The Java plugin adds Java compilation along with testing and bundling capabilities to a project. It serves as the basis for many of the other JVM language Gradle plugins. You can find a comprehensive introduction and overview to the Java Plugin in the Building Java Projects chapter.

As indicated above, this plugin adds basic building blocks for working with JVM projects. Its feature set has been superseded by other plugins, offering more features based on your project type. Instead of applying it directly to your project, you should look into the java-library or application plugins or one of the supported alternative JVM language.

Usage

To use the Java plugin, include the following in your build script:

build.gradle.kts
plugins {
    java
}
build.gradle
plugins {
    id 'java'
}

Tasks

The Java plugin adds a number of tasks to your project, as shown below.

compileJavaJavaCompile

Depends on: All tasks which contribute to the compilation classpath, including jar tasks from projects that are on the classpath via project dependencies

Compiles production Java source files using the JDK compiler.

processResourcesProcessResources

Copies production resources into the production resources directory.

classes

Depends on: compileJava, processResources

This is an aggregate task that just depends on other tasks. Other plugins may attach additional compilation tasks to it.

compileTestJavaJavaCompile

Depends on: classes, and all tasks that contribute to the test compilation classpath

Compiles test Java source files using the JDK compiler.

processTestResourcesCopy

Copies test resources into the test resources directory.

testClasses

Depends on: compileTestJava, processTestResources

This is an aggregate task that just depends on other tasks. Other plugins may attach additional test compilation tasks to it.

jarJar

Depends on: classes

Assembles the production JAR file, based on the classes and resources attached to the main source set.

javadocJavadoc

Depends on: classes

Generates API documentation for the production Java source using Javadoc.

testTest

Depends on: testClasses, and all tasks which produce the test runtime classpath

Runs the unit tests using JUnit or TestNG.

cleanDelete

Deletes the project build directory.

cleanTaskNameDelete

Deletes files created by the specified task. For example, cleanJar will delete the JAR file created by the jar task and cleanTest will delete the test results created by the test task.

SourceSet Tasks

For each source set you add to the project, the Java plugin adds the following tasks:

compileSourceSetJavaJavaCompile

Depends on: All tasks which contribute to the source set’s compilation classpath

Compiles the given source set’s Java source files using the JDK compiler.

processSourceSetResourcesCopy

Copies the given source set’s resources into the resources directory.

sourceSetClassesTask

Depends on: compileSourceSetJava, processSourceSetResources

Prepares the given source set’s classes and resources for packaging and execution. Some plugins may add additional compilation tasks for the source set.

Lifecycle Tasks

The Java plugin attaches some of its tasks to the lifecycle tasks defined by the Base Plugin — which the Java Plugin applies automatically — and it also adds a few other lifecycle tasks:

assemble

Depends on: jar

Aggregate task that assembles all the archives in the project. This task is added by the Base Plugin.

check

Depends on: test

Aggregate task that performs verification tasks, such as running the tests. Some plugins add their own verification tasks to check. You should also attach any custom Test tasks to this lifecycle task if you want them to execute for a full build. This task is added by the Base Plugin.

build

Depends on: check, assemble

Aggregate tasks that performs a full build of the project. This task is added by the Base Plugin.

buildNeeded

Depends on: build, and buildNeeded tasks in all projects that are dependencies in the testRuntimeClasspath configuration.

Performs a full build of the project and all projects it depends on.

buildDependents

Depends on: build, and buildDependents tasks in all projects that have this project as a dependency in their testRuntimeClasspath configurations

Performs a full build of the project and all projects which depend upon it.

buildConfigName — task rule

Depends on: all tasks that generate the artifacts attached to the named — ConfigName — configuration

Assembles the artifacts for the specified configuration. This rule is added by the Base Plugin.

The following diagram shows the relationships between these tasks.

javaPluginTasks
Figure 1. Java plugin - tasks

Project layout

The Java plugin assumes the project layout shown below. None of these directories need to exist or have anything in them. The Java plugin will compile whatever it finds, and handles anything which is missing.

src/main/java

Production Java source.

src/main/resources

Production resources, such as XML and properties files.

src/test/java

Test Java source.

src/test/resources

Test resources.

src/sourceSet/java

Java source for the source set named sourceSet.

src/sourceSet/resources

Resources for the source set named sourceSet.

