum time for active sessions to detect any permissions changes for the user on Keycloak. The default value is 60.
-
(Optional) The number of threads to use to refresh (in parallel) the grants for the active sessions. The default value is 5.
-
-
Save and exit the editor, then wait for rolling updates to complete.
-
Check the update in the logs or by watching the pod state transitions:
kubectl logs -f ${POD_NAME} -c kafka kubectl get pod -w
The rolling update configures the brokers to use OAuth 2.0 authorization.
-
Verify the configured permissions by accessing Kafka brokers as clients or users with specific roles, making sure they have the necessary access, or do not have the access they are not supposed to have.
4.5.3. Managing policies and permissions in Keycloak Authorization Services
This section describes the authorization models used by Keycloak Authorization Services and Kafka, and defines the important concepts in each model.
To grant permissions to access Kafka, you can map Keycloak Authorization Services objects to Kafka resources by creating an OAuth client specification in Keycloak. Kafka permissions are granted to user accounts or service accounts using Keycloak Authorization Services rules.
Examples are shown of the different user permissions required for common Kafka operations, such as creating and listing topics.
Kafka and Keycloak authorization models overview
Kafka and Keycloak Authorization Services use different authorization models.
Kafka authorization model
Kafka’s authorization model uses resource types.
When a Kafka client performs an action on a broker, the broker uses the configured KeycloakRBACAuthorizer
to check the client’s permissions, based on the action and resource type.
Kafka uses five resource types to control access: Topic
, Group
, Cluster
, TransactionalId
, and DelegationToken
.
Each resource type has a set of available permissions.
Topic
-
Create
-
Write
-
Read
-
Delete
-
Describe
-
DescribeConfigs
-
Alter
-
AlterConfigs
Group
-
Read
-
Describe
-
Delete
Cluster
-
Create
-
Describe
-
Alter
-
DescribeConfigs
-
AlterConfigs
-
IdempotentWrite
-
ClusterAction
TransactionalId
-
Describe
-
Write
DelegationToken
-
Describe
Keycloak Authorization Services model
The Keycloak Authorization Services model has four concepts for defining and granting permissions: resources, authorization scopes, policies, and permissions.
- Resources
-
A resource is a set of resource definitions that are used to match resources with permitted actions. A resource might be an individual topic, for example, or all topics with names starting with the same prefix. A resource definition is associated with a set of available authorization scopes, which represent a set of all actions available on the resource. Often, only a subset of these actions is actually permitted.
- Authorization scopes
-
An authorization scope is a set of all the available actions on a specific resource definition. When you define a new resource, you add scopes from the set of all scopes.
- Policies
-
A policy is an authorization rule that uses criteria to match against a list of accounts. Policies can match:
-
Service accounts based on client ID or roles
-
User accounts based on username, groups, or roles.
-
- Permissions
-
A permission grants a subset of authorization scopes on a specific resource definition to a set of users.
Map Keycloak Authorization Services to the Kafka authorization model
The Kafka authorization model is used as a basis for defining the Keycloak roles and resources that will control access to Kafka.
To grant Kafka permissions to user accounts or service accounts, you first create an OAuth client specification in Keycloak for the Kafka broker.
You then specify Keycloak Authorization Services rules on the client.
Typically, the client id of the OAuth client that represents the broker is kafka
.
The example configuration files provided with Strimzi use kafka
as the OAuth client id.
Note
|
If you have multiple Kafka clusters, you can use a single OAuth client ( |
The kafka
client definition must have the Authorization Enabled option enabled in the Keycloak Admin Console.
All permissions exist within the scope of the kafka
client. If you have different Kafka clusters configured with different OAuth client IDs, they each need a separate set of permissions even though they’re part of the same Keycloak realm.
When the Kafka client uses OAUTHBEARER authentication, the Keycloak authorizer (KeycloakRBACAuthorizer
) uses the access token of the current session to retrieve a list of grants from the Keycloak server.
To retrieve the grants, the authorizer evaluates the Keycloak Authorization Services policies and permissions.
An initial Keycloak configuration usually involves uploading authorization scopes to create a list of all possible actions that can be performed on each Kafka resource type. This step is performed once only, before defining any permissions. You can add authorization scopes manually instead of uploading them.
Authorization scopes must contain all the possible Kafka permissions regardless of the resource type:
-
Create
-
Write
-
Read
-
Delete
-
Describe
-
Alter
-
DescribeConfig
-
AlterConfig
-
ClusterAction
-
IdempotentWrite
Note
|
If you’re certain you won’t need a permission (for example, |
Resource patterns are used for pattern matching against the targeted resources when performing permission checks.
The general pattern format is RESOURCE-TYPE:PATTERN-NAME
.
The resource types mirror the Kafka authorization model. The pattern allows for two matching options:
-
Exact matching (when the pattern does not end with
*
) -
Prefix matching (when the pattern ends with
*
)
Topic:my-topic
Topic:orders-*
Group:orders-*
Cluster:*
Additionally, the general pattern format can be prefixed by kafka-cluster:CLUSTER-NAME
followed by a comma, where CLUSTER-NAME refers to the metadata.name
in the Kafka custom resource.
kafka-cluster:my-cluster,Topic:*
kafka-cluster:*,Group:b_*
When the kafka-cluster
prefix is missing, it is assumed to be kafka-cluster:*
.
When defining a resource, you can associate it with a list of possible authorization scopes which are relevant to the resource. Set whatever actions make sense for the targeted resource type.
Though you may add any authorization scope to any resource, only the scopes supported by the resource type are considered for access control.
Policies are used to target permissions to one or more user accounts or service accounts. Targeting can refer to:
-
Specific user or service accounts
-
Realm roles or client roles
-
User groups
-
JavaScript rules to match a client IP address
A policy is given a unique name and can be reused to target multiple permissions to multiple resources.
Use fine-grained permissions to pull together the policies, resources, and authorization scopes that grant access to users.
The name of each permission should clearly define which permissions it grants to which users.
For example, Dev Team B can read from topics starting with x
.
-
For more information about how to configure permissions through Keycloak Authorization Services, see Trying Keycloak Authorization Services.
Example permissions required for Kafka operations
The following examples demonstrate the user permissions required for performing common operations on Kafka.
To create a topic, the Create
permission is required for the specific topic, or for Cluster:kafka-cluster
.
bin/kafka-topics.sh --create --topic my-topic \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config=/tmp/config.properties
If a user has the Describe
permission on a specified topic, the topic is listed.
bin/kafka-topics.sh --list \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config=/tmp/config.properties
To display a topic’s details, Describe
and DescribeConfigs
permissions are required on the topic.
bin/kafka-topics.sh --describe --topic my-topic \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config=/tmp/config.properties
To produce messages to a topic, Describe
and Write
permissions are required on the topic.
If the topic hasn’t been created yet, and topic auto-creation is enabled, the permissions to create a topic are required.
bin/kafka-console-producer.sh --topic my-topic \
--broker-list my-cluster-kafka-bootstrap:9092 --producer.config=/tmp/config.properties
To consume messages from a topic, Describe
and Read
permissions are required on the topic.
Consuming from the topic normally relies on storing the consumer offsets in a consumer group, which requires additional Describe
and Read
permissions on the consumer group.
Two resources
are needed for matching. For example:
Topic:my-topic
Group:my-group-*
bin/kafka-console-consumer.sh --topic my-topic --group my-group-1 --from-beginning \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --consumer.config /tmp/config.properties
As well as the permissions for producing to a topic, an additional IdempotentWrite
permission is required on the
Cluster
resource.
Two resources
are needed for matching. For example:
Topic:my-topic
Cluster:kafka-cluster
bin/kafka-console-producer.sh --topic my-topic \
--broker-list my-cluster-kafka-bootstrap:9092 --producer.config=/tmp/config.properties --producer-property enable.idempotence=true --request-required-acks -1
When listing consumer groups, only the groups on which the user has the Describe
permissions are returned.
Alternatively, if the user has the Describe
permission on the Cluster:kafka-cluster
, all the consumer groups are returned.
bin/kafka-consumer-groups.sh --list \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config=/tmp/config.properties
To display a consumer group’s details, the Describe
permission is required on the group and the topics associated with the group.
bin/kafka-consumer-groups.sh --describe --group my-group-1 \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config=/tmp/config.properties
To change a topic’s configuration, the Describe
and Alter
permissions are required on the topic.
bin/kafka-topics.sh --alter --topic my-topic --partitions 2 \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config=/tmp/config.properties
In order to use kafka-configs.sh
to get a broker’s configuration, the DescribeConfigs
permission is required on the
Cluster:kafka-cluster
.
bin/kafka-configs.sh --entity-type brokers --entity-name 0 --describe --all \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config=/tmp/config.properties
To change a Kafka broker’s configuration, DescribeConfigs
and AlterConfigs
permissions are required on Cluster:kafka-cluster
.
bin/kafka-configs --entity-type brokers --entity-name 0 --alter --add-config log.cleaner.threads=2 \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config=/tmp/config.properties
To delete a topic, the Describe
and Delete
permissions are required on the topic.
bin/kafka-topics.sh --delete --topic my-topic \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config=/tmp/config.properties
To run leader selection for topic partitions, the Alter
permission is required on the Cluster:kafka-cluster
.
bin/kafka-leader-election.sh --topic my-topic --partition 0 --election-type PREFERRED /
--bootstrap-server my-cluster-kafka-bootstrap:9092 --admin.config /tmp/config.properties
To generate a partition reassignment file, Describe
permissions are required on the topics involved.
bin/kafka-reassign-partitions.sh --topics-to-move-json-file /tmp/topics-to-move.json --broker-list "0,1" --generate \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config /tmp/config.properties > /tmp/partition-reassignment.json
To execute the partition reassignment, Describe
and Alter
permissions are required on Cluster:kafka-cluster
. Also,
Describe
permissions are required on the topics involved.
bin/kafka-reassign-partitions.sh --reassignment-json-file /tmp/partition-reassignment.json --execute \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config /tmp/config.properties
To verify partition reassignment, Describe
, and AlterConfigs
permissions are required on Cluster:kafka-cluster
, and on each
of the topics involved.
bin/kafka-reassign-partitions.sh --reassignment-json-file /tmp/partition-reassignment.json --verify \
--bootstrap-server my-cluster-kafka-bootstrap:9092 --command-config /tmp/config.properties
4.5.4. Trying Keycloak Authorization Services
This example explains how to use Keycloak Authorization Services with keycloak
authorization.
Use Keycloak Authorization Services to enforce access restrictions on Kafka clients.
Keycloak Authorization Services use authorization scopes, policies and permissions to define and apply access control to resources.
Keycloak Authorization Services REST endpoints provide a list of granted permissions on resources for authenticated users. The list of grants (permissions) is fetched from the Keycloak server as the first action after an authenticated session is established by the Kafka client. The list is refreshed in the background so that changes to the grants are detected. Grants are cached and enforced locally on the Kafka broker for each user session to provide fast authorization decisions.
Strimzi provides example configuration files. These include the following example files for setting up Keycloak:
kafka-ephemeral-oauth-single-keycloak-authz.yaml
-
An example
Kafka
custom resource configured for OAuth 2.0 token-based authorization using Keycloak. You can use the custom resource to deploy a Kafka cluster that useskeycloak
authorization and token-basedoauth
authentication. kafka-authz-realm.json
-
An example Keycloak realm configured with sample groups, users, roles and clients. You can import the realm into a Keycloak instance to set up fine-grained permissions to access Kafka.
If you want to try the example with Keycloak, use these files to perform the tasks outlined in this section in the order shown.
When you configure token-based oauth
authentication, you specify a jwksEndpointUri
as the URI for local JWT validation.
When you configure keycloak
authorization, you specify a tokenEndpointUri
as the URI of the Keycloak token endpoint.
The hostname for both URIs must be the same.
In Keycloak, confidential clients with service accounts enabled can authenticate to the server in their own name using a client ID and a secret.
This is convenient for microservices that typically act in their own name, and not as agents of a particular user (like a web site).
Service accounts can have roles assigned like regular users.
They cannot, however, have groups assigned.
As a consequence, if you want to target permissions to microservices using service accounts, you cannot use group policies, and should instead use role policies.
Conversely, if you want to limit certain permissions only to regular user accounts where authentication with a username and password is required, you can achieve that as a side effect of using the group policies rather than the role policies.
This is what is used in this example for permissions that start with ClusterManager
.
Performing cluster management is usually done interactively using CLI tools.
It makes sense to require the user to log in before using the resulting access token to authenticate to the Kafka broker.
In this case, the access token represents the specific user, rather than the client application.
Accessing the Keycloak Admin Console
Set up Keycloak, then connect to its Admin Console and add the preconfigured realm.
Use the example kafka-authz-realm.json
file to import the realm.
You can check the authorization rules defined for the realm in the Admin Console.
The rules grant access to the resources on the Kafka cluster configured to use the example Keycloak realm.
-
A running Kubernetes cluster.
-
The Strimzi
examples/security/keycloak-authorization/kafka-authz-realm.json
file that contains the preconfigured realm.
-
Install the Keycloak server using the Keycloak Operator as described in Installing the Keycloak Operator in the Keycloak documentation.
-
Wait until the Keycloak instance is running.
-
Get the external hostname to be able to access the Admin Console.
NS=sso kubectl get ingress keycloak -n $NS
In this example, we assume the Keycloak server is running in the
sso
namespace. -
Get the password for the
admin
user.kubectl get -n $NS pod keycloak-0 -o yaml | less
The password is stored as a secret, so get the configuration YAML file for the Keycloak instance to identify the name of the secret (
secretKeyRef.name
). -
Use the name of the secret to obtain the clear text password.
SECRET_NAME=credential-keycloak kubectl get -n $NS secret $SECRET_NAME -o yaml | grep PASSWORD | awk '{print $2}' | base64 -D
In this example, we assume the name of the secret is
credential-keycloak
. -
Log in to the Admin Console with the username
admin
and the password you obtained.Use
https://HOSTNAME
to access the Kubernetes ingress.You can now upload the example realm to Keycloak using the Admin Console.
-
Click Add Realm to import the example realm.
-
Add the
examples/security/keycloak-authorization/kafka-authz-realm.json
file, and then click Create.You now have
kafka-authz
as your current realm in the Admin Console.The default view displays the Master realm.
-
In the Keycloak Admin Console, go to Clients > kafka > Authorization > Settings and check that Decision Strategy is set to Affirmative.
An affirmative policy means that at least one policy must be satisfied for a client to access the Kafka cluster.
-
In the Keycloak Admin Console, go to Groups, Users, Roles and Clients to view the realm configuration.
- Groups
-
Groups
are used to create user groups and set user permissions. Groups are sets of users with a name assigned. They are used to compartmentalize users into geographical, organizational or departmental units. Groups can be linked to an LDAP identity provider. You can make a user a member of a group through a custom LDAP server admin user interface, for example, to grant permissions on Kafka resources. - Users
-
Users
are used to create users. For this example,alice
andbob
are defined.alice
is a member of theClusterManager
group andbob
is a member ofClusterManager-my-cluster
group. Users can be stored in an LDAP identity provider. - Roles
-
Roles
mark users or clients as having certain permissions. Roles are a concept analogous to groups. They are usually used to tag users with organizational roles and have the requisite permissions. Roles cannot be stored in an LDAP identity provider. If LDAP is a requirement, you can use groups instead, and add Keycloak roles to the groups so that when users are assigned a group they also get a corresponding role. - Clients
-
Clients
can have specific configurations. For this example,kafka
,kafka-cli
,team-a-client
, andteam-b-client
clients are configured.-
The
kafka
client is used by Kafka brokers to perform the necessary OAuth 2.0 communication for access token validation. This client also contains the authorization services resource definitions, policies, and authorization scopes used to perform authorization on the Kafka brokers. The authorization configuration is defined in thekafka
client from the Authorization tab, which becomes visible when Authorization Enabled is switched on from the Settings tab. -
The
kafka-cli
client is a public client that is used by the Kafka command line tools when authenticating with username and password to obtain an access token or a refresh token. -
The
team-a-client
andteam-b-client
clients are confidential clients representing services with partial access to certain Kafka topics.
-
-
In the Keycloak Admin Console, go to Authorization > Permissions to see the granted permissions that use the resources and policies defined for the realm.
For example, the
kafka
client has the following permissions:Dev Team A can write to topics that start with x_ on any cluster Dev Team B can read from topics that start with x_ on any cluster Dev Team B can update consumer group offsets that start with x_ on any cluster ClusterManager of my-cluster Group has full access to cluster config on my-cluster ClusterManager of my-cluster Group has full access to consumer groups on my-cluster ClusterManager of my-cluster Group has full access to topics on my-cluster
- Dev Team A
-
The Dev Team A realm role can write to topics that start with
x_
on any cluster. This combines a resource calledTopic:x_*
,Describe
andWrite
scopes, and theDev Team A
policy. TheDev Team A
policy matches all users that have a realm role calledDev Team A
. - Dev Team B
-
The Dev Team B realm role can read from topics that start with
x_
on any cluster. This combinesTopic:x_*
,Group:x_*
resources,Describe
andRead
scopes, and theDev Team B
policy. TheDev Team B
policy matches all users that have a realm role calledDev Team B
. Matching users and clients have the ability to read from topics, and update the consumed offsets for topics and consumer groups that have names starting withx_
.
Deploying a Kafka cluster with Keycloak authorization
Deploy a Kafka cluster configured to connect to the Keycloak server.
Use the example kafka-ephemeral-oauth-single-keycloak-authz.yaml
file to deploy the Kafka cluster as a Kafka
custom resource.
The example deploys a single-node Kafka cluster with keycloak
authorization and oauth
authentication.
-
The Keycloak authorization server is deployed to your Kubernetes cluster and loaded with the example realm.
-
The Cluster Operator is deployed to your Kubernetes cluster.
-
The Strimzi
examples/security/keycloak-authorization/kafka-ephemeral-oauth-single-keycloak-authz.yaml
custom resource.
-
Use the hostname of the Keycloak instance you deployed to prepare a truststore certificate for Kafka brokers to communicate with the Keycloak server.
SSO_HOST=SSO-HOSTNAME SSO_HOST_PORT=$SSO_HOST:443 STOREPASS=storepass echo "Q" | openssl s_client -showcerts -connect $SSO_HOST_PORT 2>/dev/null | awk ' /BEGIN CERTIFICATE/,/END CERTIFICATE/ { print $0 } ' > /tmp/sso.crt
The certificate is required as Kubernetes ingress is used to make a secure (HTTPS) connection.
-
Deploy the certificate to Kubernetes as a secret.
kubectl create secret generic oauth-server-cert --from-file=/tmp/sso.crt -n $NS
-
Set the hostname as an environment variable
SSO_HOST=SSO-HOSTNAME
-
Create and deploy the example Kafka cluster.
cat examples/security/keycloak-authorization/kafka-ephemeral-oauth-single-keycloak-authz.yaml | sed -E 's#\${SSO_HOST}'"#$SSO_HOST#" | kubectl create -n $NS -f -
Preparing TLS connectivity for a CLI Kafka client session
Create a new pod for an interactive CLI session. Set up a truststore with a Keycloak certificate for TLS connectivity. The truststore is to connect to Keycloak and the Kafka broker.
-
The Keycloak authorization server is deployed to your Kubernetes cluster and loaded with the example realm.
In the Keycloak Admin Console, check the roles assigned to the clients are displayed in Clients > Service Account Roles.
-
The Kafka cluster configured to connect with Keycloak is deployed to your Kubernetes cluster.
-
Run a new interactive pod container using the Strimzi Kafka image to connect to a running Kafka broker.
NS=sso kubectl run -ti --restart=Never --image=quay.io/strimzi/kafka:0.27.0-kafka-3.0.0 kafka-cli -n $NS -- /bin/sh
NoteIf kubectl
times out waiting on the image download, subsequent attempts may result in an AlreadyExists error. -
Attach to the pod container.
kubectl attach -ti kafka-cli -n $NS
-
Use the hostname of the Keycloak instance to prepare a certificate for client connection using TLS.
SSO_HOST=SSO-HOSTNAME SSO_HOST_PORT=$SSO_HOST:443 STOREPASS=storepass echo "Q" | openssl s_client -showcerts -connect $SSO_HOST_PORT 2>/dev/null | awk ' /BEGIN CERTIFICATE/,/END CERTIFICATE/ { print $0 } ' > /tmp/sso.crt
-
Create a truststore for TLS connection to the Kafka brokers.
keytool -keystore /tmp/truststore.p12 -storetype pkcs12 -alias sso -storepass $STOREPASS -import -file /tmp/sso.crt -noprompt
-
Use the Kafka bootstrap address as the hostname of the Kafka broker and the
tls
listener port (9093) to prepare a certificate for the Kafka broker.KAFKA_HOST_PORT=my-cluster-kafka-bootstrap:9093 STOREPASS=storepass echo "Q" | openssl s_client -showcerts -connect $KAFKA_HOST_PORT 2>/dev/null | awk ' /BEGIN CERTIFICATE/,/END CERTIFICATE/ { print $0 } ' > /tmp/my-cluster-kafka.crt
-
Add the certificate for the Kafka broker to the truststore.
keytool -keystore /tmp/truststore.p12 -storetype pkcs12 -alias my-cluster-kafka -storepass $STOREPASS -import -file /tmp/my-cluster-kafka.crt -noprompt
Keep the session open to check authorized access.
Checking authorized access to Kafka using a CLI Kafka client session
Check the authorization rules applied through the Keycloak realm using an interactive CLI session. Apply the checks using Kafka’s example producer and consumer clients to create topics with user and service accounts that have different levels of access.
Use the team-a-client
and team-b-client
clients to check the authorization rules.
Use the alice
admin user to perform additional administrative tasks on Kafka.
The Strimzi Kafka image used in this example contains Kafka producer and consumer binaries.
-
ZooKeeper and Kafka are running in the Kubernetes cluster to be able to send and receive messages.
-
The interactive CLI Kafka client session is started.
-
Prepare a Kafka configuration file with authentication properties for the
team-a-client
client.SSO_HOST=SSO-HOSTNAME cat > /tmp/team-a-client.properties << EOF security.protocol=SASL_SSL ssl.truststore.location=/tmp/truststore.p12 ssl.truststore.password=$STOREPASS ssl.truststore.type=PKCS12 sasl.mechanism=OAUTHBEARER sasl.jaas.config=org.apache.kafka.common.security.oauthbearer.OAuthBearerLoginModule required \ oauth.client.id="team-a-client" \ oauth.client.secret="team-a-client-secret" \ oauth.ssl.truststore.location="/tmp/truststore.p12" \ oauth.ssl.truststore.password="$STOREPASS" \ oauth.ssl.truststore.type="PKCS12" \ oauth.token.endpoint.uri="https://$SSO_HOST/auth/realms/kafka-authz/protocol/openid-connect/token" ; sasl.login.callback.handler.class=io.strimzi.kafka.oauth.client.JaasClientOauthLoginCallbackHandler EOF
The SASL OAUTHBEARER mechanism is used. This mechanism requires a client ID and client secret, which means the client first connects to the Keycloak server to obtain an access token. The client then connects to the Kafka broker and uses the access token to authenticate.
-
Prepare a Kafka configuration file with authentication properties for the
team-b-client
client.cat > /tmp/team-b-client.properties << EOF security.protocol=SASL_SSL ssl.truststore.location=/tmp/truststore.p12 ssl.truststore.password=$STOREPASS ssl.truststore.type=PKCS12 sasl.mechanism=OAUTHBEARER sasl.jaas.config=org.apache.kafka.common.security.oauthbearer.OAuthBearerLoginModule required \ oauth.client.id="team-b-client" \ oauth.client.secret="team-b-client-secret" \ oauth.ssl.truststore.location="/tmp/truststore.p12" \ oauth.ssl.truststore.password="$STOREPASS" \ oauth.ssl.truststore.type="PKCS12" \ oauth.token.endpoint.uri="https://$SSO_HOST/auth/realms/kafka-authz/protocol/openid-connect/token" ; sasl.login.callback.handler.class=io.strimzi.kafka.oauth.client.JaasClientOauthLoginCallbackHandler EOF
-
Authenticate admin user
alice
by usingcurl
and performing a password grant authentication to obtain a refresh token.USERNAME=alice PASSWORD=alice-password GRANT_RESPONSE=$(curl -X POST "https://$SSO_HOST/auth/realms/kafka-authz/protocol/openid-connect/token" -H 'Content-Type: application/x-www-form-urlencoded' -d "grant_type=password&username=$USERNAME&password=$PASSWORD&client_id=kafka-cli&scope=offline_access" -s -k) REFRESH_TOKEN=$(echo $GRANT_RESPONSE | awk -F "refresh_token\":\"" '{printf $2}' | awk -F "\"" '{printf $1}')
The refresh token is an offline token that is long-lived and does not expire.
-
Prepare a Kafka configuration file with authentication properties for the admin user
alice
.cat > /tmp/alice.properties << EOF security.protocol=SASL_SSL ssl.truststore.location=/tmp/truststore.p12 ssl.truststore.password=$STOREPASS ssl.truststore.type=PKCS12 sasl.mechanism=OAUTHBEARER sasl.jaas.config=org.apache.kafka.common.security.oauthbearer.OAuthBearerLoginModule required \ oauth.refresh.token="$REFRESH_TOKEN" \ oauth.client.id="kafka-cli" \ oauth.ssl.truststore.location="/tmp/truststore.p12" \ oauth.ssl.truststore.password="$STOREPASS" \ oauth.ssl.truststore.type="PKCS12" \ oauth.token.endpoint.uri="https://$SSO_HOST/auth/realms/kafka-authz/protocol/openid-connect/token" ; sasl.login.callback.handler.class=io.strimzi.kafka.oauth.client.JaasClientOauthLoginCallbackHandler EOF
The
kafka-cli
public client is used for theoauth.client.id
in thesasl.jaas.config
. Since it’s a public client it does not require a secret. The client authenticates with the refresh token that was authenticated in the previous step. The refresh token requests an access token behind the scenes, which is then sent to the Kafka broker for authentication.
Use the team-a-client
configuration to check that you can produce messages to topics that start with a_
or x_
.
-
Write to topic
my-topic
.bin/kafka-console-producer.sh --broker-list my-cluster-kafka-bootstrap:9093 --topic my-topic \ --producer.config=/tmp/team-a-client.properties First message
This request returns a
Not authorized to access topics: [my-topic]
error.team-a-client
has aDev Team A
role that gives it permission to perform any supported actions on topics that start witha_
, but can only write to topics that start withx_
. The topic namedmy-topic
matches neither of those rules. -
Write to topic
a_messages
.bin/kafka-console-producer.sh --broker-list my-cluster-kafka-bootstrap:9093 --topic a_messages \ --producer.config /tmp/team-a-client.properties First message Second message
Messages are produced to Kafka successfully.
-
Press CTRL+C to exit the CLI application.
-
Check the Kafka container log for a debug log of
Authorization GRANTED
for the request.kubectl logs my-cluster-kafka-0 -f -n $NS
Use the team-a-client
configuration to consume messages from topic a_messages
.
-
Fetch messages from topic
a_messages
.bin/kafka-console-consumer.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --topic a_messages \ --from-beginning --consumer.config /tmp/team-a-client.properties
The request returns an error because the
Dev Team A
role forteam-a-client
only has access to consumer groups that have names starting witha_
. -
Update the
team-a-client
properties to specify the custom consumer group it is permitted to use.bin/kafka-console-consumer.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --topic a_messages \ --from-beginning --consumer.config /tmp/team-a-client.properties --group a_consumer_group_1
The consumer receives all the messages from the
a_messages
topic.
The team-a-client
is an account without any cluster-level access, but it can be used with some administrative operations.
-
List topics.
bin/kafka-topics.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --command-config /tmp/team-a-client.properties --list
The
a_messages
topic is returned. -
List consumer groups.
bin/kafka-consumer-groups.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --command-config /tmp/team-a-client.properties --list
The
a_consumer_group_1
consumer group is returned.Fetch details on the cluster configuration.
bin/kafka-configs.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --command-config /tmp/team-a-client.properties \ --entity-type brokers --describe --entity-default
The request returns an error because the operation requires cluster level permissions that
team-a-client
does not have.
Use the team-b-client
configuration to produce messages to topics that start with b_
.
-
Write to topic
a_messages
.bin/kafka-console-producer.sh --broker-list my-cluster-kafka-bootstrap:9093 --topic a_messages \ --producer.config /tmp/team-b-client.properties Message 1
This request returns a
Not authorized to access topics: [a_messages]
error. -
Write to topic
b_messages
.bin/kafka-console-producer.sh --broker-list my-cluster-kafka-bootstrap:9093 --topic b_messages \ --producer.config /tmp/team-b-client.properties Message 1 Message 2 Message 3
Messages are produced to Kafka successfully.
-
Write to topic
x_messages
.bin/kafka-console-producer.sh --broker-list my-cluster-kafka-bootstrap:9093 --topic x_messages \ --producer.config /tmp/team-b-client.properties Message 1
A
Not authorized to access topics: [x_messages]
error is returned, Theteam-b-client
can only read from topicx_messages
. -
Write to topic
x_messages
usingteam-a-client
.bin/kafka-console-producer.sh --broker-list my-cluster-kafka-bootstrap:9093 --topic x_messages \ --producer.config /tmp/team-a-client.properties Message 1
This request returns a
Not authorized to access topics: [x_messages]
error. Theteam-a-client
can write to thex_messages
topic, but it does not have a permission to create a topic if it does not yet exist. Beforeteam-a-client
can write to thex_messages
topic, an admin power user must create it with the correct configuration, such as the number of partitions and replicas.
Use admin user alice
to manage Kafka.
alice
has full access to manage everything on any Kafka cluster.
-
Create the
x_messages
topic asalice
.bin/kafka-topics.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --command-config /tmp/alice.properties \ --topic x_messages --create --replication-factor 1 --partitions 1
The topic is created successfully.
-
List all topics as
alice
.bin/kafka-topics.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --command-config /tmp/alice.properties --list bin/kafka-topics.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --command-config /tmp/team-a-client.properties --list bin/kafka-topics.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --command-config /tmp/team-b-client.properties --list
Admin user
alice
can list all the topics, whereasteam-a-client
andteam-b-client
can only list the topics they have access to.The
Dev Team A
andDev Team B
roles both haveDescribe
permission on topics that start withx_
, but they cannot see the other team’s topics because they do not haveDescribe
permissions on them. -
Use the
team-a-client
to produce messages to thex_messages
topic:bin/kafka-console-producer.sh --broker-list my-cluster-kafka-bootstrap:9093 --topic x_messages \ --producer.config /tmp/team-a-client.properties Message 1 Message 2 Message 3
As
alice
created thex_messages
topic, messages are produced to Kafka successfully. -
Use the
team-b-client
to produce messages to thex_messages
topic.bin/kafka-console-producer.sh --broker-list my-cluster-kafka-bootstrap:9093 --topic x_messages \ --producer.config /tmp/team-b-client.properties Message 4 Message 5
This request returns a
Not authorized to access topics: [x_messages]
error. -
Use the
team-b-client
to consume messages from thex_messages
topic:bin/kafka-console-consumer.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --topic x_messages \ --from-beginning --consumer.config /tmp/team-b-client.properties --group x_consumer_group_b
The consumer receives all the messages from the
x_messages
topic. -
Use the
team-a-client
to consume messages from thex_messages
topic.bin/kafka-console-consumer.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --topic x_messages \ --from-beginning --consumer.config /tmp/team-a-client.properties --group x_consumer_group_a
This request returns a
Not authorized to access topics: [x_messages]
error. -
Use the
team-a-client
to consume messages from a consumer group that begins witha_
.bin/kafka-console-consumer.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --topic x_messages \ --from-beginning --consumer.config /tmp/team-a-client.properties --group a_consumer_group_a
This request returns a
Not authorized to access topics: [x_messages]
error.Dev Team A
has noRead
access on topics that start with ax_
. -
Use
alice
to produce messages to thex_messages
topic.bin/kafka-console-consumer.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --topic x_messages \ --from-beginning --consumer.config /tmp/alice.properties
Messages are produced to Kafka successfully.
alice
can read from or write to any topic. -
Use
alice
to read the cluster configuration.bin/kafka-configs.sh --bootstrap-server my-cluster-kafka-bootstrap:9093 --command-config /tmp/alice.properties \ --entity-type brokers --describe --entity-default
The cluster configuration for this example is empty.
5. Using Strimzi Operators
Use the Strimzi operators to manage your Kafka cluster, and Kafka topics and users.
5.1. Using the Cluster Operator
The Cluster Operator is used to deploy a Kafka cluster and other Kafka components.
For information on deploying the Cluster Operator, see Deploying the Cluster Operator.
5.1.1. Cluster Operator configuration
You can configure the Cluster Operator using supported environment variables, and through its logging configuration.
The environment variables relate to container configuration for the deployment of the Cluster Operator image.
For more information on image
configuration, see, image
.
STRIMZI_NAMESPACE
-
A comma-separated list of namespaces that the operator should operate in. When not set, set to empty string, or set to
*
, the Cluster Operator will operate in all namespaces. The Cluster Operator deployment might use the Kubernetes Downward API to set this automatically to the namespace the Cluster Operator is deployed in.Example configuration for Cluster Operator namespacesenv: - name: STRIMZI_NAMESPACE valueFrom: fieldRef: fieldPath: metadata.namespace
-
STRIMZI_FULL_RECONCILIATION_INTERVAL_MS
-
Optional, default is 120000 ms. The interval between periodic reconciliations, in milliseconds.
STRIMZI_OPERATION_TIMEOUT_MS
-
Optional, default 300000 ms. The timeout for internal operations, in milliseconds. This value should be increased when using Strimzi on clusters where regular Kubernetes operations take longer than usual (because of slow downloading of Docker images, for example).
STRIMZI_ZOOKEEPER_ADMIN_SESSION_TIMEOUT_MS
-
Optional, default 10000 ms.
The session timeout (in milliseconds) for the Cluster Operator’s ZooKeeper admin client.
This value should be increased if ZooKeeper requests from the Cluster Operator are regularly failing due to timeout issues.
There is a maximum allowed session time set on the ZooKeeper server side via the maxSessionTimeout
config.
By default this session max value is 20 times the default tickTime
(whose default is 2000) therefore 40000 ms.
If you require a higher timeout, you will need to change the maxSessionTimeout
ZooKeeper server config value.
STRIMZI_OPERATIONS_THREAD_POOL_SIZE
-
Optional, default 10 The worker thread pool size, which is used for various asynchronous and blocking operations that are run by the cluster operator.
