mn create-app example.micronaut.micronautguide --build=gradle --lang=kotlin
Table of Contents
- 1. Getting Started
- 2. What you will need
- 3. Solution
- 4. Writing the Application
- 5. Team Configuration with @ConfigurationProperties
- 6. Team Admin Builder with @ConfigurationBuilder
- 7. Stadiums with @EachProperty
- 8. Running the Application
- 9. Controller
- 10. Generate a Micronaut Application Native Executable with GraalVM
- 11. Next steps
- 12. Help with the Micronaut Framework
@Configuration and @ConfigurationBuilder
Learn how to utilize @Configuration and @ConfigurationBuilder annotations to effectively configure declared properties.
Authors: Nirav Assar
Micronaut Version: 3.9.2
1. Getting Started
In this guide, we will create a Micronaut application written in Kotlin.
In this guide you will learn how to effectively use the annotations @ConfigurationProperties
, @ConfigurationBuilder
, and @EachProperty
to use configured properties in a Micronaut application. These annotations allow declared values to be injected into a bean for easy usage in the application.
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
Create an application 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.
|
The previous command creates a Micronaut application with the default package example.micronaut
in a directory named micronautguide
.
5. Team Configuration with @ConfigurationProperties
Imagine a feature where you can configure a sports team in a declarative manner. The team has a few attributes like team name, color, and players.
team:
name: 'Steelers'
color: 'Black'
player-names:
- 'Mason Rudolph'
- 'James Connor'
With the Micronaut framework, we can use the @ConfigurationProperties
annotation to slurp the configuration into a bean. Each property that matches the configuration in the application.yml
will call the setter in the bean. The bean will be subsequently available for injection in the application!
@ConfigurationProperties("team")
class TeamConfiguration {
var name: String? = null
var color: String? = null
var playerNames: List<String>? = null
5.1. Test @ConfigurationProperties
Let’s validate that the bean is available in the application context and is created with the values declared in the application.yml
.
@Test
fun testTeamConfiguration() {
val names = Arrays.asList("Nirav Assar", "Lionel Messi")
val items: MutableMap<String, Any> = HashMap()
items["team.name"] = "evolution"
items["team.color"] = "green"
items["team.player-names"] = names
val ctx = ApplicationContext.run(items) (1)
val teamConfiguration = ctx.getBean(TeamConfiguration::class.java)
assertEquals("evolution", teamConfiguration.name)
assertEquals("green", teamConfiguration.color)
assertEquals(names.size, teamConfiguration.playerNames!!.size)
names.forEach(Consumer { name: String? -> assertTrue(teamConfiguration.playerNames!!.contains(name!!)) })
ctx.close()
}
1 | Set up configuration properties for the test to use |
6. Team Admin Builder with @ConfigurationBuilder
The Builder pattern is a great way to build configuration objects incrementally. Read about the Builder pattern in this
DZone article to learn more. The Framework supports the Builder pattern with @ConfigurationBuilder
.
Let’s suppose we want to add team administrators to a team. The team administration is composed by using a builder pattern object. We can add a coach, manager and president to the team.
team:
name: 'Steelers'
color: 'Black'
player-names:
- 'Mason Rudolph'
- 'James Connor'
team-admin:
manager: 'Nirav Assar' (1)
coach: 'Mike Tomlin'
president: 'Dan Rooney'
1 | manager property is an example of an element that will be built |
The TeamAdmin
object abides by the Builder pattern.
package example.micronaut
class TeamAdmin private constructor(
val manager: String?,
val coach: String?,
val president: String?) { (1)
data class Builder( (2)
var manager: String? = null,
var coach: String? = null,
var president: String? = null) {
fun withManager(manager: String) = apply { this.manager = manager } (3)
fun withCoach(coach: String) = apply { this.coach = coach }
fun withPresident(president: String) = apply { this.president = president }
fun build() = TeamAdmin(manager, coach, president) (4)
}
}
1 | TeamAdmin is the configuration object which consumes the declared properties. |
2 | The builder object is used to incrementally construct the object. |
3 | An example of a builder method, where a attribute is set and then the builder itself is returned. |
4 | The final build() method creates the TeamAdmin object. |
At the bottom of TeamConfiguration
, we add the inner class TeamAdmin.Builder
and annotate it with @ConfigurationBuilder
.
This tells the Micronaut framework that configuration can be read in and an object can be constructed using the Builder pattern.
