Getting Started

3. Getting Started - Local

See the Local Machine section of the microsite for more information on setting up docker compose and manual installation.spring-doc.cn

Once you have the Data Flow server installed locally, you probably want to get started with orchestrating the deployment of readily available pre-built applications into coherent streaming or batch data pipelines. We have guides to help you get started with both Stream and Batch processing.spring-doc.cn

4. Getting Started - Cloud Foundry

This section covers how to get started with Spring Cloud Data Flow on Cloud Foundry. See the Cloud Foundry section of the microsite for more information on installing Spring Cloud Data Flow on Cloud Foundry.spring-doc.cn

Once you have the Data Flow server installed on Cloud Foundry, you probably want to get started with orchestrating the deployment of readily available pre-built applications into coherent streaming or batch data pipelines. We have guides to help you get started with both Stream and Batch processing.spring-doc.cn

5. Getting Started - Kubernetes

Spring Cloud Data Flow is a toolkit for building data integration and real-time data-processing pipelines.spring-doc.cn

Pipelines consist of Spring Boot applications built with the Spring Cloud Stream or Spring Cloud Task microservice frameworks. This makes Spring Cloud Data Flow suitable for a range of data-processing use cases, from import-export to event streaming and predictive analytics.spring-doc.cn

This project provides support for using Spring Cloud Data Flow with Kubernetes as the runtime for these pipelines, with applications packaged as Docker images.spring-doc.cn

See the Kubernetes section of the microsite for more information on installing Spring Cloud Data Flow on Kubernetes.spring-doc.cn

Once you have the Data Flow server installed on Kubernetes, you probably want to get started with orchestrating the deployment of readily available pre-built applications into a coherent streaming or batch data pipelines. We have guides to help you get started with both Stream and Batch processing.spring-doc.cn

5.1. Application and Server Properties

This section covers how you can customize the deployment of your applications. You can use a number of properties to influence settings for the applications that are deployed. Properties can be applied on a per-application basis or in the appropriate server configuration for all deployed applications.spring-doc.cn

Properties set on a per-application basis always take precedence over properties set as the server configuration. This arrangement lets you override global server level properties on a per-application basis.

Properties to be applied for all deployed Tasks are defined in the src/kubernetes/server/server-config-[binder].yaml file and for Streams in src/kubernetes/skipper/skipper-config-[binder].yaml. Replace [binder] with the messaging middleware you are using — for example, rabbit or kafka.spring-doc.cn

5.1.1. Memory and CPU Settings

Applications are deployed with default memory and CPU settings. If you need to, you can adjust these values. The following example shows how to set Limits to 1000m for CPU and 1024Mi for memory and Requests to 800m for CPU and 640Mi for memory:spring-doc.cn

deployer.<application>.kubernetes.limits.cpu=1000m
deployer.<application>.kubernetes.limits.memory=1024Mi
deployer.<application>.kubernetes.requests.cpu=800m
deployer.<application>.kubernetes.requests.memory=640Mi

Those values results in the following container settings being used:spring-doc.cn

Limits:
  cpu:	1
  memory:	1Gi
Requests:
  cpu:	800m
  memory:	640Mi

You can also control the default values to which to set the cpu and memory globally.spring-doc.cn

The following example shows how to set the CPU and memory for streams:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    limits:
                      memory: 640mi
                      cpu: 500m

The following example shows how to set the CPU and memory for tasks:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    limits:
                      memory: 640mi
                      cpu: 500m

The settings we have used so far affect only the settings for the container. They do not affect the memory setting for the JVM process in the container. If you would like to set JVM memory settings, you can set an environment variable to do so. See the next section for details.spring-doc.cn

5.1.2. Environment Variables

To influence the environment settings for a given application, you can use the spring.cloud.deployer.kubernetes.environmentVariables deployer property. For example, a common requirement in production settings is to influence the JVM memory arguments. You can do so by using the JAVA_TOOL_OPTIONS environment variable, as the following example shows:spring-doc.cn

deployer.<application>.kubernetes.environmentVariables=JAVA_TOOL_OPTIONS=-Xmx1024m
The environmentVariables property accepts a comma-delimited string. If an environment variable contains a value that is also a comma-delimited string, it must be enclosed in single quotation marks — for example, spring.cloud.deployer.kubernetes.environmentVariables=spring.cloud.stream.kafka.binder.brokers='somehost:9092, anotherhost:9093'

This overrides the JVM memory setting for the desired <application> (replace <application> with the name of your application).spring-doc.cn