STRIMZI_OPERATOR_NAMESPACE
-
The name of the namespace where the Strimzi Cluster Operator is running. Do not configure this variable manually. Use the Kubernetes Downward API.
env: - name: STRIMZI_OPERATOR_NAMESPACE valueFrom: fieldRef: fieldPath: metadata.namespace
STRIMZI_OPERATOR_NAMESPACE_LABELS
-
Optional. The labels of the namespace where the Strimzi Cluster Operator is running. Namespace labels are used to configure the namespace selector in network policies to allow the Strimzi Cluster Operator to only have access to the operands from the namespace with these labels. When not set, the namespace selector in network policies is configured to allow access to the Strimzi Cluster Operator from any namespace in the Kubernetes cluster.
env: - name: STRIMZI_OPERATOR_NAMESPACE_LABELS value: label1=value1,label2=value2
STRIMZI_LABELS_EXCLUSION_PATTERN
-
Optional, default regex pattern is
^app.kubernetes.io/(?!part-of).*
. Specifies the regex exclusion pattern used to filter labels propagation from the main custom resource to its subresources. The labels exclusion filter is not applied to labels in template sections such asspec.kafka.template.pod.metadata.labels
.env: - name: STRIMZI_LABELS_EXCLUSION_PATTERN value: "^key1.*"
STRIMZI_CUSTOM_{COMPONENT_NAME}_LABELS
-
Optional. One or more custom labels to apply to all the pods created by the
{COMPONENT_NAME}
custom resource. The Cluster Operator labels the pods when the custom resource is created or is next reconciled.Environment variables exist for the following components:
-
KAFKA
-
KAFKA_CONNECT
-
KAFKA_CONNECT_BUILD
-
ZOOKEEPER
-
ENTITY_OPERATOR
-
KAFKA_MIRROR_MAKER2
-
KAFKA_MIRROR_MAKER
-
CRUISE_CONTROL
-
KAFKA_BRIDGE
-
KAFKA_EXPORTER
-
JMX_TRANS
-
STRIMZI_CUSTOM_RESOURCE_SELECTOR
-
Optional. Specifies label selector used to filter the custom resources handled by the operator. The operator will operate only on those custom resources which will have the specified labels set. Resources without these labels will not be seen by the operator. The label selector applies to
Kafka
,KafkaConnect
,KafkaBridge
,KafkaMirrorMaker
, andKafkaMirrorMaker2
resources.KafkaRebalance
andKafkaConnector
resources will be operated only when their corresponding Kafka and Kafka Connect clusters have the matching labels.env: - name: STRIMZI_CUSTOM_RESOURCE_SELECTOR value: label1=value1,label2=value2
STRIMZI_KAFKA_IMAGES
-
Required. This provides a mapping from Kafka version to the corresponding Docker image containing a Kafka broker of that version. The required syntax is whitespace or comma separated
<version>=<image>
pairs. For example2.8.0=quay.io/strimzi/kafka:0.27.0-kafka-2.8.0, 3.0.0=quay.io/strimzi/kafka:0.27.0-kafka-3.0.0
. This is used when aKafka.spec.kafka.version
property is specified but not theKafka.spec.kafka.image
in theKafka
resource. STRIMZI_DEFAULT_KAFKA_INIT_IMAGE
-
Optional, default
quay.io/strimzi/operator:0.27.0
. The image name to use as default for the init container started before the broker for initial configuration work (that is, rack support), if no image is specified as thekafka-init-image
in theKafka
resource. STRIMZI_KAFKA_CONNECT_IMAGES
-
Required. This provides a mapping from the Kafka version to the corresponding Docker image containing a Kafka connect of that version. The required syntax is whitespace or comma separated
<version>=<image>
pairs. For example2.8.0=quay.io/strimzi/kafka:0.27.0-kafka-2.8.0, 3.0.0=quay.io/strimzi/kafka:0.27.0-kafka-3.0.0
. This is used when aKafkaConnect.spec.version
property is specified but not theKafkaConnect.spec.image
. STRIMZI_KAFKA_MIRROR_MAKER_IMAGES
-
Required. This provides a mapping from the Kafka version to the corresponding Docker image containing a Kafka mirror maker of that version. The required syntax is whitespace or comma separated
<version>=<image>
pairs. For example2.8.0=quay.io/strimzi/kafka:0.27.0-kafka-2.8.0, 3.0.0=quay.io/strimzi/kafka:0.27.0-kafka-3.0.0
. This is used when aKafkaMirrorMaker.spec.version
property is specified but not theKafkaMirrorMaker.spec.image
. STRIMZI_DEFAULT_TOPIC_OPERATOR_IMAGE
-
Optional, default
quay.io/strimzi/operator:0.27.0
. The image name to use as the default when deploying the topic operator, if no image is specified as theKafka.spec.entityOperator.topicOperator.image
inKafka
resource. STRIMZI_DEFAULT_USER_OPERATOR_IMAGE
-
Optional, default
quay.io/strimzi/operator:0.27.0
. The image name to use as the default when deploying the user operator, if no image is specified as theKafka.spec.entityOperator.userOperator.image
in theKafka
resource. STRIMZI_DEFAULT_TLS_SIDECAR_ENTITY_OPERATOR_IMAGE
-
Optional, default
quay.io/strimzi/kafka:0.27.0-kafka-3.0.0
. The image name to use as the default when deploying the sidecar container which provides TLS support for the Entity Operator, if no image is specified as theKafka.spec.entityOperator.tlsSidecar.image
in theKafka
resource. STRIMZI_IMAGE_PULL_POLICY
-
Optional. The
ImagePullPolicy
which will be applied to containers in all pods managed by Strimzi Cluster Operator. The valid values areAlways
,IfNotPresent
, andNever
. If not specified, the Kubernetes defaults will be used. Changing the policy will result in a rolling update of all your Kafka, Kafka Connect, and Kafka MirrorMaker clusters. STRIMZI_IMAGE_PULL_SECRETS
-
Optional. A comma-separated list of
Secret
names. The secrets referenced here contain the credentials to the container registries where the container images are pulled from. The secrets are used in theimagePullSecrets
field for allPods
created by the Cluster Operator. Changing this list results in a rolling update of all your Kafka, Kafka Connect, and Kafka MirrorMaker clusters. STRIMZI_KUBERNETES_VERSION
-
Optional. Overrides the Kubernetes version information detected from the API server.
Example configuration for Kubernetes version overrideenv: - name: STRIMZI_KUBERNETES_VERSION value: | major=1 minor=16 gitVersion=v1.16.2 gitCommit=c97fe5036ef3df2967d086711e6c0c405941e14b gitTreeState=clean buildDate=2019-10-15T19:09:08Z goVersion=go1.12.10 compiler=gc platform=linux/amd64
KUBERNETES_SERVICE_DNS_DOMAIN
-
Optional. Overrides the default Kubernetes DNS domain name suffix.
By default, services assigned in the Kubernetes cluster have a DNS domain name that uses the default suffix
cluster.local
.For example, for broker kafka-0:
<cluster-name>-kafka-0.<cluster-name>-kafka-brokers.<namespace>.svc.cluster.local
The DNS domain name is added to the Kafka broker certificates used for hostname verification.
If you are using a different DNS domain name suffix in your cluster, change the
KUBERNETES_SERVICE_DNS_DOMAIN
environment variable from the default to the one you are using in order to establish a connection with the Kafka brokers. STRIMZI_CONNECT_BUILD_TIMEOUT_MS
-
Optional, default 300000 ms. The timeout for building new Kafka Connect images with additional connectots, in milliseconds. This value should be increased when using Strimzi to build container images containing many connectors or using a slow container registry.
STRIMZI_NETWORK_POLICY_GENERATION
-
Optional, default
true
. Controls whether Strimzi generates network policy resources. Network policies allow connections between Kafka components.
Set this environment variable to false
to disable network policy generation. You might do this, for example, if you want to use custom network policies. Custom network policies allow more control over maintaining the connections between components.
STRIMZI_DNS_CACHE_TTL
-
Optional, default
30
. Number of seconds to cache successful name lookups in local DNS resolver. Any negative value means cache forever. Zero means do not cache. This can be useful to avoid connection errors due to long caching policies being applied. STRIMZI_FEATURE_GATES
-
Optional. Enables or disables features and functionality controlled by feature gates. For more information about each feature gate, see Feature gates.
Feature gates
Strimzi operators support feature gates to enable or disable certain features and functionality. Enabling a feature gate changes the behavior of the relevant operator and introduces the feature to your Strimzi deployment.
Feature gates have a default state of either enabled or disabled.
To modify a feature gate’s default state, use the STRIMZI_FEATURE_GATES
environment variable in the operator’s configuration.
You can modify multiple feature gates using this single environment variable.
Feature gates have three stages of maturity:
-
Alpha — typically disabled by default
-
Beta — typically enabled by default
-
General Availability (GA) — typically always enabled
Alpha stage features might be experimental or unstable, subject to change, or not sufficiently tested for production use. Beta stage features are well tested and their functionality is not likely to change. GA stage features are stable and should not change in the future. Alpha and beta stage features are removed if they do not prove to be useful.
Note
|
Feature gates might be removed when they reach GA. This means that the feature was incorporated into the Strimzi core features and can no longer be disabled. |
Feature gate | Alpha | Beta | GA |
---|---|---|---|
|
0.23.0 |
0.27.0 |
- |
|
0.24.0 |
0.27.0 |
- |
Configuring feature gates
You configure feature gates using the STRIMZI_FEATURE_GATES
environment variable in the operator’s configuration.
Specify a comma-separated list of feature gate names and prefixes.
A +
prefix enables the feature gate and a -
prefix disables it.
FeatureGate1
and disables FeatureGate2
env:
- name: STRIMZI_FEATURE_GATES
value: +FeatureGate1,-FeatureGate2
Control plane listener feature gate
Use the ControlPlaneListener
feature gate to change the communication paths used for inter-broker communications within your Kafka cluster.
In Strimzi, control plane traffic consists of controller connections that maintain the desired state of the Kafka cluster.
Data plane traffic mainly consists of data replication between the leader broker and the follower brokers.
When the ControlPlaneListener
feature gate is disabled, control plane and data plane traffic go through the same internal listener on port 9091.
This was the default behavior before the feature gate was introduced.
When ControlPlaneListener
is enabled, control plane traffic goes through a dedicated control plane listener on port 9090.
Data plane traffic continues to use the internal listener on port 9091.
Using control plane listeners might improve performance because important controller connections, such as partition leadership changes, are not delayed by data replication across brokers.
The ControlPlaneListener
feature gate is in the beta stage and has a default state of enabled.
To disable it, specify -ControlPlaneListener
in the STRIMZI_FEATURE_GATES
environment variable in the Cluster Operator configuration.
This feature gate must be disabled when:
-
Upgrading from Strimzi 0.22 and earlier
-
Downgrading to Strimzi 0.22 and earlier
Note
|
The ControlPlaneListener feature gate moved to beta stage in Strimzi 0.27.0 and is expected to remain in the beta stage until Strimzi 0.31.
|
Service Account patching feature gate
The ServiceAccountPatching
feature gate is currently in the beta phase and enabled by default.
By default, the Cluster Operator reconciles service accounts and updates them when needed.
For example, you can change service account labels and annotations after the operands are already created.
To disable service account patching, disable the ServiceAccountPatching
feature gate.
Add -ServiceAccountPatching
to the STRIMZI_FEATURE_GATES
environment variable in the Cluster Operator configuration.
Note
|
The ServiceAccountPatching feature gate moved to beta stage in Strimzi 0.27.0 and is expected to remain in the beta stage until Strimzi 0.30.
|
Logging configuration by ConfigMap
The Cluster Operator’s logging is configured by the strimzi-cluster-operator
ConfigMap
.
A ConfigMap
containing logging configuration is created when installing the Cluster Operator.
This ConfigMap
is described in the file install/cluster-operator/050-ConfigMap-strimzi-cluster-operator.yaml
.
You configure Cluster Operator logging by changing the data field log4j2.properties
in this ConfigMap
.
To update the logging configuration, you can edit the 050-ConfigMap-strimzi-cluster-operator.yaml
file and then run the following command:
kubectl create -f install/cluster-operator/050-ConfigMap-strimzi-cluster-operator.yaml
Alternatively, edit the ConfigMap
directly:
kubectl edit configmap strimzi-cluster-operator
To change the frequency of the reload interval, set a time in seconds in the monitorInterval
option in the created ConfigMap
.
If the ConfigMap
is missing when the Cluster Operator is deployed, the default logging values are used.
If the ConfigMap
is accidentally deleted after the Cluster Operator is deployed, the most recently loaded logging configuration is used.
Create a new ConfigMap
to load a new logging configuration.
Note
|
Do not remove the monitorInterval option from the ConfigMap.
|
Restricting Cluster Operator access with network policy
The Cluster Operator can run in the same namespace as the resources it manages, or in a separate namespace.
By default, the STRIMZI_OPERATOR_NAMESPACE
environment variable is configured to use the Kubernetes Downward API to find which namespace the Cluster Operator is running in.
If the Cluster Operator is running in the same namespace as the resources, only local access is required, and allowed by Strimzi.
If the Cluster Operator is running in a separate namespace to the resources it manages, any namespace in the Kubernetes cluster is allowed access to the Cluster Operator unless network policy is configured.
Use the optional STRIMZI_OPERATOR_NAMESPACE_LABELS
environment variable to establish network policy for the Cluster Operator using namespace labels.
By adding namespace labels, access to the Cluster Operator is restricted to the namespaces specified.
#...
env:
# ...
- name: STRIMZI_OPERATOR_NAMESPACE_LABELS
value: label1=value1,label2=value2
#...
Periodic reconciliation
Although the Cluster Operator reacts to all notifications about the desired cluster resources received from the Kubernetes cluster, if the operator is not running, or if a notification is not received for any reason, the desired resources will get out of sync with the state of the running Kubernetes cluster.
In order to handle failovers properly, a periodic reconciliation process is executed by the Cluster Operator so that it can compare the state of the desired resources with the current cluster deployments in order to have a consistent state across all of them.
You can set the time interval for the periodic reconciliations using the STRIMZI_FULL_RECONCILIATION_INTERVAL_MS
variable.
5.1.2. Provisioning Role-Based Access Control (RBAC)
For the Cluster Operator to function it needs permission within the Kubernetes cluster to interact with resources such as Kafka
, KafkaConnect
, and so on, as well as the managed resources, such as ConfigMaps
, Pods
, Deployments
, StatefulSets
and Services
.
Such permission is described in terms of Kubernetes role-based access control (RBAC) resources:
-
ServiceAccount
, -
Role
andClusterRole
, -
RoleBinding
andClusterRoleBinding
.
In addition to running under its own ServiceAccount
with a ClusterRoleBinding
, the Cluster Operator manages some RBAC resources for the components that need access to Kubernetes resources.
Kubernetes also includes privilege escalation protections that prevent components operating under one ServiceAccount
from granting other ServiceAccounts
privileges that the granting ServiceAccount
does not have.
Because the Cluster Operator must be able to create the ClusterRoleBindings
, and RoleBindings
needed by resources it manages, the Cluster Operator must also have those same privileges.
Delegated privileges
When the Cluster Operator deploys resources for a desired Kafka
resource it also creates ServiceAccounts
, RoleBindings
, and ClusterRoleBindings
, as follows:
-
The Kafka broker pods use a
ServiceAccount
calledcluster-name-kafka
-
When the rack feature is used, the
strimzi-cluster-name-kafka-init
ClusterRoleBinding
is used to grant thisServiceAccount
access to the nodes within the cluster via aClusterRole
calledstrimzi-kafka-broker
-
When the rack feature is not used and the cluster is not exposed via nodeport, no binding is created
-
-
The ZooKeeper pods use a
ServiceAccount
calledcluster-name-zookeeper
-
The Entity Operator pod uses a
ServiceAccount
calledcluster-name-entity-operator
-
The Topic Operator produces Kubernetes events with status information, so the
ServiceAccount
is bound to aClusterRole
calledstrimzi-entity-operator
which grants this access via thestrimzi-entity-operator
RoleBinding
-
-
The pods for
KafkaConnect
resource uses aServiceAccount
calledcluster-name-cluster-connect
-
The pods for
KafkaMirrorMaker
use aServiceAccount
calledcluster-name-mirror-maker
-
The pods for
KafkaMirrorMaker2
use aServiceAccount
calledcluster-name-mirrormaker2
-
The pods for
KafkaBridge
use aServiceAccount
calledcluster-name-bridge
ServiceAccount
The Cluster Operator is best run using a ServiceAccount
:
ServiceAccount
for the Cluster OperatorapiVersion: v1
kind: ServiceAccount
metadata:
name: strimzi-cluster-operator
labels:
app: strimzi
The Deployment
of the operator then needs to specify this in its spec.template.spec.serviceAccountName
:
Deployment
for the Cluster OperatorapiVersion: apps/v1
kind: Deployment
metadata:
name: strimzi-cluster-operator
labels:
app: strimzi
spec:
replicas: 1
selector:
matchLabels:
name: strimzi-cluster-operator
strimzi.io/kind: cluster-operator
template:
# ...
Note line 12, where the strimzi-cluster-operator
ServiceAccount
is specified as the serviceAccountName
.
ClusterRoles
The Cluster Operator needs to operate using ClusterRoles
that gives access to the necessary resources.
Depending on the Kubernetes cluster setup, a cluster administrator might be needed to create the ClusterRoles
.
Note
|
Cluster administrator rights are only needed for the creation of the ClusterRoles .
The Cluster Operator will not run under the cluster admin account.
|
The ClusterRoles
follow the principle of least privilege and contain only those privileges needed by the Cluster Operator to operate Kafka, Kafka Connect, and ZooKeeper clusters. The first set of assigned privileges allow the Cluster Operator to manage Kubernetes resources such as StatefulSets
, Deployments
, Pods
, and ConfigMaps
.
Cluster Operator uses ClusterRoles to grant permission at the namespace-scoped resources level and cluster-scoped resources level:
ClusterRole
with namespaced resources for the Cluster OperatorapiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRole
metadata:
name: strimzi-cluster-operator-namespaced
labels:
app: strimzi
rules:
- apiGroups:
- "rbac.authorization.k8s.io"
resources:
# The cluster operator needs to access and manage rolebindings to grant Strimzi components cluster permissions
- rolebindings
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- "rbac.authorization.k8s.io"
resources:
# The cluster operator needs to access and manage roles to grant the entity operator permissions
- roles
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- ""
resources:
# The cluster operator needs to access and delete pods, this is to allow it to monitor pod health and coordinate rolling updates
- pods
# The cluster operator needs to access and manage service accounts to grant Strimzi components cluster permissions
- serviceaccounts
# The cluster operator needs to access and manage config maps for Strimzi components configuration
- configmaps
# The cluster operator needs to access and manage services and endpoints to expose Strimzi components to network traffic
- services
- endpoints
# The cluster operator needs to access and manage secrets to handle credentials
- secrets
# The cluster operator needs to access and manage persistent volume claims to bind them to Strimzi components for persistent data
- persistentvolumeclaims
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- "kafka.strimzi.io"
resources:
# The cluster operator runs the KafkaAssemblyOperator, which needs to access and manage Kafka resources
- kafkas
- kafkas/status
# The cluster operator runs the KafkaConnectAssemblyOperator, which needs to access and manage KafkaConnect resources
- kafkaconnects
- kafkaconnects/status
# The cluster operator runs the KafkaConnectorAssemblyOperator, which needs to access and manage KafkaConnector resources
- kafkaconnectors
- kafkaconnectors/status
# The cluster operator runs the KafkaMirrorMakerAssemblyOperator, which needs to access and manage KafkaMirrorMaker resources
- kafkamirrormakers
- kafkamirrormakers/status
# The cluster operator runs the KafkaBridgeAssemblyOperator, which needs to access and manage BridgeMaker resources
- kafkabridges
- kafkabridges/status
# The cluster operator runs the KafkaMirrorMaker2AssemblyOperator, which needs to access and manage KafkaMirrorMaker2 resources
- kafkamirrormaker2s
- kafkamirrormaker2s/status
# The cluster operator runs the KafkaRebalanceAssemblyOperator, which needs to access and manage KafkaRebalance resources
- kafkarebalances
- kafkarebalances/status
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- "core.strimzi.io"
resources:
# The cluster operator uses StrimziPodSets to manage the Kafka and ZooKeeper pods
- strimzipodsets
- strimzipodsets/status
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
# The cluster operator needs the extensions api as the operator supports Kubernetes version 1.11+
# apps/v1 was introduced in Kubernetes 1.14
- "extensions"
resources:
# The cluster operator needs to access and manage deployments to run deployment based Strimzi components
- deployments
- deployments/scale
# The cluster operator needs to access replica sets to manage Strimzi components and to determine error states
- replicasets
# The cluster operator needs to access and manage replication controllers to manage replicasets
- replicationcontrollers
# The cluster operator needs to access and manage network policies to lock down communication between Strimzi components
- networkpolicies
# The cluster operator needs to access and manage ingresses which allow external access to the services in a cluster
- ingresses
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- "apps"
resources:
# The cluster operator needs to access and manage deployments to run deployment based Strimzi components
- deployments
- deployments/scale
- deployments/status
# The cluster operator needs to access and manage stateful sets to run stateful sets based Strimzi components
- statefulsets
# The cluster operator needs to access replica-sets to manage Strimzi components and to determine error states
- replicasets
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- ""
resources:
# The cluster operator needs to be able to create events and delegate permissions to do so
- events
verbs:
- create
- apiGroups:
# Kafka Connect Build on OpenShift requirement
- build.openshift.io
resources:
- buildconfigs
- buildconfigs/instantiate
- builds
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- networking.k8s.io
resources:
# The cluster operator needs to access and manage network policies to lock down communication between Strimzi components
- networkpolicies
# The cluster operator needs to access and manage ingresses which allow external access to the services in a cluster
- ingresses
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- route.openshift.io
resources:
# The cluster operator needs to access and manage routes to expose Strimzi components for external access
- routes
- routes/custom-host
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- policy
resources:
# The cluster operator needs to access and manage pod disruption budgets this limits the number of concurrent disruptions
# that a Strimzi component experiences, allowing for higher availability
- poddisruptionbudgets
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
The second includes the permissions needed for cluster-scoped resources.
ClusterRole
with cluster-scoped resources for the Cluster OperatorapiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRole
metadata:
name: strimzi-cluster-operator-global
labels:
app: strimzi
rules:
- apiGroups:
- "rbac.authorization.k8s.io"
resources:
# The cluster operator needs to create and manage cluster role bindings in the case of an install where a user
# has specified they want their cluster role bindings generated
- clusterrolebindings
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
- apiGroups:
- storage.k8s.io
resources:
# The cluster operator requires "get" permissions to view storage class details
# This is because only a persistent volume of a supported storage class type can be resized
- storageclasses
verbs:
- get
- apiGroups:
- ""
resources:
# The cluster operator requires "list" permissions to view all nodes in a cluster
# The listing is used to determine the node addresses when NodePort access is configured
# These addresses are then exposed in the custom resource states
- nodes
verbs:
- list
The strimzi-kafka-broker
ClusterRole
represents the access needed by the init container in Kafka pods that is used for the rack feature. As described in the Delegated privileges section, this role is also needed by the Cluster Operator in order to be able to delegate this access.
ClusterRole
for the Cluster Operator allowing it to delegate access to Kubernetes nodes to the Kafka broker podsapiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRole
metadata:
name: strimzi-kafka-broker
labels:
app: strimzi
rules:
- apiGroups:
- ""
resources:
# The Kafka Brokers require "get" permissions to view the node they are on
# This information is used to generate a Rack ID that is used for High Availability configurations
- nodes
verbs:
- get
The strimzi-topic-operator
ClusterRole
represents the access needed by the Topic Operator. As described in the Delegated privileges section, this role is also needed by the Cluster Operator in order to be able to delegate this access.
ClusterRole
for the Cluster Operator allowing it to delegate access to events to the Topic OperatorapiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRole
metadata:
name: strimzi-entity-operator
labels:
app: strimzi
rules:
- apiGroups:
- "kafka.strimzi.io"
resources:
# The entity operator runs the KafkaTopic assembly operator, which needs to access and manage KafkaTopic resources
- kafkatopics
- kafkatopics/status
# The entity operator runs the KafkaUser assembly operator, which needs to access and manage KafkaUser resources
- kafkausers
- kafkausers/status
verbs:
- get
- list
- watch
- create
- patch
- update
- delete
- apiGroups:
- ""
resources:
- events
verbs:
# The entity operator needs to be able to create events
- create
- apiGroups:
- ""
resources:
# The entity operator user-operator needs to access and manage secrets to store generated credentials
- secrets
verbs:
- get
- list
- watch
- create
- delete
- patch
- update
The strimzi-kafka-client
ClusterRole
represents the access needed by the components based on Kafka clients which use the client rack-awareness.
As described in the Delegated privileges section, this role is also needed by the Cluster Operator in order to be able to delegate this access.
ClusterRole
for the Cluster Operator allowing it to delegate access to Kubernetes nodes to the Kafka client based podsapiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRole
metadata:
name: strimzi-kafka-client
labels:
app: strimzi
rules:
- apiGroups:
- ""
resources:
# The Kafka clients (Connect, Mirror Maker, etc.) require "get" permissions to view the node they are on
# This information is used to generate a Rack ID (client.rack option) that is used for consuming from the closest
# replicas when enabled
- nodes
verbs:
- get
ClusterRoleBindings
The operator needs ClusterRoleBindings
and RoleBindings
which associates its ClusterRole
with its ServiceAccount
:
ClusterRoleBindings
are needed for ClusterRoles
containing cluster-scoped resources.
ClusterRoleBinding
for the Cluster OperatorapiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRoleBinding
metadata:
name: strimzi-cluster-operator
labels:
app: strimzi
subjects:
- kind: ServiceAccount
name: strimzi-cluster-operator
namespace: myproject
roleRef:
kind: ClusterRole
name: strimzi-cluster-operator-global
apiGroup: rbac.authorization.k8s.io
ClusterRoleBindings
are also needed for the ClusterRoles
needed for delegation:
ClusterRoleBinding
for the Cluster Operator for the Kafka broker rack-awarenessapiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRoleBinding
metadata:
name: strimzi-cluster-operator-kafka-broker-delegation
labels:
app: strimzi
# The Kafka broker cluster role must be bound to the cluster operator service account so that it can delegate the cluster role to the Kafka brokers.
# This must be done to avoid escalating privileges which would be blocked by Kubernetes.
subjects:
- kind: ServiceAccount
name: strimzi-cluster-operator
namespace: myproject
roleRef:
kind: ClusterRole
name: strimzi-kafka-broker
apiGroup: rbac.authorization.k8s.io
and
ClusterRoleBinding
for the Cluster Operator for the Kafka client rack-awarenessapiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRoleBinding
metadata:
name: strimzi-cluster-operator-kafka-client-delegation
labels:
app: strimzi
# The Kafka clients cluster role must be bound to the cluster operator service account so that it can delegate the
# cluster role to the Kafka clients using it for consuming from closest replica.
# This must be done to avoid escalating privileges which would be blocked by Kubernetes.
subjects:
- kind: ServiceAccount
name: strimzi-cluster-operator
namespace: myproject
roleRef:
kind: ClusterRole
name: strimzi-kafka-client
apiGroup: rbac.authorization.k8s.io
ClusterRoles
containing only namespaced resources are bound using RoleBindings
only.
apiVersion: rbac.authorization.k8s.io/v1
kind: RoleBinding
metadata:
name: strimzi-cluster-operator
labels:
app: strimzi
subjects:
- kind: ServiceAccount
name: strimzi-cluster-operator
namespace: myproject
roleRef:
kind: ClusterRole
name: strimzi-cluster-operator-namespaced
apiGroup: rbac.authorization.k8s.io
apiVersion: rbac.authorization.k8s.io/v1
kind: RoleBinding
metadata:
name: strimzi-cluster-operator-entity-operator-delegation
labels:
app: strimzi
# The Entity Operator cluster role must be bound to the cluster operator service account so that it can delegate the cluster role to the Entity Operator.
# This must be done to avoid escalating privileges which would be blocked by Kubernetes.
subjects:
- kind: ServiceAccount
name: strimzi-cluster-operator
namespace: myproject
roleRef:
kind: ClusterRole
name: strimzi-entity-operator
apiGroup: rbac.authorization.k8s.io
5.1.3. Configuring the Cluster Operator with default proxy settings
If you are running a Kafka cluster behind a HTTP proxy, you can still pass data in and out of the cluster. For example, you can run Kafka Connect with connectors that push and pull data from outside the proxy. Or you can use a proxy to connect with an authorization server.
Configure the Cluster Operator deployment to specify the proxy environment variables.
The Cluster Operator accepts standard proxy configuration (HTTP_PROXY
, HTTPS_PROXY
and NO_PROXY
) as environment variables.
The proxy settings are applied to all Strimzi containers.
The format for a proxy address is http://IP-ADDRESS:PORT-NUMBER. To set up a proxy with a name and password, the format is http://USERNAME:PASSWORD@IP-ADDRESS:PORT-NUMBER.
This procedure requires use of a Kubernetes user account which is able to create CustomResourceDefinitions
, ClusterRoles
and ClusterRoleBindings
.
Use of Role Base Access Control (RBAC) in the Kubernetes cluster usually means that permission to create, edit,
and delete these resources is limited to Kubernetes cluster administrators, such as system:admin
.
-
To add proxy environment variables to the Cluster Operator, update its
Deployment
configuration (install/cluster-operator/060-Deployment-strimzi-cluster-operator.yaml
).Example proxy configuration for the Cluster OperatorapiVersion: apps/v1 kind: Deployment spec: # ... template: spec: serviceAccountName: strimzi-cluster-operator containers: # ... env: # ... - name: "HTTP_PROXY" value: "http://proxy.com" (1) - name: "HTTPS_PROXY" value: "https://proxy.com" (2) - name: "NO_PROXY" value: "internal.com, other.domain.com" (3) # ...
-
Address of the proxy server.
-
Secure address of the proxy server.
-
Addresses for servers that are accessed directly as exceptions to the proxy server. The URLs are comma-separated.
Alternatively, edit the
Deployment
directly:kubectl edit deployment strimzi-cluster-operator
-
-
If you updated the YAML file instead of editing the
Deployment
directly, apply the changes:kubectl create -f install/cluster-operator/060-Deployment-strimzi-cluster-operator.yaml
5.2. Using the Topic Operator
When you create, modify or delete a topic using the KafkaTopic
resource,
the Topic Operator ensures those changes are reflected in the Kafka cluster.
The Deploying and Upgrading Strimzi guide provides instructions to deploy the Topic Operator:
5.2.1. Kafka topic resource
The KafkaTopic
resource is used to configure topics, including the number of partitions and replicas.
The full schema for KafkaTopic
is described in KafkaTopic
schema reference.
Identifying a Kafka cluster for topic handling
A KafkaTopic
resource includes a label that defines the appropriate name of the Kafka cluster (derived from the name of the Kafka
resource) to which it belongs.
For example:
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaTopic
metadata:
name: topic-name-1
labels:
strimzi.io/cluster: my-cluster
The label is used by the Topic Operator to identify the KafkaTopic
resource and create a new topic, and also in subsequent handling of the topic.
If the label does not match the Kafka cluster, the Topic Operator cannot identify the KafkaTopic
and the topic is not created.
Kafka topic usage recommendations
When working with topics, be consistent.
Always operate on either KafkaTopic
resources or topics directly in Kubernetes.
Avoid routinely switching between both methods for a given topic.
Use topic names that reflect the nature of the topic, and remember that names cannot be changed later.
If creating a topic in Kafka, use a name that is a valid Kubernetes resource name,
otherwise the Topic Operator will need to create the corresponding KafkaTopic
with a name that conforms to the Kubernetes rules.
Note
|
Recommendations for identifiers and names in Kubernetes are outlined in Identifiers and Names in Kubernetes community article. |
Kafka topic naming conventions
Kafka and Kubernetes impose their own validation rules for the naming of topics in Kafka and KafkaTopic.metadata.name
respectively.
There are valid names for each which are invalid in the other.
Using the spec.topicName
property, it is possible to create a valid topic in Kafka with a name that would be invalid for the Kafka topic in Kubernetes.
The spec.topicName
property inherits Kafka naming validation rules:
-
The name must not be longer than 249 characters.
-
Valid characters for Kafka topics are ASCII alphanumerics,
.
,_
, and-
. -
The name cannot be
.
or..
, though.
can be used in a name, such asexampleTopic.
or.exampleTopic
.
spec.topicName
must not be changed.
For example:
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaTopic
metadata:
name: topic-name-1
spec:
topicName: topicName-1 (1)
# ...
-
Upper case is invalid in Kubernetes.
cannot be changed to:
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaTopic
metadata:
name: topic-name-1
spec:
topicName: name-2
# ...
Note
|
Some Kafka client applications, such as Kafka Streams, can create topics in Kafka programmatically.
If those topics have names that are invalid Kubernetes resource names, the Topic Operator gives them a valid
|
5.2.2. Topic Operator topic store
The Topic Operator uses Kafka to store topic metadata describing topic configuration as key-value pairs. The topic store is based on the Kafka Streams key-value mechanism, which uses Kafka topics to persist the state.
Topic metadata is cached in-memory and accessed locally within the Topic Operator.
Updates from operations applied to the local in-memory cache are persisted to a backup topic store on disk.
The topic store is continually synchronized with updates from Kafka topics or Kubernetes KafkaTopic
custom resources.
Operations are handled rapidly with the topic store set up this way,
but should the in-memory cache crash it is automatically repopulated from the persistent storage.
Internal topic store topics
Internal topics support the handling of topic metadata in the topic store.
__strimzi_store_topic
-
Input topic for storing the topic metadata
__strimzi-topic-operator-kstreams-topic-store-changelog
-
Retains a log of compacted topic store values
Warning
|
Do not delete these topics, as they are essential to the running of the Topic Operator. |
Migrating topic metadata from ZooKeeper
In previous releases of Strimzi, topic metadata was stored in ZooKeeper. The new process removes this requirement, bringing the metadata into the Kafka cluster, and under the control of the Topic Operator.
When upgrading to Strimzi 0.27.0, the transition to Topic Operator control of the topic store is seamless. Metadata is found and migrated from ZooKeeper, and the old store is deleted.
