nixpkgs-suyu/doc/languages-frameworks/maven.section.md
Anderson Torres e671d3bbbd Nix docs: remove with lib; from example code
Following [Best Practices](https://nix.dev/guides/best-practices#with-scopes),
`with` is a problematic language construction and should be avoided.

Usually it is employed like a "factorization": `[ X.A X.B X.C X.D ]` is written
`with X; [ A B C D ]`.

However, as shown in the link above, the syntatical rules of `with` are not so
intuitive, and this "distributive rule" is very selective, in the sense that
`with X; [ A B C D ]` is not equivalent to `[ X.A X.B X.C X.D ]`.

However, this factorization is still useful to "squeeze" some code, especially
in lists like `meta.maintainers`.

On the other hand, it becomes less justifiable in bigger scopes. This is
especially true in cases like `with lib;` in the top of expression and in sets
like `meta = with lib; { . . . }`.

That being said, this patch removes most of example code in the current
documentation.

The exceptions are, for now
- doc/functions/generators.section.md
- doc/languages-frameworks/coq.section.md

because, well, they are way more complicated, and I couldn't parse them
mentally - yet another reason why `with` should be avoided!
2024-03-06 11:40:09 -03:00

16 KiB
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Maven

Maven is a well-known build tool for the Java ecosystem however it has some challenges when integrating into the Nix build system.

The following provides a list of common patterns with how to package a Maven project (or any JVM language that can export to Maven) as a Nix package.

Building a package using maven.buildMavenPackage

Consider the following package:

{ lib, fetchFromGitHub, jre, makeWrapper, maven }:

maven.buildMavenPackage rec {
  pname = "jd-cli";
  version = "1.2.1";

  src = fetchFromGitHub {
    owner = "intoolswetrust";
    repo = pname;
    rev = "${pname}-${version}";
    hash = "sha256-rRttA5H0A0c44loBzbKH7Waoted3IsOgxGCD2VM0U/Q=";
  };

  mvnHash = "sha256-kLpjMj05uC94/5vGMwMlFzLKNFOKeyNvq/vmB6pHTAo=";

  nativeBuildInputs = [ makeWrapper ];

  installPhase = ''
    mkdir -p $out/bin $out/share/jd-cli
    install -Dm644 jd-cli/target/jd-cli.jar $out/share/jd-cli

    makeWrapper ${jre}/bin/java $out/bin/jd-cli \
      --add-flags "-jar $out/share/jd-cli/jd-cli.jar"
  '';

  meta = {
    description = "Simple command line wrapper around JD Core Java Decompiler project";
    homepage = "https://github.com/intoolswetrust/jd-cli";
    license = lib.licenses.gpl3Plus;
    maintainers = with lib.maintainers; [ majiir ];
  };
}:

This package calls maven.buildMavenPackage to do its work. The primary difference from stdenv.mkDerivation is the mvnHash variable, which is a hash of all of the Maven dependencies.

::: {.tip} After setting maven.buildMavenPackage, we then do standard Java .jar installation by saving the .jar to $out/share/java and then making a wrapper which allows executing that file; see for additional generic information about packaging Java applications. :::

Stable Maven plugins

Maven defines default versions for its core plugins, e.g. maven-compiler-plugin. If your project does not override these versions, an upgrade of Maven will change the version of the used plugins, and therefore the derivation and hash.

When maven is upgraded, mvnHash for the derivation must be updated as well: otherwise, the project will be built on the derivation of old plugins, and fail because the requested plugins are missing.

This clearly prevents automatic upgrades of Maven: a manual effort must be made throughout nixpkgs by any maintainer wishing to push the upgrades.

To make sure that your package does not add extra manual effort when upgrading Maven, explicitly define versions for all plugins. You can check if this is the case by adding the following plugin to your (parent) POM:

<plugin>
  <groupId>org.apache.maven.plugins</groupId>
  <artifactId>maven-enforcer-plugin</artifactId>
  <version>3.3.0</version>
  <executions>
    <execution>
      <id>enforce-plugin-versions</id>
      <goals>
        <goal>enforce</goal>
      </goals>
      <configuration>
        <rules>
          <requirePluginVersions />
        </rules>
      </configuration>
    </execution>
  </executions>
</plugin>

Manually using mvn2nix

::: {.warning} This way is no longer recommended; see for the simpler and preferred way. :::

For the purposes of this example let's consider a very basic Maven project with the following pom.xml with a single dependency on emoji-java.