5.1.3. Liveness and Readiness Probes

The liveness and readiness probes use paths called /health and /info, respectively. They use a delay of 10 for both and a period of 60 and 10 respectively. You can change these defaults when you deploy the stream by using deployer properties. The liveness and readiness probes are applied only to streams.spring-doc.cn

The following example changes the liveness probe (replace <application> with the name of your application) by setting deployer properties:spring-doc.cn

deployer.<application>.kubernetes.livenessProbePath=/health
deployer.<application>.kubernetes.livenessProbeDelay=120
deployer.<application>.kubernetes.livenessProbePeriod=20

You can declare the same as part of the server global configuration for streams, as the following example shows:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    livenessProbePath: /health
                    livenessProbeDelay: 120
                    livenessProbePeriod: 20

Similarly, you can swap liveness for readiness to override the default readiness settings.spring-doc.cn

By default, port 8080 is used as the probe port. You can change the defaults for both liveness and readiness probe ports by using deployer properties, as the following example shows:spring-doc.cn

deployer.<application>.kubernetes.readinessProbePort=7000
deployer.<application>.kubernetes.livenessProbePort=7000

You can declare the same as part of the global configuration for streams, as the following example shows:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    readinessProbePort: 7000
                    livenessProbePort: 7000

By default, the liveness and readiness probe paths use Spring Boot 2.x+ actuator endpoints. To use Spring Boot 1.x actuator endpoint paths, you must adjust the liveness and readiness values, as the following example shows (replace <application> with the name of your application):spring-doc.cn

deployer.<application>.kubernetes.livenessProbePath=/health
deployer.<application>.kubernetes.readinessProbePath=/info

To automatically set both liveness and readiness endpoints on a per-application basis to the default Spring Boot 1.x paths, you can set the following property:spring-doc.cn

deployer.<application>.kubernetes.bootMajorVersion=1

You can access secured probe endpoints by using credentials stored in a Kubernetes secret. You can use an existing secret, provided the credentials are contained under the credentials key name of the secret’s data block. You can configure probe authentication on a per-application basis. When enabled, it is applied to both the liveness and readiness probe endpoints by using the same credentials and authentication type. Currently, only Basic authentication is supported.spring-doc.cn

To create a new secret:spring-doc.cn

  1. Generate the base64 string with the credentials used to access the secured probe endpoints.spring-doc.cn

    Basic authentication encodes a username and a password as a base64 string in the format of username:password.spring-doc.cn

    The following example (which includes output and in which you should replace user and pass with your values) shows how to generate a base64 string:spring-doc.cn

    $ echo -n "user:pass" | base64
    dXNlcjpwYXNz
  2. With the encoded credentials, create a file (for example, myprobesecret.yml) with the following contents:spring-doc.cn

    apiVersion: v1
    kind: Secret
    metadata:
      name: myprobesecret
    type: Opaque
    data:
      credentials: GENERATED_BASE64_STRING
  3. Replace GENERATED_BASE64_STRING with the base64-encoded value generated earlier.spring-doc.cn

  4. Create the secret by using kubectl, as the following example shows:spring-doc.cn

    $ kubectl create -f ./myprobesecret.yml
    secret "myprobesecret" created
  5. Set the following deployer properties to use authentication when accessing probe endpoints, as the following example shows:spring-doc.cn

    deployer.<application>.kubernetes.probeCredentialsSecret=myprobesecret

    Replace <application> with the name of the application to which to apply authentication.spring-doc.cn

5.1.4. Using SPRING_APPLICATION_JSON

You can use a SPRING_APPLICATION_JSON environment variable to set Data Flow server properties (including the configuration of Maven repository settings) that are common across all of the Data Flow server implementations. These settings go at the server level in the container env section of a deployment YAML. The following example shows how to do so:spring-doc.cn

env:
- name: SPRING_APPLICATION_JSON
  value: "{ \"maven\": { \"local-repository\": null, \"remote-repositories\": { \"repo1\": { \"url\": \"https://repo.spring.io/libs-snapshot\"} } } }"

5.1.5. Private Docker Registry

You can pull Docker images from a private registry on a per-application basis. First, you must create a secret in the cluster. Follow the Pull an Image from a Private Registry guide to create the secret.spring-doc.cn

Once you have created the secret, you can use the imagePullSecret property to set the secret to use, as the following example shows:spring-doc.cn

deployer.<application>.kubernetes.imagePullSecret=mysecret

Replace <application> with the name of your application and mysecret with the name of the secret you created earlier.spring-doc.cn

You can also configure the image pull secret at the global server level.spring-doc.cn

The following example shows how to do so for streams:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    imagePullSecret: mysecret

The following example shows how to do so for tasks:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    imagePullSecret: mysecret