Changing the project layout

You configure the project layout by configuring the appropriate source set. This is discussed in more detail in the following sections. Here is a brief example which changes the main Java and resource source directories.

build.gradle.kts
sourceSets {
    main {
        java {
            setSrcDirs(listOf("src/java"))
        }
        resources {
            setSrcDirs(listOf("src/resources"))
        }
    }
}
build.gradle
sourceSets {
    main {
        java {
            srcDirs = ['src/java']
        }
        resources {
            srcDirs = ['src/resources']
        }
    }
}

Source sets

The plugin adds the following source sets:

main

Contains the production source code of the project, which is compiled and assembled into a JAR.

test

Contains your test source code, which is compiled and executed using JUnit or TestNG. These are typically unit tests, but you can include any test in this source set as long as they all share the same compilation and runtime classpaths.

Source set properties

The following table lists some of the important properties of a source set. You can find more details in the API documentation for SourceSet.

name — (read-only) String

The name of the source set, used to identify it.

output — (read-only) SourceSetOutput

The output files of the source set, containing its compiled classes and resources.

output.classesDirs — (read-only) FileCollection

Default value: layout.buildDirectory.dir("classes/java/$name"), e.g. build/classes/java/main

The directories to generate the classes of this source set into. May contain directories for other JVM languages, e.g. build/classes/kotlin/main.

output.resourcesDir — File

Default value: layout.buildDirectory.dir("resources/$name"), e.g. build/resources/main

The directory to generate the resources of this source set into.

compileClasspath — FileCollection

Default value: ${name}CompileClasspath configuration

The classpath to use when compiling the source files of this source set.

annotationProcessorPath — FileCollection

Default value: ${name}AnnotationProcessor configuration

The processor path to use when compiling the source files of this source set.

runtimeClasspath — FileCollection

Default value: $output, ${name}RuntimeClasspath configuration

The classpath to use when executing the classes of this source set.

java — (read-only) SourceDirectorySet

The Java source files of this source set. Contains only .java files found in the Java source directories, and excludes all other files.

java.srcDirs — Set<File>

Default value: src/$name/java, e.g. src/main/java

The source directories containing the Java source files of this source set. You can set this to any value that is described in this section.

java.destinationDirectory — DirectoryProperty

Default value: layout.buildDirectory.dir("classes/java/$name"), e.g. build/classes/java/main

The directory to generate compiled Java sources into. You can set this to any value that is described in this section.

resources — (read-only) SourceDirectorySet

The resources of this source set. Contains only resources, and excludes any .java files found in the resource directories. Other plugins, such as the Groovy Plugin, exclude additional types of files from this collection.

resources.srcDirs — Set<File>

Default value: [src/$name/resources]

The directories containing the resources of this source set. You can set this to any type of value that is described in this section.

allJava — (read-only) SourceDirectorySet

Default value: Same as java property

All Java files of this source set. Some plugins, such as the Groovy Plugin, add additional Java source files to this collection.

allSource — (read-only) SourceDirectorySet

Default value: Sum of everything in the resources and java properties

All source files of this source set of any language. This includes all resource files and all Java source files. Some plugins, such as the Groovy Plugin, add additional source files to this collection.

Defining new source sets

See the integration test example in the Testing in Java & JVM projects chapter.

Some other simple source set examples

Adding a JAR containing the classes of a source set:

build.gradle.kts
tasks.register<Jar>("intTestJar") {
    from(sourceSets["intTest"].output)
}
build.gradle
tasks.register('intTestJar', Jar) {
    from sourceSets.intTest.output
}

Generating Javadoc for a source set:

build.gradle.kts
tasks.register<Javadoc>("intTestJavadoc") {
    source(sourceSets["intTest"].allJava)
    classpath = sourceSets["intTest"].compileClasspath
}
build.gradle
tasks.register('intTestJavadoc', Javadoc) {
    source sourceSets.intTest.allJava
    classpath = sourceSets.intTest.compileClasspath
}

Adding a test suite to run the tests in a source set:

build.gradle.kts
tasks.register<Test>("intTest") {
    testClassesDirs = sourceSets["intTest"].output.classesDirs
    classpath = sourceSets["intTest"].runtimeClasspath
}
build.gradle
tasks.register('intTest', Test) {
    testClassesDirs = sourceSets.intTest.output.classesDirs
    classpath = sourceSets.intTest.runtimeClasspath
}

Dependency management

The Java plugin adds a number of dependency configurations to your project, as shown below. Tasks such as compileJava and test then use one or more of those configurations to get the corresponding files and use them, for example by placing them on a compilation or runtime classpath.

Dependency configurations

For information on the default and archives configurations, please consult the Base Plugin reference documentation.

For information on the api or compileOnlyApi configurations, please consult the Java Library Plugin reference documentation and Dependency Management for Java Projects.