Downgrading to a Strimzi version that uses ZooKeeper to store topic metadata
If you are reverting back to a version of Strimzi earlier than 0.22, which uses ZooKeeper for the storage of topic metadata, you still downgrade your Cluster Operator to the previous version, then downgrade Kafka brokers and client applications to the previous Kafka version as standard.
However, you must also delete the topics that were created for the topic store using a kafka-admin
command, specifying the bootstrap address of the Kafka cluster.
For example:
kubectl run kafka-admin -ti --image=quay.io/strimzi/kafka:0.27.0-kafka-3.0.0 --rm=true --restart=Never -- ./bin/kafka-topics.sh --bootstrap-server localhost:9092 --topic __strimzi-topic-operator-kstreams-topic-store-changelog --delete && ./bin/kafka-topics.sh --bootstrap-server localhost:9092 --topic __strimzi_store_topic --delete
The command must correspond to the type of listener and authentication used to access the Kafka cluster.
The Topic Operator will reconstruct the ZooKeeper topic metadata from the state of the topics in Kafka.
Topic Operator topic replication and scaling
The recommended configuration for topics managed by the Topic Operator is a topic replication factor of 3, and a minimum of 2 in-sync replicas.
apiVersion: kafka.strimzi.io/v1beta2
kind: KafkaTopic
metadata:
name: my-topic
labels:
strimzi.io/cluster: my-cluster
spec:
partitions: 10 (1)
replicas: 3 (2)
config:
min.insync.replicas: 2 (3)
#...
-
The number of partitions for the topic.
-
The number of replica topic partitions. Currently, this cannot be changed in the
KafkaTopic
resource, but it can be changed using thekafka-reassign-partitions.sh
tool. -
The minimum number of replica partitions that a message must be successfully written to, or an exception is raised.
Note
|
In-sync replicas are used in conjunction with the acks configuration for producer applications.
The acks configuration determines the number of follower partitions a message must be replicated to before the message is acknowledged as successfully received.
The Topic Operator runs with acks=all , whereby messages must be acknowledged by all in-sync replicas.
|
When scaling Kafka clusters by adding or removing brokers, replication factor configuration is not changed and replicas are not reassigned automatically.
However, you can use the kafka-reassign-partitions.sh
tool to change the replication factor, and manually reassign replicas to brokers.
Alternatively, though the integration of Cruise Control for Strimzi cannot change the replication factor for topics, the optimization proposals it generates for rebalancing Kafka include commands that transfer partition replicas and change partition leadership.
Handling changes to topics
A fundamental problem that the Topic Operator needs to solve is that there is no single source of truth:
both the KafkaTopic
resource and the Kafka topic can be modified independently of the Topic Operator.
Complicating this, the Topic Operator might not always be able to observe changes at each end in real time.
For example, when the Topic Operator is down.
To resolve this, the Topic Operator maintains information about each topic in the topic store. When a change happens in the Kafka cluster or Kubernetes, it looks at both the state of the other system and the topic store in order to determine what needs to change to keep everything in sync. The same thing happens whenever the Topic Operator starts, and periodically while it is running.
For example, suppose the Topic Operator is not running, and a KafkaTopic
called my-topic is created.
When the Topic Operator starts, the topic store does not contain information on my-topic, so it can infer that the KafkaTopic
was created after it was last running.
The Topic Operator creates the topic corresponding to my-topic, and also stores metadata for my-topic in the topic store.
If you update Kafka topic configuration or apply a change through the KafkaTopic
custom resource,
the topic store is updated after the Kafka cluster is reconciled.
The topic store also allows the Topic Operator to manage scenarios where the topic configuration is changed in Kafka topics and updated through Kubernetes KafkaTopic
custom resources,
as long as the changes are not incompatible.
For example, it is possible to make changes to the same topic config key, but to different values.
For incompatible changes, the Kafka configuration takes priority, and the KafkaTopic
is updated accordingly.
Note
|
You can also use the KafkaTopic resource to delete topics using a kubectl delete -f KAFKA-TOPIC-CONFIG-FILE command.
To be able to do this, delete.topic.enable must be set to true (default) in the spec.kafka.config of the Kafka resource.
|
5.2.3. Configuring a Kafka topic
Use the properties of the KafkaTopic
resource to configure a Kafka topic.
You can use kubectl apply
to create or modify topics, and kubectl delete
to delete existing topics.
For example:
-
kubectl apply -f <topic-config-file>
-
kubectl delete KafkaTopic <topic-name>
This procedure shows how to create a topic with 10 partitions and 2 replicas.
It is important that you consider the following before making your changes:
-
Kafka does not support making the following changes through the
KafkaTopic
resource:-
Changing topic names using
spec.topicName
-
Decreasing partition size using
spec.partitions
-
-
You cannot use
spec.replicas
to change the number of replicas that were initially specified. -
Increasing
spec.partitions
for topics with keys will change how records are partitioned, which can be particularly problematic when the topic uses semantic partitioning.
-
A running Kafka cluster configured with a Kafka broker listener using TLS authentication and encryption.
-
A running Topic Operator (typically deployed with the Entity Operator).
-
For deleting a topic,
delete.topic.enable=true
(default) in thespec.kafka.config
of theKafka
resource.
-
Prepare a file containing the
KafkaTopic
to be created.An exampleKafkaTopic
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaTopic metadata: name: orders labels: strimzi.io/cluster: my-cluster spec: partitions: 10 replicas: 2
TipWhen modifying a topic, you can get the current version of the resource using kubectl get kafkatopic orders -o yaml
. -
Create the
KafkaTopic
resource in Kubernetes.kubectl apply -f TOPIC-CONFIG-FILE
5.2.4. Configuring the Topic Operator with resource requests and limits
You can allocate resources, such as CPU and memory, to the Topic Operator and set a limit on the amount of resources it can consume.
-
The Cluster Operator is running.
-
Update the Kafka cluster configuration in an editor, as required:
kubectl edit kafka MY-CLUSTER
-
In the
spec.entityOperator.topicOperator.resources
property in theKafka
resource, set the resource requests and limits for the Topic Operator.apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: # Kafka and ZooKeeper sections... entityOperator: topicOperator: resources: requests: cpu: "1" memory: 500Mi limits: cpu: "1" memory: 500Mi
-
Apply the new configuration to create or update the resource.
kubectl apply -f KAFKA-CONFIG-FILE
5.3. Using the User Operator
When you create, modify or delete a user using the KafkaUser
resource,
the User Operator ensures those changes are reflected in the Kafka cluster.
The Deploying and Upgrading Strimzi guide provides instructions to deploy the User Operator:
For more information about the schema, see KafkaUser
schema reference.
Use KafkaUser
to enable the authentication and authorization mechanisms that a specific client uses to access Kafka.
For more information on using KafkUser
to manage users and secure access to Kafka brokers, see Securing access to Kafka brokers.
5.3.1. Configuring the User Operator with resource requests and limits
You can allocate resources, such as CPU and memory, to the User Operator and set a limit on the amount of resources it can consume.
-
The Cluster Operator is running.
-
Update the Kafka cluster configuration in an editor, as required:
kubectl edit kafka MY-CLUSTER
-
In the
spec.entityOperator.userOperator.resources
property in theKafka
resource, set the resource requests and limits for the User Operator.apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka spec: # Kafka and ZooKeeper sections... entityOperator: userOperator: resources: requests: cpu: "1" memory: 500Mi limits: cpu: "1" memory: 500Mi
Save the file and exit the editor. The Cluster Operator applies the changes automatically.
5.4. Monitoring operators using Prometheus metrics
Strimzi operators expose Prometheus metrics. The metrics are automatically enabled and contain information about:
-
Number of reconciliations
-
Number of Custom Resources the operator is processing
-
Duration of reconciliations
-
JVM metrics from the operators
Additionally, we provide an example Grafana dashboard.
For more information about Prometheus, see the Introducing Metrics to Kafka in the Deploying and Upgrading Strimzi guide.
6. Kafka Bridge
This chapter provides an overview of the Strimzi Kafka Bridge and helps you get started using its REST API to interact with Strimzi.
-
To try out the Kafka Bridge in your local environment, see the Kafka Bridge quickstart later in this chapter.
-
For detailed configuration steps, see Kafka Bridge cluster configuration.
6.1. Kafka Bridge API documentation
For the full list of REST API endpoints and descriptions, including example requests and responses, see the Kafka Bridge API reference.
6.2. Kafka Bridge overview
You can use the Strimzi Kafka Bridge as an interface to make specific types of HTTP requests to the Kafka cluster.
6.2.1. Kafka Bridge interface
The Kafka Bridge provides a RESTful interface that allows HTTP-based clients to interact with a Kafka cluster. It offers the advantages of a web API connection to Strimzi, without the need for client applications to interpret the Kafka protocol.
The API has two main resources — consumers
and topics
— that are exposed and made accessible through endpoints to interact with consumers and producers in your Kafka cluster. The resources relate only to the Kafka Bridge, not the consumers and producers connected directly to Kafka.
HTTP requests
The Kafka Bridge supports HTTP requests to a Kafka cluster, with methods to:
-
Send messages to a topic.
-
Retrieve messages from topics.
-
Retrieve a list of partitions for a topic.
-
Create and delete consumers.
-
Subscribe consumers to topics, so that they start receiving messages from those topics.
-
Retrieve a list of topics that a consumer is subscribed to.
-
Unsubscribe consumers from topics.
-
Assign partitions to consumers.
-
Commit a list of consumer offsets.
-
Seek on a partition, so that a consumer starts receiving messages from the first or last offset position, or a given offset position.
The methods provide JSON responses and HTTP response code error handling. Messages can be sent in JSON or binary formats.
Clients can produce and consume messages without the requirement to use the native Kafka protocol.
-
To view the API documentation, including example requests and responses, see the Kafka Bridge API reference.
6.2.2. Supported clients for the Kafka Bridge
You can use the Kafka Bridge to integrate both internal and external HTTP client applications with your Kafka cluster.
- Internal clients
-
Internal clients are container-based HTTP clients running in the same Kubernetes cluster as the Kafka Bridge itself. Internal clients can access the Kafka Bridge on the host and port defined in the
KafkaBridge
custom resource. - External clients
-
External clients are HTTP clients running outside the Kubernetes cluster in which the Kafka Bridge is deployed and running. External clients can access the Kafka Bridge through an OpenShift Route, a loadbalancer service, or using an Ingress.
6.2.3. Securing the Kafka Bridge
Strimzi does not currently provide any encryption, authentication, or authorization for the Kafka Bridge. This means that requests sent from external clients to the Kafka Bridge are:
-
Not encrypted, and must use HTTP rather than HTTPS
-
Sent without authentication
However, you can secure the Kafka Bridge using other methods, such as:
-
Kubernetes Network Policies that define which pods can access the Kafka Bridge.
-
Reverse proxies with authentication or authorization, for example, OAuth2 proxies.
-
API Gateways.
-
Ingress or OpenShift Routes with TLS termination.
The Kafka Bridge supports TLS encryption and TLS and SASL authentication when connecting to the Kafka Brokers. Within your Kubernetes cluster, you can configure:
-
TLS or SASL-based authentication between the Kafka Bridge and your Kafka cluster
-
A TLS-encrypted connection between the Kafka Bridge and your Kafka cluster.
For more information, see Configuring the Kafka Bridge.
You can use ACLs in Kafka brokers to restrict the topics that can be consumed and produced using the Kafka Bridge.
6.2.4. Accessing the Kafka Bridge outside of Kubernetes
After deployment, the Strimzi Kafka Bridge can only be accessed by applications running in the same Kubernetes cluster.
These applications use the <kafka_bridge_name>-bridge-service
service to access the API.
If you want to make the Kafka Bridge accessible to applications running outside of the Kubernetes cluster, you can expose it manually by creating one of the following features:
-
LoadBalancer
orNodePort
type services -
Ingress
resources -
OpenShift routes
If you decide to create Services, use the labels from the selector
of the <kafka_bridge_name>-bridge-service
service to configure the pods to which the service will route the traffic:
# ...
selector:
strimzi.io/cluster: kafka-bridge-name (1)
strimzi.io/kind: KafkaBridge
#...
-
Name of the Kafka Bridge custom resource in your Kubernetes cluster.
6.2.5. Requests to the Kafka Bridge
Specify data formats and HTTP headers to ensure valid requests are submitted to the Kafka Bridge.
Content Type headers
API request and response bodies are always encoded as JSON.
-
When performing consumer operations,
POST
requests must provide the followingContent-Type
header if there is a non-empty body:Content-Type: application/vnd.kafka.v2+json
-
When performing producer operations,
POST
requests must provideContent-Type
headers specifying the embedded data format of the messages produced. This can be eitherjson
orbinary
.Embedded data format Content-Type header JSON
Content-Type: application/vnd.kafka.json.v2+json
Binary
Content-Type: application/vnd.kafka.binary.v2+json
The embedded data format is set per consumer, as described in the next section.
The Content-Type
must not be set if the POST
request has an empty body.
An empty body can be used to create a consumer with the default values.
Embedded data format
The embedded data format is the format of the Kafka messages that are transmitted, over HTTP, from a producer to a consumer using the Kafka Bridge. Two embedded data formats are supported: JSON and binary.
When creating a consumer using the /consumers/groupid
endpoint, the POST
request body must specify an embedded data format of either JSON or binary. This is specified in the format
field, for example:
{
"name": "my-consumer",
"format": "binary", (1)
...
}
-
A binary embedded data format.
The embedded data format specified when creating a consumer must match the data format of the Kafka messages it will consume.
If you choose to specify a binary embedded data format, subsequent producer requests must provide the binary data in the request body as Base64-encoded strings. For example, when sending messages using the /topics/topicname
endpoint, records.value
must be encoded in Base64:
{
"records": [
{
"key": "my-key",
"value": "ZWR3YXJkdGhldGhyZWVsZWdnZWRjYXQ="
},
]
}
Producer requests must also provide a Content-Type
header that corresponds to the embedded data format, for example, Content-Type: application/vnd.kafka.binary.v2+json
.
Message format
When sending messages using the /topics
endpoint, you enter the message payload in the request body, in the records
parameter.
The records
parameter can contain any of these optional fields:
-
Message
headers
-
Message
key
-
Message
value
-
Destination
partition
POST
request to /topicscurl -X POST \
http://localhost:8080/topics/my-topic \
-H 'content-type: application/vnd.kafka.json.v2+json' \
-d '{
"records": [
{
"key": "my-key",
"value": "sales-lead-0001"
"partition": 2
"headers": [
{
"key": "key1",
"value": "QXBhY2hlIEthZmthIGlzIHRoZSBib21iIQ==" (1)
}
]
},
]
}'
-
The header value in binary format and encoded as Base64.
Accept headers
After creating a consumer, all subsequent GET requests must provide an Accept
header in the following format:
Accept: application/vnd.kafka.EMBEDDED-DATA-FORMAT.v2+json
The EMBEDDED-DATA-FORMAT
is either json
or binary
.
For example, when retrieving records for a subscribed consumer using an embedded data format of JSON, include this Accept header:
Accept: application/vnd.kafka.json.v2+json
6.2.6. CORS
Cross-Origin Resource Sharing (CORS) allows you to specify allowed methods and originating URLs for accessing the Kafka cluster in your Kafka Bridge HTTP configuration.
# ...
cors:
allowedOrigins: "https://strimzi.io"
allowedMethods: "GET,POST,PUT,DELETE,OPTIONS,PATCH"
# ...
CORS allows for simple and preflighted requests between origin sources on different domains.
Simple requests are suitable for standard requests using GET
, HEAD
, POST
methods.
A preflighted request sends a HTTP OPTIONS request as an initial check that the actual request is safe to send.
On confirmation, the actual request is sent.
Preflight requests are suitable for methods that require greater safeguards, such as PUT
and DELETE
,
and use non-standard headers.
All requests require an Origin
value in their header, which is the source of the HTTP request.
Simple request
For example, this simple request header specifies the origin as https://strimzi.io
.
Origin: https://strimzi.io
The header information is added to the request.
curl -v -X GET HTTP-ADDRESS/bridge-consumer/records \
-H 'Origin: https://strimzi.io'\
-H 'content-type: application/vnd.kafka.v2+json'
In the response from the Kafka Bridge, an Access-Control-Allow-Origin
header is returned.
HTTP/1.1 200 OK
Access-Control-Allow-Origin: * (1)
-
Returning an asterisk (
*
) shows the resource can be accessed by any domain.
Preflighted request
An initial preflight request is sent to Kafka Bridge using an OPTIONS
method.
The HTTP OPTIONS request sends header information to check that Kafka Bridge will allow the actual request.
Here the preflight request checks that a POST
request is valid from https://strimzi.io
.
OPTIONS /my-group/instances/my-user/subscription HTTP/1.1
Origin: https://strimzi.io
Access-Control-Request-Method: POST (1)
Access-Control-Request-Headers: Content-Type (2)
-
Kafka Bridge is alerted that the actual request is a
POST
request. -
The actual request will be sent with a
Content-Type
header.
OPTIONS
is added to the header information of the preflight request.
curl -v -X OPTIONS -H 'Origin: https://strimzi.io' \
-H 'Access-Control-Request-Method: POST' \
-H 'content-type: application/vnd.kafka.v2+json'
Kafka Bridge responds to the initial request to confirm that the request will be accepted. The response header returns allowed origins, methods and headers.
HTTP/1.1 200 OK
Access-Control-Allow-Origin: https://strimzi.io
Access-Control-Allow-Methods: GET,POST,PUT,DELETE,OPTIONS,PATCH
Access-Control-Allow-Headers: content-type
If the origin or method is rejected, an error message is returned.
The actual request does not require Access-Control-Request-Method
header, as it was confirmed in the preflight request,
but it does require the origin header.
curl -v -X POST HTTP-ADDRESS/topics/bridge-topic \
-H 'Origin: https://strimzi.io' \
-H 'content-type: application/vnd.kafka.v2+json'
The response shows the originating URL is allowed.
HTTP/1.1 200 OK
Access-Control-Allow-Origin: https://strimzi.io
6.2.7. Kafka Bridge deployment
You deploy the Kafka Bridge into your Kubernetes cluster by using the Cluster Operator.
After the Kafka Bridge is deployed, the Cluster Operator creates Kafka Bridge objects in your Kubernetes cluster. Objects include the deployment, service, and pod, each named after the name given in the custom resource for the Kafka Bridge.
-
For deployment instructions, see Deploying Kafka Bridge to your Kubernetes cluster in the Deploying and Upgrading Strimzi guide.
-
For detailed information on configuring the Kafka Bridge, see Kafka Bridge cluster configuration
-
For information on configuring the host and port for the
KafkaBridge
resource, see Configuring the Kafka Bridge. -
For information on integrating external clients, see Accessing the Kafka Bridge outside of Kubernetes.
6.3. Kafka Bridge quickstart
Use this quickstart to try out the Strimzi Kafka Bridge in your local development environment. You will learn how to:
-
Deploy the Kafka Bridge to your Kubernetes cluster
-
Expose the Kafka Bridge service to your local machine by using port-forwarding
-
Produce messages to topics and partitions in your Kafka cluster
-
Create a Kafka Bridge consumer
-
Perform basic consumer operations, such as subscribing the consumer to topics and retrieving the messages that you produced
In this quickstart, HTTP requests are formatted as curl commands that you can copy and paste to your terminal. Access to a Kubernetes cluster is required.
Ensure you have the prerequisites and then follow the tasks in the order provided in this chapter.
In this quickstart, you will produce and consume messages in JSON format, not binary. For more information on the data formats and HTTP headers used in the example requests, see Requests to the Kafka Bridge.
-
Cluster administrator access to a local or remote Kubernetes cluster.
-
Strimzi is installed.
-
A running Kafka cluster, deployed by the Cluster Operator, in a Kubernetes namespace.
-
The Entity Operator is deployed and running as part of the Kafka cluster.
6.3.1. Deploying the Kafka Bridge to your Kubernetes cluster
Strimzi includes a YAML example that specifies the configuration of the Strimzi Kafka Bridge. Make some minimal changes to this file and then deploy an instance of the Kafka Bridge to your Kubernetes cluster.
-
Edit the
examples/bridge/kafka-bridge.yaml
file.apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaBridge metadata: name: quickstart (1) spec: replicas: 1 bootstrapServers: <cluster-name>-kafka-bootstrap:9092 (2) http: port: 8080
-
When the Kafka Bridge is deployed,
-bridge
is appended to the name of the deployment and other related resources. In this example, the Kafka Bridge deployment is namedquickstart-bridge
and the accompanying Kafka Bridge service is namedquickstart-bridge-service
. -
In the
bootstrapServers
property, enter the name of the Kafka cluster as the<cluster-name>
.
-
-
Deploy the Kafka Bridge to your Kubernetes cluster:
kubectl apply -f examples/bridge/kafka-bridge.yaml
A
quickstart-bridge
deployment, service, and other related resources are created in your Kubernetes cluster. -
Verify that the Kafka Bridge was successfully deployed:
kubectl get deployments
NAME READY UP-TO-DATE AVAILABLE AGE quickstart-bridge 1/1 1 1 34m my-cluster-connect 1/1 1 1 24h my-cluster-entity-operator 1/1 1 1 24h #...
After deploying the Kafka Bridge to your Kubernetes cluster, expose the Kafka Bridge service to your local machine.
-
For more detailed information about configuring the Kafka Bridge, see Kafka Bridge cluster configuration.
6.3.2. Exposing the Kafka Bridge service to your local machine
Use port forwarding to expose the Strimzi Kafka Bridge service to your local machine on http://localhost:8080.
Note
|
Port forwarding is only suitable for development and testing purposes. |
-
List the names of the pods in your Kubernetes cluster:
kubectl get pods -o name pod/kafka-consumer # ... pod/quickstart-bridge-589d78784d-9jcnr pod/strimzi-cluster-operator-76bcf9bc76-8dnfm
-
Connect to the
quickstart-bridge
pod on port8080
:kubectl port-forward pod/quickstart-bridge-589d78784d-9jcnr 8080:8080 &
NoteIf port 8080 on your local machine is already in use, use an alternative HTTP port, such as 8008
.
API requests are now forwarded from port 8080 on your local machine to port 8080 in the Kafka Bridge pod.
6.3.3. Producing messages to topics and partitions
After you have deployed Kafka Bridge and exposed its service, you can produce messages to topics in JSON format by using the topics endpoint. You can specify destination partitions for messages in the request body, as shown here. The partitions endpoint provides an alternative method for specifying a single destination partition for all messages as a path parameter.
-
In a text editor, create a YAML definition for a Kafka topic with three partitions.
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaTopic metadata: name: bridge-quickstart-topic labels: strimzi.io/cluster: <kafka-cluster-name> (1) spec: partitions: 3 (2) replicas: 1 config: retention.ms: 7200000 segment.bytes: 1073741824
-
The name of the Kafka cluster in which the Kafka Bridge is deployed.
-
The number of partitions for the topic.
-
-
Save the file to the
examples/topic
directory asbridge-quickstart-topic.yaml
. -
Create the topic in your Kubernetes cluster:
kubectl apply -f examples/topic/bridge-quickstart-topic.yaml
-
Using the Kafka Bridge, produce three messages to the topic you created:
curl -X POST \ http://localhost:8080/topics/bridge-quickstart-topic \ -H 'content-type: application/vnd.kafka.json.v2+json' \ -d '{ "records": [ { "key": "my-key", "value": "sales-lead-0001" }, { "value": "sales-lead-0002", "partition": 2 }, { "value": "sales-lead-0003" } ] }'
-
sales-lead-0001
is sent to a partition based on the hash of the key. -
sales-lead-0002
is sent directly to partition 2. -
sales-lead-0003
is sent to a partition in thebridge-quickstart-topic
topic using a round-robin method.
-
-
If the request is successful, the Kafka Bridge returns an
offsets
array, along with a200
code and acontent-type
header ofapplication/vnd.kafka.v2+json
. For each message, theoffsets
array describes:-
The partition that the message was sent to
-
The current message offset of the partition
Example response#... { "offsets":[ { "partition":0, "offset":0 }, { "partition":2, "offset":0 }, { "partition":0, "offset":1 } ] }
-
Make other curl requests to find information on topics and partitions.
- List topics
-
curl -X GET \ http://localhost:8080/topics
Example response[ "__strimzi_store_topic", "__strimzi-topic-operator-kstreams-topic-store-changelog", "bridge-quickstart-topic", "my-topic" ]
- Get topic configuration and partition details
-
curl -X GET \ http://localhost:8080/topics/bridge-quickstart-topic
Example response{ "name": "bridge-quickstart-topic", "configs": { "compression.type": "producer", "leader.replication.throttled.replicas": "", "min.insync.replicas": "1", "message.downconversion.enable": "true", "segment.jitter.ms": "0", "cleanup.policy": "delete", "flush.ms": "9223372036854775807", "follower.replication.throttled.replicas": "", "segment.bytes": "1073741824", "retention.ms": "604800000", "flush.messages": "9223372036854775807", "message.format.version": "2.8-IV1", "max.compaction.lag.ms": "9223372036854775807", "file.delete.delay.ms": "60000", "max.message.bytes": "1048588", "min.compaction.lag.ms": "0", "message.timestamp.type": "CreateTime", "preallocate": "false", "index.interval.bytes": "4096", "min.cleanable.dirty.ratio": "0.5", "unclean.leader.election.enable": "false", "retention.bytes": "-1", "delete.retention.ms": "86400000", "segment.ms": "604800000", "message.timestamp.difference.max.ms": "9223372036854775807", "segment.index.bytes": "10485760" }, "partitions": [ { "partition": 0, "leader": 0, "replicas": [ { "broker": 0, "leader": true, "in_sync": true }, { "broker": 1, "leader": false, "in_sync": true }, { "broker": 2, "leader": false, "in_sync": true } ] }, { "partition": 1, "leader": 2, "replicas": [ { "broker": 2, "leader": true, "in_sync": true }, { "broker": 0, "leader": false, "in_sync": true }, { "broker": 1, "leader": false, "in_sync": true } ] }, { "partition": 2, "leader": 1, "replicas": [ { "broker": 1, "leader": true, "in_sync": true }, { "broker": 2, "leader": false, "in_sync": true }, { "broker": 0, "leader": false, "in_sync": true } ] } ] }
- List the partitions of a specific topic
-
curl -X GET \ http://localhost:8080/topics/bridge-quickstart-topic/partitions
Example response[ { "partition": 0, "leader": 0, "replicas": [ { "broker": 0, "leader": true, "in_sync": true }, { "broker": 1, "leader": false, "in_sync": true }, { "broker": 2, "leader": false, "in_sync": true } ] }, { "partition": 1, "leader": 2, "replicas": [ { "broker": 2, "leader": true, "in_sync": true }, { "broker": 0, "leader": false, "in_sync": true }, { "broker": 1, "leader": false, "in_sync": true } ] }, { "partition": 2, "leader": 1, "replicas": [ { "broker": 1, "leader": true, "in_sync": true }, { "broker": 2, "leader": false, "in_sync": true }, { "broker": 0, "leader": false, "in_sync": true } ] } ]
- List the details of a specific topic partition
-
curl -X GET \ http://localhost:8080/topics/bridge-quickstart-topic/partitions/0
Example response{ "partition": 0, "leader": 0, "replicas": [ { "broker": 0, "leader": true, "in_sync": true }, { "broker": 1, "leader": false, "in_sync": true }, { "broker": 2, "leader": false, "in_sync": true } ] }
- List the offsets of a specific topic partition
-
curl -X GET \ http://localhost:8080/topics/bridge-quickstart-topic/partitions/0/offsets
Example response{ "beginning_offset": 0, "end_offset": 1 }
After producing messages to topics and partitions, create a Kafka Bridge consumer.
-
POST /topics/{topicname} in the API reference documentation.
-
POST /topics/{topicname}/partitions/{partitionid} in the API reference documentation.
6.3.4. Creating a Kafka Bridge consumer
Before you can perform any consumer operations in the Kafka cluster, you must first create a consumer by using the consumers endpoint. The consumer is referred to as a Kafka Bridge consumer.
-
Create a Kafka Bridge consumer in a new consumer group named
bridge-quickstart-consumer-group
:curl -X POST http://localhost:8080/consumers/bridge-quickstart-consumer-group \ -H 'content-type: application/vnd.kafka.v2+json' \ -d '{ "name": "bridge-quickstart-consumer", "auto.offset.reset": "earliest", "format": "json", "enable.auto.commit": false, "fetch.min.bytes": 512, "consumer.request.timeout.ms": 30000 }'
-
The consumer is named
bridge-quickstart-consumer
and the embedded data format is set asjson
. -
Some basic configuration settings are defined.
-
The consumer will not commit offsets to the log automatically because the
enable.auto.commit
setting isfalse
. You will commit the offsets manually later in this quickstart.If the request is successful, the Kafka Bridge returns the consumer ID (
instance_id
) and base URL (base_uri
) in the response body, along with a200
code.Example response#... { "instance_id": "bridge-quickstart-consumer", "base_uri":"http://<bridge-name>-bridge-service:8080/consumers/bridge-quickstart-consumer-group/instances/bridge-quickstart-consumer" }
-
-
Copy the base URL (
base_uri
) to use in the other consumer operations in this quickstart.
Now that you have created a Kafka Bridge consumer, you can subscribe it to topics.
-
POST /consumers/{groupid} in the API reference documentation.
6.3.5. Subscribing a Kafka Bridge consumer to topics
After you have created a Kafka Bridge consumer, subscribe it to one or more topics by using the subscription endpoint. Once subscribed, the consumer starts receiving all messages that are produced to the topic.
-
Subscribe the consumer to the
bridge-quickstart-topic
topic that you created earlier, in Producing messages to topics and partitions:curl -X POST http://localhost:8080/consumers/bridge-quickstart-consumer-group/instances/bridge-quickstart-consumer/subscription \ -H 'content-type: application/vnd.kafka.v2+json' \ -d '{ "topics": [ "bridge-quickstart-topic" ] }'
The
topics
array can contain a single topic (as shown here) or multiple topics. If you want to subscribe the consumer to multiple topics that match a regular expression, you can use thetopic_pattern
string instead of thetopics
array.If the request is successful, the Kafka Bridge returns a
204
(No Content) code only.
After subscribing a Kafka Bridge consumer to topics, you can retrieve messages from the consumer.
-
POST /consumers/{groupid}/instances/{name}/subscription in the API reference documentation.
6.3.6. Retrieving the latest messages from a Kafka Bridge consumer
Retrieve the latest messages from the Kafka Bridge consumer by requesting data from the records endpoint. In production, HTTP clients can call this endpoint repeatedly (in a loop).
-
Produce additional messages to the Kafka Bridge consumer, as described in Producing messages to topics and partitions.
-
Submit a
GET
request to therecords
endpoint:curl -X GET http://localhost:8080/consumers/bridge-quickstart-consumer-group/instances/bridge-quickstart-consumer/records \ -H 'accept: application/vnd.kafka.json.v2+json'
After creating and subscribing to a Kafka Bridge consumer, a first GET request will return an empty response because the poll operation starts a rebalancing process to assign partitions.
-
Repeat step two to retrieve messages from the Kafka Bridge consumer.
The Kafka Bridge returns an array of messages — describing the topic name, key, value, partition, and offset — in the response body, along with a
200
code. Messages are retrieved from the latest offset by default.HTTP/1.1 200 OK content-type: application/vnd.kafka.json.v2+json #... [ { "topic":"bridge-quickstart-topic", "key":"my-key", "value":"sales-lead-0001", "partition":0, "offset":0 }, { "topic":"bridge-quickstart-topic", "key":null, "value":"sales-lead-0003", "partition":0, "offset":1 }, #...
NoteIf an empty response is returned, produce more records to the consumer as described in Producing messages to topics and partitions, and then try retrieving messages again.
After retrieving messages from a Kafka Bridge consumer, try committing offsets to the log.
-
GET /consumers/{groupid}/instances/{name}/records in the API reference documentation.
6.3.7. Commiting offsets to the log
Use the offsets endpoint to manually commit offsets to the log for all messages received by the Kafka Bridge consumer. This is required because the Kafka Bridge consumer that you created earlier, in Creating a Kafka Bridge consumer, was configured with the enable.auto.commit
setting as false
.
-
Commit offsets to the log for the
bridge-quickstart-consumer
:curl -X POST http://localhost:8080/consumers/bridge-quickstart-consumer-group/instances/bridge-quickstart-consumer/offsets
Because no request body is submitted, offsets are committed for all the records that have been received by the consumer. Alternatively, the request body can contain an array (OffsetCommitSeekList) that specifies the topics and partitions that you want to commit offsets for.
If the request is successful, the Kafka Bridge returns a
204
code only.
After committing offsets to the log, try out the endpoints for seeking to offsets.
-
POST /consumers/{groupid}/instances/{name}/offsets in the API reference documentation.
6.3.8. Seeking to offsets for a partition
Use the positions endpoints to configure the Kafka Bridge consumer to retrieve messages for a partition from a specific offset, and then from the latest offset. This is referred to in Apache Kafka as a seek operation.
-
Seek to a specific offset for partition 0 of the
quickstart-bridge-topic
topic:curl -X POST http://localhost:8080/consumers/bridge-quickstart-consumer-group/instances/bridge-quickstart-consumer/positions \ -H 'content-type: application/vnd.kafka.v2+json' \ -d '{ "offsets": [ { "topic": "bridge-quickstart-topic", "partition": 0, "offset": 2 } ] }'
If the request is successful, the Kafka Bridge returns a
204
code only. -
Submit a
GET
request to therecords
endpoint:curl -X GET http://localhost:8080/consumers/bridge-quickstart-consumer-group/instances/bridge-quickstart-consumer/records \ -H 'accept: application/vnd.kafka.json.v2+json'
The Kafka Bridge returns messages from the offset that you seeked to.
-
Restore the default message retrieval behavior by seeking to the last offset for the same partition. This time, use the positions/end endpoint.
curl -X POST http://localhost:8080/consumers/bridge-quickstart-consumer-group/instances/bridge-quickstart-consumer/positions/end \ -H 'content-type: application/vnd.kafka.v2+json' \ -d '{ "partitions": [ { "topic": "bridge-quickstart-topic", "partition": 0 } ] }'
If the request is successful, the Kafka Bridge returns another
204
code.
Note
|
You can also use the positions/beginning endpoint to seek to the first offset for one or more partitions. |
In this quickstart, you have used the Strimzi Kafka Bridge to perform several common operations on a Kafka cluster. You can now delete the Kafka Bridge consumer that you created earlier.
