mn create-app --features=rabbitmq,reactor,graalvm example.micronaut.books --build=maven --lang=kotlin
RabbitMQ and the Micronaut Framework - Event-Driven Applications
Use RabbitMQ to communicate between your Micronaut applications.
Authors: Iván López
Micronaut Version: 3.9.2
1. Getting Started
In this guide, we will create a Micronaut application written in Kotlin.
In this guide, we will create two microservices that will use RabbitMQ to communicate with each other in an asynchronous and decoupled way.
RabbitMQ is an open-source message-broker software that originally implemented the Advanced Message Queuing Protocol (AMQP) and has since been extended with a plug-in architecture to support Streaming Text Oriented Messaging Protocol (STOMP), Message Queuing Telemetry Transport (MQTT), and other protocols.
2. What you will need
To complete this guide, you will need the following:
-
Some time on your hands
-
A decent text editor or IDE
-
JDK 1.8 or greater installed with
JAVA_HOME
configured appropriately
3. Solution
We recommend that you follow the instructions in the next sections and create the application step by step. However, you can go right to the completed example.
-
Download and unzip the source
4. Writing the application
Let’s describe the microservices you will build through the guide.
-
books
- It returns a list of books. It uses a domain consisting of a book name and ISBN. It also publishes a message in RabbitMQ every time a book is accessed. -
analytics
- It connects to RabbitMQ to update the analytics for every book (a counter). It also exposes an endpoint to get the analytics.
4.1. Books microservice
Create the books
microservice using the Micronaut Command Line Interface or with Micronaut Launch.
If you don’t specify the --build argument, Gradle is used as the build tool. If you don’t specify the --lang argument, Java is used as the language.
|
If you use Micronaut Launch, select Micronaut Application as application type and add the rabbitmq
, reactor
, and graalvm
features.
The previous command creates a directory named books
and a Micronaut application inside it with default package example.micronaut
.
Create a BookController
class to handle incoming HTTP requests into the books
microservice:
package example.micronaut
import io.micronaut.http.annotation.Controller
import io.micronaut.http.annotation.Get
import java.util.Optional
@Controller("/books") (1)
class BookController(private val bookService: BookService) { (2)
@Get (3)
fun listAll(): List<Book> = bookService.listAll()
@Get("/{isbn}") (4)
fun findBook(isbn: String): Optional<Book> = bookService.findByIsbn(isbn)
}
1 | The class is defined as a controller with the @Controller annotation mapped to the path /books . |
2 | Inject BookService using constructor injection. |
3 | The @Get annotation maps the listAll method to an HTTP GET request on /books . |
4 | The @Get annotation maps the findBook method to an HTTP GET request on /books/{isbn} . |
The previous controller responds a List<Book>
. Create the Book
POJO:
package example.micronaut
import io.micronaut.serde.annotation.Serdeable
@Serdeable
data class Book(val isbn: String, val name: String)
To keep this guide simple there is no database persistence, and the list of books is kept in memory in BookService
:
package example.micronaut
import java.util.Optional
import javax.annotation.PostConstruct
import jakarta.inject.Singleton
@Singleton
class BookService {
private val bookStore: MutableList<Book> = mutableListOf()
@PostConstruct
fun init() {
bookStore.add(Book("1491950358", "Building Microservices"))
bookStore.add(Book("1680502395", "Release It!"))
bookStore.add(Book("0321601912", "Continuous Delivery"))
}
fun listAll(): List<Book> = bookStore
fun findByIsbn(isbn: String): Optional<Book> =
bookStore.stream()
.filter { (i) -> i == isbn }
.findFirst()
}
4.2. Analytics microservice
Create the analytics
microservice using the Micronaut Command Line Interface or with Micronaut Launch.
mn create-app --features=rabbitmq,graalvm example.micronaut.analytics --build=maven --lang=kotlin
If you don’t specify the --build argument, Gradle is used as the build tool. If you don’t specify the --lang argument, Java is used as the language.
|
If you use Micronaut Launch, select Micronaut Application as application type and add the kafka
and graalvm
features.
