Operator SDK - Samples - Spring Boot - Auto Config

Sample usage with Spring Boot

License

License

Categories

Categories

Spring Boot Container Microservices Auto Application Layer Libs Code Generators Configuration config
GroupId

GroupId

io.javaoperatorsdk
ArtifactId

ArtifactId

operator-framework-samples-spring-boot-auto-configuration
Last Version

Last Version

1.8.2
Release Date

Release Date

Type

Type

jar
Description

Description

Operator SDK - Samples - Spring Boot - Auto Config
Sample usage with Spring Boot

Download operator-framework-samples-spring-boot-auto-configuration

How to add to project

<!-- https://jarcasting.com/artifacts/io.javaoperatorsdk/operator-framework-samples-spring-boot-auto-configuration/ -->
<dependency>
    <groupId>io.javaoperatorsdk</groupId>
    <artifactId>operator-framework-samples-spring-boot-auto-configuration</artifactId>
    <version>1.8.2</version>
</dependency>
// https://jarcasting.com/artifacts/io.javaoperatorsdk/operator-framework-samples-spring-boot-auto-configuration/
implementation 'io.javaoperatorsdk:operator-framework-samples-spring-boot-auto-configuration:1.8.2'
// https://jarcasting.com/artifacts/io.javaoperatorsdk/operator-framework-samples-spring-boot-auto-configuration/
implementation ("io.javaoperatorsdk:operator-framework-samples-spring-boot-auto-configuration:1.8.2")
'io.javaoperatorsdk:operator-framework-samples-spring-boot-auto-configuration:jar:1.8.2'
<dependency org="io.javaoperatorsdk" name="operator-framework-samples-spring-boot-auto-configuration" rev="1.8.2">
  <artifact name="operator-framework-samples-spring-boot-auto-configuration" type="jar" />
</dependency>
@Grapes(
@Grab(group='io.javaoperatorsdk', module='operator-framework-samples-spring-boot-auto-configuration', version='1.8.2')
)
libraryDependencies += "io.javaoperatorsdk" % "operator-framework-samples-spring-boot-auto-configuration" % "1.8.2"
[io.javaoperatorsdk/operator-framework-samples-spring-boot-auto-configuration "1.8.2"]

Dependencies

compile (4)

Group / Artifact Type Version
io.javaoperatorsdk : operator-framework-samples-common jar 1.8.2
io.javaoperatorsdk : operator-framework-spring-boot-starter jar 1.8.2
org.springframework.boot : spring-boot-starter-log4j2 jar
io.javaoperatorsdk : operator-framework-spring-boot-starter-test jar 1.8.2

test (1)

Group / Artifact Type Version
org.springframework.boot : spring-boot-starter-test jar

Project Modules

There are no modules declared in this project.

java-operator-sdk

Java CI with Maven Discord

Build Kubernetes Operators in Java without hassle. Inspired by operator-sdk.

Table of Contents

  1. Features
  2. Why build your own Operator?
  3. Roadmap and Release Notes
  4. Join us on Discord!
  5. Usage

Features

  • Framework for handling Kubernetes API events
  • Automatic registration of Custom Resource watches
  • Retry action on failure
  • Smart event scheduling (only handle the latest event for the same resource)

Check out this blog post about the non-trivial yet common problems needed to be solved for every operator. In case you are interested how to handle more complex scenarios take a look on event sources.

Why build your own Operator?

  • Infrastructure automation using the power and flexibility of Java. See blog post.
  • Provisioning of complex applications - avoiding Helm chart hell
  • Integration with Cloud services - e.g. Secret stores
  • Safer deployment of applications - only expose cluster to users by Custom Resources

Roadmap and Release Notes

  • Testing of the framework and all samples while running on a real cluster.
  • Generate a project skeleton
  • Generate Java classes from CRD
  • Integrate with OLM (Operator Lifecycle Manager)

Overview of the 1.9.0 changes

Overview of the 1.8.0 changes

Overview of the 1.7.0 changes
  • Doneable classes have been removed along with all the involved complexity
  • Controller annotation has been simplified: the crdName field has been removed as that value is computed from the associated custom resource implementation
  • Custom Resource implementation classes now need to be annotated with Group and Version annotations so that they can be identified properly. Optionally, they can also be annotated with Kind (if the name of the implementation class doesn't match the desired kind) and Plural if the plural version cannot be automatically computed (or the default computed version doesn't match your expectations).
  • The CustomResource class that needs to be extended is now parameterized with spec and status types, so you can have an empty default implementation that does what you'd expect. If you don't need a status, using Void for the associated type should work.
  • Custom Resources that are namespace-scoped need to implement the Namespaced interface so that the client can generate the proper URLs. This means, in particular, that CustomResource implementations that do not implement Namespaced are considered cluster-scoped. As a consequence, the isClusterScoped method/field has been removed from the appropriate classes (Controller annotation, in particular) as this is now inferred from the CustomResource type associated with your Controller.

Many of these changes might not be immediately apparent but will result in 404 errors when connecting to the cluster. Please check that the Custom Resource implementations are properly annotated and that the value corresponds to your CRD manifest. If the namespace appear to be missing in your request URL, don't forget that namespace-scoped Custom Resources need to implement the Namescaped interface.

Join us on Discord!

Discord Invite Link

Usage

We have several sample Operators under the samples directory:

  • pure-java: Minimal Operator implementation which only parses the Custom Resource and prints to stdout. Implemented with and without Spring Boot support. The two samples share the common module.
  • spring-boot-plain: Sample showing integration with Spring Boot.