-
POST /consumers/{groupid}/instances/{name}/positions in the API reference documentation.
-
POST /consumers/{groupid}/instances/{name}/positions/beginning in the API reference documentation.
-
POST /consumers/{groupid}/instances/{name}/positions/end in the API reference documentation.
6.3.9. Deleting a Kafka Bridge consumer
Delete the Kafka Bridge consumer that you used throughout this quickstart.
-
Delete the Kafka Bridge consumer by sending a
DELETE
request to the instances endpoint.curl -X DELETE http://localhost:8080/consumers/bridge-quickstart-consumer-group/instances/bridge-quickstart-consumer
If the request is successful, the Kafka Bridge returns a
204
code.
-
DELETE /consumers/{groupid}/instances/{name} in the API reference documentation.
7. Cruise Control for cluster rebalancing
You can deploy Cruise Control to your Strimzi cluster and use it to rebalance the Kafka cluster.
Cruise Control is an open source system for automating Kafka operations, such as monitoring cluster workload, rebalancing a cluster based on predefined constraints, and detecting and fixing anomalies. It consists of four main components—the Load Monitor, the Analyzer, the Anomaly Detector, and the Executor—and a REST API for client interactions. Strimzi utilizes the REST API to support the following Cruise Control features:
-
Generating optimization proposals from multiple optimization goals.
-
Rebalancing a Kafka cluster based on an optimization proposal.
Other Cruise Control features are not currently supported, including anomaly detection, notifications, write-your-own goals, and changing the topic replication factor.
Strimzi provides example configuration files.
Example YAML configuration files for Cruise Control are provided in examples/cruise-control/
.
7.1. Why use Cruise Control?
Cruise Control reduces the time and effort involved in running an efficient and balanced Kafka cluster.
A typical cluster can become unevenly loaded over time. Partitions that handle large amounts of message traffic might be unevenly distributed across the available brokers. To rebalance the cluster, administrators must monitor the load on brokers and manually reassign busy partitions to brokers with spare capacity.
Cruise Control automates the cluster rebalancing process. It constructs a workload model of resource utilization for the cluster—based on CPU, disk, and network load—and generates optimization proposals (that you can approve or reject) for more balanced partition assignments. A set of configurable optimization goals is used to calculate these proposals.
When you approve an optimization proposal, Cruise Control applies it to your Kafka cluster. When the cluster rebalancing operation is complete, the broker pods are used more effectively and the Kafka cluster is more evenly balanced.
7.2. Optimization goals overview
To rebalance a Kafka cluster, Cruise Control uses optimization goals to generate optimization proposals, which you can approve or reject.
Optimization goals are constraints on workload redistribution and resource utilization across a Kafka cluster. Strimzi supports most of the optimization goals developed in the Cruise Control project. The supported goals, in the default descending order of priority, are as follows:
-
Rack-awareness
-
Minimum number of leader replicas per broker for a set of topics
-
Replica capacity
-
Capacity: Disk capacity, Network inbound capacity, Network outbound capacity, CPU capacity
-
Replica distribution
-
Potential network output
-
Resource distribution: Disk utilization distribution, Network inbound utilization distribution, Network outbound utilization distribution, CPU utilization distribution
NoteThe resource distribution goals are controlled using capacity limits on broker resources.
-
Leader bytes-in rate distribution
-
Topic replica distribution
-
Leader replica distribution
-
Preferred leader election
For more information on each optimization goal, see Goals in the Cruise Control Wiki.
Note
|
Intra-broker disk goals, "Write your own" goals, and Kafka assigner goals are not yet supported. |
Goals configuration in Strimzi custom resources
You configure optimization goals in Kafka
and KafkaRebalance
custom resources. Cruise Control has configurations for hard optimization goals that must be satisfied, as well as main, default, and user-provided optimization goals.
Optimization goals for resource distribution (disk, network inbound, network outbound, and CPU) are subject to capacity limits on broker resources.
The following sections describe each goal configuration in more detail.
Hard goals and soft goals
Hard goals are goals that must be satisfied in optimization proposals. Goals that are not configured as hard goals are known as soft goals. You can think of soft goals as best effort goals: they do not need to be satisfied in optimization proposals, but are included in optimization calculations. An optimization proposal that violates one or more soft goals, but satisfies all hard goals, is valid.
Cruise Control will calculate optimization proposals that satisfy all the hard goals and as many soft goals as possible (in their priority order). An optimization proposal that does not satisfy all the hard goals is rejected by Cruise Control and not sent to the user for approval.
Note
|
For example, you might have a soft goal to distribute a topic’s replicas evenly across the cluster (the topic replica distribution goal). Cruise Control will ignore this goal if doing so enables all the configured hard goals to be met. |
In Cruise Control, the following main optimization goals are preset as hard goals:
RackAwareGoal; MinTopicLeadersPerBrokerGoal; ReplicaCapacityGoal; DiskCapacityGoal; NetworkInboundCapacityGoal; NetworkOutboundCapacityGoal; CpuCapacityGoal
You configure hard goals in the Cruise Control deployment configuration, by editing the hard.goals
property in Kafka.spec.cruiseControl.config
.
-
To inherit the preset hard goals from Cruise Control, do not specify the
hard.goals
property inKafka.spec.cruiseControl.config
-
To change the preset hard goals, specify the desired goals in the
hard.goals
property, using their fully-qualified domain names.
Kafka
configuration for hard optimization goalsapiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
kafka:
# ...
zookeeper:
# ...
entityOperator:
topicOperator: {}
userOperator: {}
cruiseControl:
brokerCapacity:
inboundNetwork: 10000KB/s
outboundNetwork: 10000KB/s
config:
hard.goals: >
com.linkedin.kafka.cruisecontrol.analyzer.goals.NetworkInboundCapacityGoal,
com.linkedin.kafka.cruisecontrol.analyzer.goals.NetworkOutboundCapacityGoal
# ...
Increasing the number of configured hard goals will reduce the likelihood of Cruise Control generating valid optimization proposals.
If skipHardGoalCheck: true
is specified in the KafkaRebalance
custom resource, Cruise Control does not check that the list of user-provided optimization goals (in KafkaRebalance.spec.goals
) contains all the configured hard goals (hard.goals
).
Therefore, if some, but not all, of the user-provided optimization goals are in the hard.goals
list, Cruise Control will still treat them as hard goals even if skipHardGoalCheck: true
is specified.
Main optimization goals
The main optimization goals are available to all users. Goals that are not listed in the main optimization goals are not available for use in Cruise Control operations.
Unless you change the Cruise Control deployment configuration, Strimzi will inherit the following main optimization goals from Cruise Control, in descending priority order:
RackAwareGoal; ReplicaCapacityGoal; DiskCapacityGoal; NetworkInboundCapacityGoal; NetworkOutboundCapacityGoal; CpuCapacityGoal; ReplicaDistributionGoal; PotentialNwOutGoal; DiskUsageDistributionGoal; NetworkInboundUsageDistributionGoal; NetworkOutboundUsageDistributionGoal; CpuUsageDistributionGoal; TopicReplicaDistributionGoal; LeaderReplicaDistributionGoal; LeaderBytesInDistributionGoal; PreferredLeaderElectionGoal
Six of these goals are preset as hard goals.
To reduce complexity, we recommend that you use the inherited main optimization goals, unless you need to completely exclude one or more goals from use in KafkaRebalance
resources. The priority order of the main optimization goals can be modified, if desired, in the configuration for default optimization goals.
You configure main optimization goals, if necessary, in the Cruise Control deployment configuration: Kafka.spec.cruiseControl.config.goals
-
To accept the inherited main optimization goals, do not specify the
goals
property inKafka.spec.cruiseControl.config
. -
If you need to modify the inherited main optimization goals, specify a list of goals, in descending priority order, in the
goals
configuration option.
Note
|
If you change the inherited main optimization goals, you must ensure that the hard goals, if configured in the hard.goals property in Kafka.spec.cruiseControl.config , are a subset of the main optimization goals that you configured. Otherwise, errors will occur when generating optimization proposals.
|
Default optimization goals
Cruise Control uses the default optimization goals to generate the cached optimization proposal. For more information about the cached optimization proposal, see Optimization proposals overview.
You can override the default optimization goals by setting user-provided optimization goals in a KafkaRebalance
custom resource.
Unless you specify default.goals
in the Cruise Control deployment configuration, the main optimization goals are used as the default optimization goals.
In this case, the cached optimization proposal is generated using the main optimization goals.
-
To use the main optimization goals as the default goals, do not specify the
default.goals
property inKafka.spec.cruiseControl.config
. -
To modify the default optimization goals, edit the
default.goals
property inKafka.spec.cruiseControl.config
. You must use a subset of the main optimization goals.
Kafka
configuration for default optimization goalsapiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
kafka:
# ...
zookeeper:
# ...
entityOperator:
topicOperator: {}
userOperator: {}
cruiseControl:
brokerCapacity:
inboundNetwork: 10000KB/s
outboundNetwork: 10000KB/s
config:
default.goals: >
com.linkedin.kafka.cruisecontrol.analyzer.goals.RackAwareGoal,
com.linkedin.kafka.cruisecontrol.analyzer.goals.ReplicaCapacityGoal,
com.linkedin.kafka.cruisecontrol.analyzer.goals.DiskCapacityGoal
# ...
If no default optimization goals are specified, the cached proposal is generated using the main optimization goals.
User-provided optimization goals
User-provided optimization goals narrow down the configured default goals for a particular optimization proposal.
You can set them, as required, in spec.goals
in a KafkaRebalance
custom resource:
KafkaRebalance.spec.goals
User-provided optimization goals can generate optimization proposals for different scenarios.
For example, you might want to optimize leader replica distribution across the Kafka cluster without considering disk capacity or disk utilization.
So, you create a KafkaRebalance
custom resource containing a single user-provided goal for leader replica distribution.
User-provided optimization goals must:
-
Include all configured hard goals, or an error occurs
-
Be a subset of the main optimization goals
To ignore the configured hard goals when generating an optimization proposal, add the skipHardGoalCheck: true
property to the KafkaRebalance
custom resource. See Generating optimization proposals.
-
Configurations in the Cruise Control Wiki.
7.3. Optimization proposals overview
An optimization proposal is a summary of proposed changes that would produce a more balanced Kafka cluster, with partition workloads distributed more evenly among the brokers. Each optimization proposal is based on the set of optimization goals that was used to generate it, subject to any configured capacity limits on broker resources.
An optimization proposal is contained in the Status.Optimization Result
property of a KafkaRebalance
custom resource.
The information provided is a summary of the full optimization proposal.
Use the summary to decide whether to:
-
Approve the optimization proposal. This instructs Cruise Control to apply the proposal to the Kafka cluster and start a cluster rebalance operation.
-
Reject the optimization proposal. You can change the optimization goals and then generate another proposal.
All optimization proposals are dry runs: you cannot approve a cluster rebalance without first generating an optimization proposal. There is no limit to the number of optimization proposals that can be generated.
Cached optimization proposal
Cruise Control maintains a cached optimization proposal based on the configured default optimization goals. Generated from the workload model, the cached optimization proposal is updated every 15 minutes to reflect the current state of the Kafka cluster. If you generate an optimization proposal using the default optimization goals, Cruise Control returns the most recent cached proposal.
To change the cached optimization proposal refresh interval, edit the proposal.expiration.ms
setting in the Cruise Control deployment configuration.
Consider a shorter interval for fast changing clusters, although this increases the load on the Cruise Control server.
Contents of optimization proposals
An optimization proposal consists of two main sections:
-
The summary is stored in the
status
of theKafkaRebalance
resource. -
The broker load is stored in a ConfigMap that contains data as a JSON string.
The summary provides an overview of the proposed cluster rebalance and indicates the scale of the changes involved. The broker load shows before and after values for the proposed rebalance, so you can see the impact on each of the brokers in the cluster.
Summary
The following table explains the properties contained in the optimization proposal’s summary section:
JSON property | Description |
---|---|
|
The total number of partition replicas that will be transferred between the disks of the cluster’s brokers. Performance impact during rebalance operation: Relatively high, but lower than |
|
Not yet supported. An empty list is returned. |
|
The number of partition replicas that will be moved between separate brokers. Performance impact during rebalance operation: Relatively high. |
|
A measurement of the overall balancedness of a Kafka Cluster, before and after the optimization proposal was generated. The score is calculated by subtracting the sum of the The |
|
The sum of the size of each partition replica that will be moved between disks on the same broker (see also Performance impact during rebalance operation: Variable. The larger the number, the longer the cluster rebalance will take to complete. Moving a large amount of data between disks on the same broker has less impact than between separate brokers (see |
|
The number of metrics windows upon which the optimization proposal is based. |
|
The sum of the size of each partition replica that will be moved to a separate broker (see also Performance impact during rebalance operation: Variable. The larger the number, the longer the cluster rebalance will take to complete. |
|
The percentage of partitions in the Kafka cluster covered by the optimization proposal. Affected by the number of |
|
If you specified a regular expression in the |
|
The number of partitions whose leaders will be switched to different replicas. This involves a change to ZooKeeper configuration. Performance impact during rebalance operation: Relatively low. |
|
Not yet supported. An empty list is returned. |
Broker load
The broker load is stored in a ConfigMap (with the same name as the KafkaRebalance custom resource) as a JSON formatted string. This JSON string consists of a JSON object with keys for each broker IDs linking to a number of metrics for each broker. Each metric consist of three values. The first is the metric value before the optimization proposal is applied, the second is the expected value of the metric after the proposal is applied, and the third is the difference between the first two values (after minus before).
Note
|
The ConfigMap appears when the KafkaRebalance resource is in the ProposalReady state and remains after the rebalance is complete.
|
To extract the JSON string from the ConfigMap you could use the following command, which uses the jq command line JSON parser tool:
kubectl get configmap MY-REBALANCE -o json | jq '.["data"]["brokerLoad.json"]|fromjson|.'
The following table explains the properties contained in the optimization proposal’s broker load ConfigMap:
JSON property | Description |
---|---|
|
The number of replicas on this broker that are partition leaders. |
|
The number of replicas on this broker. |
|
The CPU utilization as a percentage of the defined capacity. |
|
The disk utilization as a percentage of the defined capacity. |
|
The absolute disk usage in MB. |
|
The total network output rate for the broker. |
|
The network input rate for all partition leader replicas on this broker. |
|
The network input rate for all follower replicas on this broker. |
|
The hypothetical maximum network output rate that would be realized if this broker became the leader of all the replicas it currently hosts. |
7.4. Rebalance performance tuning overview
You can adjust several performance tuning options for cluster rebalances. These options control how partition replica and leadership movements in a rebalance are executed, as well as the bandwidth that is allocated to a rebalance operation.
Partition reassignment commands
Optimization proposals are comprised of separate partition reassignment commands. When you approve a proposal, the Cruise Control server applies these commands to the Kafka cluster.
A partition reassignment command consists of either of the following types of operations:
-
Partition movement: Involves transferring the partition replica and its data to a new location. Partition movements can take one of two forms:
-
Inter-broker movement: The partition replica is moved to a log directory on a different broker.
-
Intra-broker movement: The partition replica is moved to a different log directory on the same broker.
-
-
Leadership movement: This involves switching the leader of the partition’s replicas.
Cruise Control issues partition reassignment commands to the Kafka cluster in batches. The performance of the cluster during the rebalance is affected by the number of each type of movement contained in each batch.
Replica movement strategies
Cluster rebalance performance is also influenced by the replica movement strategy that is applied to the batches of partition reassignment commands.
By default, Cruise Control uses the BaseReplicaMovementStrategy
, which simply applies the commands in the order they were generated.
However, if there are some very large partition reassignments early in the proposal, this strategy can slow down the application of the other reassignments.
Cruise Control provides four alternative replica movement strategies that can be applied to optimization proposals:
-
PrioritizeSmallReplicaMovementStrategy
: Order reassignments in order of ascending size. -
PrioritizeLargeReplicaMovementStrategy
: Order reassignments in order of descending size. -
PostponeUrpReplicaMovementStrategy
: Prioritize reassignments for replicas of partitions which have no out-of-sync replicas. -
PrioritizeMinIsrWithOfflineReplicasStrategy
: Prioritize reassignments with (At/Under)MinISR partitions with offline replicas. This strategy will only work ifcruiseControl.config.concurrency.adjuster.min.isr.check.enabled
is set totrue
in theKafka
custom resource’s spec.
These strategies can be configured as a sequence. The first strategy attempts to compare two partition reassignments using its internal logic. If the reassignments are equivalent, then it passes them to the next strategy in the sequence to decide the order, and so on.
Rebalance tuning options
Cruise Control provides several configuration options for tuning the rebalance parameters discussed above. You can set these tuning options at either the Cruise Control server or optimization proposal levels:
-
The Cruise Control server setting can be set in the Kafka custom resource under
Kafka.spec.cruiseControl.config
. -
The individual rebalance performance configurations can be set under
KafkaRebalance.spec
.
The relevant configurations are summarized below:
Server and KafkaRebalance Configuration |
Description | Default Value |
---|---|---|
|
The maximum number of inter-broker partition movements in each partition reassignment batch |
5 |
|
||
|
The maximum number of intra-broker partition movements in each partition reassignment batch |
2 |
|
||
|
The maximum number of partition leadership changes in each partition reassignment batch |
1000 |
|
||
|
The bandwidth (in bytes per second) to be assigned to the reassigning of partitions |
No Limit |
|
||
|
The list of strategies (in priority order) used to determine the order in which partition reassignment commands are executed for generated proposals. For the server setting, use a comma separated string with the fully qualified names of the strategy class (add |
|
|
Changing the default settings affects the length of time that the rebalance takes to complete, as well as the load placed on the Kafka cluster during the rebalance. Using lower values reduces the load but increases the amount of time taken, and vice versa.
7.5. Cruise Control configuration
The config
property in Kafka.spec.cruiseControl
contains configuration options as keys with values as one of the following JSON types:
-
String
-
Number
-
Boolean
You can specify and configure all the options listed in the "Configurations" section of the Cruise Control documentation, apart from those managed directly by Strimzi. Specifically, you cannot modify configuration options with keys equal to or starting with one of the keys mentioned here.
If restricted options are specified, they are ignored and a warning message is printed to the Cluster Operator log file. All the supported options are passed to Cruise Control.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
# ...
cruiseControl:
# ...
config:
default.goals: >
com.linkedin.kafka.cruisecontrol.analyzer.goals.RackAwareGoal,
com.linkedin.kafka.cruisecontrol.analyzer.goals.ReplicaCapacityGoal
cpu.balance.threshold: 1.1
metadata.max.age.ms: 300000
send.buffer.bytes: 131072
# ...
Cross-Origin Resource Sharing configuration
Cross-Origin Resource Sharing (CORS) allows you to specify allowed methods and originating URLs for accessing REST APIs.
By default, CORS is disabled for the Cruise Control REST API.
When enabled, only GET
requests for read-only access to the Kafka cluster state are allowed.
This means that external applications, which are running in different origins than the Strimzi components, cannot make POST
requests to the Cruise Control API.
However, those applications can make GET
requests to access read-only information about the Kafka cluster, such as the current cluster load or the most recent optimization proposal.
You enable and configure CORS in Kafka.spec.cruiseControl.config
.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
# ...
cruiseControl:
# ...
config:
webserver.http.cors.enabled: true
webserver.http.cors.origin: "*"
webserver.http.cors.exposeheaders: "User-Task-ID,Content-Type"
# ...
For more information, see REST APIs in the Cruise Control Wiki.
Capacity configuration
Cruise Control uses capacity limits to determine if optimization goals for resource distribution are being broken. There are four goals of this type:
-
DiskUsageDistributionGoal
- Disk utilization distribution -
CpuUsageDistributionGoal
- CPU utilization distribution -
NetworkInboundUsageDistributionGoal
- Network inbound utilization distribution -
NetworkOutboundUsageDistributionGoal
- Network outbound utilization distribution
You specify capacity limits for Kafka broker resources in the brokerCapacity
property in Kafka.spec.cruiseControl
.
They are enabled by default and you can change their default values.
Capacity limits can be set for the following broker resources, using the standard Kubernetes byte units (K, M, G and T) or their bibyte (power of two) equivalents (Ki, Mi, Gi and Ti):
-
disk
- Disk storage per broker (Default: 100000Mi) -
cpuUtilization
- CPU utilization as a percentage (Default: 100) -
inboundNetwork
- Inbound network throughput in byte units per second (Default: 10000KiB/s) -
outboundNetwork
- Outbound network throughput in byte units per second (Default: 10000KiB/s)
Because Strimzi Kafka brokers are homogeneous, Cruise Control applies the same capacity limits to every broker it is monitoring.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
# ...
cruiseControl:
# ...
brokerCapacity:
disk: 100Gi
cpuUtilization: 100
inboundNetwork: 10000KiB/s
outboundNetwork: 10000KiB/s
# ...
For more information, refer to the BrokerCapacity
schema reference.
Logging configuration
Cruise Control has its own configurable logger:
-
rootLogger.level
Cruise Control uses the Apache log4j 2
logger implementation.
Use the logging
property to configure loggers and logger levels.
You can set the log levels by specifying the logger and level directly (inline) or use a custom (external) ConfigMap.
If a ConfigMap is used, you set logging.valueFrom.configMapKeyRef.name
property to the name of the ConfigMap containing the external logging configuration. Inside the ConfigMap, the logging configuration is described using log4j.properties
. Both logging.valueFrom.configMapKeyRef.name
and logging.valueFrom.configMapKeyRef.key
properties are mandatory. A ConfigMap using the exact logging configuration specified is created with the custom resource when the Cluster Operator is running, then recreated after each reconciliation. If you do not specify a custom ConfigMap, default logging settings are used. If a specific logger value is not set, upper-level logger settings are inherited for that logger.
Here we see examples of inline
and external
logging.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
# ...
spec:
cruiseControl:
# ...
logging:
type: inline
loggers:
rootLogger.level: "INFO"
# ...
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
# ...
spec:
cruiseControl:
# ...
logging:
type: external
valueFrom:
configMapKeyRef:
name: customConfigMap
key: cruise-control-log4j.properties
# ...
Cruise Control REST API security
The Cruise Control REST API is secured with HTTP Basic authentication and SSL to protect the cluster against potentially destructive Cruise Control operations, such as decommissioning Kafka brokers.
We recommend that Cruise Control in Strimzi is only used with these settings enabled. You should not disable the built-in HTTP Basic authentication or SSL settings described below.
-
To disable the built-in HTTP Basic authentication, set
webserver.security.enable
tofalse
. -
To disable the built-in SSL, set
webserver.ssl.enable
tofalse
.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
# ...
cruiseControl:
config:
webserver.security.enable: false
webserver.ssl.enable: false
# ...
7.6. Deploying Cruise Control
To deploy Cruise Control to your Strimzi cluster, define the configuration using the cruiseControl
property in the Kafka
resource, and then create or update the resource.
Deploy one instance of Cruise Control per Kafka cluster.
-
A Kubernetes cluster
-
A running Cluster Operator
-
Edit the
Kafka
resource and add thecruiseControl
property.The properties you can configure are shown in this example configuration:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: # ... cruiseControl: brokerCapacity: (1) inboundNetwork: 10000KB/s outboundNetwork: 10000KB/s # ... config: (2) default.goals: > com.linkedin.kafka.cruisecontrol.analyzer.goals.RackAwareGoal, com.linkedin.kafka.cruisecontrol.analyzer.goals.ReplicaCapacityGoal # ... cpu.balance.threshold: 1.1 metadata.max.age.ms: 300000 send.buffer.bytes: 131072 # ... resources: (3) requests: cpu: 1 memory: 512Mi limits: cpu: 2 memory: 2Gi logging: (4) type: inline loggers: rootLogger.level: "INFO" template: (5) pod: metadata: labels: label1: value1 securityContext: runAsUser: 1000001 fsGroup: 0 terminationGracePeriodSeconds: 120 readinessProbe: (6) initialDelaySeconds: 15 timeoutSeconds: 5 livenessProbe: (7) initialDelaySeconds: 15 timeoutSeconds: 5 # ...
-
Specifies capacity limits for broker resources. For more information, see Capacity configuration.
-
Defines the Cruise Control configuration, including the default optimization goals (in
default.goals
) and any customizations to the main optimization goals (ingoals
) or the hard goals (inhard.goals
). You can provide any standard Cruise Control configuration option apart from those managed directly by Strimzi. For more information on configuring optimization goals, see Optimization goals overview. -
CPU and memory resources reserved for Cruise Control. For more information, see
resources
. -
Defined loggers and log levels added directly (inline) or indirectly (external) through a ConfigMap. A custom ConfigMap must be placed under the log4j.properties key. Cruise Control has a single logger named
rootLogger.level
. You can set the log level to INFO, ERROR, WARN, TRACE, DEBUG, FATAL or OFF. For more information, see Logging configuration.
-
-
Create or update the resource:
kubectl apply -f kafka.yaml
-
Verify that Cruise Control was successfully deployed:
kubectl get deployments -l app.kubernetes.io/name=cruise-control
Auto-created topics
The following table shows the three topics that are automatically created when Cruise Control is deployed. These topics are required for Cruise Control to work properly and must not be deleted or changed.
Auto-created topic | Created by | Function |
---|---|---|
|
Strimzi Metrics Reporter |
Stores the raw metrics from the Metrics Reporter in each Kafka broker. |
|
Cruise Control |
Stores the derived metrics for each partition. These are created by the Metric Sample Aggregator. |
|
Cruise Control |
Stores the metrics samples used to create the Cluster Workload Model. |
To prevent the removal of records that are needed by Cruise Control, log compaction is disabled in the auto-created topics.
After configuring and deploying Cruise Control, you can generate optimization proposals.
7.7. Generating optimization proposals
When you create or update a KafkaRebalance
resource, Cruise Control generates an optimization proposal for the Kafka cluster based on the configured optimization goals.
Analyze the information in the optimization proposal and decide whether to approve it.
-
You have deployed Cruise Control to your Strimzi cluster.
-
You have configured optimization goals and, optionally, capacity limits on broker resources.
-
Create a
KafkaRebalance
resource:-
To use the default optimization goals defined in the
Kafka
resource, leave thespec
property empty:apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaRebalance metadata: name: my-rebalance labels: strimzi.io/cluster: my-cluster spec: {}
-
To configure user-provided optimization goals instead of using the default goals, add the
goals
property and enter one or more goals.In the following example, rack awareness and replica capacity are configured as user-provided optimization goals:
apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaRebalance metadata: name: my-rebalance labels: strimzi.io/cluster: my-cluster spec: goals: - RackAwareGoal - ReplicaCapacityGoal
-
To ignore the configured hard goals, add the
skipHardGoalCheck: true
property:apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaRebalance metadata: name: my-rebalance labels: strimzi.io/cluster: my-cluster spec: goals: - RackAwareGoal - ReplicaCapacityGoal skipHardGoalCheck: true
-
-
Create or update the resource:
kubectl apply -f your-file
The Cluster Operator requests the optimization proposal from Cruise Control. This might take a few minutes depending on the size of the Kafka cluster.
-
Check the status of the
KafkaRebalance
resource:kubectl describe kafkarebalance rebalance-cr-name
Cruise Control returns one of two statuses:
-
PendingProposal
: The rebalance operator is polling the Cruise Control API to check if the optimization proposal is ready. -
ProposalReady
: The optimization proposal is ready for review and, if desired, approval. The optimization proposal is contained in theStatus.Optimization Result
property of theKafkaRebalance
resource.
-
-
Review the optimization proposal.
kubectl describe kafkarebalance rebalance-cr-name
Here is an example proposal:
Status: Conditions: Last Transition Time: 2020-05-19T13:50:12.533Z Status: ProposalReady Type: State Observed Generation: 1 Optimization Result: Data To Move MB: 0 Excluded Brokers For Leadership: Excluded Brokers For Replica Move: Excluded Topics: Intra Broker Data To Move MB: 0 Monitored Partitions Percentage: 100 Num Intra Broker Replica Movements: 0 Num Leader Movements: 0 Num Replica Movements: 26 On Demand Balancedness Score After: 81.8666802863978 On Demand Balancedness Score Before: 78.01176356230222 Recent Windows: 1 Session Id: 05539377-ca7b-45ef-b359-e13564f1458c
The properties in the
Optimization Result
section describe the pending cluster rebalance operation. For descriptions of each property, see Contents of optimization proposals.
7.8. Approving an optimization proposal
You can approve an optimization proposal generated by Cruise Control, if its status is ProposalReady
.
Cruise Control will then apply the optimization proposal to the Kafka cluster, reassigning partitions to brokers and changing partition leadership.
Caution
|
This is not a dry run. Before you approve an optimization proposal, you must:
|
-
You have generated an optimization proposal from Cruise Control.
-
The
KafkaRebalance
custom resource status isProposalReady
.
Perform these steps for the optimization proposal that you want to approve:
-
Unless the optimization proposal is newly generated, check that it is based on current information about the state of the Kafka cluster. To do so, refresh the optimization proposal to make sure it uses the latest cluster metrics:
-
Annotate the
KafkaRebalance
resource in Kubernetes withrefresh
:kubectl annotate kafkarebalance rebalance-cr-name strimzi.io/rebalance=refresh
-
Check the status of the
KafkaRebalance
resource:kubectl describe kafkarebalance rebalance-cr-name
-
Wait until the status changes to
ProposalReady
.
-
-
Approve the optimization proposal that you want Cruise Control to apply.
Annotate the
KafkaRebalance
resource in Kubernetes:kubectl annotate kafkarebalance rebalance-cr-name strimzi.io/rebalance=approve
-
The Cluster Operator detects the annotated resource and instructs Cruise Control to rebalance the Kafka cluster.
-
Check the status of the
KafkaRebalance
resource:kubectl describe kafkarebalance rebalance-cr-name
-
Cruise Control returns one of three statuses:
-
Rebalancing: The cluster rebalance operation is in progress.
-
Ready: The cluster rebalancing operation completed successfully. To use the same
KafkaRebalance
custom resource to generate another optimization proposal, apply therefresh
annotation to the custom resource. This moves the custom resource to thePendingProposal
orProposalReady
state. You can then review the optimization proposal and approve it, if desired. -
NotReady: An error occurred—see Fixing problems with a
KafkaRebalance
resource.
-
7.9. Stopping a cluster rebalance
Once started, a cluster rebalance operation might take some time to complete and affect the overall performance of the Kafka cluster.
If you want to stop a cluster rebalance operation that is in progress, apply the stop
annotation to the KafkaRebalance
custom resource.
This instructs Cruise Control to finish the current batch of partition reassignments and then stop the rebalance.
When the rebalance has stopped, completed partition reassignments have already been applied; therefore, the state of the Kafka cluster is different when compared to prior to the start of the rebalance operation.
If further rebalancing is required, you should generate a new optimization proposal.
Note
|
The performance of the Kafka cluster in the intermediate (stopped) state might be worse than in the initial state. |
-
You have approved the optimization proposal by annotating the
KafkaRebalance
custom resource withapprove
. -
The status of the
KafkaRebalance
custom resource isRebalancing
.
-
Annotate the
KafkaRebalance
resource in Kubernetes:kubectl annotate kafkarebalance rebalance-cr-name strimzi.io/rebalance=stop
-
Check the status of the
KafkaRebalance
resource:kubectl describe kafkarebalance rebalance-cr-name
-
Wait until the status changes to
Stopped
.
7.10. Fixing problems with a KafkaRebalance
resource
If an issue occurs when creating a KafkaRebalance
resource or interacting with Cruise Control, the error is reported in the resource status, along with details of how to fix it.
The resource also moves to the NotReady
state.
To continue with the cluster rebalance operation, you must fix the problem in the KafkaRebalance
resource itself or with the overall Cruise Control deployment.
Problems might include the following:
-
A misconfigured parameter in the
KafkaRebalance
resource. -
The
strimzi.io/cluster
label for specifying the Kafka cluster in theKafkaRebalance
resource is missing. -
The Cruise Control server is not deployed as the
cruiseControl
property in theKafka
resource is missing. -
The Cruise Control server is not reachable.
After fixing the issue, you need to add the refresh
annotation to the KafkaRebalance
resource.
During a “refresh”, a new optimization proposal is requested from the Cruise Control server.
-
You have approved an optimization proposal.
-
The status of the
KafkaRebalance
custom resource for the rebalance operation isNotReady
.
-
Get information about the error from the
KafkaRebalance
status:kubectl describe kafkarebalance rebalance-cr-name
-
Attempt to resolve the issue in the
KafkaRebalance
resource. -
Annotate the
KafkaRebalance
resource in Kubernetes:kubectl annotate kafkarebalance rebalance-cr-name strimzi.io/rebalance=refresh
-
Check the status of the
KafkaRebalance
resource:kubectl describe kafkarebalance rebalance-cr-name
-
Wait until the status changes to
PendingProposal
, or directly toProposalReady
.
8. Distributed tracing
Distributed tracing allows you to track the progress of transactions between applications in a distributed system. In a microservices architecture, tracing tracks the progress of transactions between services. Trace data is useful for monitoring application performance and investigating issues with target systems and end-user applications.
In Strimzi, tracing facilitates the end-to-end tracking of messages: from source systems to Kafka, and then from Kafka to target systems and applications. It complements the metrics that are available to view in Grafana dashboards, as well as the component loggers.
How Strimzi supports tracing
Support for tracing is built in to the following components:
-
Kafka Connect
-
MirrorMaker
-
MirrorMaker 2.0
-
Strimzi Kafka Bridge
You enable and configure tracing for these components using template configuration properties in their custom resources.
To enable tracing in Kafka producers, consumers, and Kafka Streams API applications, you instrument application code using the OpenTracing Apache Kafka Client Instrumentation library (included with Strimzi). When instrumented, clients generate trace data; for example, when producing messages or writing offsets to the log.
Traces are sampled according to a sampling strategy and then visualized in the Jaeger user interface.
Note
|
Tracing is not supported for Kafka brokers. Setting up tracing for applications and systems beyond Strimzi is outside the scope of this chapter. To learn more about this subject, search for "inject and extract" in the OpenTracing documentation. |
Outline of procedures
To set up tracing for Strimzi, follow these procedures in order:
-
Set up tracing for clients:
-
Instrument clients with tracers:
-
Set up tracing for MirrorMaker, Kafka Connect, and the Kafka Bridge
-
The Jaeger backend components are deployed to your Kubernetes cluster. For deployment instructions, see the Jaeger deployment documentation.
8.1. Overview of OpenTracing and Jaeger
Strimzi uses the OpenTracing and Jaeger projects.