To keep this guide simple there is no database persistence, and the books analytics is kept in memory in AnalyticsService
:
package example.micronaut
import java.util.concurrent.ConcurrentHashMap
import jakarta.inject.Singleton
@Singleton
class AnalyticsService {
private val bookAnalytics: MutableMap<Book, Long> = ConcurrentHashMap() (1)
fun updateBookAnalytics(book: Book) { (2)
bookAnalytics.compute(book) { k, v ->
if (v == null) return@compute 1L else return@compute v + 1
}
}
fun listAnalytics(): List<BookAnalytics> = (3)
bookAnalytics.entries.map { (key, value) -> BookAnalytics(key.isbn, value) }
}
1 | Keep the books analytics in memory. |
2 | Initialize and update the analytics for the book passed as parameter. |
3 | Return all the analytics. |
Create the Book
POJO used by AnalyticsService
:
package example.micronaut
import io.micronaut.serde.annotation.Serdeable
@Serdeable
data class Book(val isbn: String, val name: String)
The previous service responds a List<BookAnalytics>
. Create the BookAnalytics
POJO:
package example.micronaut
import io.micronaut.serde.annotation.Serdeable
@Serdeable
data class BookAnalytics(val bookIsbn: String, val count: Long)
Write a test:
package example.micronaut
import io.micronaut.test.extensions.junit5.annotation.MicronautTest
import org.junit.jupiter.api.Assertions.assertEquals
import org.junit.jupiter.api.Test
import jakarta.inject.Inject
@MicronautTest (1)
class AnalyticsServiceTest {
@Inject (2)
lateinit var analyticsService: AnalyticsService
@Test
fun testUpdateBookAnalyticsAndGetAnalytics() {
val b1 = Book("1491950358", "Building Microservices")
val b2 = Book("1680502395", "Release It!")
analyticsService.updateBookAnalytics(b1)
analyticsService.updateBookAnalytics(b1)
analyticsService.updateBookAnalytics(b1)
analyticsService.updateBookAnalytics(b2)
val analytics = analyticsService.listAnalytics()
assertEquals(2, analytics.size)
assertEquals(3, findBookAnalytics(b1, analytics).count)
assertEquals(1, findBookAnalytics(b2, analytics).count)
}
private fun findBookAnalytics(b: Book, analytics: List<BookAnalytics>): BookAnalytics {
val ba : BookAnalytics? = analytics.filter { (bookIsbn) -> bookIsbn == b.isbn }.firstOrNull()
return ba ?: throw RuntimeException("Book not found")
}
}
1 | micronaut-test-junit5 is added automatically to build.gradle (or pom.xml ) when creating an application with the CLI. For more information, see the documentation. |
2 | Just inject the collaborator and @MicronautTest will take care of everything. |
Create a Controller to expose the analytics:
package example.micronaut
import io.micronaut.http.annotation.Controller
import io.micronaut.http.annotation.Get
@Controller("/analytics")
class AnalyticsController(private val analyticsService: AnalyticsService) {
@Get
fun listAnalytics(): List<BookAnalytics> = (1)
analyticsService.listAnalytics()
}
1 | Just expose the analytics. |
The application doesn’t expose the method |
To run the tests:
./mvnw test
Modify the Application
class to use dev
as a default environment:
The Micronaut framework supports the concept of one or many default environments. A default environment is one that is only applied if no other environments are explicitly specified or deduced.
package example.micronaut
import io.micronaut.context.env.Environment.DEVELOPMENT
import io.micronaut.runtime.Micronaut.build
fun main(args: Array<String>) {
build()
.args(*args)
.packages("example.micronaut")
.defaultEnvironments(DEVELOPMENT)
.start()
}
Create src/main/resources/application-dev.yml
. The Micronaut framework applies this configuration file only for the dev
environment.
micronaut:
server:
port: 8081 (1)
1 | Start the analytics microservice on port 8081. |
5. Test Resources
When the application is started locally — either under test or by running the application — resolution of the rabbitmq.uri
property is detected and the Test Resources service will start a local RabbitMQ docker container, and inject the properties required to use this as the message broker.
When running under production, you should replace this property with the location of your production message broker via an environment variable.
RABBITMQ_URI=amqp://production-server:5672
For more information, see the RabbitMQ section of the Test Resources documentation.