We are using the builder only here, so we will have to call builder.build() to actually get the TeamAdmin object, at a later time. In our case, we will call builder.build() in the JUnit test.
|
package example.micronaut
import com.fasterxml.jackson.annotation.JsonIgnoreProperties;
import io.micronaut.context.annotation.ConfigurationBuilder
import io.micronaut.context.annotation.ConfigurationProperties
import io.micronaut.serde.annotation.Serdeable
@Serdeable (1)
@JsonIgnoreProperties("builder") (2)
//tag::teamConfigClassNoBuilder[]
@ConfigurationProperties("team")
class TeamConfiguration {
var name: String? = null
var color: String? = null
var playerNames: List<String>? = null
//end::teamConfigClassNoBuilder[]
//tag::teamConfigClassBuilder[]
@ConfigurationBuilder(prefixes = ["with"], configurationPrefix = "team-admin") (3)
var builder = TeamAdmin.Builder() (4)
//end::teamConfigClassBuilder[]
}
//tag::gettersandsetters[]
//end::gettersandsetters[]
1 | Declare the @Serdeable annotation at the type level in your source code to allow the type to be serialized or deserialized. |
2 | Mark the builder as being ignored during serialization. |
3 | prefixes tells the Micronaut framework to find methods that are prefixed by with ; configurationPrefix allows the developer to customize the application.yml element |
4 | Instantiate the builder object so it can be populated with configuration values. |
6.1. Test @ConfigurationBuilder
We can validate @ConfigurationBuilder
is applied properly with the following JUnit test. The test format is similar to previous tests.
@Test
fun testTeamConfigurationBuilder() {
val names = Arrays.asList("Nirav Assar", "Lionel Messi")
val items: MutableMap<String, Any> = HashMap()
items["team.name"] = "evolution"
items["team.color"] = "green"
items["team.team-admin.manager"] = "Jerry Jones" (1)
items["team.team-admin.coach"] = "Tommy O'Neill"
items["team.team-admin.president"] = "Mark Scanell"
items["team.player-names"] = names
val ctx = ApplicationContext.run(items)
val teamConfiguration = ctx.getBean(TeamConfiguration::class.java)
val teamAdmin = teamConfiguration.builder.build() (2)
assertEquals("evolution", teamConfiguration.name)
assertEquals("green", teamConfiguration.color)
assertEquals("Nirav Assar", teamConfiguration.playerNames!![0])
assertEquals("Lionel Messi", teamConfiguration.playerNames!![1])
// check the builder has values set
assertEquals("Jerry Jones", teamConfiguration.builder.manager)
assertEquals("Tommy O'Neill", teamConfiguration.builder.coach)
assertEquals("Mark Scanell", teamConfiguration.builder.president)
// check the object can be built
assertEquals("Jerry Jones", teamAdmin.manager) (3)
assertEquals("Tommy O'Neill", teamAdmin.coach)
assertEquals("Mark Scanell", teamAdmin.president)
ctx.close()
1 | Properties which will invoke the builder methods on TeamAdmin.Builder |
2 | The builder object is now configured, so we must run build() on it to create the TeamAdmin object |
3 | Verify the object is created with the applicaton.yml properties |
7. Stadiums with @EachProperty
The Micronaut framework is also able to read a "list" of configurations that are related. Imagine we would like to declare stadiums and their attributes.
stadium:
coors: (1)
city: 'Denver'
size: 50000
pnc:
city: 'Pittsburgh'
size: 35000
1 | This element will be the name of the bean. |
We can use @EachProperty
which will cycle through the configuration and read each nested clause as a bean. The higher level
property will be parameterized as the name.
package example.micronaut
import io.micronaut.context.annotation.EachProperty
import io.micronaut.context.annotation.Parameter
import io.micronaut.serde.annotation.Serdeable
@Serdeable (1)
@EachProperty("stadium") (2)
class StadiumConfiguration
constructor(@param:Parameter val name: String) { (3)
var city: String? = null
var size: Int? = null
}
1 | Declare the @Serdeable annotation at the type level in your source code to allow the type to be serialized or deserialized. |
2 | Establish the top layer of configuration |
3 | name is read in from the property key and send as a parameter to the bean. |
7.1. Test @EachProperty
Validate the configuration with a test. Notice multiple beans are created from the configuration. In a controller we can
inject a particular StadiumConfiguration
instance bean by using the @Named
parameter with qualifier name.