OpenTracing is an API specification that is independent from the tracing or monitoring system.
-
The OpenTracing APIs are used to instrument application code
-
Instrumented applications generate traces for individual transactions across the distributed system
-
Traces are composed of spans that define specific units of work over time
Jaeger is a tracing system for microservices-based distributed systems.
-
Jaeger implements the OpenTracing APIs and provides client libraries for instrumentation
-
The Jaeger user interface allows you to query, filter, and analyze trace data
8.2. Setting up tracing for Kafka clients
Initialize a Jaeger tracer to instrument your client applications for distributed tracing.
8.2.1. Initializing a Jaeger tracer for Kafka clients
Configure and initialize a Jaeger tracer using a set of tracing environment variables.
In each client application:
-
Add Maven dependencies for Jaeger to the
pom.xml
file for the client application:<dependency> <groupId>io.jaegertracing</groupId> <artifactId>jaeger-client</artifactId> <version>1.3.2</version> </dependency>
-
Define the configuration of the Jaeger tracer using the tracing environment variables.
-
Create the Jaeger tracer from the environment variables that you defined in step two:
Tracer tracer = Configuration.fromEnv().getTracer();
NoteFor alternative ways to initialize a Jaeger tracer, see the Java OpenTracing library documentation. -
Register the Jaeger tracer as a global tracer:
GlobalTracer.register(tracer);
A Jaeger tracer is now initialized for the client application to use.
8.2.2. Environment variables for tracing
Use these environment variables when configuring a Jaeger tracer for Kafka clients.
Note
|
The tracing environment variables are part of the Jaeger project and are subject to change. For the latest environment variables, see the Jaeger documentation. |
Property | Required | Description |
---|---|---|
|
Yes |
The name of the Jaeger tracer service. |
|
No |
The hostname for communicating with the |
|
No |
The port used for communicating with the |
|
No |
The |
|
No |
The authentication token to send to the endpoint as a bearer token. |
|
No |
The username to send to the endpoint if using basic authentication. |
|
No |
The password to send to the endpoint if using basic authentication. |
|
No |
A comma-separated list of formats to use for propagating the trace context. Defaults to the standard Jaeger format. Valid values are |
|
No |
Indicates whether the reporter should also log the spans. |
|
No |
The reporter’s maximum queue size. |
|
No |
The reporter’s flush interval, in ms. Defines how frequently the Jaeger reporter flushes span batches. |
|
No |
The sampling strategy to use for client traces:
To sample all traces, use the Constant sampling strategy with a parameter of 1. For more information, see the Jaeger documentation. |
|
No |
The sampler parameter (number). |
|
No |
The hostname and port to use if a Remote sampling strategy is selected. |
|
No |
A comma-separated list of tracer-level tags that are added to all reported spans. The value can also refer to an environment variable using the format |
8.3. Instrumenting Kafka clients with tracers
Instrument Kafka producer and consumer clients, and Kafka Streams API applications for distributed tracing.
8.3.1. Instrumenting producers and consumers for tracing
Use a Decorator pattern or Interceptors to instrument your Java producer and consumer application code for tracing.
In the application code of each producer and consumer application:
-
Add the Maven dependency for OpenTracing to the producer or consumer’s
pom.xml
file.<dependency> <groupId>io.opentracing.contrib</groupId> <artifactId>opentracing-kafka-client</artifactId> <version>0.1.15</version> </dependency>
-
Instrument your client application code using either a Decorator pattern or Interceptors.
-
To use a Decorator pattern:
// Create an instance of the KafkaProducer: KafkaProducer<Integer, String> producer = new KafkaProducer<>(senderProps); // Create an instance of the TracingKafkaProducer: TracingKafkaProducer<Integer, String> tracingProducer = new TracingKafkaProducer<>(producer, tracer); // Send: tracingProducer.send(...); // Create an instance of the KafkaConsumer: KafkaConsumer<Integer, String> consumer = new KafkaConsumer<>(consumerProps); // Create an instance of the TracingKafkaConsumer: TracingKafkaConsumer<Integer, String> tracingConsumer = new TracingKafkaConsumer<>(consumer, tracer); // Subscribe: tracingConsumer.subscribe(Collections.singletonList("messages")); // Get messages: ConsumerRecords<Integer, String> records = tracingConsumer.poll(1000); // Retrieve SpanContext from polled record (consumer side): ConsumerRecord<Integer, String> record = ... SpanContext spanContext = TracingKafkaUtils.extractSpanContext(record.headers(), tracer);
-
To use Interceptors:
// Register the tracer with GlobalTracer: GlobalTracer.register(tracer); // Add the TracingProducerInterceptor to the sender properties: senderProps.put(ProducerConfig.INTERCEPTOR_CLASSES_CONFIG, TracingProducerInterceptor.class.getName()); // Create an instance of the KafkaProducer: KafkaProducer<Integer, String> producer = new KafkaProducer<>(senderProps); // Send: producer.send(...); // Add the TracingConsumerInterceptor to the consumer properties: consumerProps.put(ConsumerConfig.INTERCEPTOR_CLASSES_CONFIG, TracingConsumerInterceptor.class.getName()); // Create an instance of the KafkaConsumer: KafkaConsumer<Integer, String> consumer = new KafkaConsumer<>(consumerProps); // Subscribe: consumer.subscribe(Collections.singletonList("messages")); // Get messages: ConsumerRecords<Integer, String> records = consumer.poll(1000); // Retrieve the SpanContext from a polled message (consumer side): ConsumerRecord<Integer, String> record = ... SpanContext spanContext = TracingKafkaUtils.extractSpanContext(record.headers(), tracer);
-
Custom span names in a Decorator pattern
A span is a logical unit of work in Jaeger, with an operation name, start time, and duration.
To use a Decorator pattern to instrument your producer and consumer applications, define custom span names by passing a BiFunction
object as an additional argument when creating the TracingKafkaProducer
and TracingKafkaConsumer
objects. The OpenTracing Apache Kafka Client Instrumentation library includes several built-in span names.
// Create a BiFunction for the KafkaProducer that operates on (String operationName, ProducerRecord consumerRecord) and returns a String to be used as the name:
BiFunction<String, ProducerRecord, String> producerSpanNameProvider =
(operationName, producerRecord) -> "CUSTOM_PRODUCER_NAME";
// Create an instance of the KafkaProducer:
KafkaProducer<Integer, String> producer = new KafkaProducer<>(senderProps);
// Create an instance of the TracingKafkaProducer
TracingKafkaProducer<Integer, String> tracingProducer = new TracingKafkaProducer<>(producer,
tracer,
producerSpanNameProvider);
// Spans created by the tracingProducer will now have "CUSTOM_PRODUCER_NAME" as the span name.
// Create a BiFunction for the KafkaConsumer that operates on (String operationName, ConsumerRecord consumerRecord) and returns a String to be used as the name:
BiFunction<String, ConsumerRecord, String> consumerSpanNameProvider =
(operationName, consumerRecord) -> operationName.toUpperCase();
// Create an instance of the KafkaConsumer:
KafkaConsumer<Integer, String> consumer = new KafkaConsumer<>(consumerProps);
// Create an instance of the TracingKafkaConsumer, passing in the consumerSpanNameProvider BiFunction:
TracingKafkaConsumer<Integer, String> tracingConsumer = new TracingKafkaConsumer<>(consumer,
tracer,
consumerSpanNameProvider);
// Spans created by the tracingConsumer will have the operation name as the span name, in upper-case.
// "receive" -> "RECEIVE"
Built-in span names
When defining custom span names, you can use the following BiFunctions
in the ClientSpanNameProvider
class. If no spanNameProvider
is specified, CONSUMER_OPERATION_NAME
and PRODUCER_OPERATION_NAME
are used.
BiFunction | Description |
---|---|
|
Returns the |
|
Returns a String concatenation of |
|
Returns the name of the topic that the message was sent to or retrieved from in the format |
|
Returns a String concatenation of |
|
Returns the operation name and the topic name: |
|
Returns a String concatenation of |
8.3.2. Instrumenting Kafka Streams applications for tracing
This section describes how to instrument Kafka Streams API applications for distributed tracing.
In each Kafka Streams API application:
-
Add the
opentracing-kafka-streams
dependency to the pom.xml file for your Kafka Streams API application:<dependency> <groupId>io.opentracing.contrib</groupId> <artifactId>opentracing-kafka-streams</artifactId> <version>0.1.15</version> </dependency>
-
Create an instance of the
TracingKafkaClientSupplier
supplier interface:KafkaClientSupplier supplier = new TracingKafkaClientSupplier(tracer);
-
Provide the supplier interface to
KafkaStreams
:KafkaStreams streams = new KafkaStreams(builder.build(), new StreamsConfig(config), supplier); streams.start();
8.4. Setting up tracing for MirrorMaker, Kafka Connect, and the Kafka Bridge
Distributed tracing is supported for MirrorMaker, MirrorMaker 2.0, Kafka Connect, and the Strimzi Kafka Bridge.
For MirrorMaker and MirrorMaker 2.0, messages are traced from the source cluster to the target cluster. The trace data records messages entering and leaving the MirrorMaker or MirrorMaker 2.0 component.
Only messages produced and consumed by Kafka Connect itself are traced. To trace messages sent between Kafka Connect and external systems, you must configure tracing in the connectors for those systems. For more information, see Configuring Kafka Connect.
Messages produced and consumed by the Kafka Bridge are traced. Incoming HTTP requests from client applications to send and receive messages through the Kafka Bridge are also traced. To have end-to-end tracing, you must configure tracing in your HTTP clients.
8.4.1. Enabling tracing in MirrorMaker, Kafka Connect, and Kafka Bridge resources
Update the configuration of KafkaMirrorMaker
, KafkaMirrorMaker2
, KafkaConnect
, and KafkaBridge
custom resources to specify and configure a Jaeger tracer service for each resource. Updating a tracing-enabled resource in your Kubernetes cluster triggers two events:
-
Interceptor classes are updated in the integrated consumers and producers in MirrorMaker, MirrorMaker 2.0, Kafka Connect, or the Strimzi Kafka Bridge.
-
For MirrorMaker, MirrorMaker 2.0, and Kafka Connect, the tracing agent initializes a Jaeger tracer based on the tracing configuration defined in the resource.
-
For the Kafka Bridge, a Jaeger tracer based on the tracing configuration defined in the resource is initialized by the Kafka Bridge itself.
Perform these steps for each KafkaMirrorMaker
, KafkaMirrorMaker2
, KafkaConnect
, and KafkaBridge
resource.
-
In the
spec.template
property, configure the Jaeger tracer service. For example:Jaeger tracer configuration for Kafka ConnectapiVersion: kafka.strimzi.io/v1beta2 kind: KafkaConnect metadata: name: my-connect-cluster spec: #... template: connectContainer: (1) env: - name: JAEGER_SERVICE_NAME value: my-jaeger-service - name: JAEGER_AGENT_HOST value: jaeger-agent-name - name: JAEGER_AGENT_PORT value: "6831" tracing: (2) type: jaeger #...
Jaeger tracer configuration for MirrorMakerapiVersion: kafka.strimzi.io/v1beta2 kind: KafkaMirrorMaker metadata: name: my-mirror-maker spec: #... template: mirrorMakerContainer: env: - name: JAEGER_SERVICE_NAME value: my-jaeger-service - name: JAEGER_AGENT_HOST value: jaeger-agent-name - name: JAEGER_AGENT_PORT value: "6831" tracing: type: jaeger #...
Jaeger tracer configuration for MirrorMaker 2.0apiVersion: kafka.strimzi.io/v1beta2 kind: KafkaMirrorMaker2 metadata: name: my-mm2-cluster spec: #... template: connectContainer: env: - name: JAEGER_SERVICE_NAME value: my-jaeger-service - name: JAEGER_AGENT_HOST value: jaeger-agent-name - name: JAEGER_AGENT_PORT value: "6831" tracing: type: jaeger #...
Jaeger tracer configuration for the Kafka BridgeapiVersion: kafka.strimzi.io/v1beta2 kind: KafkaBridge metadata: name: my-bridge spec: #... template: bridgeContainer: env: - name: JAEGER_SERVICE_NAME value: my-jaeger-service - name: JAEGER_AGENT_HOST value: jaeger-agent-name - name: JAEGER_AGENT_PORT value: "6831" tracing: type: jaeger #...
-
Use the tracing environment variables as template configuration properties.
-
Set the
spec.tracing.type
property tojaeger
.
-
-
Create or update the resource:
kubectl apply -f your-file
9. Managing TLS certificates
Strimzi supports TLS for encrypted communication between Kafka and Strimzi components.
Communication between Kafka brokers (interbroker communication), between ZooKeeper nodes (internodal communication), and between those components and the Strimzi operators is always encrypted. Communication between Kafka clients and Kafka brokers is encrypted according to how the cluster is configured. For the Kafka and Strimzi components, TLS certificates are also used for authentication.
The Cluster Operator automatically sets up and renews TLS certificates to enable encryption and authentication within your cluster. It also sets up other TLS certificates if you want to enable encryption or TLS authentication between Kafka brokers and clients.
Certificate Authority (CA) certificates are generated by the Cluster Operator to verify the identities of components and clients. If you don’t want to use the CAs generated by the Cluster Operator, you can install your own cluster and client CA certificates.
You can also provide Kafka listener certificates for TLS listeners or external listeners that have TLS encryption enabled. Use Kafka listener certificates to incorporate the security infrastructure you already have in place.
Note
|
Any certificates you provide are not renewed by the Cluster Operator. |
9.1. Certificate Authorities
To support encryption, each Strimzi component needs its own private keys and public key certificates. All component certificates are signed by an internal Certificate Authority (CA) called the cluster CA.
Similarly, each Kafka client application connecting to Strimzi using TLS client authentication needs to provide private keys and certificates. A second internal CA, named the clients CA, is used to sign certificates for the Kafka clients.
9.1.1. CA certificates
Both the cluster CA and clients CA have a self-signed public key certificate.
Kafka brokers are configured to trust certificates signed by either the cluster CA or clients CA. Components that clients do not need to connect to, such as ZooKeeper, only trust certificates signed by the cluster CA. Unless TLS encryption for external listeners is disabled, client applications must trust certificates signed by the cluster CA. This is also true for client applications that perform mutual TLS authentication.
By default, Strimzi automatically generates and renews CA certificates issued by the cluster CA or clients CA.
You can configure the management of these CA certificates in the Kafka.spec.clusterCa
and Kafka.spec.clientsCa
objects.
Certificates provided by users are not renewed.
You can provide your own CA certificates for the cluster CA or clients CA. For more information, see Installing your own CA certificates. If you provide your own certificates, you must manually renew them when needed.
9.1.2. Installing your own CA certificates
This procedure describes how to install your own CA certificates and keys instead of using the CA certificates and private keys generated by the Cluster Operator.
The Cluster Operator automatically generates and renews the following secrets:
CLUSTER-NAME-cluster-ca
-
The cluster secret that contains the private key for the cluster CA.
CLUSTER-NAME-cluster-ca-cert
-
The cluster secret that contains a cluster CA certificate. The certificate contains a public key to validate the identity of Kafka brokers.
CLUSTER-NAME-clients-ca
-
The client secret that contains the private key for the client CA.
CLUSTER-NAME-clients-ca-cert
-
The client secret that contains a client CA certificate. The certificate contains a public key to validate the identity of clients accessing the Kafka brokers.
Strimzi uses these secrets by default.
This procedure describes the steps to replace the secrets to use your own cluster or client CA certificates.
-
The Cluster Operator is running.
-
A Kafka cluster is not yet deployed.
-
Your own X.509 certificates and keys in PEM format for the cluster CA or clients CA.
-
If you want to use a cluster or clients CA which is not a Root CA, you have to include the whole chain in the certificate file. The chain should be in the following order:
-
The cluster or clients CA
-
One or more intermediate CAs
-
The root CA
-
-
All CAs in the chain should be configured using the X509v3 Basic Constraints extension. Basic Constraints limit the path length of a certificate chain.
-
-
The OpenSSL TLS management tool for converting certificates.
The Cluster Operator generates the following files for the CLUSTER-NAME-cluster-ca-cert
secret:
-
ca.crt
cluster certificate in PEM format -
ca.p12
cluster certificate in PKCS #12 format -
ca.password
to access the PKCS #12 file
Some applications cannot use PEM certificates and support only PKCS #12 certificates. You can also add your own cluster certificate in PKCS #12 format.
If you don’t have a cluster certificate in PKCS #12 format, use the OpenSSL TLS management tool to generate one from your ca.crt
file.
openssl pkcs12 -export -in ca.crt --nokeys -out ca.p12 -password pass:P12-PASSWORD -caname ca.crt
Replace P12-PASSWORD with your own password.
You can do the same for the CLUSTER-NAME-clients-ca-cert
secret, which also contains certificates in PEM and PKCS #12 format by default.
-
Replace the CA certificate generated by the Cluster Operator.
-
Delete the existing secret.
kubectl delete secret CA-CERTIFICATE-SECRET
CA-CERTIFICATE-SECRET is the name of the
Secret
:-
CLUSTER-NAME-cluster-ca-cert
for the cluster CA certificate -
CLUSTER-NAME-clients-ca-cert
for the clients CA certificate
Replace CLUSTER-NAME with the name of your Kafka cluster.
Ignore any "Not Exists" errors.
-
-
Create the new secret.
Client secret creation with a certificate in PEM format onlykubectl create secret generic CLUSTER-NAME-clients-ca-cert --from-file=ca.crt=ca.crt
Cluster secret creation with certificates in PEM and PKCS #12 formatkubectl create secret generic CLUSTER-NAME-cluster-ca-cert \ --from-file=ca.crt=ca.crt \ --from-file=ca.p12=ca.p12 \ --from-literal=ca.password=P12-PASSWORD
-
-
Replace the private key generated by the Cluster Operator.
-
Delete the existing secret.
kubectl delete secret CA-KEY-SECRET
CA-KEY-SECRET is the name of CA key:
-
CLUSTER-NAME-cluster-ca
for the cluster CA key -
CLUSTER-NAME-clients-ca
for the clients CA key
-
-
Create the new secret.
kubectl create secret generic CA-KEY-SECRET --from-file=ca.key=ca.key
-
-
Label the secrets.
kubectl label secret CA-CERTIFICATE-SECRET strimzi.io/kind=Kafka strimzi.io/cluster=CLUSTER-NAME
kubectl label secret CA-KEY-SECRET strimzi.io/kind=Kafka strimzi.io/cluster=CLUSTER-NAME
-
Label
strimzi.io/kind=Kafka
identifies the Kafka custom resource. -
Label
strimzi.io/cluster=CLUSTER-NAME
identifies the Kafka cluster.
-
-
Create the
Kafka
resource for your cluster, configuring either theKafka.spec.clusterCa
or theKafka.spec.clientsCa
object to not use generated CAs.Example fragmentKafka
resource configuring the cluster CA to use certificates you supply for yourselfkind: Kafka version: kafka.strimzi.io/v1beta2 spec: # ... clusterCa: generateCertificateAuthority: false
-
To renew CA certificates you have previously installed, see Renewing your own CA certificates.
9.2. Secrets
Strimzi uses secrets to store private and public key certificates for Kafka clusters, clients, and users. Secrets are used for establishing TLS encrypted connections between Kafka brokers, and between brokers and clients. They are also used for mutual TLS authentication.
Cluster and clients secrets are always pairs: one contains the public key and one contains the private key.
- Cluster secret
-
A cluster secret contains the cluster CA to sign Kafka broker certificates. Connecting clients use the certificate to establish a TLS encrypted connection with a Kafka cluster. The certificate verifies broker identity.
- Client secret
-
A client secret contains the clients CA for a user to sign its own client certificate. This allows mutual authentication against the Kafka cluster. The broker validates a client’s identity through the certificate.
- User secret
-
A user secret contains a private key and certificate. The secret is created and signed by the clients CA when a new user is created. The key and certificate are used to authenticate and authorize the user when accessing the cluster.
9.2.1. Secrets in PEM and PKCS #12 formats
Secrets provide private keys and certificates in PEM and PKCS #12 formats. Use the format that’s suitable for your client. Using private keys and certificates in PEM format means that users have to get them from the secrets, and generate a corresponding truststore or keystore to use in their applications. PKCS #12 storage provides a truststore or keystore that can be used directly.
PKCS #12 defines an archive file format (.p12
) for storing cryptography objects into a single file with password protection.
You can use PKCS #12 to manage certificates and keys in one place.
Each secret contains fields specific to PKCS #12.
-
The
.p12
field contains the certificates and keys. -
The
.password
field is the password that protects the archive.
All keys are 2048 bits in size and are valid by default for 365 days from initial generation. You can change the validity period.
9.2.2. Secrets generated by the Cluster Operator
The Cluster Operator generates the following certificates, which are saved as secrets in the Kubernetes cluster. Strimzi uses these secrets by default.
The cluster CA and clients CA have separate secrets for the private key and public key.
<cluster_name>-cluster-ca
-
Contains the private key of the cluster CA. Strimzi and Kafka components use the private key to sign server certificates.
<cluster_name>-cluster-ca-cert
-
Contains the public key of the cluster CA. Kafka clients use the public key to verify the identity of the Kafka brokers they are connecting to with TLS server authentication.
<cluster_name>-clients-ca
-
Contains the private key of the clients CA. Kafka clients use the private key to sign new user certificates for TLS client authentication when connecting to Kafka brokers.
<cluster_name>-clients-ca-cert
-
Contains the public key of the client CA. Kafka brokers use the public key to verify the identity of clients accessing the Kafka brokers when TLS client authentication is used.
Secrets for communication between Strimzi components contain a private key and a public key certificate signed by the cluster CA.
<cluster_name>-kafka-brokers
-
Contains the private and public keys for Kafka brokers.
<cluster_name>-zookeeper-nodes
-
Contains the private and public keys for ZooKeeper nodes.
<cluster_name>-cluster-operator-certs
-
Contains the private and public keys for encrypting communication between the Cluster Operator and Kafka or ZooKeeper.
<cluster_name>-entity-operator-certs
-
Contains the private and public keys for encrypting communication between the Entity Operator and Kafka or ZooKeeper.
<cluster_name>-cruise-control-certs
-
Contains the private and public keys for encrypting communication between Cruise Control and Kafka or ZooKeeper.
<cluster_name>-kafka-exporter-certs
-
Contains the private and public keys for encrypting communication between Kafka Exporter and Kafka or ZooKeeper.
Note
|
You can provide your own server certificates and private keys to connect to to Kafka brokers using Kafka listener certificates rather than certificates signed by the cluster CA or clients CA. |
9.2.3. Cluster CA secrets
Cluster CA secrets are managed by the Cluster Operator in a Kafka cluster.
Only the <cluster_name>-cluster-ca-cert
secret is required by clients.
All other cluster secrets are accessed by Strimzi components.
You can enforce this using Kubernetes role-based access controls, if necessary.
Note
|
The CA certificates in <cluster_name>-cluster-ca-cert must be trusted by Kafka client applications so that they validate the Kafka broker certificates when connecting to Kafka brokers over TLS.
|
Field | Description |
---|---|
|
The current private key for the cluster CA. |
Field | Description |
---|---|
|
PKCS #12 archive file for storing certificates and keys. |
|
Password for protecting the PKCS #12 archive file. |
|
The current certificate for the cluster CA. |
Field | Description |
---|---|
|
PKCS #12 archive file for storing certificates and keys. |
|
Password for protecting the PKCS #12 archive file. |
|
Certificate for a Kafka broker pod <num>. Signed by a current or former cluster CA private key in |
|
Private key for a Kafka broker pod |
Field | Description |
---|---|
|
PKCS #12 archive file for storing certificates and keys. |
|
Password for protecting the PKCS #12 archive file. |
|
Certificate for ZooKeeper node <num>. Signed by a current or former cluster CA private key in |
|
Private key for ZooKeeper pod |
Field | Description |
---|---|
|
PKCS #12 archive file for storing certificates and keys. |
|
Password for protecting the PKCS #12 archive file. |
|
Certificate for TLS communication between the Cluster Operator and Kafka or ZooKeeper.
Signed by a current or former cluster CA private key in |
|
Private key for TLS communication between the Cluster Operator and Kafka or ZooKeeper. |
Field | Description |
---|---|
|
PKCS #12 archive file for storing certificates and keys. |
|
Password for protecting the PKCS #12 archive file. |
|
Certificate for TLS communication between the Entity Operator and Kafka or ZooKeeper.
Signed by a current or former cluster CA private key in |
|
Private key for TLS communication between the Entity Operator and Kafka or ZooKeeper. |
Field | Description |
---|---|
|
PKCS #12 archive file for storing certificates and keys. |
|
Password for protecting the PKCS #12 archive file. |
|
Certificate for TLS communication between Cruise Control and Kafka or ZooKeeper.
Signed by a current or former cluster CA private key in |
|
Private key for TLS communication between the Cruise Control and Kafka or ZooKeeper. |
Field | Description |
---|---|
|
PKCS #12 archive file for storing certificates and keys. |
|
Password for protecting the PKCS #12 archive file. |
|
Certificate for TLS communication between Kafka Exporter and Kafka or ZooKeeper.
Signed by a current or former cluster CA private key in |
|
Private key for TLS communication between the Kafka Exporter and Kafka or ZooKeeper. |
9.2.4. Client CA secrets
Clients CA secrets are managed by the Cluster Operator in a Kafka cluster.
The certificates in <cluster_name>-clients-ca-cert
are those which the Kafka brokers trust.
The <cluster_name>-clients-ca
secret is used to sign the certificates of client applications.
This secret must be accessible to the Strimzi components and for administrative access if you are intending to issue application certificates without using the User Operator.
You can enforce this using Kubernetes role-based access controls, if necessary.
Field | Description |
---|---|
|
The current private key for the clients CA. |
Field | Description |
---|---|
|
PKCS #12 archive file for storing certificates and keys. |
|
Password for protecting the PKCS #12 archive file. |
|
The current certificate for the clients CA. |
9.2.5. User secrets
User secrets are managed by the User Operator.
When a user is created using the User Operator, a secret is generated using the name of the user.
Secret name | Field within secret | Description |
---|---|---|
|
|
PKCS #12 archive file for storing certificates and keys. |
|
Password for protecting the PKCS #12 archive file. |
|
|
Certificate for the user, signed by the clients CA |
|
|
Private key for the user |
9.2.6. Adding labels and annotations to cluster CA secrets
By configuring the clusterCaCert
template property in the Kafka
custom resource, you can add custom labels and annotations to the Cluster CA secrets created by the Cluster Operator.
Labels and annotations are useful for identifying objects and adding contextual information.
You configure template properties in Strimzi custom resources.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
name: my-cluster
spec:
kafka:
# ...
template:
clusterCaCert:
metadata:
labels:
label1: value1
label2: value2
annotations:
annotation1: value1
annotation2: value2
# ...
For more information on configuring template properties, see Customizing Kubernetes resources.
9.2.7. Disabling ownerReference
in the CA secrets
By default, the Cluster and Client CA secrets are created with an ownerReference
property that is set to the Kafka
custom resource.
This means that, when the Kafka
custom resource is deleted, the CA secrets are also deleted (garbage collected) by Kubernetes.
If you want to reuse the CA for a new cluster, you can disable the ownerReference
by setting the generateSecretOwnerReference
property for the Cluster and Client CA secrets to false
in the Kafka
configuration.
When the ownerReference
is disabled, CA secrets are not deleted by Kubernetes when the corresponding Kafka
custom resource is deleted.
ownerReference
for Cluster and Client CAsapiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
# ...
spec:
# ...
clusterCa:
generateSecretOwnerReference: false
clientsCa:
generateSecretOwnerReference: false
# ...
9.3. Certificate renewal and validity periods
Cluster CA and clients CA certificates are only valid for a limited time period, known as the validity period. This is usually defined as a number of days since the certificate was generated.
For CA certificates automatically created by the Cluster Operator, you can configure the validity period of:
-
Cluster CA certificates in
Kafka.spec.clusterCa.validityDays
-
Client CA certificates in
Kafka.spec.clientsCa.validityDays
The default validity period for both certificates is 365 days. Manually-installed CA certificates should have their own validity periods defined.
When a CA certificate expires, components and clients that still trust that certificate will not accept TLS connections from peers whose certificates were signed by the CA private key. The components and clients need to trust the new CA certificate instead.
To allow the renewal of CA certificates without a loss of service, the Cluster Operator will initiate certificate renewal before the old CA certificates expire.
You can configure the renewal period of the certificates created by the Cluster Operator:
-
Cluster CA certificates in
Kafka.spec.clusterCa.renewalDays
-
Client CA certificates in
Kafka.spec.clientsCa.renewalDays
The default renewal period for both certificates is 30 days.
The renewal period is measured backwards, from the expiry date of the current certificate.
Not Before Not After
| |
|<--------------- validityDays --------------->|
<--- renewalDays --->|
To make a change to the validity and renewal periods after creating the Kafka cluster, you configure and apply the Kafka
custom resource,
and manually renew the CA certificates.
If you do not manually renew the certificates, the new periods will be used the next time the certificate is renewed automatically.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
# ...
spec:
# ...
clusterCa:
renewalDays: 30
validityDays: 365
generateCertificateAuthority: true
clientsCa:
renewalDays: 30
validityDays: 365
generateCertificateAuthority: true
# ...
The behavior of the Cluster Operator during the renewal period depends on the settings for the certificate generation properties,
generateCertificateAuthority
and generateCertificateAuthority
.
true
-
If the properties are set to
true
, a CA certificate is generated automatically by the Cluster Operator, and renewed automatically within the renewal period. false
-
If the properties are set to
false
, a CA certificate is not generated by the Cluster Operator. Use this option if you are installing your own certificates.
9.3.1. Renewal process with automatically generated CA certificates
The Cluster Operator performs the following process to renew CA certificates:
-
Generate a new CA certificate, but retain the existing key. The new certificate replaces the old one with the name
ca.crt
within the correspondingSecret
. -
Generate new client certificates (for ZooKeeper nodes, Kafka brokers, and the Entity Operator). This is not strictly necessary because the signing key has not changed, but it keeps the validity period of the client certificate in sync with the CA certificate.
-
Restart ZooKeeper nodes so that they will trust the new CA certificate and use the new client certificates.
-
Restart Kafka brokers so that they will trust the new CA certificate and use the new client certificates.
-
Restart the Topic and User Operators so that they will trust the new CA certificate and use the new client certificates.
9.3.2. Client certificate renewal
The Cluster Operator is not aware of the client applications using the Kafka cluster.
When connecting to the cluster, and to ensure they operate correctly, client applications must:
-
Trust the cluster CA certificate published in the <cluster>-cluster-ca-cert Secret.
-
Use the credentials published in their <user-name> Secret to connect to the cluster.
The User Secret provides credentials in PEM and PKCS #12 format, or it can provide a password when using SCRAM-SHA authentication. The User Operator creates the user credentials when a user is created.
You must ensure clients continue to work after certificate renewal. The renewal process depends on how the clients are configured.
If you are provisioning client certificates and keys manually, you must generate new client certificates and ensure the new certificates are used by clients within the renewal period. Failure to do this by the end of the renewal period could result in client applications being unable to connect to the cluster.
Note
|
For workloads running inside the same Kubernetes cluster and namespace, Secrets can be mounted as a volume so the client Pods construct their keystores and truststores from the current state of the Secrets. For more details on this procedure, see Configuring internal clients to trust the cluster CA. |
9.3.3. Manually renewing the CA certificates generated by the Cluster Operator
Cluster and clients CA certificates generated by the Cluster Operator auto-renew at the start of their respective certificate renewal periods.
However, you can use the strimzi.io/force-renew
annotation to manually renew one or both of these certificates before the certificate renewal period starts.
You might do this for security reasons, or if you have changed the renewal or validity periods for the certificates.
A renewed certificate uses the same private key as the old certificate.
Note
|
If you are using your own CA certificates, the force-renew annotation cannot be used.
Instead, follow the procedure for renewing your own CA certificates.
|
-
The Cluster Operator is running.
-
A Kafka cluster in which CA certificates and private keys are installed.
-
Apply the
strimzi.io/force-renew
annotation to theSecret
that contains the CA certificate that you want to renew.Table 15. Annotation for the Secret that forces renewal of certificates Certificate Secret Annotate command Cluster CA
KAFKA-CLUSTER-NAME-cluster-ca-cert
kubectl annotate secret KAFKA-CLUSTER-NAME-cluster-ca-cert strimzi.io/force-renew=true
Clients CA
KAFKA-CLUSTER-NAME-clients-ca-cert
kubectl annotate secret KAFKA-CLUSTER-NAME-clients-ca-cert strimzi.io/force-renew=true
At the next reconciliation the Cluster Operator will generate a new CA certificate for the
Secret
that you annotated. If maintenance time windows are configured, the Cluster Operator will generate the new CA certificate at the first reconciliation within the next maintenance time window.Client applications must reload the cluster and clients CA certificates that were renewed by the Cluster Operator.
-
Check the period the CA certificate is valid:
For example, using an
openssl
command:kubectl get secret CA-CERTIFICATE-SECRET -o 'jsonpath={.data.CA-CERTIFICATE}' | base64 -d | openssl x509 -subject -issuer -startdate -enddate -noout
CA-CERTIFICATE-SECRET is the name of the
Secret
, which isKAFKA-CLUSTER-NAME-cluster-ca-cert
for the cluster CA certificate andKAFKA-CLUSTER-NAME-clients-ca-cert
for the clients CA certificate.CA-CERTIFICATE is the name of the CA certificate, such as
jsonpath={.data.ca\.crt}
.The command returns a
notBefore
andnotAfter
date, which is the validity period for the CA certificate.For example, for a cluster CA certificate:
subject=O = io.strimzi, CN = cluster-ca v0 issuer=O = io.strimzi, CN = cluster-ca v0 notBefore=Jun 30 09:43:54 2020 GMT notAfter=Jun 30 09:43:54 2021 GMT
-
Delete old certificates from the Secret.
When components are using the new certificates, older certificates might still be active. Delete the old certificates to remove any potential security risk.
9.3.4. Replacing private keys used by the CA certificates generated by the Cluster Operator
You can replace the private keys used by the cluster CA and clients CA certificates generated by the Cluster Operator. When a private key is replaced, the Cluster Operator generates a new CA certificate for the new private key.
Note
|
If you are using your own CA certificates, the force-replace annotation cannot be used.
Instead, follow the procedure for renewing your own CA certificates.
|
-
The Cluster Operator is running.