6. Running the application
Run the books
microservice:
./mvnw mn:run
16:35:55.614 [main] INFO io.micronaut.runtime.Micronaut - Startup completed in 576ms. Server Running: http://localhost:8080
Run analytics
microservice:
./mvnw mn:run
16:35:55.614 [main] INFO io.micronaut.runtime.Micronaut - Startup completed in 623ms. Server Running: http://localhost:8081
You can run curl
commands to test the application:
curl http://localhost:8080/books
[{"isbn":"1491950358","name":"Building Microservices"},{"isbn":"1680502395","name":"Release It!"},{"isbn":"0321601912","name":"Continuous Delivery"}]
curl http://localhost:8080/books/1491950358
{"isbn":"1491950358","name":"Building Microservices"}
curl http://localhost:8081/analytics
[]
Please note that getting the analytics returns an empty list because the applications are not communicating to each other (yet).
6.1. Books microservice
Via Test Resources the Micronaut application will connect to a RabbitMQ instance running inside Docker so it is not necessary to add anything to application.yml
.
In case you want to change the configuration, add the following:
rabbitmq:
uri: amqp://rabbitmq-server:5672
6.1.1. Create RabbitMQ exchange, queue and binding
Before being able to send and receive messages using RabbitMQ it is necessary to define the exchange, queue and binding. One option is create them directly in the RabbitMQ Admin UI available on port 15672.
Use guest for both username and password.
|
Another option is to create them programmatically.
Create the class ChannelPoolListener
:
package example.micronaut
import com.rabbitmq.client.BuiltinExchangeType
import com.rabbitmq.client.Channel
import io.micronaut.rabbitmq.connect.ChannelInitializer
import java.io.IOException
import jakarta.inject.Singleton
@Singleton
class ChannelPoolListener : ChannelInitializer() {
@Throws(IOException::class)
override fun initialize(channel: Channel, name: String) {
channel.exchangeDeclare("micronaut", BuiltinExchangeType.DIRECT, true) (1)
channel.queueDeclare("analytics", true, false, false, null) (2)
channel.queueBind("analytics", "micronaut", "analytics") (3)
}
}
1 | Define an exchange named micronaut . From the producer point of view everything is sent to the exchange with the appropriate routing key |
2 | Define a queue named analytics . The consumer will listen for messages in that queue. |
3 | Define a binding between the exchange and the queue using the routing key analytics . |
6.1.2. Create RabbitMQ client (producer)
Let’s create an interface to send messages to RabbitMQ. The Micronaut framework will implement the interface at compilation time:
package example.micronaut
import io.micronaut.rabbitmq.annotation.Binding
import io.micronaut.rabbitmq.annotation.RabbitClient
@RabbitClient("micronaut") (1)
interface AnalyticsClient {
@Binding("analytics") (2)
fun updateAnalytics(book: Book) (3)
}
1 | Set the exchange used to send the messages. |
2 | Set the routing key. |
3 | Send the Book POJO. The Micronaut framework will automatically convert it to JSON before sending it. |
6.1.3. Send Analytics information automatically
Sending a message to RabbitMQ is as simple as injecting AnalyticsClient
and calling updateAnalytics
method. The goal
is to do it automatically every time a book is returned, i.e., every time there is a call to http://localhost:8080/books/{isbn}
.
To achieve this we will create an Http Server Filter.
Create the AnalyticsFilter
class:
package example.micronaut
import io.micronaut.http.HttpRequest
import io.micronaut.http.MutableHttpResponse
import io.micronaut.http.annotation.Filter
import io.micronaut.http.filter.HttpServerFilter
import io.micronaut.http.filter.ServerFilterChain
import reactor.core.publisher.Flux
import reactor.core.publisher.Mono
import org.reactivestreams.Publisher
@Filter("/books/?*") (1)
class AnalyticsFilter(private val analyticsClient: AnalyticsClient) (3)
: HttpServerFilter { (2)
override fun doFilter(request: HttpRequest<*>, (4)
chain: ServerFilterChain): Publisher<MutableHttpResponse<*>> =
Flux
.from(chain.proceed(request)) (5)
.flatMap { response: MutableHttpResponse<*> ->
Mono.fromCallable {
val book = response.getBody(Book::class.java) (6)
book.ifPresent { book: Book -> analyticsClient.updateAnalytics(book) } (7)
response
}
}
}
1 | Annotate the class with @Filter and define the ANT Matcher pattern to intercept all the calls to the desire URI. |
2 | The class needs to implement HttpServerFilter . |
3 | Constructor injection for RabbitMQ AnalyticsClient . |
4 | Override doFilter method. |
5 | Execute the request. This will call the controller action. |