<?xml version="1.0" encoding="UTF-8"?>
<project xmlns="http://maven.apache.org/POM/4.0.0" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
        xsi:schemaLocation="http://maven.apache.org/POM/4.0.0 http://maven.apache.org/xsd/maven-4.0.0.xsd">
  <modelVersion>4.0.0</modelVersion>
  <groupId>io.github.fzakaria</groupId>
  <artifactId>maven-demo</artifactId>
  <version>1.0</version>
  <packaging>jar</packaging>
  <name>NixOS Maven Demo</name>

  <dependencies>
    <dependency>
        <groupId>com.vdurmont</groupId>
        <artifactId>emoji-java</artifactId>
        <version>5.1.1</version>
      </dependency>
  </dependencies>
</project>

Our main class file will be very simple:

import com.vdurmont.emoji.EmojiParser;

public class Main {
  public static void main(String[] args) {
    String str = "NixOS :grinning: is super cool :smiley:!";
    String result = EmojiParser.parseToUnicode(str);
    System.out.println(result);
  }
}

You find this demo project at https://github.com/fzakaria/nixos-maven-example.

Solving for dependencies

buildMaven with NixOS/mvn2nix-maven-plugin

buildMaven is an alternative method that tries to follow similar patterns of other programming languages by generating a lock file. It relies on the maven plugin mvn2nix-maven-plugin.

First you generate a project-info.json file using the maven plugin.

This should be executed in the project's source repository or be told which pom.xml to execute with.

# run this step within the project's source repository
 mvn org.nixos.mvn2nix:mvn2nix-maven-plugin:mvn2nix

 cat project-info.json | jq | head
{
  "project": {
    "artifactId": "maven-demo",
    "groupId": "org.nixos",
    "version": "1.0",
    "classifier": "",
    "extension": "jar",
    "dependencies": [
      {
        "artifactId": "maven-resources-plugin",

This file is then given to the buildMaven function, and it returns 2 attributes.

repo: A Maven repository that is a symlink farm of all the dependencies found in the project-info.json

build: A simple derivation that runs through mvn compile & mvn package to build the JAR. You may use this as inspiration for more complicated derivations.

Here is an example of building the Maven repository

{ pkgs ? import <nixpkgs> { } }:
with pkgs;
(buildMaven ./project-info.json).repo

The benefit over the double invocation as we will see below, is that the /nix/store entry is a linkFarm of every package, so that changes to your dependency set doesn't involve downloading everything from scratch.

 tree $(nix-build --no-out-link build-maven-repository.nix) | head
/nix/store/g87va52nkc8jzbmi1aqdcf2f109r4dvn-maven-repository
├── antlr
│   └── antlr
│       └── 2.7.2
│           ├── antlr-2.7.2.jar -> /nix/store/d027c8f2cnmj5yrynpbq2s6wmc9cb559-antlr-2.7.2.jar
│           └── antlr-2.7.2.pom -> /nix/store/mv42fc5gizl8h5g5vpywz1nfiynmzgp2-antlr-2.7.2.pom
├── avalon-framework
│   └── avalon-framework
│       └── 4.1.3
│           ├── avalon-framework-4.1.3.jar -> /nix/store/iv5fp3955w3nq28ff9xfz86wvxbiw6n9-avalon-framework-4.1.3.jar

Double Invocation

::: {.note} This pattern is the simplest but may cause unnecessary rebuilds due to the output hash changing. :::

The double invocation is a simple way to get around the problem that nix-build may be sandboxed and have no Internet connectivity.

It treats the entire Maven repository as a single source to be downloaded, relying on Maven's dependency resolution to satisfy the output hash. This is similar to fetchers like fetchgit, except it has to run a Maven build to determine what to download.

The first step will be to build the Maven project as a fixed-output derivation in order to collect the Maven repository -- below is an example.

