Check the NeoForged Project Listing for latest releases.
If you are updating to a new major version of the plugin, refer to the list of breaking changes.
- Uses the latest Gradle best practices and is compatible with Gradle 8.8
- Creates the necessary artifacts to compile Minecraft mods for NeoForge
- Runs the game from Gradle or IntelliJ for debugging and testing
- Automatically creates and uses a development-friendly logging configuration for the testing the mod
- Supports the Gradle configuration cache to speed up repeated runs of Gradle tasks
In gradle.properties
:
# Enable Gradle configuration cache if you'd like:
org.gradle.configuration-cache=true
In settings.gradle
:
plugins {
// This plugin allows Gradle to automatically download arbitrary versions of Java for you
id 'org.gradle.toolchains.foojay-resolver-convention' version '0.8.0'
}
In build.gradle
:
plugins {
// Apply the plugin. You can find the latest version at https://projects.neoforged.net/neoforged/ModDevGradle
id 'net.neoforged.moddev' version '1.0.11'
}
neoForge {
// We currently only support NeoForge versions later than 21.0.x
// See https://projects.neoforged.net/neoforged/neoforge for the latest updates
version = "21.0.103-beta"
// Validate AT files and raise errors when they have invalid targets
// This option is false by default, but turning it on is recommended
validateAccessTransformers = true
runs {
client {
client()
}
data {
data()
}
server {
server()
}
}
mods {
testproject {
sourceSet sourceSets.main
}
}
}
See the example code in the test project.
In multi-loader projects, you'll often need a subproject for your cross-loader code. This project will also need access to Minecraft classes, but without any loader-specific extensions.
This plugin solves that by offering a "Vanilla-mode" which you enable by specifying a NeoForm version instead of a NeoForge version. NeoForm contains the necessary configuration to produce Minecraft jar-files that you can compile against that contain no other modifications.
In Vanilla-mode, only the client
, server
and data
run types are supported.
Since the plugin includes no mod loader code in this mode, only basic resource- and data packs will be usable in-game.
In build.gradle
:
Apply the plugin as usual and use a configuration block like this:
neoForge {
// Look for versions on https://projects.neoforged.net/neoforged/neoform
neoFormVersion = "1.21-20240613.152323"
runs {
client {
client()
}
server {
server()
}
data {
data()
}
}
}
Sometimes IntelliJ gets into a state where clicking "Attach Sources" while viewing a decompiled Minecraft class will not work.
Reloading the Gradle Project and then clicking "Attach Sources" again will usually fix this problem.
This error typically happens when switching to ModDevGradle from another plugin with an idePostSync
task.
This can be fixed by unregistering the task in IntelliJ IDEA, as follows:
Click to expand
- Open the Gradle tool window on the right, and right-click the Gradle project.
- Click on
Tasks Activation
.
- Select the
idePostSync
task and delete it using the-
button.
- Sync the Gradle project again.
Any number of runs can be added in the neoForge { runs { ... } }
block.
Every run must have a type. Currently, the supported types are client
, data
, gameTestServer
, server
.
The run type can be set as follows:
neoForge {
runs {
<run name> {
// This is the standard syntax:
type = "gameTestServer"
// Client, data and server runs can use a shorthand instead:
// client()
// data()
// server()
// Changes the working directory used for this run.
// The default is the 'run' subdirectory of your project
gameDirectory = project.file('runs/client')
// Add arguments passed to the main method
programArguments = ["--arg"]
programArgument("--arg")
// Add arguments passed to the JVM
jvmArguments = ["-XX:+AllowEnhancedClassRedefinition"]
jvmArgument("-XX:+AllowEnhancedClassRedefinition")
// Add system properties
systemProperties = [
"a.b.c": "xyz"
]
systemProperty("a.b.c", "xyz")
// Set or add environment variables
environment = [
"FOO_BAR": "123"
]
environment("FOO_BAR", "123")
// Optionally set the log-level used by the game
logLevel = org.slf4j.event.Level.DEBUG
// You can change the name used for this run in your IDE
ideName = "Run Game Tests"
// You can disable a run configuration being generated for your IDE
disableIdeRun()
// ... alternatively you can set ideName = ""
// Changes the source set whose runtime classpath is used for this run. This defaults to "main"
// Eclipse does not support having multiple runtime classpaths per project (except for unit tests).
sourceSet = sourceSets.main
// Changes which local mods are loaded in this run.
// This defaults to all mods declared in this project (inside of mods { ... } ).
loadedMods = [mods.<mod name 1>, mods.<mod name 2>]
// Allows advanced users to run additional Gradle tasks before each launch of this run
// Please note that using this feature will significantly slow down launching the game
taskBefore tasks.named("generateSomeCodeTask")
}
}
}
Please have a look at RunModel.java for the list of supported properties. Here is an example that sets a system property to change the log level to debug:
neoForge {
runs {
configureEach {
systemProperty 'forge.logging.console.level', 'debug'
}
}
}
To embed external Jar-files into your mod file, you can use the jarJar
configuration added by the plugin.