6 | Get the response from the controller and return the body as a Book . |
7 | If the book is found, use RabbitMQ client to send a message. |
6.2. Analytics microservice
6.2.1. Create RabbitMQ exchange, queue and binding
As we already did in Books Microservice, let’s create the class ChannelPoolListener
to define the exchange, queue
and binding:
package example.micronaut
import com.rabbitmq.client.BuiltinExchangeType
import com.rabbitmq.client.Channel
import io.micronaut.rabbitmq.connect.ChannelInitializer
import java.io.IOException
import jakarta.inject.Singleton
@Singleton
class ChannelPoolListener : ChannelInitializer() {
@Throws(IOException::class)
override fun initialize(channel: Channel, name: String) {
channel.exchangeDeclare("micronaut", BuiltinExchangeType.DIRECT, true)
channel.queueDeclare("analytics", true, false, false, null)
channel.queueBind("analytics", "micronaut", "analytics")
}
}
Instead of copy-paste the class in every project it would be better to create a new Gradle (or Maven) module and share it among all the microservices. |
6.2.2. Create RabbitMQ consumer
Create a new class to act as a consumer of the messages sent to RabbitMQ by the Books Microservice. The Micronaut framework will
implement the consumer at compile time. Create AnalyticsListener
:
package example.micronaut
import io.micronaut.context.annotation.Requires
import io.micronaut.context.env.Environment
import io.micronaut.rabbitmq.annotation.Queue
import io.micronaut.rabbitmq.annotation.RabbitListener
@Requires(notEnv = [Environment.TEST]) (1)
@RabbitListener (2)
class AnalyticsListener(private val analyticsService: AnalyticsService) { (3)
@Queue("analytics") (4)
fun updateAnalytics(book: Book) =
analyticsService.updateBookAnalytics(book) (5)
}
1 | Do not load this bean for the test environment. This enable us to run the tests without having a RabbitMQ instance running. |
2 | Annotate the class with @RabbitListener to indicate that this bean will consume messages from RabbitMQ. |
3 | Constructor injection for AnalyticsService . |
4 | Annotate the method with @Queue . This listener will listen to messages in analytics queue. |
5 | Call the previously created method to update the analytics for the book. |
6.3. Running the application
Run books
microservice:
./mvnw mn:run
16:35:55.614 [main] INFO io.micronaut.runtime.Micronaut - Startup completed in 576ms. Server Running: http://localhost:8080
Execute a curl
request to get one book:
curl http://localhost:8080/books/1491950358
{"isbn":"1491950358","name":"Building Microservices"}
Open RabbitMQ Admin UI on http://localhost:15672 and use guest
for both username and password. Select queues
and
analytics
queue. You can see that there is a message in the queue.
Expand the "Get messages" option and get one message. You can see all the information: exchange
, routing key, and the
`payload
serialized to JSON:
Run analytics
microservice:
./mvnw mn:run
16:35:55.614 [main] INFO io.micronaut.runtime.Micronaut - Startup completed in 623ms. Server Running: http://localhost:8081
The application will consume and process the message automatically after the startup. Go to RabbitMQ Admin UI and check that the message has been consumed:
Now, run a curl
to get the analytics:
curl http://localhost:8081/analytics
[{"bookIsbn":"1491950358","count":1}]
7. Generate a Micronaut Application Native Executable with GraalVM
We will use GraalVM, the polyglot embeddable virtual machine, to generate a native executable of our Micronaut application.
Compiling native executables ahead of time with GraalVM improves startup time and reduces the memory footprint of JVM-based applications.
Only Java and Kotlin projects support using GraalVM’s native-image tool. Groovy relies heavily on reflection, which is only partially supported by GraalVM.
|
7.1. Native executable generation
The easiest way to install GraalVM on Linux or Mac is to use SDKMan.io.
sdk install java 22.3.r11-grl
If you still use Java 8, use the JDK11 version of GraalVM. |
sdk install java 22.3.r17-grl
For installation on Windows, or for manual installation on Linux or Mac, see the GraalVM Getting Started documentation.
After installing GraalVM, install the native-image
component, which is not installed by default:
gu install native-image
To generate a native executable using Maven, run:
./mvnw package -Dpackaging=native-image
The native executable is created in the target
directory and can be run with target/micronautguide
.
Start the native executables for the two microservices and run the same curl
request as before to check that everything works with GraalVM.
8. Next steps
Read more about RabbitMQ support in the Micronaut framework.