::: {.note} Traditionally the Maven repository is at ~/.m2/repository. We will override this to be the $out directory. :::

{ lib, stdenv, maven }:
stdenv.mkDerivation {
  name = "maven-repository";
  buildInputs = [ maven ];
  src = ./.; # or fetchFromGitHub, cleanSourceWith, etc
  buildPhase = ''
    mvn package -Dmaven.repo.local=$out
  '';

  # keep only *.{pom,jar,sha1,nbm} and delete all ephemeral files with lastModified timestamps inside
  installPhase = ''
    find $out -type f \
      -name \*.lastUpdated -or \
      -name resolver-status.properties -or \
      -name _remote.repositories \
      -delete
  '';

  # don't do any fixup
  dontFixup = true;
  outputHashAlgo = "sha256";
  outputHashMode = "recursive";
  # replace this with the correct SHA256
  outputHash = lib.fakeSha256;
}

The build will fail, and tell you the expected outputHash to place. When you've set the hash, the build will return with a /nix/store entry whose contents are the full Maven repository.

::: {.warning} Some additional files are deleted that would cause the output hash to change potentially on subsequent runs. :::

 tree $(nix-build --no-out-link double-invocation-repository.nix) | head
/nix/store/8kicxzp98j68xyi9gl6jda67hp3c54fq-maven-repository
├── backport-util-concurrent
│   └── backport-util-concurrent
│       └── 3.1
│           ├── backport-util-concurrent-3.1.pom
│           └── backport-util-concurrent-3.1.pom.sha1
├── classworlds
│   └── classworlds
│       ├── 1.1
│       │   ├── classworlds-1.1.jar

If your package uses SNAPSHOT dependencies or version ranges; there is a strong likelihood that over-time your output hash will change since the resolved dependencies may change. Hence this method is less recommended then using buildMaven.

Building a JAR

Regardless of which strategy is chosen above, the step to build the derivation is the same.

{ stdenv, maven, callPackage }:
# pick a repository derivation, here we will use buildMaven
let repository = callPackage ./build-maven-repository.nix { };
in stdenv.mkDerivation rec {
  pname = "maven-demo";
  version = "1.0";

  src = builtins.fetchTarball "https://github.com/fzakaria/nixos-maven-example/archive/main.tar.gz";
  buildInputs = [ maven ];

  buildPhase = ''
    echo "Using repository ${repository}"
    mvn --offline -Dmaven.repo.local=${repository} package;
  '';

  installPhase = ''
    install -Dm644 target/${pname}-${version}.jar $out/share/java
  '';
}

::: {.tip} We place the library in $out/share/java since JDK package has a stdenv setup hook that adds any JARs in the share/java directories of the build inputs to the CLASSPATH environment. :::

 tree $(nix-build --no-out-link build-jar.nix)
/nix/store/7jw3xdfagkc2vw8wrsdv68qpsnrxgvky-maven-demo-1.0
└── share
    └── java
        └── maven-demo-1.0.jar

2 directories, 1 file

Runnable JAR

The previous example builds a jar file but that's not a file one can run.

You need to use it with java -jar $out/share/java/output.jar and make sure to provide the required dependencies on the classpath.

The following explains how to use makeWrapper in order to make the derivation produce an executable that will run the JAR file you created.

We will use the same repository we built above (either double invocation or buildMaven) to setup a CLASSPATH for our JAR.

The following two methods are more suited to Nix then building an UberJar which may be the more traditional approach.

CLASSPATH

This method is ideal if you are providing a derivation for nixpkgs and don't want to patch the project's pom.xml.

We will read the Maven repository and flatten it to a single list. This list will then be concatenated with the CLASSPATH separator to create the full classpath.

We make sure to provide this classpath to the makeWrapper.