Replace mysecret with the name of the secret you created earlier.spring-doc.cn

5.1.6. Annotations

You can add annotations to Kubernetes objects on a per-application basis. The supported object types are pod Deployment, Service, and Job. Annotations are defined in a key:value format, allowing for multiple annotations separated by a comma. For more information and use cases on annotations, see Annotations.spring-doc.cn

The following example shows how you can configure applications to use annotations:spring-doc.cn

deployer.<application>.kubernetes.podAnnotations=annotationName:annotationValue
deployer.<application>.kubernetes.serviceAnnotations=annotationName:annotationValue,annotationName2:annotationValue2
deployer.<application>.kubernetes.jobAnnotations=annotationName:annotationValue

Replace <application> with the name of your application and the value of your annotations.spring-doc.cn

5.1.7. Entry Point Style

An entry point style affects how application properties are passed to the container to be deployed. Currently, three styles are supported:spring-doc.cn

  • exec (default): Passes all application properties and command line arguments in the deployment request as container arguments. Application properties are transformed into the format of --key=value.spring-doc.cn

  • shell: Passes all application properties and command line arguments as environment variables. Each of the applicationor command-line argument properties is transformed into an uppercase string and . characters are replaced with _.spring-doc.cn

  • boot: Creates an environment variable called SPRING_APPLICATION_JSON that contains a JSON representation of all application properties. Command line arguments from the deployment request are set as container args.spring-doc.cn

In all cases, environment variables defined at the server-level configuration and on a per-application basis are sent on to the container as is.

You can configure an application as follows:spring-doc.cn

deployer.<application>.kubernetes.entryPointStyle=<Entry Point Style>

Replace <application> with the name of your application and <Entry Point Style> with your desired entry point style.spring-doc.cn

You can also configure the entry point style at the global server level.spring-doc.cn

The following example shows how to do so for streams:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    entryPointStyle: entryPointStyle

The following example shows how to do so for tasks:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    entryPointStyle: entryPointStyle

Replace entryPointStyle with the desired entry point style.spring-doc.cn

You should choose an Entry Point Style of either exec or shell, to correspond to how the ENTRYPOINT syntax is defined in the container’s Dockerfile. For more information and uses cases on exec versus shell, see the ENTRYPOINT section of the Docker documentation.spring-doc.cn

Using the boot entry point style corresponds to using the exec style ENTRYPOINT. Command line arguments from the deployment request are passed to the container, with the addition of application properties being mapped into the SPRING_APPLICATION_JSON environment variable rather than command line arguments.spring-doc.cn

When you use the boot Entry Point Style, the deployer.<application>.kubernetes.environmentVariables property must not contain SPRING_APPLICATION_JSON.

5.1.8. Deployment Service Account

You can configure a custom service account for application deployments through properties. You can use an existing service account or create a new one. One way to create a service account is by using kubectl, as the following example shows:spring-doc.cn

$ kubectl create serviceaccount myserviceaccountname
serviceaccount "myserviceaccountname" created

Then you can configure individual applications as follows:spring-doc.cn

deployer.<application>.kubernetes.deploymentServiceAccountName=myserviceaccountname

Replace <application> with the name of your application and myserviceaccountname with your service account name.spring-doc.cn

You can also configure the service account name at the global server level.spring-doc.cn

The following example shows how to do so for streams:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    deploymentServiceAccountName: myserviceaccountname

The following example shows how to do so for tasks:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    deploymentServiceAccountName: myserviceaccountname

Replace myserviceaccountname with the service account name to be applied to all deployments.spring-doc.cn

5.1.9. Image Pull Policy

An image pull policy defines when a Docker image should be pulled to the local registry. Currently, three policies are supported:spring-doc.cn

  • IfNotPresent (default): Do not pull an image if it already exists.spring-doc.cn

  • Always: Always pull the image regardless of whether it already exists.spring-doc.cn

  • Never: Never pull an image. Use only an image that already exists.spring-doc.cn

The following example shows how you can individually configure applications:spring-doc.cn

deployer.<application>.kubernetes.imagePullPolicy=Always

Replace <application> with the name of your application and Always with your desired image pull policy.spring-doc.cn

You can configure an image pull policy at the global server level.spring-doc.cn

The following example shows how to do so for streams:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    imagePullPolicy: Always

The following example shows how to do so for tasks:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    imagePullPolicy: Always

Replace Always with your desired image pull policy.spring-doc.cn

5.1.10. Deployment Labels

You can set custom labels on objects related to Deployment. See Labels for more information on labels. Labels are specified in key:value format.spring-doc.cn