package example.micronaut
import io.micronaut.context.ApplicationContext
import io.micronaut.inject.qualifiers.Qualifiers
import org.junit.jupiter.api.Assertions.assertEquals
import org.junit.jupiter.api.Test
class StadiumConfigurationTest {
@Test
fun testStadiumConfiguration() {
val items: MutableMap<String, Any> = HashMap()
items["stadium.fenway.city"] = "Boston" (1)
items["stadium.fenway.size"] = 60000
items["stadium.wrigley.city"] = "Chicago" (1)
items["stadium.wrigley.size"] = 45000
val ctx = ApplicationContext.run(items)
(2)
val fenwayConfiguration = ctx.getBean(StadiumConfiguration::class.java, Qualifiers.byName("fenway"))
val wrigleyConfiguration = ctx.getBean(StadiumConfiguration::class.java, Qualifiers.byName("wrigley"))
assertEquals("fenway", fenwayConfiguration.name)
assertEquals(60000, fenwayConfiguration.size)
assertEquals("wrigley", wrigleyConfiguration.name)
assertEquals(45000, wrigleyConfiguration.size)
ctx.close()
}
}
1 | Multiple configurations can be declared for the same class. |
2 | Since there are multiple beans to retrieve a bean a Qualifier must be sent. |
8. Running the Application
To run the application, use the ./gradlew run
command, which starts the application on port 8080.
9. Controller
Configuration beans can be injected into the application with just like any other beans. As a demonstration, create a controller where the beans are constructor injected. The StadiumConfiguration
class has two instances, so for injection we need to use the @Named
annotation with a qualifier name to specify the bean.
package example.micronaut
import io.micronaut.http.annotation.Controller
import io.micronaut.http.annotation.Get
import jakarta.inject.Named
@Controller("/my")
class MyController(val teamConfiguration: TeamConfiguration,
@Named("pnc") val stadiumConfiguration: StadiumConfiguration) { (1)
@Get("/team")
fun team(): TeamConfiguration {
return teamConfiguration
}
@Get("/stadium")
fun stadium(): StadiumConfiguration {
return stadiumConfiguration
}
}
1 | Injection of configuration beans; @Named annotation is needed to choose which StadiumConfiguration instance is retrieved. |
In the browser go to http://localhost:8080/my/team and http://localhost:8080/my/stadium. |
Add test:
package example.micronaut
import io.micronaut.http.HttpRequest
import io.micronaut.http.client.HttpClient
import io.micronaut.http.client.annotation.Client
import io.micronaut.test.extensions.junit5.annotation.MicronautTest
import org.junit.jupiter.api.Assertions.assertEquals
import org.junit.jupiter.api.Assertions.assertTrue
import org.junit.jupiter.api.Test
import java.util.Arrays
import java.util.function.Consumer
import jakarta.inject.Inject
@MicronautTest
class MyControllerTest(@Client("/") val client: HttpClient) {
@Test
fun testMyTeam() {
val teamConfiguration = client.toBlocking()
.retrieve(HttpRequest.GET<Any>("/my/team"), TeamConfiguration::class.java)
assertEquals("Steelers", teamConfiguration.name)
assertEquals("Black", teamConfiguration.color)
val expectedPlayers = Arrays.asList("Mason Rudolph", "James Connor")
assertEquals(expectedPlayers.size, teamConfiguration.playerNames!!.size)
expectedPlayers.forEach(Consumer { name: String? -> assertTrue(teamConfiguration.playerNames!!.contains(name!!)) })
}
@Test
fun testMyStadium() {
val conf = client.toBlocking()
.retrieve(HttpRequest.GET<Any>("/my/stadium"), StadiumConfiguration::class.java)
assertEquals("Pittsburgh", conf.city)
assertEquals(35000, conf.size)
}
}
10. 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.
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10.1. 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 Gradle, run:
./gradlew nativeCompile
The native executable is created in build/native/nativeCompile
directory and can be run with build/native/nativeCompile/micronautguide
.
It is possible to customize the name of the native executable or pass additional parameters to GraalVM:
graalvmNative {
binaries {
main {
imageName.set('mn-graalvm-application') (1)
buildArgs.add('--verbose') (2)
}
}
}
1 | The native executable name will now be mn-graalvm-application |
2 | It is possible to pass extra arguments to build the native executable |
You can invoke the controller exposed by the native executable:
curl http://localhost:8080/my/stadium
curl http://localhost:8080/my/team
11. Next steps
Visit Micronaut Application Configuration to learn more.
12. Help with the Micronaut Framework
The Micronaut Foundation sponsored the creation of this Guide. A variety of consulting and support services are available.