For example, if you have a coremod in a subproject and want to embed its jar file, you can use the following syntax.
dependencies {
jarJar project(":coremod")
}
When starting the game, FML will use the group and artifact id of an embedded Jar-file to determine if the same file has been embedded in other mods. For subprojects, the group id is the root project name, while the artifact id is the name of the subproject. Besides the group and artifact id, the Java module name of an embedded Jar also has to be unique across all loaded Jar files. To decrease the likelihood of conflicts if no explicit module name is set, we prefix the filename of embedded subprojects with the group id.
When you want to bundle external dependencies, Jar-in-Jar has to be able to select a single copy of that dependency when it is bundled by multiple mods (possibly even in different versions). To support this scenario, you should set a supported version range to avoid mod incompatibilities.
dependencies {
jarJar(implementation("org.commonmark:commonmark")) {
version {
// The version range your mod is actually compatible with.
// Note that you may receive a *lower* version than your preferred if another
// Mod is only compatible up to 1.7.24, for example, your mod might get 1.7.24 at runtime.
strictly '[0.1, 1.0)'
prefer '0.21.0' // The version actually used in your dev workspace
}
}
}
Version ranges use the Maven version range format:
Range | Meaning |
---|---|
(,1.0] | x <= 1.0 |
1.0 | Soft requirement on 1.0. It allows for any version. |
[1.0] | Hard requirement on 1.0 |
[1.2,1.3] | 1.2 <= x <= 1.3 |
[1.0,2.0) | 1.0 <= x < 2.0 |
[1.5,) | x >= 1.5 |
(,1.0],[1.2,) | x <= 1.0 or x >= 1.2. Multiple sets are comma-separated |
(,1.1),(1.1,) | This excludes 1.1 if it is known not to work in combination with this library |
External dependencies will only be loaded in your runs if they are mods (with a META-INF/neoforge.mods.toml
file),
or if they have the FMLModType
entry set in their META-INF/MANIFEST.MF
file.
Usually, Java libraries do not fit either of these requirements,
leading to a ClassNotFoundException
at run time when you try to call them from your mod.
To fix this, the library needs to be added to the additionalRuntimeClasspath
as follows:
dependencies {
// This is still required to add the library in your jar and at compile time.
jarJar(implementation("org.commonmark:commonmark")) { /* ... */ }
// This adds the library to all the runs.
additionalRuntimeClasspath "org.commonmark:commonmark:0.21.0"
}
Advanced: The additional runtime classpath can be configured per-run.
For example, to add a dependency to the client
run only, it can be added to clientAdditionalRuntimeClasspath
.
If you work with source sets that do not extend from main
, and would like the modding dependencies to be available
in those source sets, you can use the following api:
sourceSets {
anotherSourceSet // example
}
neoForge {
// ...
addModdingDependenciesTo sourceSets.anotherSourceSet
mods {
mymod {
sourceSet sourceSets.main
// Do not forget to add additional source-sets here!
sourceSet sourceSets.anotherSourceSet
}
}
}
dependencies {
implementation sourceSets.anotherSourceSet.output
}
You can use community-sourced parameter-names and Javadoc for Minecraft source code from ParchmentMC.
The easiest way is setting the Parchment version in your gradle.properties:
neoForge.parchment.minecraftVersion=1.21
neoForge.parchment.mappingsVersion=2024.06.23
Alternatively, you can set it in your build.gradle:
neoForge {
// [...]
parchment {
// Get versions from https://parchmentmc.org/docs/getting-started
// Omit the "v"-prefix in mappingsVersion
minecraftVersion = "1.20.6"
mappingsVersion = "2024.05.01"
}
}
On top of gametests, this plugin supports unit testing mods with JUnit.
For the minimal setup, add the following code to your build script:
// Add a test dependency on the test engine JUnit
dependencies {
testImplementation 'org.junit.jupiter:junit-jupiter:5.7.1'
testRuntimeOnly 'org.junit.platform:junit-platform-launcher'
}
// Enable JUnit in Gradle:
test {
useJUnitPlatform()
}
neoForge {
unitTest {
// Enable JUnit support in the moddev plugin
enable()
// Configure which mod is being tested.
// This allows NeoForge to load the test/ classes and resources as belonging to the mod.
testedMod = mods.<mod name > // <mod name> must match the name in the mods { } block.
// Configure which mods are loaded in the test environment, if the default (all declared mods) is not appropriate.
// This must contain testedMod, and can include other mods as well.
// loadedMods = [mods.<mod name >, mods.<mod name 2>]
}
}
You can now use the @Test
annotation for your unit tests inside the test/
folder,
and reference Minecraft classes.
With the NeoForge test framework, you can run your unit tests in the context of a Minecraft server:
dependencies {
testImplementation "net.neoforged:testframework:<neoforge version>"
}
With this dependency, you can annotate your test class as follows:
@ExtendWith(EphemeralTestServerProvider.class)
public class TestClass {
@Test
public void testMethod(MinecraftServer server) {
// Use server...
