mn create-app example.micronaut.micronautguide \
--features=crac,micronaut-aot,graalvm \
--build=gradle \
--lang=kotlin \
--test=junit
Table of Contents
Building a Docker Image of your Micronaut application
Micronaut build plugins offer several ways to build Docker images - JAR, GraalVM native executable, CRaC
Authors: Sergio del Amo
Micronaut Version: 4.6.3
1. Getting Started
In this guide, we will create a Micronaut application written in Kotlin.
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 (e.g. IntelliJ IDEA)
-
JDK 17 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 with the Kotlin DSL is used as the build tool. If you don’t specify the --lang argument, Java is used as the language.If you don’t specify the --test argument, JUnit is used for Java and Kotlin, and Spock is used for Groovy.
|
The previous command creates a Micronaut application with the default package example.micronaut
in a directory named micronautguide
.
If you use Micronaut Launch, select Micronaut Application as application type and add crac
, micronaut-aot
, and graalvm
features.
If you have an existing Micronaut application and want to add the functionality described here, you can view the dependency and configuration changes from the specified features, and apply those changes to your application. |
5. Building a Docker Image with the Micronaut Gradle Plugin
The Micronaut Gradle Plugin offers the following tasks to build Docker images:
-
dockerBuild
- Builds a Docker Image using the Docker Gradle plugin -
dockerBuildNative
- Builds a Native Docker Image using GraalVM Native Image -
optimizedDockerBuild
- Build an optimized application and package it into a Docker image. -
optimizedDockerBuildNative
- Build a native image containing the optimized application and package it into a Docker Image
6. Controller
Add a controller which responds with the JSON payload in the root route.
{"message":"Hello World"}
package example.micronaut
import io.micronaut.http.annotation.Controller
import io.micronaut.http.annotation.Get
@Controller (1)
class HelloController {
@Get (2)
fun index() = mapOf("message" to "Hello World") (3)
}
1 | The class is defined as a controller with the @Controller annotation mapped to the path / . |
2 | The @Get annotation maps the method to an HTTP GET request. |
3 | The Micronaut framework will automatically convert it to JSON before sending it. |
7. Time To First Request Measurement script
In this guide, we use the following script to measure time to first request of a Docker image.
#!/usr/bin/env bash
set -e
TYPE="docker"
PORT=8080
DELAY=20
usage() {
echo "$0: Time to first request for native, java or docker applications"
echo ""
echo " $0 [-d|-j|-n] [-p port] ARTIFACT"
echo ""
echo " -d : ARTIFACT is a docker image (default)"
echo " -j : ARTIFACT is a fat jar"
echo " -n : ARTIFACT is a native executable"
echo " -p : port to check (default 8080)"
echo ""
}
while getopts 'djnp:' flag; do
case "${flag}" in
d) TYPE="docker" ;;
j) TYPE="java" ;;
n) TYPE="native" ;;
p) PORT="${OPTARG}" ;;
*) usage
exit 1 ;;
esac
done
shift $(($OPTIND - 1))
echo $1
if [ $# -eq 0 ]; then
echo "Needs the docker image or Jar file to run"
exit 1
fi
execute() {
local END=$((SECONDS+DELAY))
while ! curl -o /dev/null -s "http://localhost:${PORT}"; do
if [ $SECONDS -gt $END ]; then
echo "No response from the app in $DELAY seconds" >&2
exit 1
fi
sleep 0.001;
done
}
mytime() {
exec 3>&1 4>&2
mytime=$(TIMEFORMAT="%3R"; { time $1 1>&3 2>&4; } 2>&1)
exec 3>&- 4>&-
echo $mytime
}
if [[ "$TYPE" == "java" ]]; then
java -jar $1 &
PID=$!
TTFR=$(mytime execute)
kill -9 $PID
elif [[ "$TYPE" == "docker" ]]; then
CONTAINER=$(docker run -d --rm -p $PORT:$PORT --privileged $1)
TTFR=$(mytime execute)
docker container kill $CONTAINER > /dev/null
else
$1 &
PID=$!
TTFR=$(mytime execute)
kill -9 $PID
fi
if [ "$TTFR" != "" ]; then
echo "${TTFR} seconds"
else
exit 1
fi
7.1. Docker Image
Generate a Docker Image with:
./gradlew dockerBuild
...