Dependency Declaration Configurations

implementation

Represents dependencies that are required both at compile time and runtime for the main source set of a project (i.e., implementation only dependencies).

compileOnly

Represents dependencies that are required only at compile time and are not included in the runtime classpath (i.e., compile time only dependencies, not used at runtime).

runtimeOnly

Represents dependencies that are required only at runtime and are not included in the compile classpath (i.e., dependencies required only at runtime).

testImplementation extends implementation

Represents dependencies that are required both at compile time and runtime for the test source set of a project (i.e., implementation only dependencies for tests).

testCompileOnly

Represents dependencies that are required only at compile time for the test source set of a project and are not included in the runtime classpath (i.e., additional dependencies only for compiling tests, not used at runtime).

testRuntimeOnly extends runtimeOnly

Represents dependencies that are required only at runtime for the test source set of a project (i.e., runtime only dependencies for running tests).

annotationProcessor

Represents annotation processors used during the compilation of a project’s source code (i.e., annotation processors used during compilation).

Resolvable Configurations

compileClasspath extends compileOnly, implementation

Represents the classpath used when compiling the main sources, which includes dependencies from both compileOnly and implementation configurations. Used by task compileJava.

runtimeClasspath extends runtimeOnly, implementation

Represents the classpath used to run the main sources, which includes dependencies from both runtimeOnly and implementation configurations. Used by task run.

testCompileClasspath extends testCompileOnly, testImplementation

Represents the classpath used to compile the test sources, which includes dependencies from both testCompileOnly and testImplementation configurations. Used by task compileTestJava.

testRuntimeClasspath extends testRuntimeOnly, testImplementation

Represents the classpath used to run the test sources, which includes dependencies from both testRuntimeOnly and testImplementation configurations. Used by task test.

The following diagrams show the dependency configurations for the main and test source sets respectively. You can use this legend to interpret the colors:

  • blue background — you can declare dependencies against the configuration.

  • green background — the configuration is for consumption by tasks, not for you to declare dependencies.

  • grey background — a task.

java main configurations
Figure 2. Java plugin - main source set dependency configurations
java test configurations
Figure 3. Java plugin - test source set dependency configurations

For each source set you add to the project, the Java plugins adds the following dependency configurations:

SourceSet dependency configurations

sourceSetImplementation

Compile time dependencies for the given source set. Used by sourceSetCompileClasspath, sourceSetRuntimeClasspath.

sourceSetCompileOnly

Compile time only dependencies for the given source set, not used at runtime.

sourceSetCompileClasspath extends sourceSetCompileOnly, sourceSetImplementation

Compile classpath, used when compiling source. Used by compileSourceSetJava.

sourceSetAnnotationProcessor

Annotation processors used during compilation of this source set.

sourceSetRuntimeOnly

Runtime only dependencies for the given source set.

sourceSetRuntimeClasspath extends sourceSetRuntimeOnly, sourceSetImplementation

Runtime classpath contains elements of the implementation, as well as runtime only elements.

Contributed extension

The Java plugin adds the java extension to the project. This allows to configure a number of Java related properties inside a dedicated DSL block.

build.gradle.kts
java {
    toolchain {
        languageVersion = JavaLanguageVersion.of(17)
    }
}
build.gradle
java {
    toolchain {
        languageVersion = JavaLanguageVersion.of(17)
    }
}

Below is the list of properties and DSL functions with short explanations available inside the java extension.

Toolchain and compatibility

toolchain

Java toolchain to be used by tasks using JVM tools, such as compilation and execution. Default value: build JVM toolchain.

JavaVersion sourceCompatibility

Java version compatibility to use when compiling Java source. Default value: language version of the toolchain from this extension.
Note that using a toolchain is preferred to using a compatibility setting for most cases.

JavaVersion targetCompatibility

Java version to generate classes for. Default value: sourceCompatibility.
Note that using a toolchain is preferred to using a compatibility setting for most cases.

Packaging

withJavadocJar()

Automatically packages Javadoc and creates a variant javadocElements with an artifact -javadoc.jar, which will be part of the publication.

withSourcesJar()

Automatically packages source code and creates a variant sourceElements with an artifact -sources.jar, which will be part of the publication.