}
}
This plugin supports
Gradle's centralized repositories declaration
in settings.gradle
by offering a separate plugin to apply the repositories to develop mods.
It can be used in the following way in settings.gradle
:
plugins {
id 'net.neoforged.moddev.repositories' version '<version>'
}
dependencyResolutionManagement {
repositories {
mavenCentral()
}
}
Please note that defining any repository in build.gradle will completely disable the centrally managed repositories for that project. You can also use the repositories plugin in a project to add the repositories there, even if dependency management has been overridden.
Access Transformers are an advanced feature allowing mods to relax the access modifiers on Minecraft classes, fields, and methods.
To use this feature, you can place an access transformer data file at src/main/resources/META-INF/accesstransformer.cfg
,
adhering to the access transformer format.
When you use the default file location, you do not need to configure anything.
If you'd like to use additional or different access transformer files, you can modify the paths MDG reads them from
by setting the accessTransformers
property.
Important
If you do not use the default path, you have to also modify your neoforge.mods.toml and configure the paths. Please see the NeoForge documentation for details.
The elements are in the same format that project.files(...)
expects.
neoForge {
// Pulling in an access transformer from the parent project
// (Option 1) Add a single access transformer, and keep the default:
accessTransformers.from "../src/main/resources/META-INF/accesstransformer.cfg"
// (Option 2) Overwrite the whole list of access transformers, removing the default:
accessTransformers = ["../src/main/resources/META-INF/accesstransformer.cfg"]
}
In addition, you can add additional access transformers to the accessTransformers
configuration using normal
Project dependency syntax in your dependencies block.
Optionally, access transformers can be published to a Maven repository so they are usable by other mods.
To publish an access transformer, add a publish
declaration as follows:
neoForge {
accessTransformers {
publish file("src/main/resources/META-INF/accesstransformer.cfg")
}
}
If there is a single access transformer, it will be published under the accesstransformer
classifier.
If there are multiple, they will be published under the accesstransformer1
, accesstransformer2
, etc... classifiers.
To consume an access transformer, add it as an accessTransformer
dependency.
This will find all the published access transformers regardless of their file names.
For example:
dependencies {
accessTransformer "<group>:<artifact>:<version>"
}
Interface injection is an advanced feature allowing mods to add additional interfaces to Minecraft classes and interfaces at development time. This feature requires that mods use ASM or Mixins to make the same extensions at runtime.
To use this feature, place an interface injection data-file in your project and configure the interfaceInjectionData
property to include it.
Since this feature only applies at development time, you do not need to include this data file in your jar.
Important
This feature only applies at development time. You need to use Mixins or Coremods to make it work at runtime.
build.gradle
neoForge {
interfaceInjectionData.from "interfaces.json"
}
interfaces.json
{
"net/minecraft/world/item/ItemStack": [
"testproject/FunExtensions"
]
}
In addition, you can add additional data-files to the interfaceInjectionData
configuration using normal
Project dependency syntax in your dependencies block.
The publication of interface injection data follows the same principles as the publication of access transformers.
If there is a data file, it will be published under the interfaceinjection
classifier.
If there are multiple, they will be published under the interfaceinjection1
, interfaceinjection2
, etc... classifiers.
// Publish a file:
neoForge {
interfaceInjectionData {
publish file("interfaces.json")
}
}
// Consume it:
dependencies {
interfaceInjectionData "<group>:<artifact>:<version>"
}
For testing during the development of NeoForge and its various platform libraries, it can be useful to globally override the version to an unreleased one. This works:
configurations.all {
resolutionStrategy {
force 'cpw.mods:securejarhandler:2.1.43'
}
}
The NeoForm process executed to create the Minecraft jars contains additional intermediate results, which may be useful in advanced build scripts.
You can request those results to be written to specific output files by using the additionalMinecraftArtifacts
property.
Which results are available depends on the NeoForm/NeoForge version used.
neoForge {
// Request NFRT to write additional results to the given locations
// This happens alongside the creation of the normal Minecraft jar
additionalMinecraftArtifacts.put('vanillaDeobfuscated', project.file('vanilla.jar'))
}
neoFormRuntime {
// Use a specific NFRT version
// Gradle Property: neoForge.neoFormRuntime.version
version = "1.2.3"
// Control use of cache
// Gradle Property: neoForge.neoFormRuntime.enableCache
enableCache = false
// Enable Verbose Output
// Gradle Property: neoForge.neoFormRuntime.verbose
verbose = true
// Use Eclipse Compiler for Minecraft
// Gradle Property: neoForge.neoFormRuntime.useEclipseCompiler
useEclipseCompiler = true
// Print more information when NFRT cannot use a cached result
// Gradle Property: neoForge.neoFormRuntime.analyzeCacheMisses
analyzeCacheMisses = true
}
You can add tasks to be run when the IDE reloads your Gradle project. Advanced users might find this useful to run code generation tasks whenever the IDE syncs the project.
neoForge {
ideSyncTask tasks.named("generateSomeCodeTask")
}