-
A Kafka cluster in which CA certificates and private keys are installed.
-
Apply the
strimzi.io/force-replace
annotation to theSecret
that contains the private key that you want to renew.Table 16. Commands for replacing private keys Private key for Secret Annotate command Cluster CA
CLUSTER-NAME-cluster-ca
kubectl annotate secret CLUSTER-NAME-cluster-ca strimzi.io/force-replace=true
Clients CA
CLUSTER-NAME-clients-ca
kubectl annotate secret CLUSTER-NAME-clients-ca strimzi.io/force-replace=true
At the next reconciliation the Cluster Operator will:
-
Generate a new private key for the
Secret
that you annotated -
Generate a new CA certificate
If maintenance time windows are configured, the Cluster Operator will generate the new private key and CA certificate at the first reconciliation within the next maintenance time window.
Client applications must reload the cluster and clients CA certificates that were renewed by the Cluster Operator.
9.3.5. Renewing your own CA certificates
This procedure describes how to renew CA certificates and keys you installed yourself, instead of using the certificates generated by the Cluster Operator.
If you are using your own certificates, the Cluster Operator will not renew them automatically. Therefore, it is important that you follow this procedure during the renewal period of the certificate in order to replace CA certificates that will soon expire.
The procedure describes the renewal of CA certificates in PEM format.
-
The Cluster Operator is running.
-
You have new cluster and clients X.509 certificates and keys in PEM format.
These could be generated using an openssl
command, such as:
openssl req -x509 -new -days NUMBER-OF-DAYS-VALID --nodes -out ca.crt -keyout ca.key
-
Check the details of the current CA certificates in the
Secret
:kubectl describe secret CA-CERTIFICATE-SECRET
CA-CERTIFICATE-SECRET is the name of the
Secret
, which isKAFKA-CLUSTER-NAME-cluster-ca-cert
for the cluster CA certificate andKAFKA-CLUSTER-NAME-clients-ca-cert
for the clients CA certificate. -
Create a directory to contain the existing CA certificates in the secret.
mkdir new-ca-cert-secret cd new-ca-cert-secret
-
Fetch the secret for each CA certificate you wish to renew:
kubectl get secret CA-CERTIFICATE-SECRET -o 'jsonpath={.data.CA-CERTIFICATE}' | base64 -d > CA-CERTIFICATE
Replace CA-CERTIFICATE with the name of each CA certificate.
-
Rename the old
ca.crt
file asca-DATE.crt
, where DATE is the certificate expiry date in the format YEAR-MONTH-DAYTHOUR-MINUTE-SECONDZ.For example
ca-2018-09-27T17-32-00Z.crt
.mv ca.crt ca-$(date -u -d"$(openssl x509 -enddate -noout -in ca.crt | sed 's/.*=//')" +'%Y-%m-%dT%H-%M-%SZ').crt
-
Copy your new CA certificate into the directory, naming it
ca.crt
:cp PATH-TO-NEW-CERTIFICATE ca.crt
-
Put your CA certificate in the corresponding
Secret
.-
Delete the existing secret:
kubectl delete secret CA-CERTIFICATE-SECRET
CA-CERTIFICATE-SECRET is the name of the
Secret
, as returned in the first step.Ignore any "Not Exists" errors.
-
Recreate the secret:
kubectl create secret generic CA-CERTIFICATE-SECRET --from-file=.
-
-
Delete the directory you created:
cd .. rm -r new-ca-cert-secret
-
Put your CA key in the corresponding
Secret
.-
Delete the existing secret:
kubectl delete secret CA-KEY-SECRET
CA-KEY-SECRET is the name of CA key, which is
KAFKA-CLUSTER-NAME-cluster-ca
for the cluster CA key andKAFKA-CLUSTER-NAME-clients-ca
for the clients CA key. -
Recreate the secret with the new CA key:
kubectl create secret generic CA-KEY-SECRET --from-file=ca.key=CA-KEY-SECRET-FILENAME
-
-
Label the secrets with the labels
strimzi.io/kind=Kafka
andstrimzi.io/cluster=KAFKA-CLUSTER-NAME
:kubectl label secret CA-CERTIFICATE-SECRET strimzi.io/kind=Kafka strimzi.io/cluster=KAFKA-CLUSTER-NAME kubectl label secret CA-KEY-SECRET strimzi.io/kind=Kafka strimzi.io/cluster=KAFKA-CLUSTER-NAME
9.4. TLS connections
9.4.1. ZooKeeper communication
Communication between the ZooKeeper nodes on all ports, as well as between clients and ZooKeeper, is encrypted using TLS.
Communication between Kafka brokers and ZooKeeper nodes is also encrypted.
9.4.2. Kafka inter-broker communication
Communication between Kafka brokers is always encrypted using TLS.
Unless the ControlPlaneListener
feature gate is enabled, all inter-broker communication goes through an internal listener on port 9091.
If you enable the feature gate, traffic from the control plane goes through an internal control plane listener on port 9090.
Traffic from the data plane continues to use the existing internal listener on port 9091.
These internal listeners are not available to Kafka clients.
9.4.3. Topic and User Operators
All Operators use encryption for communication with both Kafka and ZooKeeper. In Topic and User Operators, a TLS sidecar is used when communicating with ZooKeeper.
9.4.4. Cruise Control
Cruise Control uses encryption for communication with both Kafka and ZooKeeper. A TLS sidecar is used when communicating with ZooKeeper.
9.4.5. Kafka Client connections
Encrypted or unencrypted communication between Kafka brokers and clients is configured using the tls
property for spec.kafka.listeners
.
9.5. Configuring internal clients to trust the cluster CA
This procedure describes how to configure a Kafka client that resides inside the Kubernetes cluster — connecting to a TLS listener — to trust the cluster CA certificate.
The easiest way to achieve this for an internal client is to use a volume mount to access the Secrets
containing the necessary certificates and keys.
Follow the steps to configure trust certificates that are signed by the cluster CA for Java-based Kafka Producer, Consumer, and Streams APIs.
Choose the steps to follow according to the certificate format of the cluster CA: PKCS #12 (.p12
) or PEM (.crt
).
The steps describe how to mount the Cluster Secret that verifies the identity of the Kafka cluster to the client pod.
-
The Cluster Operator must be running.
-
There needs to be a
Kafka
resource within the Kubernetes cluster. -
You need a Kafka client application inside the Kubernetes cluster that will connect using TLS, and needs to trust the cluster CA certificate.
-
The client application must be running in the same namespace as the
Kafka
resource.
-
Mount the cluster Secret as a volume when defining the client pod.
For example:
kind: Pod apiVersion: v1 metadata: name: client-pod spec: containers: - name: client-name image: client-name volumeMounts: - name: secret-volume mountPath: /data/p12 env: - name: SECRET_PASSWORD valueFrom: secretKeyRef: name: my-secret key: my-password volumes: - name: secret-volume secret: secretName: my-cluster-cluster-ca-cert
Here we’re mounting:
-
The PKCS #12 file into an exact path, which can be configured
-
The password into an environment variable, where it can be used for Java configuration
-
-
Configure the Kafka client with the following properties:
-
A security protocol option:
-
security.protocol: SSL
when using TLS for encryption (with or without TLS authentication). -
security.protocol: SASL_SSL
when using SCRAM-SHA authentication over TLS.
-
-
ssl.truststore.location
with the truststore location where the certificates were imported. -
ssl.truststore.password
with the password for accessing the truststore. -
ssl.truststore.type=PKCS12
to identify the truststore type.
-
-
Mount the cluster Secret as a volume when defining the client pod.
For example:
kind: Pod apiVersion: v1 metadata: name: client-pod spec: containers: - name: client-name image: client-name volumeMounts: - name: secret-volume mountPath: /data/crt volumes: - name: secret-volume secret: secretName: my-cluster-cluster-ca-cert
-
Use the certificate with clients that use certificates in X.509 format.
9.6. Configuring external clients to trust the cluster CA
This procedure describes how to configure a Kafka client that resides outside the Kubernetes cluster – connecting to an external
listener – to trust the cluster CA certificate.
Follow this procedure when setting up the client and during the renewal period, when the old clients CA certificate is replaced.
Follow the steps to configure trust certificates that are signed by the cluster CA for Java-based Kafka Producer, Consumer, and Streams APIs.
Choose the steps to follow according to the certificate format of the cluster CA: PKCS #12 (.p12
) or PEM (.crt
).
The steps describe how to obtain the certificate from the Cluster Secret that verifies the identity of the Kafka cluster.
Important
|
The <cluster-name>-cluster-ca-cert Secret will contain more than one CA certificate during the CA certificate renewal period.
Clients must add all of them to their truststores.
|
-
The Cluster Operator must be running.
-
There needs to be a
Kafka
resource within the Kubernetes cluster. -
You need a Kafka client application outside the Kubernetes cluster that will connect using TLS, and needs to trust the cluster CA certificate.
-
Extract the cluster CA certificate and password from the
CLUSTER-NAME-cluster-ca-cert
Secret of the Kafka cluster.kubectl get secret CLUSTER-NAME-cluster-ca-cert -o jsonpath='{.data.ca\.p12}' | base64 -d > ca.p12
kubectl get secret CLUSTER-NAME-cluster-ca-cert -o jsonpath='{.data.ca\.password}' | base64 -d > ca.password
Replace CLUSTER-NAME with the name of the Kafka cluster.
-
Configure the Kafka client with the following properties:
-
A security protocol option:
-
security.protocol: SSL
when using TLS for encryption (with or without TLS authentication). -
security.protocol: SASL_SSL
when using SCRAM-SHA authentication over TLS.
-
-
ssl.truststore.location
with the truststore location where the certificates were imported. -
ssl.truststore.password
with the password for accessing the truststore. This property can be omitted if it is not needed by the truststore. -
ssl.truststore.type=PKCS12
to identify the truststore type.
-
-
Extract the cluster CA certificate from the
CLUSTER-NAME-cluster-ca-cert
Secret of the Kafka cluster.kubectl get secret CLUSTER-NAME-cluster-ca-cert -o jsonpath='{.data.ca\.crt}' | base64 -d > ca.crt
-
Use the certificate with clients that use certificates in X.509 format.
9.7. Kafka listener certificates
You can provide your own server certificates and private keys for the following types of listeners:
-
Internal TLS listeners for communication within the Kubernetes cluster
-
External listeners (
route
,loadbalancer
,ingress
, andnodeport
types), which have TLS encryption enabled, for communication between Kafka clients and Kafka brokers
These user-provided certificates are called Kafka listener certificates.
Providing Kafka listener certificates for external listeners allows you to leverage existing security infrastructure, such as your organization’s private CA or a public CA. Kafka clients will connect to Kafka brokers using Kafka listener certificates rather than certificates signed by the cluster CA or clients CA.
You must manually renew Kafka listener certificates when needed.
9.7.1. Providing your own Kafka listener certificates
This procedure shows how to configure a listener to use your own private key and server certificate, called a Kafka listener certificate.
Your client applications should use the CA public key as a trusted certificate in order to verify the identity of the Kafka broker.
-
A Kubernetes cluster.
-
The Cluster Operator is running.
-
For each listener, a compatible server certificate signed by an external CA.
-
Provide an X.509 certificate in PEM format.
-
Specify the correct Subject Alternative Names (SANs) for each listener. For more information, see Alternative subjects in server certificates for Kafka listeners.
-
You can provide a certificate that includes the whole CA chain in the certificate file.
-
-
Create a
Secret
containing your private key and server certificate:kubectl create secret generic my-secret --from-file=my-listener-key.key --from-file=my-listener-certificate.crt
-
Edit the
Kafka
resource for your cluster. Configure the listener to use yourSecret
, certificate file, and private key file in theconfiguration.brokerCertChainAndKey
property.Example configuration for aloadbalancer
external listener with TLS encryption enabled# ... listeners: - name: plain port: 9092 type: internal tls: false - name: external port: 9094 type: loadbalancer tls: true authentication: type: tls configuration: brokerCertChainAndKey: secretName: my-secret certificate: my-listener-certificate.crt key: my-listener-key.key # ...
Example configuration for a TLS listener# ... listeners: - name: plain port: 9092 type: internal tls: false - name: tls port: 9093 type: internal tls: true authentication: type: tls configuration: brokerCertChainAndKey: secretName: my-secret certificate: my-listener-certificate.crt key: my-listener-key.key # ...
-
Apply the new configuration to create or update the resource:
kubectl apply -f kafka.yaml
The Cluster Operator starts a rolling update of the Kafka cluster, which updates the configuration of the listeners.
NoteA rolling update is also started if you update a Kafka listener certificate in a Secret
that is already used by a TLS or external listener.
9.7.2. Alternative subjects in server certificates for Kafka listeners
In order to use TLS hostname verification with your own Kafka listener certificates, you must use the correct Subject Alternative Names (SANs) for each listener. The certificate SANs must specify hostnames for:
-
All of the Kafka brokers in your cluster
-
The Kafka cluster bootstrap service
You can use wildcard certificates if they are supported by your CA.
TLS listener SAN examples
Use the following examples to help you specify hostnames of the SANs in your certificates for TLS listeners.
//Kafka brokers
*.<cluster-name>-kafka-brokers
*.<cluster-name>-kafka-brokers.<namespace>.svc
// Bootstrap service
<cluster-name>-kafka-bootstrap
<cluster-name>-kafka-bootstrap.<namespace>.svc
// Kafka brokers
<cluster-name>-kafka-0.<cluster-name>-kafka-brokers
<cluster-name>-kafka-0.<cluster-name>-kafka-brokers.<namespace>.svc
<cluster-name>-kafka-1.<cluster-name>-kafka-brokers
<cluster-name>-kafka-1.<cluster-name>-kafka-brokers.<namespace>.svc
# ...
// Bootstrap service
<cluster-name>-kafka-bootstrap
<cluster-name>-kafka-bootstrap.<namespace>.svc
External listener SAN examples
For external listeners which have TLS encryption enabled, the hostnames you need to specify in certificates depends on the external listener type
.
External listener type | In the SANs, specify… |
---|---|
|
Addresses of all Kafka broker You can use a matching wildcard name. |
|
Addresses of all Kafka broker You can use a matching wildcard name. |
|
Addresses of all Kubernetes worker nodes that the Kafka broker pods might be scheduled to. You can use a matching wildcard name. |
10. Managing Strimzi
This chapter covers tasks to maintain a deployment of Strimzi.
10.1. Working with custom resources
You can use kubectl
commands to retrieve information and perform other operations on Strimzi custom resources.
Using kubectl
with the status
subresource of a custom resource allows you to get the information about the resource.
10.1.1. Performing kubectl
operations on custom resources
Use kubectl
commands, such as get
, describe
, edit
, or delete
, to perform operations on resource types.
For example, kubectl get kafkatopics
retrieves a list of all Kafka topics and kubectl get kafkas
retrieves all deployed Kafka clusters.
When referencing resource types, you can use both singular and plural names:
kubectl get kafkas
gets the same results as kubectl get kafka
.
You can also use the short name of the resource.
Learning short names can save you time when managing Strimzi.
The short name for Kafka
is k
, so you can also run kubectl get k
to list all Kafka clusters.
kubectl get k
NAME DESIRED KAFKA REPLICAS DESIRED ZK REPLICAS
my-cluster 3 3
Strimzi resource | Long name | Short name |
---|---|---|
Kafka |
kafka |
k |
Kafka Topic |
kafkatopic |
kt |
Kafka User |
kafkauser |
ku |
Kafka Connect |
kafkaconnect |
kc |
Kafka Connector |
kafkaconnector |
kctr |
Kafka Mirror Maker |
kafkamirrormaker |
kmm |
Kafka Mirror Maker 2 |
kafkamirrormaker2 |
kmm2 |
Kafka Bridge |
kafkabridge |
kb |
Kafka Rebalance |
kafkarebalance |
kr |
Resource categories
Categories of custom resources can also be used in kubectl
commands.
All Strimzi custom resources belong to the category strimzi
, so you can use strimzi
to get all the Strimzi resources with one command.
For example, running kubectl get strimzi
lists all Strimzi custom resources in a given namespace.
kubectl get strimzi
NAME DESIRED KAFKA REPLICAS DESIRED ZK REPLICAS
kafka.kafka.strimzi.io/my-cluster 3 3
NAME PARTITIONS REPLICATION FACTOR
kafkatopic.kafka.strimzi.io/kafka-apps 3 3
NAME AUTHENTICATION AUTHORIZATION
kafkauser.kafka.strimzi.io/my-user tls simple
The kubectl get strimzi -o name
command returns all resource types and resource names.
The -o name
option fetches the output in the type/name format
kubectl get strimzi -o name
kafka.kafka.strimzi.io/my-cluster
kafkatopic.kafka.strimzi.io/kafka-apps
kafkauser.kafka.strimzi.io/my-user
You can combine this strimzi
command with other commands.
For example, you can pass it into a kubectl delete
command to delete all resources in a single command.
kubectl delete $(kubectl get strimzi -o name)
kafka.kafka.strimzi.io "my-cluster" deleted
kafkatopic.kafka.strimzi.io "kafka-apps" deleted
kafkauser.kafka.strimzi.io "my-user" deleted
Deleting all resources in a single operation might be useful, for example, when you are testing new Strimzi features.
Querying the status of sub-resources
There are other values you can pass to the -o
option.
For example, by using -o yaml
you get the output in YAML format.
Usng -o json
will return it as JSON.
You can see all the options in kubectl get --help
.
One of the most useful options is the JSONPath support, which allows you to pass JSONPath expressions to query the Kubernetes API. A JSONPath expression can extract or navigate specific parts of any resource.
For example, you can use the JSONPath expression {.status.listeners[?(@.type=="tls")].bootstrapServers}
to get the bootstrap address from the status of the Kafka custom resource and use it in your Kafka clients.
Here, the command finds the bootstrapServers
value of the tls
listeners.
kubectl get kafka my-cluster -o=jsonpath='{.status.listeners[?(@.type=="tls")].bootstrapServers}{"\n"}'
my-cluster-kafka-bootstrap.myproject.svc:9093
By changing the type condition to @.type=="external"
or @.type=="plain"
you can also get the address of the other Kafka listeners.
kubectl get kafka my-cluster -o=jsonpath='{.status.listeners[?(@.type=="external")].bootstrapServers}{"\n"}'
192.168.1.247:9094
You can use jsonpath
to extract any other property or group of properties from any custom resource.
10.1.2. Strimzi custom resource status information
Several resources have a status
property, as described in the following table.
Strimzi resource | Schema reference | Publishes status information on… |
---|---|---|
|
The Kafka cluster. |
|
|
The Kafka Connect cluster, if deployed. |
|
|
KafkaConnector resources, if deployed. |
|
|
The Kafka MirrorMaker tool, if deployed. |
|
|
Kafka topics in your Kafka cluster. |
|
|
Kafka users in your Kafka cluster. |
|
|
The Strimzi Kafka Bridge, if deployed. |
The status
property of a resource provides information on the resource’s:
-
Current state, in the
status.conditions
property -
Last observed generation, in the
status.observedGeneration
property
The status
property also provides resource-specific information. For example:
-
KafkaStatus
provides information on listener addresses, and the id of the Kafka cluster. -
KafkaConnectStatus
provides the REST API endpoint for Kafka Connect connectors. -
KafkaUserStatus
provides the user name of the Kafka user and theSecret
in which their credentials are stored. -
KafkaBridgeStatus
provides the HTTP address at which external client applications can access the Bridge service.
A resource’s current state is useful for tracking progress related to the resource achieving its desired state, as defined by the spec
property. The status conditions provide the time and reason the state of the resource changed and details of events preventing or delaying the operator from realizing the resource’s desired state.
The last observed generation is the generation of the resource that was last reconciled by the Cluster Operator. If the value of observedGeneration
is different from the value of metadata.generation
, the operator has not yet processed the latest update to the resource. If these values are the same, the status information reflects the most recent changes to the resource.
Strimzi creates and maintains the status of custom resources, periodically evaluating the current state of the custom resource and updating its status accordingly.
When performing an update on a custom resource using kubectl edit
, for example, its status
is not editable. Moreover, changing the status
would not affect the configuration of the Kafka cluster.
Here we see the status
property specified for a Kafka custom resource.
apiVersion: kafka.strimzi.io/v1beta2
kind: Kafka
metadata:
spec:
# ...
status:
conditions: (1)
- lastTransitionTime: 2021-07-23T23:46:57+0000
status: "True"
type: Ready (2)
observedGeneration: 4 (3)
listeners: (4)
- addresses:
- host: my-cluster-kafka-bootstrap.myproject.svc
port: 9092
type: plain
- addresses:
- host: my-cluster-kafka-bootstrap.myproject.svc
port: 9093
certificates:
- |
-----BEGIN CERTIFICATE-----
...
-----END CERTIFICATE-----
type: tls
- addresses:
- host: 172.29.49.180
port: 9094
certificates:
- |
-----BEGIN CERTIFICATE-----
...
-----END CERTIFICATE-----
type: external
clusterId: CLUSTER-ID (5)
# ...
-
Status
conditions
describe criteria related to the status that cannot be deduced from the existing resource information, or are specific to the instance of a resource. -
The
Ready
condition indicates whether the Cluster Operator currently considers the Kafka cluster able to handle traffic. -
The
observedGeneration
indicates the generation of theKafka
custom resource that was last reconciled by the Cluster Operator. -
The
listeners
describe the current Kafka bootstrap addresses by type. -
The Kafka cluster id.
ImportantThe address in the custom resource status for external listeners with type nodeport
is currently not supported.
Note
|
The Kafka bootstrap addresses listed in the status do not signify that those endpoints or the Kafka cluster is in a ready state. |
You can access status information for a resource from the command line. For more information, see Finding the status of a custom resource.
10.1.3. Finding the status of a custom resource
This procedure describes how to find the status of a custom resource.
-
A Kubernetes cluster.
-
The Cluster Operator is running.
-
Specify the custom resource and use the
-o jsonpath
option to apply a standard JSONPath expression to select thestatus
property:kubectl get kafka <kafka_resource_name> -o jsonpath='{.status}'
This expression returns all the status information for the specified custom resource. You can use dot notation, such as
status.listeners
orstatus.observedGeneration
, to fine-tune the status information you wish to see.
-
For more information about using JSONPath, see JSONPath support.
10.2. Pausing reconciliation of custom resources
Sometimes it is useful to pause the reconciliation of custom resources managed by Strimzi Operators, so that you can perform fixes or make updates. If reconciliations are paused, any changes made to custom resources are ignored by the Operators until the pause ends.
If you want to pause reconciliation of a custom resource, set the strimzi.io/pause-reconciliation
annotation to true
in its configuration.
This instructs the appropriate Operator to pause reconciliation of the custom resource.
For example, you can apply the annotation to the KafkaConnect
resource so that reconciliation by the Cluster Operator is paused.
You can also create a custom resource with the pause annotation enabled. The custom resource is created, but it is ignored.
-
The Strimzi Operator that manages the custom resource is running.
-
Annotate the custom resource in Kubernetes, setting
pause-reconciliation
totrue
:kubectl annotate KIND-OF-CUSTOM-RESOURCE NAME-OF-CUSTOM-RESOURCE strimzi.io/pause-reconciliation="true"
For example, for the
KafkaConnect
custom resource:kubectl annotate KafkaConnect my-connect strimzi.io/pause-reconciliation="true"
-
Check that the status conditions of the custom resource show a change to
ReconciliationPaused
:kubectl describe KIND-OF-CUSTOM-RESOURCE NAME-OF-CUSTOM-RESOURCE
The
type
condition changes toReconciliationPaused
at thelastTransitionTime
.Example custom resource with a paused reconciliation condition typeapiVersion: kafka.strimzi.io/v1beta2 kind: KafkaConnect metadata: annotations: strimzi.io/pause-reconciliation: "true" strimzi.io/use-connector-resources: "true" creationTimestamp: 2021-03-12T10:47:11Z #... spec: # ... status: conditions: - lastTransitionTime: 2021-03-12T10:47:41.689249Z status: "True" type: ReconciliationPaused
-
To resume reconciliation, you can set the annotation to
false
, or remove the annotation.
10.3. Evicting pods with Strimzi Drain Cleaner
Kafka and ZooKeeper pods might be evicted during Kubernetes upgrades, maintenance or pod rescheduling.
If your Kafka broker and ZooKeeper pods were deployed by Strimzi, you can use the Strimzi Drain Cleaner tool to handle the pod evictions.
You need to set the podDisruptionBudget
for your Kafka deployment to 0
(zero) for the Strimzi Drain Cleaner to work.
By deploying the Strimzi Drain Cleaner, you can use the Cluster Operator to move Kafka pods instead of Kubernetes. The Cluster Operator ensures that topics are never under-replicated. Kafka can remain operational during the eviction process. The Cluster Operator waits for topics to synchronize, as the Kubernetes worker nodes drain consecutively.
An admission webhook notifies the Strimzi Drain Cleaner of pod eviction requests to the Kubernetes API. The Strimzi Drain Cleaner then adds a rolling update annotation to the pods to be drained. This informs the Cluster Operator to perform a rolling update of an evicted pod.
Note
|
If you are not using the Strimzi Drain Cleaner, you can add pod annotations to perform rolling updates manually. |
The Strimzi Drain Cleaner deployment files include a ValidatingWebhookConfiguration
resource file.
The resource provides the configuration for registering the webhook with the Kubernetes API.
The configuration defines the rules
for the Kubernetes API to follow in the event of a pod eviction request.
The rules specify that only CREATE
operations related to pods/eviction
sub-resources are intercepted.
If these rules are met, the API forwards the notification.
The clientConfig
points to the Strimzi Drain Cleaner service and /drainer
endpoint that exposes the webhook.
The webhook uses a secure TLS connection, which requires authentication.
The caBundle
property specifies the certificate chain to validate HTTPS communication.
Certificates are encoded in Base64.
apiVersion: admissionregistration.k8s.io/v1
kind: ValidatingWebhookConfiguration
# ...
webhooks:
- name: strimzi-drain-cleaner.strimzi.io
rules:
- apiGroups: [""]
apiVersions: ["v1"]
operations: ["CREATE"]
resources: ["pods/eviction"]
scope: "Namespaced"
clientConfig:
service:
namespace: "strimzi-drain-cleaner"
name: "strimzi-drain-cleaner"
path: /drainer
port: 443
caBundle: Cg==
# ...
10.3.1. Prerequisites
To deploy and use the Strimzi Drain Cleaner, you need to download the deployment files.
The Strimzi Drain Cleaner deployment files are accessible from the GitHub release archive.
10.3.2. Deploying the Strimzi Drain Cleaner
Deploy the Strimzi Drain Cleaner to the Kubernetes cluster where the Cluster Operator and Kafka cluster are running.
-
You have downloaded the Strimzi Drain Cleaner deployment files.
-
You have a highly available Kafka cluster deployment running with Kubernetes worker nodes that you would like to update.
-
Topics are replicated for high availability.
Topic configuration specifies a replication factor of at least 3 and a minimum number of in-sync replicas to 1 less than the replication factor.
Kafka topic replicated for high availabilityapiVersion: kafka.strimzi.io/v1beta2 kind: KafkaTopic metadata: name: my-topic labels: strimzi.io/cluster: my-cluster spec: partitions: 1 replicas: 3 config: # ... min.insync.replicas: 2 # ...
If you don’t want to include ZooKeeper, you can remove the --zookeeper
command option from the Strimzi Drain Cleaner Deployment
configuration file.
apiVersion: apps/v1
kind: Deployment
spec:
# ...
template:
spec:
serviceAccountName: strimzi-drain-cleaner
containers:
- name: strimzi-drain-cleaner
# ...
command:
- "/application"
- "-Dquarkus.http.host=0.0.0.0"
- "--kafka"
- "--zookeeper" (1)
# ...
-
Remove this option to exclude ZooKeeper from Strimzi Drain Cleaner operations.
-
Configure a pod disruption budget of
0
(zero) for your Kafka deployment usingtemplate
settings in theKafka
resource.Specifying a pod disruption budgetapiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster namespace: myproject spec: kafka: template: podDisruptionBudget: maxUnavailable: 0 # ... zookeeper: template: podDisruptionBudget: maxUnavailable: 0 # ...
Reducing the maximum pod disruption budget to zero prevents Kubernetes from automatically evicting the pods in case of voluntary disruptions, so pods must be evicted by the Strimzi Drain Cleaner.
Add the same configuration for ZooKeeper if you want to use Strimzi Drain Cleaner to drain ZooKeeper nodes.
-
Update the
Kafka
resource:kubectl apply -f <kafka-configuration-file>
-
Deploy the Strimzi Drain Cleaner.
You can use
cert-manager
in the deployment process.-
If you are using
cert-manager
with Kubernetes, apply the resources in the/install/drain-cleaner/certmanager
directory.kubectl apply -f ./install/drain-cleaner/certmanager
The TLS certificates for the webhook are generated automatically and injected into the webhook configuration.
-
If you are using OpenShift, apply the resources in the
/install/drain-cleaner/openshift
directory.kubectl apply -f ./install/drain-cleaner/openshift
-
If you are not using
cert-manager
with Kubernetes, apply the resources in the/install/drain-cleaner/kubernetes
directory.kubectl apply -f ./install/drain-cleaner/kubernetes
The resources are configured with TLS certificates that have already been generated. Use these certificates if you are not changing any configuration for the Strimzi Drain Cleaner, such as namespaces, service names, or pod names.
NoteYou can use the build script and files provided in webhook-certificates
to generate your own certificates. The script uses theCFSSL
and openSSL tools to generate the certificates. After you have generated the certificates, you need to add them to the040-Secret.yaml
and070-ValidatingWebhookConfiguration.yaml
files.
-
10.3.3. Using the Strimzi Drain Cleaner
Use the Strimzi Drain Cleaner in combination with the Cluster Operator to move Kafka broker or ZooKeeper pods from nodes that are being drained. When you run the Strimzi Drain Cleaner, it annotates pods with a rolling update pod annotation. The Cluster Operator performs rolling updates based on the annotation.
-
You have deployed the Strimzi Drain Cleaner.
-
Drain a specified Kubernetes node hosting the Kafka broker or ZooKeeper pods.
kubectl get nodes kubectl drain <name-of-node> --delete-emptydir-data --ignore-daemonsets --timeout=6000s --force
-
Check the eviction events in the Strimzi Drain Cleaner log to verify that the pods have been annotated for restart.
Strimzi Drain Cleaner log show annotations of podsINFO ... Received eviction webhook for Pod my-cluster-zookeeper-2 in namespace my-project INFO ... Pod my-cluster-zookeeper-2 in namespace my-project will be annotated for restart INFO ... Pod my-cluster-zookeeper-2 in namespace my-project found and annotated for restart INFO ... Received eviction webhook for Pod my-cluster-kafka-0 in namespace my-project INFO ... Pod my-cluster-kafka-0 in namespace my-project will be annotated for restart INFO ... Pod my-cluster-kafka-0 in namespace my-project found and annotated for restart
-
Check the reconciliation events in the Cluster Operator log to verify the rolling updates.
Cluster Operator log shows rolling updatesINFO PodOperator:68 - Reconciliation #13(timer) Kafka(my-project/my-cluster): Rolling Pod my-cluster-zookeeper-2 INFO PodOperator:68 - Reconciliation #13(timer) Kafka(my-project/my-cluster): Rolling Pod my-cluster-kafka-0 INFO AbstractOperator:500 - Reconciliation #13(timer) Kafka(my-project/my-cluster): reconciled
10.4. Manually starting rolling updates of Kafka and ZooKeeper clusters
Strimzi supports the use of annotations on StatefulSet
and Pod
resources to manually trigger a rolling update of Kafka and ZooKeeper clusters through the Cluster Operator.
Rolling updates restart the pods of the resource with new ones.
Manually performing a rolling update on a specific pod or set of pods from the same StatefulSet
is usually only required in exceptional circumstances.
However, rather than deleting the pods directly, if you perform the rolling update through the Cluster Operator you ensure that:
-
The manual deletion of the pod does not conflict with simultaneous Cluster Operator operations, such as deleting other pods in parallel.
-
The Cluster Operator logic handles the Kafka configuration specifications, such as the number of in-sync replicas.
10.4.1. Prerequisites
To perform a manual rolling update, you need a running Cluster Operator and Kafka cluster.
See the Deploying and Upgrading Strimzi guide for instructions on running a:
10.4.2. Performing a rolling update using a StatefulSet annotation
This procedure describes how to manually trigger a rolling update of an existing Kafka cluster or ZooKeeper cluster using a Kubernetes StatefulSet
annotation.
-
Find the name of the
StatefulSet
that controls the Kafka or ZooKeeper pods you want to manually update.For example, if your Kafka cluster is named my-cluster, the corresponding
StatefulSet
names are my-cluster-kafka and my-cluster-zookeeper. -
Annotate the
StatefulSet
resource in Kubernetes.Use
kubectl annotate
:kubectl annotate statefulset cluster-name-kafka strimzi.io/manual-rolling-update=true kubectl annotate statefulset cluster-name-zookeeper strimzi.io/manual-rolling-update=true
-
Wait for the next reconciliation to occur (every two minutes by default). A rolling update of all pods within the annotated
StatefulSet
is triggered, as long as the annotation was detected by the reconciliation process. When the rolling update of all the pods is complete, the annotation is removed from theStatefulSet
.
10.4.3. Performing a rolling update using a Pod annotation
This procedure describes how to manually trigger a rolling update of an existing Kafka cluster or ZooKeeper cluster using a Kubernetes Pod
annotation.
When multiple pods from the same StatefulSet
are annotated, consecutive rolling updates are performed within the same reconciliation run.
You can perform a rolling update on a Kafka cluster regardless of the topic replication factor used. But for Kafka to stay operational during the update, you’ll need the following:
-
A highly available Kafka cluster deployment running with nodes that you wish to update.
-
Topics replicated for high availability.
Topic configuration specifies a replication factor of at least 3 and a minimum number of in-sync replicas to 1 less than the replication factor.
Kafka topic replicated for high availabilityapiVersion: kafka.strimzi.io/v1beta2 kind: KafkaTopic metadata: name: my-topic labels: strimzi.io/cluster: my-cluster spec: partitions: 1 replicas: 3 config: # ... min.insync.replicas: 2 # ...