There are also more samples in the standalone samples repo:

  • webserver: Simple example creating an NGINX webserver from a Custom Resource containing HTML code.
  • mysql-schema: Operator managing schemas in a MySQL database.
  • tomcat: Operator with two controllers, managing Tomcat instances and Webapps for these.

Add dependency to your project with Maven:

<dependency>
  <groupId>io.javaoperatorsdk</groupId>
  <artifactId>operator-framework</artifactId>
  <version>{see https://search.maven.org/search?q=a:operator-framework for latest version}</version>
</dependency>

Or alternatively with Gradle, which also requires declaring the SDK as an annotation processor to generate the mappings between controllers and custom resource classes:

dependencies {
    implementation "io.javaoperatorsdk:operator-framework:${javaOperatorVersion}"
    annotationProcessor "io.javaoperatorsdk:operator-framework:${javaOperatorVersion}"
}

Once you've added the dependency, define a main method initializing the Operator and registering a controller.

public class Runner {

   public static void main(String[] args) {
       Operator operator = new Operator(new DefaultKubernetesClient(),
           DefaultConfigurationService.instance());
       operator.register(new WebServerController());
   }
}

The Controller implements the business logic and describes all the classes needed to handle the CRD.

@Controller
public class WebServerController implements ResourceController<WebServer> {
   
    // Return the changed resource, so it gets updated. See javadoc for details.
    @Override
    public UpdateControl<CustomService> createOrUpdateResource(CustomService resource, Context<WebServer> context) {
        // ... your logic ...
        return UpdateControl.updateStatusSubResource(resource);
    }
}

A sample custom resource POJO representation

@Group("sample.javaoperatorsdk")
@Version("v1")
public class WebServer extends CustomResource<WebServerSpec, WebServerStatus> implements Namespaced {}

public class WebServerSpec {

    private String html;

    public String getHtml() {
        return html;
    }

    public void setHtml(String html) {
        this.html = html;
    }
}

Deactivating CustomResource implementations validation

The operator will, by default, query the deployed CRDs to check that the CustomResource implementations match what is known to the cluster. This requires an additional query to the cluster and, sometimes, elevated privileges for the operator to be able to read the CRDs from the cluster. This validation is mostly meant to help users new to operator development get started and avoid common mistakes. Advanced users or production deployments might want to skip this step. This is done by setting the CHECK_CRD_ENV_KEY environment variable to false.

Automatic generation of CRDs

To automatically generate CRD manifests from your annotated Custom Resource classes, you only need to add the following dependencies to your project:

<dependency>
  <groupId>io.fabric8</groupId>
  <artifactId>crd-generator-apt</artifactId>
  <scope>provided</scope>
</dependency>

The CRD will be generated in target/classes/META-INF/fabric8 (or in target/test-classes/META-INF/fabric8, if you use the test scope) with the CRD name suffixed by the generated spec version. For example, a CR using the java-operator-sdk.io group with a mycrs plural form will result in 2 files:

  • mycrs.java-operator-sdk.io-v1.yml
  • mycrs.java-operator-sdk.io-v1beta1.yml

NOTE:

Quarkus users using the quarkus-operator-sdk extension do not need to add any extra dependency to get their CRD generated as this is handled by the extension itself.

Quarkus

A Quarkus extension is also provided to ease the development of Quarkus-based operators.

Add this dependency to your project:

<dependency>
  <groupId>io.quarkiverse.operatorsdk</groupId>
  <artifactId>quarkus-operator-sdk</artifactId>
  <version>{see https://search.maven.org/search?q=a:quarkus-operator-sdk for latest version}</version>
</dependency>

Create an Application, Quarkus will automatically create and inject a KubernetesClient (or OpenShiftClient), Operator, ConfigurationService and ResourceController instances that your application can use. Below, you can see the minimal code you need to write to get your operator and controllers up and running:

@QuarkusMain
public class QuarkusOperator implements QuarkusApplication {

  @Inject Operator operator;

  public static void main(String... args) {
    Quarkus.run(QuarkusOperator.class, args);
  }

  @Override
  public int run(String... args) throws Exception {
    operator.start();
    Quarkus.waitForExit();
    return 0;
  }
}

Spring Boot

You can also let Spring Boot wire your application together and automatically register the controllers.

Add this dependency to your project:

<dependency>
 <groupId>io.javaoperatorsdk</groupId>
 <artifactId>operator-framework-spring-boot-starter</artifactId>
 <version>{see https://search.maven.org/search?q=a:operator-framework-spring-boot-starter for latest version}</version>
</dependency>

Create an Application

@SpringBootApplication
public class Application {
    public static void main(String[] args) {
        SpringApplication.run(Application.class, args);
    }
}

Spring Boot test support

Adding the following dependency would let you mock the operator for the tests where loading the spring container is necessary, but it doesn't need real access to a Kubernetes cluster.

<dependency>
 <groupId>io.javaoperatorsdk</groupId>
 <artifactId>operator-framework-spring-boot-starter-test</artifactId>
 <version>{see https://search.maven.org/search?q=a:operator-framework-spring-boot-starter for latest version}</version>
</dependency>

Mock the operator:

@SpringBootTest
@EnableMockOperator
public class SpringBootStarterSampleApplicationTest {

  @Test
  void contextLoads() {}
}

Versions

Version
1.8.2
1.8.1
1.8.0
1.7.5
1.7.4
1.7.3
1.7.2
1.7.1
1.7.0
1.6.2
1.6.1
1.5.0
1.4.0
1.3.0