..
.
Removing intermediate container 784f978688d1
---> e5c1b8b8dbcb
Successfully built e5c1b8b8dbcb
Successfully tagged micronautguide:latest
Created image with ID 'e5c1b8b8dbcb'.
Supply to image name and tag to the time to first request script:
./ttfr.sh micronautguide:latest
micronautguide:latest
...
.
2.473 seconds
7.2. Docker image with a GraalVM native executable inside
Generate a Docker Image with:
./gradlew dockerBuildNative
> Task :generateResourcesConfigFile
[native-image-plugin] Resources configuration written into /Users/sdelamo/github/micronaut-projects/micronaut-guides/build/code/micronaut-docker-image/micronaut-docker-image-gradle-java/build/native/generated/generateResourcesConfigFile/resource-config.json
> Task :dockerfileNative
Dockerfile written to: /Users/sdelamo/github/micronaut-projects/micronaut-guides/build/code/micronaut-docker-image/micronaut-docker-image-gradle-java/build/docker/native-main/DockerfileNative
> Task :dockerBuildNative
...
Step 1/14 : FROM ghcr.io/graalvm/native-image-community:17-ol9 AS graalvm
....
....
....
========================================================================================================================
GraalVM Native Image: Generating 'application' (executable)...
========================================================================================================================
...
Step 14/14 : ENTRYPOINT ["/app/application"]
---> Running in 447363f48c82
Removing intermediate container 447363f48c82
---> 0b57ab829518
Successfully built 0b57ab829518
Successfully tagged micronautguide:latest
Created image with ID '0b57ab829518'.
BUILD SUCCESSFUL in 2m 26s
Run the time to first request script with the Native Docker Image:
./ttfr.sh micronautguide:latest
micronautguide:latest
...
.
0.047
seconds
8. CRaC Docker Image
Generate a Docker Image containing a CRaC enabled JDK and a pre-warmed, checkpointed application:
./gradlew dockerBuildCrac
...
Successfully built ba78619b8d86
Successfully tagged micronautguide:latest
Created image with ID 'ba78619b8d86'.
BUILD SUCCESSFUL in 1m 41s
13 actionable tasks: 9 executed, 4 up-to-date
Run the time to first request script with CRaC Docker Image:
./ttfr.sh micronautguide:latest
micronautguide:latest
...
.
0.462 seconds
8.1. AOT Optimized Docker Image
./gradlew optimizedDockerBuild
Run the time to first request script with AOT optimized Docker Image:
./ttfr.sh micronautguide:latest
micronautguide:latest
...
.
2,359 seconds
8.2. AOT Optimized Docker Image with a native executable inside
./gradlew optimizedDockerBuildNative
Run the time to first request script with AOT optimized Docker Image:
./ttfr.sh micronautguide:latest
micronautguide:latest
...
.
0.039 seconds
9. Comparisons
Micronaut Framework offers many options for packaging your application as a Docker Image. As illustrated in the following chart, you can speed up your Docker Images by using the GraalVM integration in the Micronaut Framework, the CRaC (Coordinated Restore at checkpoint) integration in the Micronaut Framework, Micronaut AOT Gradle Plugin or Maven Plugin integration with Micronaut AOT.
The following chart illustrates the speed gains you can obtain:
Docker Image |
2s 473ms |
Optimized Docker Image |
2s 359ms |
CRaC Docker Image |
462ms |
Native Docker Image |
47ms |
Optimized Native Docker Image |
39ms |
I used the following hardware to calculate the previous benchmarks
Characteristic |
Value |
Model Name |
iMac Pro 2017 |
Processor |
3GHz 10-Core Intel Xeon W |
Memory |
32 GB 2666 MHz DDR4 |
Total Number of Cores |
10 |
Operating System |
Mac OS X 10.15.7 (Mojave) |
10. Next steps
Explore more features with Micronaut Guides.
Learn more about:
11. Help with the Micronaut Framework
The Micronaut Foundation sponsored the creation of this Guide. A variety of consulting and support services are available.
12. License
All guides are released with an Apache license 2.0 license for the code and a Creative Commons Attribution 4.0 license for the writing and media (images…). |