The following example shows how you can individually configure applications:spring-doc.cn

deployer.<application>.kubernetes.deploymentLabels=myLabelName:myLabelValue

Replace <application> with the name of your application, myLabelName with your label name, and myLabelValue with the value of your label.spring-doc.cn

Additionally, you can apply multiple labels, as the following example shows:spring-doc.cn

deployer.<application>.kubernetes.deploymentLabels=myLabelName:myLabelValue,myLabelName2:myLabelValue2

5.1.11. Tolerations

Tolerations work with taints to ensure pods are not scheduled onto particular nodes. Tolerations are set into the pod configuration while taints are set onto nodes. See the Taints and Tolerations section of the Kubernetes reference for more information.spring-doc.cn

The following example shows how you can individually configure applications:spring-doc.cn

deployer.<application>.kubernetes.tolerations=[{key: 'mykey' operator: 'Equal', value: 'myvalue', effect: 'NoSchedule'}]

Replace <application> with the name of your application and the key-value pairs according to your desired toleration configuration.spring-doc.cn

You can configure tolerations at the global server level as well.spring-doc.cn

The following example shows how to do so for streams:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    tolerations:
                      - key: mykey
                        operator: Equal
                        value: myvalue
                        effect: NoSchedule

The following example shows how to do so for tasks:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    tolerations:
                      - key: mykey
                        operator: Equal
                        value: myvalue
                        effect: NoSchedule

Replace the tolerations key-value pairs according to your desired toleration configuration.spring-doc.cn

5.1.12. Secret References

Secrets can be referenced and their entire data contents can be decoded and inserted into the pod environment as individual variables. See the Configure all key-value pairs in a Secret as container environment variables section of the Kubernetes reference for more information.spring-doc.cn

The following example shows how you can individually configure applications:spring-doc.cn

deployer.<application>.kubernetes.secretRefs=testsecret

You can also specify multiple secrets, as follows:spring-doc.cn

deployer.<application>.kubernetes.secretRefs=[testsecret,anothersecret]

Replace <application> with the name of your application and the secretRefs attribute with the appropriate values for your application environment and secret.spring-doc.cn

You can configure secret references at the global server level as well.spring-doc.cn

The following example shows how to do so for streams:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    secretRefs:
                      - testsecret
                      - anothersecret

The following example shows how to do so for tasks:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    secretRefs:
                      - testsecret
                      - anothersecret

Replace the items of secretRefs with one or more secret names.spring-doc.cn

5.1.13. Secret Key References

Secrets can be referenced and their decoded value can be inserted into the pod environment. See the Using Secrets as Environment Variables section of the Kubernetes reference for more information.spring-doc.cn

The following example shows how you can individually configure applications:spring-doc.cn

deployer.<application>.kubernetes.secretKeyRefs=[{envVarName: 'MY_SECRET', secretName: 'testsecret', dataKey: 'password'}]

Replace <application> with the name of your application and the envVarName, secretName, and dataKey attributes with the appropriate values for your application environment and secret.spring-doc.cn

You can configure secret key references at the global server level as well.spring-doc.cn

The following example shows how to do so for streams:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    secretKeyRefs:
                      - envVarName: MY_SECRET
                        secretName: testsecret
                        dataKey: password

The following example shows how to do so for tasks:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    secretKeyRefs:
                      - envVarName: MY_SECRET
                        secretName: testsecret
                        dataKey: password

Replace the envVarName, secretName, and dataKey attributes with the appropriate values for your secret.spring-doc.cn

5.1.14. ConfigMap References

A ConfigMap can be referenced and its entire data contents can be decoded and inserted into the pod environment as individual variables. See the Configure all key-value pairs in a ConfigMap as container environment variables section of the Kubernetes reference for more information.spring-doc.cn

The following example shows how you can individually configure applications:spring-doc.cn

deployer.<application>.kubernetes.configMapRefs=testcm

You can also specify multiple ConfigMap instances, as follows:spring-doc.cn

deployer.<application>.kubernetes.configMapRefs=[testcm,anothercm]

Replace <application> with the name of your application and the configMapRefs attribute with the appropriate values for your application environment and ConfigMap.spring-doc.cn

You can configure ConfigMap references at the global server level as well.spring-doc.cn

The following example shows how to do so for streams. Edit the appropriate skipper-config-(binder).yaml, replacing (binder) with the corresponding binder in use:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    configMapRefs:
                      - testcm
                      - anothercm

The following example shows how to do so for tasks by editing the server-config.yaml file:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    configMapRefs:
                      - testcm
                      - anothercm

Replace the items of configMapRefs with one or more secret names.spring-doc.cn

5.1.15. ConfigMap Key References

A ConfigMap can be referenced and its associated key value inserted into the pod environment. See the Define container environment variables using ConfigMap data section of the Kubernetes reference for more information.spring-doc.cn