-
Find the name of the Kafka or ZooKeeper
Pod
you want to manually update.For example, if your Kafka cluster is named my-cluster, the corresponding
Pod
names are my-cluster-kafka-index and my-cluster-zookeeper-index. The index starts at zero and ends at the total number of replicas minus one. -
Annotate the
Pod
resource in Kubernetes.Use
kubectl annotate
:kubectl annotate pod cluster-name-kafka-index strimzi.io/manual-rolling-update=true kubectl annotate pod cluster-name-zookeeper-index strimzi.io/manual-rolling-update=true
-
Wait for the next reconciliation to occur (every two minutes by default). A rolling update of the annotated
Pod
is triggered, as long as the annotation was detected by the reconciliation process. When the rolling update of a pod is complete, the annotation is removed from thePod
.
10.5. Discovering services using labels and annotations
Service discovery makes it easier for client applications running in the same Kubernetes cluster as Strimzi to interact with a Kafka cluster.
A service discovery label and annotation is generated for services used to access the Kafka cluster:
-
Internal Kafka bootstrap service
-
HTTP Bridge service
The label helps to make the service discoverable, and the annotation provides connection details that a client application can use to make the connection.
The service discovery label, strimzi.io/discovery
, is set as true
for the Service
resources.
The service discovery annotation has the same key, providing connection details in JSON format for each service.
Example internal Kafka bootstrap service
apiVersion: v1
kind: Service
metadata:
annotations:
strimzi.io/discovery: |-
[ {
"port" : 9092,
"tls" : false,
"protocol" : "kafka",
"auth" : "scram-sha-512"
}, {
"port" : 9093,
"tls" : true,
"protocol" : "kafka",
"auth" : "tls"
} ]
labels:
strimzi.io/cluster: my-cluster
strimzi.io/discovery: "true"
strimzi.io/kind: Kafka
strimzi.io/name: my-cluster-kafka-bootstrap
name: my-cluster-kafka-bootstrap
spec:
#...
Example HTTP Bridge service
apiVersion: v1
kind: Service
metadata:
annotations:
strimzi.io/discovery: |-
[ {
"port" : 8080,
"tls" : false,
"auth" : "none",
"protocol" : "http"
} ]
labels:
strimzi.io/cluster: my-bridge
strimzi.io/discovery: "true"
strimzi.io/kind: KafkaBridge
strimzi.io/name: my-bridge-bridge-service
10.5.1. Returning connection details on services
You can find the services by specifying the discovery label when fetching services from the command line or a corresponding API call.
kubectl get service -l strimzi.io/discovery=true
The connection details are returned when retrieving the service discovery label.
10.6. Recovering a cluster from persistent volumes
You can recover a Kafka cluster from persistent volumes (PVs) if they are still present.
You might want to do this, for example, after:
-
A namespace was deleted unintentionally
-
A whole Kubernetes cluster is lost, but the PVs remain in the infrastructure
10.6.1. Recovery from namespace deletion
Recovery from namespace deletion is possible because of the relationship between persistent volumes and namespaces.
A PersistentVolume
(PV) is a storage resource that lives outside of a namespace.
A PV is mounted into a Kafka pod using a PersistentVolumeClaim
(PVC), which lives inside a namespace.
The reclaim policy for a PV tells a cluster how to act when a namespace is deleted. If the reclaim policy is set as:
-
Delete (default), PVs are deleted when PVCs are deleted within a namespace
-
Retain, PVs are not deleted when a namespace is deleted
To ensure that you can recover from a PV if a namespace is deleted unintentionally, the policy must be reset from Delete to Retain in the PV specification using the persistentVolumeReclaimPolicy
property:
apiVersion: v1
kind: PersistentVolume
# ...
spec:
# ...
persistentVolumeReclaimPolicy: Retain
Alternatively, PVs can inherit the reclaim policy of an associated storage class. Storage classes are used for dynamic volume allocation.
By configuring the reclaimPolicy
property for the storage class, PVs that use the storage class are created with the appropriate reclaim policy.
The storage class is configured for the PV using the storageClassName
property.
apiVersion: v1
kind: StorageClass
metadata:
name: gp2-retain
parameters:
# ...
# ...
reclaimPolicy: Retain
apiVersion: v1
kind: PersistentVolume
# ...
spec:
# ...
storageClassName: gp2-retain
Note
|
If you are using Retain as the reclaim policy, but you want to delete an entire cluster, you need to delete the PVs manually. Otherwise they will not be deleted, and may cause unnecessary expenditure on resources. |
10.6.2. Recovery from loss of a Kubernetes cluster
When a cluster is lost, you can use the data from disks/volumes to recover the cluster if they were preserved within the infrastructure. The recovery procedure is the same as with namespace deletion, assuming PVs can be recovered and they were created manually.
10.6.3. Recovering a deleted cluster from persistent volumes
This procedure describes how to recover a deleted cluster from persistent volumes (PVs).
In this situation, the Topic Operator identifies that topics exist in Kafka, but the KafkaTopic
resources do not exist.
When you get to the step to recreate your cluster, you have two options:
-
Use Option 1 when you can recover all
KafkaTopic
resources.The
KafkaTopic
resources must therefore be recovered before the cluster is started so that the corresponding topics are not deleted by the Topic Operator. -
Use Option 2 when you are unable to recover all
KafkaTopic
resources.In this case, you deploy your cluster without the Topic Operator, delete the Topic Operator topic store metadata, and then redeploy the Kafka cluster with the Topic Operator so it can recreate the
KafkaTopic
resources from the corresponding topics.
Note
|
If the Topic Operator is not deployed, you only need to recover the PersistentVolumeClaim (PVC) resources.
|
In this procedure, it is essential that PVs are mounted into the correct PVC to avoid data corruption.
A volumeName
is specified for the PVC and this must match the name of the PV.
For more information, see:
Note
|
The procedure does not include recovery of KafkaUser resources, which must be recreated manually.
If passwords and certificates need to be retained, secrets must be recreated before creating the KafkaUser resources.
|
-
Check information on the PVs in the cluster:
kubectl get pv
Information is presented for PVs with data.
Example output showing columns important to this procedure:
NAME RECLAIMPOLICY CLAIM pvc-5e9c5c7f-3317-11ea-a650-06e1eadd9a4c ... Retain ... myproject/data-my-cluster-zookeeper-1 pvc-5e9cc72d-3317-11ea-97b0-0aef8816c7ea ... Retain ... myproject/data-my-cluster-zookeeper-0 pvc-5ead43d1-3317-11ea-97b0-0aef8816c7ea ... Retain ... myproject/data-my-cluster-zookeeper-2 pvc-7e1f67f9-3317-11ea-a650-06e1eadd9a4c ... Retain ... myproject/data-0-my-cluster-kafka-0 pvc-7e21042e-3317-11ea-9786-02deaf9aa87e ... Retain ... myproject/data-0-my-cluster-kafka-1 pvc-7e226978-3317-11ea-97b0-0aef8816c7ea ... Retain ... myproject/data-0-my-cluster-kafka-2
-
NAME shows the name of each PV.
-
RECLAIM POLICY shows that PVs are retained.
-
CLAIM shows the link to the original PVCs.
-
-
Recreate the original namespace:
kubectl create namespace myproject
-
Recreate the original PVC resource specifications, linking the PVCs to the appropriate PV:
For example:
apiVersion: v1 kind: PersistentVolumeClaim metadata: name: data-0-my-cluster-kafka-0 spec: accessModes: - ReadWriteOnce resources: requests: storage: 100Gi storageClassName: gp2-retain volumeMode: Filesystem volumeName: pvc-7e1f67f9-3317-11ea-a650-06e1eadd9a4c
-
Edit the PV specifications to delete the
claimRef
properties that bound the original PVC.For example:
apiVersion: v1 kind: PersistentVolume metadata: annotations: kubernetes.io/createdby: aws-ebs-dynamic-provisioner pv.kubernetes.io/bound-by-controller: "yes" pv.kubernetes.io/provisioned-by: kubernetes.io/aws-ebs creationTimestamp: "<date>" finalizers: - kubernetes.io/pv-protection labels: failure-domain.beta.kubernetes.io/region: eu-west-1 failure-domain.beta.kubernetes.io/zone: eu-west-1c name: pvc-7e226978-3317-11ea-97b0-0aef8816c7ea resourceVersion: "39431" selfLink: /api/v1/persistentvolumes/pvc-7e226978-3317-11ea-97b0-0aef8816c7ea uid: 7efe6b0d-3317-11ea-a650-06e1eadd9a4c spec: accessModes: - ReadWriteOnce awsElasticBlockStore: fsType: xfs volumeID: aws://eu-west-1c/vol-09db3141656d1c258 capacity: storage: 100Gi claimRef: apiVersion: v1 kind: PersistentVolumeClaim name: data-0-my-cluster-kafka-2 namespace: myproject resourceVersion: "39113" uid: 54be1c60-3319-11ea-97b0-0aef8816c7ea nodeAffinity: required: nodeSelectorTerms: - matchExpressions: - key: failure-domain.beta.kubernetes.io/zone operator: In values: - eu-west-1c - key: failure-domain.beta.kubernetes.io/region operator: In values: - eu-west-1 persistentVolumeReclaimPolicy: Retain storageClassName: gp2-retain volumeMode: Filesystem
In the example, the following properties are deleted:
claimRef: apiVersion: v1 kind: PersistentVolumeClaim name: data-0-my-cluster-kafka-2 namespace: myproject resourceVersion: "39113" uid: 54be1c60-3319-11ea-97b0-0aef8816c7ea
-
Deploy the Cluster Operator.
kubectl create -f install/cluster-operator -n my-project
-
Recreate your cluster.
Follow the steps depending on whether or not you have all the
KafkaTopic
resources needed to recreate your cluster.Option 1: If you have all the
KafkaTopic
resources that existed before you lost your cluster, including internal topics such as committed offsets from__consumer_offsets
:-
Recreate all
KafkaTopic
resources.It is essential that you recreate the resources before deploying the cluster, or the Topic Operator will delete the topics.
-
Deploy the Kafka cluster.
For example:
kubectl apply -f kafka.yaml
Option 2: If you do not have all the
KafkaTopic
resources that existed before you lost your cluster:-
Deploy the Kafka cluster, as with the first option, but without the Topic Operator by removing the
topicOperator
property from the Kafka resource before deploying.If you include the Topic Operator in the deployment, the Topic Operator will delete all the topics.
-
Delete the internal topic store topics from the Kafka cluster:
kubectl run kafka-admin -ti --image=quay.io/strimzi/kafka:0.27.0-kafka-3.0.0 --rm=true --restart=Never -- ./bin/kafka-topics.sh --bootstrap-server localhost:9092 --topic __strimzi-topic-operator-kstreams-topic-store-changelog --delete && ./bin/kafka-topics.sh --bootstrap-server localhost:9092 --topic __strimzi_store_topic --delete
The command must correspond to the type of listener and authentication used to access the Kafka cluster.
-
Enable the Topic Operator by redeploying the Kafka cluster with the
topicOperator
property to recreate theKafkaTopic
resources.For example:
apiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: #... entityOperator: topicOperator: {} (1) #...
-
Here we show the default configuration, which has no additional properties. You specify the required configuration using the properties described in
EntityTopicOperatorSpec
schema reference.
-
-
Verify the recovery by listing the
KafkaTopic
resources:kubectl get KafkaTopic
10.7. Setting limits on brokers using the Kafka Static Quota plugin
Use the Kafka Static Quota plugin to set throughput and storage limits on brokers in your Kafka cluster.
You enable the plugin and set limits by configuring the Kafka
resource.
You can set a byte-rate threshold and storage quotas to put limits on the clients interacting with your brokers.
You can set byte-rate thresholds for producer and consumer bandwidth. The total limit is distributed across all clients accessing the broker. For example, you can set a byte-rate threshold of 40 MBps for producers. If two producers are running, they are each limited to a throughput of 20 MBps.
Storage quotas throttle Kafka disk storage limits between a soft limit and hard limit. The limits apply to all available disk space. Producers are slowed gradually between the soft and hard limit. The limits prevent disks filling up too quickly and exceeding their capacity. Full disks can lead to issues that are hard to rectify. The hard limit is the maximum storage limit.
Note
|
For JBOD storage, the limit applies across all disks. If a broker is using two 1 TB disks and the quota is 1.1 TB, one disk might fill and the other disk will be almost empty. |
-
The Cluster Operator that manages the Kafka cluster is running.
-
Add the plugin properties to the
config
of theKafka
resource.The plugin properties are shown in this example configuration.
Example Kafka Static Quota plugin configurationapiVersion: kafka.strimzi.io/v1beta2 kind: Kafka metadata: name: my-cluster spec: kafka: # ... config: client.quota.callback.class: io.strimzi.kafka.quotas.StaticQuotaCallback (1) client.quota.callback.static.produce: 1000000 (2) client.quota.callback.static.fetch: 1000000 (3) client.quota.callback.static.storage.soft: 400000000000 (4) client.quota.callback.static.storage.hard: 500000000000 (5) client.quota.callback.static.storage.check-interval: 5 (6)
-
Loads the Kafka Static Quota plugin.
-
Sets the producer byte-rate threshold. 1 MBps in this example.
-
Sets the consumer byte-rate threshold. 1 MBps in this example.
-
Sets the lower soft limit for storage. 400 GB in this example.
-
Sets the higher hard limit for storage. 500 GB in this example.
-
Sets the interval in seconds between checks on storage. 5 seconds in this example. You can set this to 0 to disable the check.
-
-
Update the resource.
kubectl apply -f KAFKA-CONFIG-FILE
10.8. Tuning Kafka configuration
Use configuration properties to optimize the performance of Kafka brokers, producers and consumers.
A minimum set of configuration properties is required, but you can add or adjust properties to change how producers and consumers interact with Kafka brokers. For example, you can tune latency and throughput of messages so that clients can respond to data in real time.
You might start by analyzing metrics to gauge where to make your initial configurations, then make incremental changes and further comparisons of metrics until you have the configuration you need.
For more information about Apache Kafka configuration properties, see the Apache Kafka documentation.
10.8.1. Kafka broker configuration tuning
Use configuration properties to optimize the performance of Kafka brokers. You can use standard Kafka broker configuration options, except for properties managed directly by Strimzi.
Basic broker configuration
Certain broker configuration options are managed directly by Strimzi, driven by the Kafka
custom resource specification:
-
broker.id
is the ID of the Kafka broker -
log.dirs
are the directories for log data -
zookeeper.connect
is the configuration to connect Kafka with ZooKeeper -
listener
exposes the Kafka cluster to clients -
authorization
mechanisms allow or decline actions executed by users -
authentication
mechanisms prove the identity of users requiring access to Kafka
Broker IDs start from 0 (zero) and correspond to the number of broker replicas.
Log directories are mounted to /var/lib/kafka/data/kafka-logIDX
based on the spec.kafka.storage
configuration in the Kafka
custom resource.
IDX is the Kafka broker pod index.
As such, you cannot configure these options through the config
property of the Kafka
custom resource.
For a list of exclusions, see the KafkaClusterSpec
schema reference.
However, a typical broker configuration will include settings for properties related to topics, threads and logs.
# ...
num.partitions=1
default.replication.factor=3
offsets.topic.replication.factor=3
transaction.state.log.replication.factor=3
transaction.state.log.min.isr=2
log.retention.hours=168
log.segment.bytes=1073741824
log.retention.check.interval.ms=300000
num.network.threads=3
num.io.threads=8
num.recovery.threads.per.data.dir=1
socket.send.buffer.bytes=102400
socket.receive.buffer.bytes=102400
socket.request.max.bytes=104857600
group.initial.rebalance.delay.ms=0
zookeeper.connection.timeout.ms=6000
# ...
Replicating topics for high availability
Basic topic properties set the default number of partitions and replication factor for topics, which will apply to topics that are created without these properties being explicitly set, including when topics are created automatically.
# ...
num.partitions=1
auto.create.topics.enable=false
default.replication.factor=3
min.insync.replicas=2
replica.fetch.max.bytes=1048576
# ...
The auto.create.topics.enable
property is enabled by default so that topics that do not already exist are created automatically when needed by producers and consumers.
If you are using automatic topic creation, you can set the default number of partitions for topics using num.partitions
.
Generally, however, this property is disabled so that more control is provided over topics through explicit topic creation.
For example, you can use the Strimzi KafkaTopic
resource or applications to create topics.
For high availability environments, it is advisable to increase the replication factor to at least 3 for topics and set the minimum number of in-sync replicas required to 1 less than the replication factor.
For topics created using the KafkaTopic
resource, the replication factor is set using spec.replicas
.
For data durability, you should also set min.insync.replicas
in your topic configuration and message delivery acknowledgments using acks=all
in your producer configuration.
Use replica.fetch.max.bytes
to set the maximum size, in bytes, of messages fetched by each follower that replicates the leader partition.
Change this value according to the average message size and throughput. When considering the total memory allocation required for read/write buffering, the memory available must also be able to accommodate the maximum replicated message size when multiplied by all followers.
The delete.topic.enable
property is enabled by default to allow topics to be deleted.
In a production environment, you should disable this property to avoid accidental topic deletion, resulting in data loss.
You can, however, temporarily enable it and delete topics and then disable it again.
If delete.topic.enable
is enabled, you can delete topics using the KafkaTopic
resource.
# ...
auto.create.topics.enable=false
delete.topic.enable=true
# ...
Internal topic settings for transactions and commits
If you are using transactions to enable atomic writes to partitions from producers, the state of the transactions is stored in the internal __transaction_state
topic.
By default, the brokers are configured with a replication factor of 3 and a minimum of 2 in-sync replicas for this topic, which means that a minimum of three brokers are required in your Kafka cluster.
# ...
transaction.state.log.replication.factor=3
transaction.state.log.min.isr=2
# ...
Similarly, the internal __consumer_offsets
topic, which stores consumer state, has default settings for the number of partitions and replication factor.
# ...
offsets.topic.num.partitions=50
offsets.topic.replication.factor=3
# ...
Do not reduce these settings in production. You can increase the settings in a production environment. As an exception, you might want to reduce the settings in a single-broker test environment.
Improving request handling throughput by increasing I/O threads
Network threads handle requests to the Kafka cluster, such as produce and fetch requests from client applications. Produce requests are placed in a request queue. Responses are placed in a response queue.
The number of network threads should reflect the replication factor and the levels of activity from client producers and consumers interacting with the Kafka cluster. If you are going to have a lot of requests, you can increase the number of threads, using the amount of time threads are idle to determine when to add more threads.
To reduce congestion and regulate the request traffic, you can limit the number of requests allowed in the request queue before the network thread is blocked.
I/O threads pick up requests from the request queue to process them. Adding more threads can improve throughput, but the number of CPU cores and disk bandwidth imposes a practical upper limit. At a minimum, the number of I/O threads should equal the number of storage volumes.
# ...
num.network.threads=3 (1)
queued.max.requests=500 (2)
num.io.threads=8 (3)
num.recovery.threads.per.data.dir=1 (4)
# ...
-
The number of network threads for the Kafka cluster.
-
The number of requests allowed in the request queue.
-
The number of I/O threads for a Kafka broker.
-
The number of threads used for log loading at startup and flushing at shutdown.
Configuration updates to the thread pools for all brokers might occur dynamically at the cluster level. These updates are restricted to between half the current size and twice the current size.
Note
|
Kafka broker metrics can help with working out the number of threads required.
For example, metrics for the average time network threads are idle (kafka.network:type=SocketServer,name=NetworkProcessorAvgIdlePercent ) indicate the percentage of resources used.
If there is 0% idle time, all resources are in use, which means that adding more threads might be beneficial.
|
If threads are slow or limited due to the number of disks, you can try increasing the size of the buffers for network requests to improve throughput:
# ...
replica.socket.receive.buffer.bytes=65536
# ...
And also increase the maximum number of bytes Kafka can receive:
# ...
socket.request.max.bytes=104857600
# ...
Increasing bandwidth for high latency connections
Kafka batches data to achieve reasonable throughput over high-latency connections from Kafka to clients, such as connections between datacenters. However, if high latency is a problem, you can increase the size of the buffers for sending and receiving messages.
# ...
socket.send.buffer.bytes=1048576
socket.receive.buffer.bytes=1048576
# ...
You can estimate the optimal size of your buffers using a bandwidth-delay product calculation, which multiplies the maximum bandwidth of the link (in bytes/s) with the round-trip delay (in seconds) to give an estimate of how large a buffer is required to sustain maximum throughput.
Managing logs with data retention policies
Kafka uses logs to store message data. Logs are a series of segments associated with various indexes. New messages are written to an active segment, and never subsequently modified. Segments are read when serving fetch requests from consumers. Periodically, the active segment is rolled to become read-only and a new active segment is created to replace it. There is only a single segment active at a time. Older segments are retained until they are eligible for deletion.
Configuration at the broker level sets the maximum size in bytes of a log segment and the amount of time in milliseconds before an active segment is rolled:
# ...
log.segment.bytes=1073741824
log.roll.ms=604800000
# ...
You can override these settings at the topic level using segment.bytes
and segment.ms
.
Whether you need to lower or raise these values depends on the policy for segment deletion.
A larger size means the active segment contains more messages and is rolled less often.
Segments also become eligible for deletion less often.
You can set time-based or size-based log retention and cleanup policies so that logs are kept manageable. Depending on your requirements, you can use log retention configuration to delete old segments. If log retention policies are used, non-active log segments are removed when retention limits are reached. Deleting old segments bounds the storage space required for the log so you do not exceed disk capacity.
For time-based log retention, you set a retention period based on hours, minutes and milliseconds. The retention period is based on the time messages were appended to the segment.
The milliseconds configuration has priority over minutes, which has priority over hours. The minutes and milliseconds configuration is null by default, but the three options provide a substantial level of control over the data you wish to retain. Preference should be given to the milliseconds configuration, as it is the only one of the three properties that is dynamically updateable.
# ...
log.retention.ms=1680000
# ...
If log.retention.ms
is set to -1, no time limit is applied to log retention, so all logs are retained.
Disk usage should always be monitored, but the -1 setting is not generally recommended as it can lead to issues with full disks, which can be hard to rectify.
For size-based log retention, you set a maximum log size (of all segments in the log) in bytes:
# ...
log.retention.bytes=1073741824
# ...
In other words, a log will typically have approximately log.retention.bytes/log.segment.bytes segments once it reaches a steady state. When the maximum log size is reached, older segments are removed.
A potential issue with using a maximum log size is that it does not take into account the time messages were appended to a segment. You can use time-based and size-based log retention for your cleanup policy to get the balance you need. Whichever threshold is reached first triggers the cleanup.
If you wish to add a time delay before a segment file is deleted from the system, you can add the delay using log.segment.delete.delay.ms
for all topics at the broker level or file.delete.delay.ms
for specific topics in the topic configuration.
# ...
log.segment.delete.delay.ms=60000
# ...
Removing log data with cleanup policies
The method of removing older log data is determined by the log cleaner configuration.
The log cleaner is enabled for the broker by default:
# ...
log.cleaner.enable=true
# ...
You can set the cleanup policy at the topic or broker level. Broker-level configuration is the default for topics that do not have policy set.
You can set policy to delete logs, compact logs, or do both:
# ...
log.cleanup.policy=compact,delete
# ...
The delete
policy corresponds to managing logs with data retention policies.
It is suitable when data does not need to be retained forever.
The compact
policy guarantees to keep the most recent message for each message key.
Log compaction is suitable where message values are changeable, and you want to retain the latest update.
If cleanup policy is set to delete logs, older segments are deleted based on log retention limits. Otherwise, if the log cleaner is not enabled, and there are no log retention limits, the log will continue to grow.
If cleanup policy is set for log compaction, the head of the log operates as a standard Kafka log, with writes for new messages appended in order. In the tail of a compacted log, where the log cleaner operates, records will be deleted if another record with the same key occurs later in the log. Messages with null values are also deleted. If you’re not using keys, you can’t use compaction because keys are needed to identify related messages. While Kafka guarantees that the latest messages for each key will be retained, it does not guarantee that the whole compacted log will not contain duplicates.
Using keys to identify messages, Kafka compaction keeps the latest message (with the highest offset) for a specific message key, eventually discarding earlier messages that have the same key. In other words, the message in its latest state is always available and any out-of-date records of that particular message are eventually removed when the log cleaner runs. You can restore a message back to a previous state.
Records retain their original offsets even when surrounding records get deleted. Consequently, the tail can have non-contiguous offsets. When consuming an offset that’s no longer available in the tail, the record with the next higher offset is found.
If you choose only a compact policy, your log can still become arbitrarily large. In which case, you can set policy to compact and delete logs. If you choose to compact and delete, first the log data is compacted, removing records with a key in the head of the log. After which, data that falls before the log retention threshold is deleted.
You set the frequency the log is checked for cleanup in milliseconds:
# ...
log.retention.check.interval.ms=300000
# ...
Adjust the log retention check interval in relation to the log retention settings. Smaller retention sizes might require more frequent checks.
The frequency of cleanup should be often enough to manage the disk space, but not so often it affects performance on a topic.
You can also set a time in milliseconds to put the cleaner on standby if there are no logs to clean:
# ...
log.cleaner.backoff.ms=15000
# ...
If you choose to delete older log data, you can set a period in milliseconds to retain the deleted data before it is purged:
# ...
log.cleaner.delete.retention.ms=86400000
# ...
The deleted data retention period gives time to notice the data is gone before it is irretrievably deleted.
To delete all messages related to a specific key, a producer can send a tombstone message. A tombstone has a null value and acts as a marker to tell a consumer the value is deleted. After compaction, only the tombstone is retained, which must be for a long enough period for the consumer to know that the message is deleted. When older messages are deleted, having no value, the tombstone key is also deleted from the partition.
Managing disk utilization
There are many other configuration settings related to log cleanup, but of particular importance is memory allocation.
The deduplication property specifies the total memory for cleanup across all log cleaner threads. You can set an upper limit on the percentage of memory used through the buffer load factor.
# ...
log.cleaner.dedupe.buffer.size=134217728
log.cleaner.io.buffer.load.factor=0.9
# ...
Each log entry uses exactly 24 bytes, so you can work out how many log entries the buffer can handle in a single run and adjust the setting accordingly.
If possible, consider increasing the number of log cleaner threads if you are looking to reduce the log cleaning time:
# ...
log.cleaner.threads=8
# ...
If you are experiencing issues with 100% disk bandwidth usage, you can throttle the log cleaner I/O so that the sum of the read/write operations is less than a specified double value based on the capabilities of the disks performing the operations:
# ...
log.cleaner.io.max.bytes.per.second=1.7976931348623157E308
# ...
Handling large message sizes
The default batch size for messages is 1MB, which is optimal for maximum throughput in most use cases. Kafka can accommodate larger batches at a reduced throughput, assuming adequate disk capacity.
Large message sizes are handled in four ways:
-
Producer-side message compression writes compressed messages to the log.
-
Reference-based messaging sends only a reference to data stored in some other system in the message’s value.
-
Inline messaging splits messages into chunks that use the same key, which are then combined on output using a stream-processor like Kafka Streams.
-
Broker and producer/consumer client application configuration built to handle larger message sizes.
The reference-based messaging and message compression options are recommended and cover most situations. With any of these options, care must be take to avoid introducing performance issues.
For producer configuration, you specify a compression.type
, such as Gzip, which is then applied to batches of data generated by the producer.
Using the broker configuration compression.type=producer
, the broker retains whatever compression the producer used.
Whenever producer and topic compression do not match, the broker has to compress batches again prior to appending them to the log, which impacts broker performance.
Compression also adds additional processing overhead on the producer and decompression overhead on the consumer, but includes more data in a batch, so is often beneficial to throughput when message data compresses well.
Combine producer-side compression with fine-tuning of the batch size to facilitate optimum throughput. Using metrics helps to gauge the average batch size needed.
Reference-based messaging is useful for data replication when you do not know how big a message will be. The external data store must be fast, durable, and highly available for this configuration to work. Data is written to the data store and a reference to the data is returned. The producer sends a message containing the reference to Kafka. The consumer gets the reference from the message and uses it to fetch the data from the data store.
As the message passing requires more trips, end-to-end latency will increase. Another significant drawback of this approach is there is no automatic clean up of the data in the external system when the Kafka message gets cleaned up. A hybrid approach would be to only send large messages to the data store and process standard-sized messages directly.
Inline messaging is complex, but it does not have the overhead of depending on external systems like reference-based messaging.
The producing client application has to serialize and then chunk the data if the message is too big.
The producer then uses the Kafka ByteArraySerializer
or similar to serialize each chunk again before sending it.
The consumer tracks messages and buffers chunks until it has a complete message.
The consuming client application receives the chunks, which are assembled before deserialization.
Complete messages are delivered to the rest of the consuming application in order according to the offset of the first or last chunk for each set of chunked messages.
Successful delivery of the complete message is checked against offset metadata to avoid duplicates during a rebalance.
Inline messaging has a performance overhead on the consumer side because of the buffering required, particularly when handling a series of large messages in parallel. The chunks of large messages can become interleaved, so that it is not always possible to commit when all the chunks of a message have been consumed if the chunks of another large message in the buffer are incomplete. For this reason, the buffering is usually supported by persisting message chunks or by implementing commit logic.
If larger messages cannot be avoided, and to avoid blocks at any point of the message flow, you can increase message limits.
To do this, configure message.max.bytes
at the topic level to set the maximum record batch size for individual topics.
If you set message.max.bytes
at the broker level, larger messages are allowed for all topics.
The broker will reject any message that is greater than the limit set with message.max.bytes
.
The buffer size for the producers (max.request.size
) and consumers (message.max.bytes
) must be able to accommodate the larger messages.
Controlling the log flush of message data
Log flush properties control the periodic writes of cached message data to disk. The scheduler specifies the frequency of checks on the log cache in milliseconds:
# ...
log.flush.scheduler.interval.ms=2000
# ...
You can control the frequency of the flush based on the maximum amount of time that a message is kept in-memory and the maximum number of messages in the log before writing to disk:
# ...
log.flush.interval.ms=50000
log.flush.interval.messages=100000
# ...
The wait between flushes includes the time to make the check and the specified interval before the flush is carried out. Increasing the frequency of flushes can affect throughput.
Generally, the recommendation is to not set explicit flush thresholds and let the operating system perform background flush using its default settings. Partition replication provides greater data durability than writes to any single disk as a failed broker can recover from its in-sync replicas.
If you are using application flush management, setting lower flush thresholds might be appropriate if you are using faster disks.
Partition rebalancing for availability
Partitions can be replicated across brokers for fault tolerance. For a given partition, one broker is elected leader and handles all produce requests (writes to the log). Partition followers on other brokers replicate the partition data of the partition leader for data reliability in the event of the leader failing.
Followers do not normally serve clients, though rack
configuration allows a consumer to consume messages from the closest replica when a Kafka cluster spans multiple datacenters.
Followers operate only to replicate messages from the partition leader and allow recovery should the leader fail.
Recovery requires an in-sync follower. Followers stay in sync by sending fetch requests to the leader, which returns messages to the follower in order.
The follower is considered to be in sync if it has caught up with the most recently committed message on the leader.
The leader checks this by looking at the last offset requested by the follower.
An out-of-sync follower is usually not eligible as a leader should the current leader fail, unless unclean leader election is allowed.
You can adjust the lag time before a follower is considered out of sync:
# ...
replica.lag.time.max.ms=30000
# ...
Lag time puts an upper limit on the time to replicate a message to all in-sync replicas and how long a producer has to wait for an acknowledgment. If a follower fails to make a fetch request and catch up with the latest message within the specified lag time, it is removed from in-sync replicas. You can reduce the lag time to detect failed replicas sooner, but by doing so you might increase the number of followers that fall out of sync needlessly. The right lag time value depends on both network latency and broker disk bandwidth.
When a leader partition is no longer available, one of the in-sync replicas is chosen as the new leader. The first broker in a partition’s list of replicas is known as the preferred leader. By default, Kafka is enabled for automatic partition leader rebalancing based on a periodic check of leader distribution. That is, Kafka checks to see if the preferred leader is the current leader. A rebalance ensures that leaders are evenly distributed across brokers and brokers are not overloaded.
You can use Cruise Control for Strimzi to figure out replica assignments to brokers that balance load evenly across the cluster. Its calculation takes into account the differing load experienced by leaders and followers. A failed leader affects the balance of a Kafka cluster because the remaining brokers get the extra work of leading additional partitions.
For the assignment found by Cruise Control to actually be balanced it is necessary that partitions are lead by the preferred leader. Kafka can automatically ensure that the preferred leader is being used (where possible), changing the current leader if necessary. This ensures that the cluster remains in the balanced state found by Cruise Control.
You can control the frequency, in seconds, of the rebalance check and the maximum percentage of imbalance allowed for a broker before a rebalance is triggered.
#...
auto.leader.rebalance.enable=true
leader.imbalance.check.interval.seconds=300
leader.imbalance.per.broker.percentage=10
#...
The percentage leader imbalance for a broker is the ratio between the current number of partitions for which the broker is the current leader and the number of partitions for which it is the preferred leader. You can set the percentage to zero to ensure that preferred leaders are always elected, assuming they are in sync.
If the checks for rebalances need more control, you can disable automated rebalances. You can then choose when to trigger a rebalance using the kafka-leader-election.sh
command line tool.
Note
|
The Grafana dashboards provided with Strimzi show metrics for under-replicated partitions and partitions that do not have an active leader. |
Unclean leader election
Leader election to an in-sync replica is considered clean because it guarantees no loss of data. And this is what happens by default. But what if there is no in-sync replica to take on leadership? Perhaps the ISR (in-sync replica) only contained the leader when the leader’s disk died. If a minimum number of in-sync replicas is not set, and there are no followers in sync with the partition leader when its hard drive fails irrevocably, data is already lost. Not only that, but a new leader cannot be elected because there are no in-sync followers.
You can configure how Kafka handles leader failure:
# ...
unclean.leader.election.enable=false
# ...
Unclean leader election is disabled by default, which means that out-of-sync replicas cannot become leaders. With clean leader election, if no other broker was in the ISR when the old leader was lost, Kafka waits until that leader is back online before messages can be written or read. Unclean leader election means out-of-sync replicas can become leaders, but you risk losing messages. The choice you make depends on whether your requirements favor availability or durability.
You can override the default configuration for specific topics at the topic level. If you cannot afford the risk of data loss, then leave the default configuration.
Avoiding unnecessary consumer group rebalances
For consumers joining a new consumer group, you can add a delay so that unnecessary rebalances to the broker are avoided:
# ...
group.initial.rebalance.delay.ms=3000
# ...
The delay is the amount of time that the coordinator waits for members to join. The longer the delay, the more likely it is that all the members will join in time and avoid a rebalance. But the delay also prevents the group from consuming until the period has ended.