{ stdenv, maven, callPackage, makeWrapper, jre }:
let
  repository = callPackage ./build-maven-repository.nix { };
in stdenv.mkDerivation rec {
  pname = "maven-demo";
  version = "1.0";

  src = builtins.fetchTarball
    "https://github.com/fzakaria/nixos-maven-example/archive/main.tar.gz";
  nativeBuildInputs = [ makeWrapper ];
  buildInputs = [ maven ];

  buildPhase = ''
    echo "Using repository ${repository}"
    mvn --offline -Dmaven.repo.local=${repository} package;
  '';

  installPhase = ''
    mkdir -p $out/bin

    classpath=$(find ${repository} -name "*.jar" -printf ':%h/%f');
    install -Dm644 target/${pname}-${version}.jar $out/share/java
    # create a wrapper that will automatically set the classpath
    # this should be the paths from the dependency derivation
    makeWrapper ${jre}/bin/java $out/bin/${pname} \
          --add-flags "-classpath $out/share/java/${pname}-${version}.jar:''${classpath#:}" \
          --add-flags "Main"
  '';
}

MANIFEST file via Maven Plugin

This method is ideal if you are the project owner and want to change your pom.xml to set the CLASSPATH within it.

Augment the pom.xml to create a JAR with the following manifest:

<build>
  <plugins>
    <plugin>
        <artifactId>maven-jar-plugin</artifactId>
        <configuration>
            <archive>
                <manifest>
                    <addClasspath>true</addClasspath>
                    <classpathPrefix>../../repository/</classpathPrefix>
                    <classpathLayoutType>repository</classpathLayoutType>
                    <mainClass>Main</mainClass>
                </manifest>
                <manifestEntries>
                    <Class-Path>.</Class-Path>
                </manifestEntries>
            </archive>
        </configuration>
    </plugin>
  </plugins>
</build>

The above plugin instructs the JAR to look for the necessary dependencies in the lib/ relative folder. The layout of the folder is also in the maven repository style.

 unzip -q -c $(nix-build --no-out-link runnable-jar.nix)/share/java/maven-demo-1.0.jar META-INF/MANIFEST.MF

Manifest-Version: 1.0
Archiver-Version: Plexus Archiver
Built-By: nixbld
Class-Path: . ../../repository/com/vdurmont/emoji-java/5.1.1/emoji-jav
 a-5.1.1.jar ../../repository/org/json/json/20170516/json-20170516.jar
Created-By: Apache Maven 3.6.3
Build-Jdk: 1.8.0_265
Main-Class: Main

We will modify the derivation above to add a symlink to our repository so that it's accessible to our JAR during the installPhase.

{ stdenv, maven, callPackage, makeWrapper, jre }:
# pick a repository derivation, here we will use buildMaven
let repository = callPackage ./build-maven-repository.nix { };
in stdenv.mkDerivation rec {
  pname = "maven-demo";
  version = "1.0";

  src = builtins.fetchTarball
    "https://github.com/fzakaria/nixos-maven-example/archive/main.tar.gz";
  nativeBuildInputs = [ makeWrapper ];
  buildInputs = [ maven ];

  buildPhase = ''
    echo "Using repository ${repository}"
    mvn --offline -Dmaven.repo.local=${repository} package;
  '';

  installPhase = ''
    mkdir -p $out/bin

    # create a symbolic link for the repository directory
    ln -s ${repository} $out/repository

    install -Dm644 target/${pname}-${version}.jar $out/share/java
    # create a wrapper that will automatically set the classpath
    # this should be the paths from the dependency derivation
    makeWrapper ${jre}/bin/java $out/bin/${pname} \
          --add-flags "-jar $out/share/java/${pname}-${version}.jar"
  '';
}

::: {.note} Our script produces a dependency on jre rather than jdk to restrict the runtime closure necessary to run the application. :::

This will give you an executable shell-script that launches your JAR with all the dependencies available.

 tree $(nix-build --no-out-link runnable-jar.nix)
/nix/store/8d4c3ibw8ynsn01ibhyqmc1zhzz75s26-maven-demo-1.0
├── bin
│   └── maven-demo
├── repository -> /nix/store/g87va52nkc8jzbmi1aqdcf2f109r4dvn-maven-repository
└── share
    └── java
        └── maven-demo-1.0.jar

 $(nix-build --no-out-link --option tarball-ttl 1 runnable-jar.nix)/bin/maven-demo
NixOS 😀 is super cool 😃!