The following example shows how you can individually configure applications:spring-doc.cn

deployer.<application>.kubernetes.configMapKeyRefs=[{envVarName: 'MY_CM', configMapName: 'testcm', dataKey: 'platform'}]

Replace <application> with the name of your application and the envVarName, configMapName, and dataKey attributes with the appropriate values for your application environment and ConfigMap.spring-doc.cn

You can configure ConfigMap references at the global server level as well.spring-doc.cn

The following example shows how to do so for streams. Edit the appropriate skipper-config-(binder).yaml, replacing (binder) with the corresponding binder in use:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    configMapKeyRefs:
                      - envVarName: MY_CM
                        configMapName: testcm
                        dataKey: platform

The following example shows how to do so for tasks by editing the server-config.yaml file:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    configMapKeyRefs:
                      - envVarName: MY_CM
                        configMapName: testcm
                        dataKey: platform

Replace the envVarName, configMapName, and dataKey attributes with the appropriate values for your ConfigMap.spring-doc.cn

5.1.16. Pod Security Context

You can confiure the pod security context to run processes under the specified UID (user ID) or GID (group ID). This is useful when you want to not run processes under the default root UID and GID. You can define either the runAsUser (UID) or fsGroup (GID), and you can configure them to work together. See the Security Context section of the Kubernetes reference for more information.spring-doc.cn

The following example shows how you can individually configure application pods:spring-doc.cn

deployer.<application>.kubernetes.podSecurityContext={runAsUser: 65534, fsGroup: 65534}

Replace <application> with the name of your application and the runAsUser and/or fsGroup attributes with the appropriate values for your container environment.spring-doc.cn

You can configure the pod security context at the global server level as well.spring-doc.cn

The following example shows how to do so for streams. Edit the appropriate skipper-config-(binder).yaml, replacing (binder) with the corresponding binder in use:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    podSecurityContext:
                      runAsUser: 65534
                      fsGroup: 65534

The following example shows how to do so for tasks by editing the server-config.yaml file:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    podSecurityContext:
                      runAsUser: 65534
                      fsGroup: 65534

Replace the runAsUser and/or fsGroup attributes with the appropriate values for your container environment.spring-doc.cn

5.1.17. Service Ports

When you deploy applications, a kubernetes Service object is created with a default port of 8080. If the server.port property is set, it overrides the default port value. You can add additional ports to the Service object on a per-application basis. You can add multiple ports with a comma delimiter.spring-doc.cn

The following example shows how you can configure additional ports on a Service object for an application:spring-doc.cn

deployer.<application>.kubernetes.servicePorts=5000
deployer.<application>.kubernetes.servicePorts=5000,9000

Replace <application> with the name of your application and the value of your ports.spring-doc.cn

5.1.18. StatefulSet Init Container

When deploying an application by using a StatefulSet, an Init Container is used to set the instance index in the pod. By default, the image used is busybox, which you can be customize.spring-doc.cn

The following example shows how you can individually configure application pods:spring-doc.cn

deployer.<application>.kubernetes.statefulSetInitContainerImageName=myimage:mylabel

Replace <application> with the name of your application and the statefulSetInitContainerImageName attribute with the appropriate value for your environment.spring-doc.cn

You can configure the StatefulSet Init Container at the global server level as well.spring-doc.cn

The following example shows how to do so for streams. Edit the appropriate skipper-config-(binder).yaml, replacing (binder) with the corresponding binder in use:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        skipper:
          server:
            platform:
              kubernetes:
                accounts:
                  default:
                    statefulSetInitContainerImageName: myimage:mylabel

The following example shows how to do so for tasks by editing the server-config.yaml file:spring-doc.cn

data:
  application.yaml: |-
    spring:
      cloud:
        dataflow:
          task:
            platform:
              kubernetes:
                accounts:
                  default:
                    statefulSetInitContainerImageName: myimage:mylabel

Replace the statefulSetInitContainerImageName attribute with the appropriate value for your environment.spring-doc.cn

5.1.19. Init Containers

When you deploy applications, you can set a custom Init Container on a per-application basis. Refer to the Init Containers section of the Kubernetes reference for more information.spring-doc.cn

The following example shows how you can configure an Init Container for an application:spring-doc.cn

deployer.<application>.kubernetes.initContainer={containerName: 'test', imageName: 'busybox:latest', commands: ['sh', '-c', 'echo hello']}

Replace <application> with the name of your application and set the values of the initContainer attributes appropriate for your Init Container.spring-doc.cn