10.8.2. Kafka producer configuration tuning
Use a basic producer configuration with optional properties that are tailored to specific use cases.
Adjusting your configuration to maximize throughput might increase latency or vice versa. You will need to experiment and tune your producer configuration to get the balance you need.
Basic producer configuration
Connection and serializer properties are required for every producer. Generally, it is good practice to add a client id for tracking, and use compression on the producer to reduce batch sizes in requests.
In a basic producer configuration:
-
The order of messages in a partition is not guaranteed.
-
The acknowledgment of messages reaching the broker does not guarantee durability.
# ...
bootstrap.servers=localhost:9092 (1)
key.serializer=org.apache.kafka.common.serialization.StringSerializer (2)
value.serializer=org.apache.kafka.common.serialization.StringSerializer (3)
client.id=my-client (4)
compression.type=gzip (5)
# ...
-
(Required) Tells the producer to connect to a Kafka cluster using a host:port bootstrap server address for a Kafka broker. The producer uses the address to discover and connect to all brokers in the cluster. Use a comma-separated list to specify two or three addresses in case a server is down, but it’s not necessary to provide a list of all the brokers in the cluster.
-
(Required) Serializer to transform the key of each message to bytes prior to them being sent to a broker.
-
(Required) Serializer to transform the value of each message to bytes prior to them being sent to a broker.
-
(Optional) The logical name for the client, which is used in logs and metrics to identify the source of a request.
-
(Optional) The codec for compressing messages, which are sent and might be stored in compressed format and then decompressed when reaching a consumer. Compression is useful for improving throughput and reducing the load on storage, but might not be suitable for low latency applications where the cost of compression or decompression could be prohibitive.
Data durability
You can apply greater data durability, to minimize the likelihood that messages are lost, using message delivery acknowledgments.
# ...
acks=all (1)
# ...
-
Specifying
acks=all
forces a partition leader to replicate messages to a certain number of followers before acknowledging that the message request was successfully received. Because of the additional checks,acks=all
increases the latency between the producer sending a message and receiving acknowledgment.
The number of brokers which need to have appended the messages to their logs before the acknowledgment is sent to the producer is determined by the topic’s min.insync.replicas
configuration.
A typical starting point is to have a topic replication factor of 3, with two in-sync replicas on other brokers.
In this configuration, the producer can continue unaffected if a single broker is unavailable.
If a second broker becomes unavailable, the producer won’t receive acknowledgments and won’t be able to produce more messages.
acks=all
# ...
min.insync.replicas=2 (1)
# ...
-
Use
2
in-sync replicas. The default is1
.
Note
|
If the system fails, there is a risk of unsent data in the buffer being lost. |
Ordered delivery
Idempotent producers avoid duplicates as messages are delivered exactly once.
IDs and sequence numbers are assigned to messages to ensure the order of delivery, even in the event of failure.
If you are using acks=all
for data consistency, enabling idempotency makes sense for ordered delivery.
# ...
enable.idempotence=true (1)
max.in.flight.requests.per.connection=5 (2)
acks=all (3)
retries=2147483647 (4)
# ...
-
Set to
true
to enable the idempotent producer. -
With idempotent delivery the number of in-flight requests may be greater than 1 while still providing the message ordering guarantee. The default is 5 in-flight requests.
-
Set
acks
toall
. -
Set the number of attempts to resend a failed message request.
If you are not using acks=all
and idempotency because of the performance cost,
set the number of in-flight (unacknowledged) requests to 1 to preserve ordering.
Otherwise, a situation is possible where Message-A fails only to succeed after Message-B was already written to the broker.
# ...
enable.idempotence=false (1)
max.in.flight.requests.per.connection=1 (2)
retries=2147483647
# ...
-
Set to
false
to disable the idempotent producer. -
Set the number of in-flight requests to exactly
1
.
Reliability guarantees
Idempotence is useful for exactly once writes to a single partition. Transactions, when used with idempotence, allow exactly once writes across multiple partitions.
Transactions guarantee that messages using the same transactional ID are produced once, and either all are successfully written to the respective logs or none of them are.
# ...
enable.idempotence=true
max.in.flight.requests.per.connection=5
acks=all
retries=2147483647
transactional.id=UNIQUE-ID (1)
transaction.timeout.ms=900000 (2)
# ...
-
Specify a unique transactional ID.
-
Set the maximum allowed time for transactions in milliseconds before a timeout error is returned. The default is
900000
or 15 minutes.
The choice of transactional.id
is important in order that the transactional guarantee is maintained.
Each transactional id should be used for a unique set of topic partitions.
For example, this can be achieved using an external mapping of topic partition names to transactional ids,
or by computing the transactional id from the topic partition names using a function that avoids collisions.
Optimizing throughput and latency
Usually, the requirement of a system is to satisfy a particular throughput target for a proportion of messages within a given latency. For example, targeting 500,000 messages per second with 95% of messages being acknowledged within 2 seconds.
It’s likely that the messaging semantics (message ordering and durability) of your producer are defined by the requirements for your application.
For instance, it’s possible that you don’t have the option of using acks=0
or acks=1
without breaking some important property or guarantee provided by your application.
Broker restarts have a significant impact on high percentile statistics. For example, over a long period the 99th percentile latency is dominated by behavior around broker restarts. This is worth considering when designing benchmarks or comparing performance numbers from benchmarking with performance numbers seen in production.
Depending on your objective, Kafka offers a number of configuration parameters and techniques for tuning producer performance for throughput and latency.
- Message batching (
linger.ms
andbatch.size
) -
Message batching delays sending messages in the hope that more messages destined for the same broker will be sent, allowing them to be batched into a single produce request. Batching is a compromise between higher latency in return for higher throughput. Time-based batching is configured using
linger.ms
, and size-based batching is configured usingbatch.size
. - Compression (
compression.type
) -
Message compression adds latency in the producer (CPU time spent compressing the messages), but makes requests (and potentially disk writes) smaller, which can increase throughput. Whether compression is worthwhile, and the best compression to use, will depend on the messages being sent. Compression happens on the thread which calls
KafkaProducer.send()
, so if the latency of this method matters for your application you should consider using more threads. - Pipelining (
max.in.flight.requests.per.connection
) -
Pipelining means sending more requests before the response to a previous request has been received. In general more pipelining means better throughput, up to a threshold at which other effects, such as worse batching, start to counteract the effect on throughput.
When your application calls KafkaProducer.send()
the messages are:
-
Processed by any interceptors
-
Serialized
-
Assigned to a partition
-
Compressed
-
Added to a batch of messages in a per-partition queue
At which point the send()
method returns.
So the time send()
is blocked is determined by:
-
The time spent in the interceptors, serializers and partitioner
-
The compression algorithm used
-
The time spent waiting for a buffer to use for compression
Batches will remain in the queue until one of the following occurs:
-
The batch is full (according to
batch.size
) -
The delay introduced by
linger.ms
has passed -
The sender is about to send message batches for other partitions to the same broker, and it is possible to add this batch too
-
The producer is being flushed or closed
Look at the configuration for batching and buffering to mitigate the impact of send()
blocking on latency.
# ...
linger.ms=100 (1)
batch.size=16384 (2)
buffer.memory=33554432 (3)
# ...
-
The
linger
property adds a delay in milliseconds so that larger batches of messages are accumulated and sent in a request. The default is0'.
-
If a maximum
batch.size
in bytes is used, a request is sent when the maximum is reached, or messages have been queued for longer thanlinger.ms
(whichever comes sooner). Adding the delay allows batches to accumulate messages up to the batch size. -
The buffer size must be at least as big as the batch size, and be able to accommodate buffering, compression and in-flight requests.
Improve throughput of your message requests by adjusting the maximum time to wait before a message is delivered and completes a send request.
You can also direct messages to a specified partition by writing a custom partitioner to replace the default.
# ...
delivery.timeout.ms=120000 (1)
partitioner.class=my-custom-partitioner (2)
# ...
-
The maximum time in milliseconds to wait for a complete send request. You can set the value to
MAX_LONG
to delegate to Kafka an indefinite number of retries. The default is120000
or 2 minutes. -
Specify the class name of the custom partitioner.
10.8.3. Kafka consumer configuration tuning
Use a basic consumer configuration with optional properties that are tailored to specific use cases.
When tuning your consumers your primary concern will be ensuring that they cope efficiently with the amount of data ingested. As with the producer tuning, be prepared to make incremental changes until the consumers operate as expected.
Basic consumer configuration
Connection and deserializer properties are required for every consumer. Generally, it is good practice to add a client id for tracking.
In a consumer configuration, irrespective of any subsequent configuration:
-
The consumer fetches from a given offset and consumes the messages in order, unless the offset is changed to skip or re-read messages.
-
The broker does not know if the consumer processed the responses, even when committing offsets to Kafka, because the offsets might be sent to a different broker in the cluster.
# ...
bootstrap.servers=localhost:9092 (1)
key.deserializer=org.apache.kafka.common.serialization.StringDeserializer (2)
value.deserializer=org.apache.kafka.common.serialization.StringDeserializer (3)
client.id=my-client (4)
group.id=my-group-id (5)
# ...
-
(Required) Tells the consumer to connect to a Kafka cluster using a host:port bootstrap server address for a Kafka broker. The consumer uses the address to discover and connect to all brokers in the cluster. Use a comma-separated list to specify two or three addresses in case a server is down, but it is not necessary to provide a list of all the brokers in the cluster. If you are using a loadbalancer service to expose the Kafka cluster, you only need the address for the service because the availability is handled by the loadbalancer.
-
(Required) Deserializer to transform the bytes fetched from the Kafka broker into message keys.
-
(Required) Deserializer to transform the bytes fetched from the Kafka broker into message values.
-
(Optional) The logical name for the client, which is used in logs and metrics to identify the source of a request. The id can also be used to throttle consumers based on processing time quotas.
-
(Conditional) A group id is required for a consumer to be able to join a consumer group.
Scaling data consumption using consumer groups
Consumer groups share a typically large data stream generated by one or multiple producers from a given topic.
Consumers are grouped using a group.id
property, allowing messages to be spread across the members.
One of the consumers in the group is elected leader and decides how the partitions are assigned to the consumers in the group.
Each partition can only be assigned to a single consumer.
If you do not already have as many consumers as partitions,
you can scale data consumption by adding more consumer instances with the same group.id
.
Adding more consumers to a group than there are partitions will not help throughput,
but it does mean that there are consumers on standby should one stop functioning.
If you can meet throughput goals with fewer consumers, you save on resources.
Consumers within the same consumer group send offset commits and heartbeats to the same broker. So the greater the number of consumers in the group, the higher the request load on the broker.
# ...
group.id=my-group-id (1)
# ...
-
Add a consumer to a consumer group using a group id.
Message ordering guarantees
Kafka brokers receive fetch requests from consumers that ask the broker to send messages from a list of topics, partitions and offset positions.
A consumer observes messages in a single partition in the same order that they were committed to the broker, which means that Kafka only provides ordering guarantees for messages in a single partition. Conversely, if a consumer is consuming messages from multiple partitions, the order of messages in different partitions as observed by the consumer does not necessarily reflect the order in which they were sent.
If you want a strict ordering of messages from one topic, use one partition per consumer.
Optimizing throughput and latency
Control the number of messages returned when your client application calls KafkaConsumer.poll()
.
Use the fetch.max.wait.ms
and fetch.min.bytes
properties to increase the minimum amount of data fetched by the consumer from the Kafka broker.
Time-based batching is configured using fetch.max.wait.ms
, and size-based batching is configured using fetch.min.bytes
.
If CPU utilization in the consumer or broker is high, it might be because there are too many requests from the consumer.
You can adjust fetch.max.wait.ms
and fetch.min.bytes
properties higher so that there are fewer requests and messages are delivered in bigger batches.
By adjusting higher, throughput is improved with some cost to latency.
You can also adjust higher if the amount of data being produced is low.
For example, if you set fetch.max.wait.ms
to 500ms and fetch.min.bytes
to 16384 bytes,
when Kafka receives a fetch request from the consumer it will respond when the first of either threshold is reached.
Conversely, you can adjust the fetch.max.wait.ms
and fetch.min.bytes
properties lower to improve end-to-end latency.
# ...
fetch.max.wait.ms=500 (1)
fetch.min.bytes=16384 (2)
# ...
-
The maximum time in milliseconds the broker will wait before completing fetch requests. The default is
500
milliseconds. -
If a minimum batch size in bytes is used, a request is sent when the minimum is reached, or messages have been queued for longer than
fetch.max.wait.ms
(whichever comes sooner). Adding the delay allows batches to accumulate messages up to the batch size.
Use the fetch.max.bytes
and max.partition.fetch.bytes
properties to increase the maximum amount of data fetched by the consumer from the Kafka broker.
The fetch.max.bytes
property sets a maximum limit in bytes on the amount of data fetched from the broker at one time.
The max.partition.fetch.bytes
sets a maximum limit in bytes on how much data is returned for each partition,
which must always be larger than the number of bytes set in the broker or topic configuration for max.message.bytes
.
The maximum amount of memory a client can consume is calculated approximately as:
NUMBER-OF-BROKERS * fetch.max.bytes and NUMBER-OF-PARTITIONS * max.partition.fetch.bytes
If memory usage can accommodate it, you can increase the values of these two properties. By allowing more data in each request, latency is improved as there are fewer fetch requests.
# ...
fetch.max.bytes=52428800 (1)
max.partition.fetch.bytes=1048576 (2)
# ...
-
The maximum amount of data in bytes returned for a fetch request.
-
The maximum amount of data in bytes returned for each partition.
Avoiding data loss or duplication when committing offsets
The Kafka auto-commit mechanism allows a consumer to commit the offsets of messages automatically. If enabled, the consumer will commit offsets received from polling the broker at 5000ms intervals.
The auto-commit mechanism is convenient, but it introduces a risk of data loss and duplication. If a consumer has fetched and transformed a number of messages, but the system crashes with processed messages in the consumer buffer when performing an auto-commit, that data is lost. If the system crashes after processing the messages, but before performing the auto-commit, the data is duplicated on another consumer instance after rebalancing.
Auto-committing can avoid data loss only when all messages are processed before the next poll to the broker, or the consumer closes.
To minimize the likelihood of data loss or duplication, you can set enable.auto.commit
to false
and develop your client application to have more control over committing offsets.
Or you can use auto.commit.interval.ms
to decrease the intervals between commits.
# ...
enable.auto.commit=false (1)
# ...
-
Auto commit is set to false to provide more control over committing offsets.
By setting to enable.auto.commit
to false
, you can commit offsets after all processing has been performed and the message has been consumed.
For example, you can set up your application to call the Kafka commitSync
and commitAsync
commit APIs.
The commitSync
API commits the offsets in a message batch returned from polling.
You call the API when you are finished processing all the messages in the batch.
If you use the commitSync
API, the application will not poll for new messages until the last offset in the batch is committed.
If this negatively affects throughput, you can commit less frequently,
or you can use the commitAsync
API.
The commitAsync
API does not wait for the broker to respond to a commit request,
but risks creating more duplicates when rebalancing.
A common approach is to combine both commit APIs in an application, with the commitSync
API used just before shutting the consumer down or rebalancing to make sure the final commit is successful.
Controlling transactional messages
Consider using transactional ids and enabling idempotence (enable.idempotence=true
) on the producer side to guarantee exactly-once delivery.
On the consumer side, you can then use the isolation.level
property to control how transactional messages are read by the consumer.
The isolation.level
property has two valid values:
-
read_committed
-
read_uncommitted
(default)
Use read_committed
to ensure that only transactional messages that have been committed are read by the consumer.
However, this will cause an increase in end-to-end latency, because the consumer will not be able to return a message until the brokers have written the transaction markers that record the result of the transaction (committed or aborted).
# ...
enable.auto.commit=false
isolation.level=read_committed (1)
# ...
-
Set to
read_committed
so that only committed messages are read by the consumer.
Recovering from failure to avoid data loss
Use the session.timeout.ms
and heartbeat.interval.ms
properties to configure the time taken to check and recover from consumer failure within a consumer group.
The session.timeout.ms
property specifies the maximum amount of time in milliseconds a consumer within a consumer group can be out of contact with a broker before being considered inactive and a rebalancing is triggered between the active consumers in the group.
When the group rebalances, the partitions are reassigned to the members of the group.
The heartbeat.interval.ms
property specifies the interval in milliseconds between heartbeat checks to the consumer group coordinator to indicate that the consumer is active and connected.
The heartbeat interval must be lower, usually by a third, than the session timeout interval.
If you set the session.timeout.ms
property lower, failing consumers are detected earlier, and rebalancing can take place quicker.
However, take care not to set the timeout so low that the broker fails to receive a heartbeat in time and triggers an unnecessary rebalance.
Decreasing the heartbeat interval reduces the chance of accidental rebalancing, but more frequent heartbeats increases the overhead on broker resources.
Managing offset policy
Use the auto.offset.reset
property to control how a consumer behaves when no offsets have been committed,
or a committed offset is no longer valid or deleted.
Suppose you deploy a consumer application for the first time, and it reads messages from an existing topic.
Because this is the first time the group.id
is used, the __consumer_offsets
topic does not contain any offset information for this application.
The new application can start processing all existing messages from the start of the log or only new messages.
The default reset value is latest
, which starts at the end of the partition, and consequently means some messages are missed.
To avoid data loss, but increase the amount of processing, set auto.offset.reset
to earliest
to start at the beginning of the partition.
Also consider using the earliest
option to avoid messages being lost when the offsets retention period (offsets.retention.minutes
) configured for a broker has ended.
If a consumer group or standalone consumer is inactive and commits no offsets during the retention period, previously committed offsets are deleted from __consumer_offsets
.
# ...
heartbeat.interval.ms=3000 (1)
session.timeout.ms=10000 (2)
auto.offset.reset=earliest (3)
# ...
-
Adjust the heartbeat interval lower according to anticipated rebalances.
-
If no heartbeats are received by the Kafka broker before the timeout duration expires, the consumer is removed from the consumer group and a rebalance is initiated. If the broker configuration has a
group.min.session.timeout.ms
andgroup.max.session.timeout.ms
, the session timeout value must be within that range. -
Set to
earliest
to return to the start of a partition and avoid data loss if offsets were not committed.
If the amount of data returned in a single fetch request is large,
a timeout might occur before the consumer has processed it.
In this case, you can lower max.partition.fetch.bytes
or increase session.timeout.ms
.
Minimizing the impact of rebalances
The rebalancing of a partition between active consumers in a group is the time it takes for:
-
Consumers to commit their offsets
-
The new consumer group to be formed
-
The group leader to assign partitions to group members
-
The consumers in the group to receive their assignments and start fetching
Clearly, the process increases the downtime of a service, particularly when it happens repeatedly during a rolling restart of a consumer group cluster.
In this situation, you can use the concept of static membership to reduce the number of rebalances. Rebalancing assigns topic partitions evenly among consumer group members. Static membership uses persistence so that a consumer instance is recognized during a restart after a session timeout.
The consumer group coordinator can identify a new consumer instance using a unique id that is specified using the group.instance.id
property.
During a restart, the consumer is assigned a new member id, but as a static member it continues with the same instance id,
and the same assignment of topic partitions is made.
If the consumer application does not make a call to poll at least every max.poll.interval.ms
milliseconds, the consumer is considered to be failed, causing a rebalance.
If the application cannot process all the records returned from poll in time, you can avoid a rebalance by using the max.poll.interval.ms
property to specify the interval in milliseconds between polls for new messages from a consumer.
Or you can use the max.poll.records
property to set a maximum limit on the number of records returned from the consumer buffer, allowing your application to process fewer records within the max.poll.interval.ms
limit.
# ...
group.instance.id=UNIQUE-ID (1)
max.poll.interval.ms=300000 (2)
max.poll.records=500 (3)
# ...
-
The unique instance id ensures that a new consumer instance receives the same assignment of topic partitions.
-
Set the interval to check the consumer is continuing to process messages.
-
Sets the number of processed records returned from the consumer.
10.9. Uninstalling Strimzi
This procedure describes how to uninstall Strimzi and remove resources related to the deployment.
In order to perform this procedure, identify resources created specifically for a deployment and referenced from the Strimzi resource.
Such resources include:
-
Secrets (Custom CAs and certificates, Kafka Connect secrets, and other Kafka secrets)
-
Logging
ConfigMaps
(of typeexternal
)
These are resources referenced by Kafka
, KafkaConnect
, KafkaMirrorMaker
, or KafkaBridge
configuration.
-
Delete the Cluster Operator
Deployment
, relatedCustomResourceDefinitions
, andRBAC
resources:kubectl delete -f install/cluster-operator
WarningDeleting CustomResourceDefinitions
results in the garbage collection of the corresponding custom resources (Kafka
,KafkaConnect
,KafkaMirrorMaker
, orKafkaBridge
) and the resources dependent on them (Deployments, StatefulSets, and other dependent resources). -
Delete the resources you identified in the prerequisites.
10.10. Frequently asked questions
10.10.1. Questions related to the Cluster Operator
Why do I need cluster administrator privileges to install Strimzi?
To install Strimzi, you need to be able to create the following cluster-scoped resources:
-
Custom Resource Definitions (CRDs) to instruct Kubernetes about resources that are specific to Strimzi, such as
Kafka
andKafkaConnect
-
ClusterRoles
andClusterRoleBindings
Cluster-scoped resources, which are not scoped to a particular Kubernetes namespace, typically require cluster administrator privileges to install.
As a cluster administrator, you can inspect all the resources being installed (in the /install/
directory) to ensure that the ClusterRoles
do not grant unnecessary privileges.
After installation, the Cluster Operator runs as a regular Deployment
, so any standard (non-admin) Kubernetes user with privileges to access the Deployment
can configure it.
The cluster administrator can grant standard users the privileges necessary to manage Kafka
custom resources.
See also:
Why does the Cluster Operator need to create ClusterRoleBindings
?
Kubernetes has built-in privilege escalation prevention, which means that the Cluster Operator cannot grant privileges it does not have itself, specifically, it cannot grant such privileges in a namespace it cannot access. Therefore, the Cluster Operator must have the privileges necessary for all the components it orchestrates.
The Cluster Operator needs to be able to grant access so that:
-
The Topic Operator can manage
KafkaTopics
, by creatingRoles
andRoleBindings
in the namespace that the operator runs in -
The User Operator can manage
KafkaUsers
, by creatingRoles
andRoleBindings
in the namespace that the operator runs in -
The failure domain of a
Node
is discovered by Strimzi, by creating aClusterRoleBinding
When using rack-aware partition assignment, the broker pod needs to be able to get information about the Node
it is running on,
for example, the Availability Zone in Amazon AWS.
A Node
is a cluster-scoped resource, so access to it can only be granted through a ClusterRoleBinding
, not a namespace-scoped RoleBinding
.
Can standard Kubernetes users create Kafka custom resources?
By default, standard Kubernetes users will not have the privileges necessary to manage the custom resources handled by the Cluster Operator. The cluster administrator can grant a user the necessary privileges using Kubernetes RBAC resources.
For more information, see Designating Strimzi administrators in the Deploying and Upgrading Strimzi guide.
What do the failed to acquire lock warnings in the log mean?
For each cluster, the Cluster Operator executes only one operation at a time. The Cluster Operator uses locks to make sure that there are never two parallel operations running for the same cluster. Other operations must wait until the current operation completes before the lock is released.
- INFO
-
Examples of cluster operations include cluster creation, rolling update, scale down , and scale up.
If the waiting time for the lock takes too long, the operation times out and the following warning message is printed to the log:
2018-03-04 17:09:24 WARNING AbstractClusterOperations:290 - Failed to acquire lock for kafka cluster lock::kafka::myproject::my-cluster
Depending on the exact configuration of STRIMZI_FULL_RECONCILIATION_INTERVAL_MS
and STRIMZI_OPERATION_TIMEOUT_MS
, this
warning message might appear occasionally without indicating any underlying issues.
Operations that time out are picked up in the next periodic reconciliation, so that the operation can acquire the lock and execute again.
Should this message appear periodically, even in situations when there should be no other operations running for a given cluster, it might indicate that the lock was not properly released due to an error. If this is the case, try restarting the Cluster Operator.
Why is hostname verification failing when connecting to NodePorts using TLS?
Currently, off-cluster access using NodePorts with TLS encryption enabled does not support TLS hostname verification. As a result, the clients that verify the hostname will fail to connect. For example, the Java client will fail with the following exception:
Caused by: java.security.cert.CertificateException: No subject alternative names matching IP address 168.72.15.231 found
at sun.security.util.HostnameChecker.matchIP(HostnameChecker.java:168)
at sun.security.util.HostnameChecker.match(HostnameChecker.java:94)
at sun.security.ssl.X509TrustManagerImpl.checkIdentity(X509TrustManagerImpl.java:455)
at sun.security.ssl.X509TrustManagerImpl.checkIdentity(X509TrustManagerImpl.java:436)
at sun.security.ssl.X509TrustManagerImpl.checkTrusted(X509TrustManagerImpl.java:252)
at sun.security.ssl.X509TrustManagerImpl.checkServerTrusted(X509TrustManagerImpl.java:136)
at sun.security.ssl.ClientHandshaker.serverCertificate(ClientHandshaker.java:1501)
... 17 more
To connect, you must disable hostname verification.
In the Java client, you can do this by setting the configuration option ssl.endpoint.identification.algorithm
to an empty string.
When configuring the client using a properties file, you can do it this way:
ssl.endpoint.identification.algorithm=
When configuring the client directly in Java, set the configuration option to an empty string:
props.put("ssl.endpoint.identification.algorithm", "");
11. Custom resource API reference
11.1. Common configuration properties
Common configuration properties apply to more than one resource.
11.1.1. replicas
Use the replicas
property to configure replicas.
The type of replication depends on the resource.
-
KafkaTopic
uses a replication factor to configure the number of replicas of each partition within a Kafka cluster. -
Kafka components use replicas to configure the number of pods in a deployment to provide better availability and scalability.
Note
|
When running a Kafka component on Kubernetes it may not be necessary to run multiple replicas for high availability. When the node where the component is deployed crashes, Kubernetes will automatically reschedule the Kafka component pod to a different node. However, running Kafka components with multiple replicas can provide faster failover times as the other nodes will be up and running. |
11.1.2. bootstrapServers
Use the bootstrapServers
property to configure a list of bootstrap servers.
The bootstrap server lists can refer to Kafka clusters that are not deployed in the same Kubernetes cluster. They can also refer to a Kafka cluster not deployed by Strimzi.
If on the same Kubernetes cluster, each list must ideally contain the Kafka cluster bootstrap service which is named CLUSTER-NAME-kafka-bootstrap
and a port number.
If deployed by Strimzi but on different Kubernetes clusters, the list content depends on the approach used for exposing the clusters (routes, ingress, nodeports or loadbalancers).
When using Kafka with a Kafka cluster not managed by Strimzi, you can specify the bootstrap servers list according to the configuration of the given cluster.
11.1.3. ssl
Use the three allowed ssl
configuration options for client connection using a specific cipher suite for a TLS version.
A cipher suite combines algorithms for secure connection and data transfer.
You can also configure the ssl.endpoint.identification.algorithm
property to enable or disable hostname verification.
# ...
spec:
config:
ssl.cipher.suites: "TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384" (1)
ssl.enabled.protocols: "TLSv1.2" (2)
ssl.protocol: "TLSv1.2" (3)
ssl.endpoint.identification.algorithm: HTTPS (4)
# ...
-
The cipher suite for TLS using a combination of
ECDHE
key exchange mechanism,RSA
authentication algorithm,AES
bulk encyption algorithm andSHA384
MAC algorithm. -
The SSl protocol
TLSv1.2
is enabled. -
Specifies the
TLSv1.2
protocol to generate the SSL context. Allowed values areTLSv1.1
andTLSv1.2
. -
Hostname verification is enabled by setting to
HTTPS
. An empty string disables the verification.
11.1.4. trustedCertificates
Having set tls
to configure TLS encryption, use the trustedCertificates
property to provide a list of secrets with key names under which the certificates are stored in X.509 format.
You can use the secrets created by the Cluster Operator for the Kafka cluster,
or you can create your own TLS certificate file, then create a Secret
from the file:
kubectl create secret generic MY-SECRET \
--from-file=MY-TLS-CERTIFICATE-FILE.crt
tls:
trustedCertificates:
- secretName: my-cluster-cluster-cert
certificate: ca.crt
- secretName: my-cluster-cluster-cert
certificate: ca2.crt
If certificates are stored in the same secret, it can be listed multiple times.
If you want to enable TLS, but use the default set of public certification authorities shipped with Java,
you can specify trustedCertificates
as an empty array:
tls:
trustedCertificates: []
For information on configuring TLS client authentication, see KafkaClientAuthenticationTls
schema reference.
11.1.5. resources
You request CPU and memory resources for components. Limits specify the maximum resources that can be consumed by a given container.
Resource requests and limits for the Topic Operator and User Operator are set in the Kafka
resource.
Use the reources.requests
and resources.limits
properties to configure resource requests and limits.
For every deployed container, Strimzi allows you to request specific resources and define the maximum consumption of those resources.
Strimzi supports requests and limits for the following types of resources:
-
cpu
-
memory
Strimzi uses the Kubernetes syntax for specifying these resources.
For more information about managing computing resources on Kubernetes, see Managing Compute Resources for Containers.
Resource requests
Requests specify the resources to reserve for a given container. Reserving the resources ensures that they are always available.
Important
|
If the resource request is for more than the available free resources in the Kubernetes cluster, the pod is not scheduled. |
A request may be configured for one or more supported resources.
# ...
resources:
requests:
cpu: 12
memory: 64Gi
# ...
Resource limits
Limits specify the maximum resources that can be consumed by a given container. The limit is not reserved and might not always be available. A container can use the resources up to the limit only when they are available. Resource limits should be always higher than the resource requests.
A resource may be configured for one or more supported limits.
# ...
resources:
limits:
cpu: 12
memory: 64Gi
# ...
Supported CPU formats
CPU requests and limits are supported in the following formats:
-
Number of CPU cores as integer (
5
CPU core) or decimal (2.5
CPU core). -
Number or millicpus / millicores (
100m
) where 1000 millicores is the same1
CPU core.
# ...
resources:
requests:
cpu: 500m
limits:
cpu: 2.5
# ...
Note
|
The computing power of 1 CPU core may differ depending on the platform where Kubernetes is deployed. |
For more information on CPU specification, see the Meaning of CPU.
Supported memory formats
Memory requests and limits are specified in megabytes, gigabytes, mebibytes, and gibibytes.
-
To specify memory in megabytes, use the
M
suffix. For example1000M
. -
To specify memory in gigabytes, use the
G
suffix. For example1G
. -
To specify memory in mebibytes, use the
Mi
suffix. For example1000Mi
. -
To specify memory in gibibytes, use the
Gi
suffix. For example1Gi
.
# ...
resources:
requests:
memory: 512Mi
limits:
memory: 2Gi
# ...
For more details about memory specification and additional supported units, see Meaning of memory.
11.1.6. image
Use the image
property to configure the container image used by the component.
Overriding container images is recommended only in special situations where you need to use a different container registry or a customized image.
For example, if your network does not allow access to the container repository used by Strimzi, you can copy the Strimzi images or build them from the source. However, if the configured image is not compatible with Strimzi images, it might not work properly.
A copy of the container image might also be customized and used for debugging.
You can specify which container image to use for a component using the image
property in the following resources:
-
Kafka.spec.kafka
-
Kafka.spec.zookeeper
-
Kafka.spec.entityOperator.topicOperator
-
Kafka.spec.entityOperator.userOperator
-
Kafka.spec.entityOperator.tlsSidecar
-
Kafka.spec.jmxTrans
-
KafkaConnect.spec
-
KafkaMirrorMaker.spec
-
KafkaMirrorMaker2.spec
-
KafkaBridge.spec
Configuring the image
property for Kafka, Kafka Connect, and Kafka MirrorMaker
Kafka, Kafka Connect, and Kafka MirrorMaker support multiple versions of Kafka. Each component requires its own image. The default images for the different Kafka versions are configured in the following environment variables:
-
STRIMZI_KAFKA_IMAGES
-
STRIMZI_KAFKA_CONNECT_IMAGES
-
STRIMZI_KAFKA_MIRROR_MAKER_IMAGES
These environment variables contain mappings between the Kafka versions and their corresponding images.
The mappings are used together with the image
and version
properties:
-
If neither
image
norversion
are given in the custom resource then theversion
will default to the Cluster Operator’s default Kafka version, and the image will be the one corresponding to this version in the environment variable. -
If
image
is given butversion
is not, then the given image is used and theversion
is assumed to be the Cluster Operator’s default Kafka version. -
If
version
is given butimage
is not, then the image that corresponds to the given version in the environment variable is used. -
If both
version
andimage
are given, then the given image is used. The image is assumed to contain a Kafka image with the given version.
The image
and version
for the different components can be configured in the following properties:
-
For Kafka in
spec.kafka.image
andspec.kafka.version
. -
For Kafka Connect and Kafka MirrorMaker in
spec.image
andspec.version
.
Warning
|
It is recommended to provide only the version and leave the image property unspecified.
This reduces the chance of making a mistake when configuring the custom resource.
If you need to change the images used for different versions of Kafka, it is preferable to configure the Cluster Operator’s environment variables.
|
Configuring the image
property in other resources
For the image
property in the other custom resources, the given value will be used during deployment.
If the image
property is missing, the image
specified in the Cluster Operator configuration will be used.
If the image
name is not defined in the Cluster Operator configuration, then the default value will be used.
-
For Topic Operator:
-
Container image specified in the
STRIMZI_DEFAULT_TOPIC_OPERATOR_IMAGE
environment variable from the Cluster Operator configuration. -
quay.io/strimzi/operator:0.27.0
container image.
-
-
For User Operator:
-
Container image specified in the
STRIMZI_DEFAULT_USER_OPERATOR_IMAGE
environment variable from the Cluster Operator configuration. -
quay.io/strimzi/operator:0.27.0
container image.
-
-
For Entity Operator TLS sidecar:
-
Container image specified in the
STRIMZI_DEFAULT_TLS_SIDECAR_ENTITY_OPERATOR_IMAGE
environment variable from the Cluster Operator configuration. -
quay.io/strimzi/kafka:0.27.0-kafka-3.0.0
container image.
-
-
For Kafka Exporter:
-
Container image specified in the
STRIMZI_DEFAULT_KAFKA_EXPORTER_IMAGE
en
-