Directory properties

String reporting.baseDir

The name of the directory to generate reports into, relative to the build directory. Default value: reports

(read-only) File reportsDir

The directory to generate reports into. Default value: reporting.baseDirectory

String testResultsDirName

The name of the directory to generate test result .xml files into, relative to the build directory. Default value: test-results

(read-only) File testResultsDir

The directory to generate test result .xml files into. Default value: layout.buildDirectory.dir(testResultsDirName)

String testReportDirName

The name of the directory to generate the test report into, relative to the reports directory. Default value: tests

(read-only) File testReportDir

The directory to generate the test report into. Default value: reportsDir/testReportDirName

String libsDirName

The name of the directory to generate libraries into, relative to the build directory. Default value: libs

(read-only) File libsDir

The directory to generate libraries into. Default value: layout.buildDirectory.dir(libsDirName)

String distsDirName

The name of the directory to generate distributions into, relative to the build directory. Default value: distributions

(read-only) File distsDir

The directory to generate distributions into. Default value: layout.buildDirectory.dir(distsDirName)

String docsDirName

The name of the directory to generate documentation into, relative to the build directory. Default value: docs

(read-only) File docsDir

The directory to generate documentation into. Default value: layout.buildDirectory.dir(docsDirName)

String dependencyCacheDirName

The name of the directory to cache source dependency information relative to the build directory. Default value: dependency-cache.

Other properties

(read-only) SourceSetContainer sourceSets

Contains the project’s source sets. Default value: Not null SourceSetContainer

String archivesBaseName

The basename to use for archives, such as JAR or ZIP files. Default value: projectName

Manifest manifest

The manifest to include in all JAR files. Default value: an empty manifest.

Convention properties (deprecated)

The Java Plugin adds a number of convention properties to the project. You can use these properties in your build script as though they were properties of the project object. These are deprecated and superseded by the extension described above. See the JavaPluginConvention DSL documentation for information on them.

Testing

See the Testing in Java & JVM projects chapter for more details.

Publishing

components.java

A SoftwareComponent for publishing the production JAR created by the jar task. This component includes the runtime dependency information for the JAR.

See also the java extension.

Incremental Java compilation

Gradle comes with a sophisticated incremental Java compiler that is active by default.

This gives you the following benefits

  • Incremental builds are much faster.

  • The smallest possible number of class files are changed. Classes that don’t need to be recompiled remain unchanged in the output directory. An example scenario when this is really useful is using JRebel — the fewer output classes are changed the quicker the JVM can use refreshed classes.

To help you understand how incremental compilation works, the following provides a high-level overview:

  • Gradle will recompile all classes affected by a change.

  • A class is affected if it has been changed or if it depends on another affected class. This works no matter if the other class is defined in the same project, another project or even an external library.

  • A class’s dependencies are determined from type references in its bytecode or symbol analysis via a compiler plugin.

  • Since source-retention annotations are not visible in bytecode, changes to a source-retention annotation will result in full recompilation.

  • You can improve incremental compilation performance by applying good software design principles like loose coupling. For instance, if you put an interface between a concrete class and its dependents, the dependent classes are only recompiled when the interface changes, but not when the implementation changes.

  • The class analysis is cached in the project directory, so the first build after a clean checkout can be slower. Consider turning off the incremental compiler on your build server.

  • The class analysis is also an output stored in the build cache, which means that if a compilation output is fetched from the build cache, then the incremental compilation analysis will be too and the next compilation will be incremental.

Known issues

  • If you are using an annotation processor that reads resources (e.g. a configuration file), you need to declare those resources as an input of the compile task.

  • If a resource file is changed, Gradle will trigger a full recompilation.

  • Using a custom executable or javaHome deactivates some optimizations. The compile task does not use incremental build immediately after a compile error or if a Java constant changes. Use toolchains instead if possible.

  • Having a source structure that does not match the package names, while legal for compilation, might end up causing trouble in the toolchain. Even more if annotation processing and caching are involved.

Incremental annotation processing

Starting with Gradle 4.7, the incremental compiler also supports incremental annotation processing. All annotation processors need to opt in to this feature, otherwise they will trigger a full recompilation.

As a user you can see which annotation processors are triggering full recompilations in the --info log. Incremental annotation processing will be deactivated if a custom executable or javaHome is configured on the compile task.

Making an annotation processor incremental

Please first have a look at incremental Java compilation, as incremental annotation processing builds on top of it.

Gradle supports incremental compilation for two common categories of annotation processors: "isolating" and "aggregating". Please consult the information below to decide which category fits your processor.

You can then register your processor for incremental compilation using a file in the processor’s META-INF directory. The format is one line per processor, with the fully qualified name of the processor class and its case-insensitive category separated by a comma.

Example: Registering incremental annotation processors

processor/src/main/resources/META-INF/gradle/incremental.annotation.processors
org.gradle.EntityProcessor,isolating
org.gradle.ServiceRegistryProcessor,dynamic

If your processor can only decide at runtime whether it is incremental or not, you can declare it as "dynamic" in the META-INF descriptor and return its true type at runtime using the Processor#getSupportedOptions() method.

Example: Registering incremental annotation processors dynamically

processor/src/main/java/org/gradle/ServiceRegistryProcessor.java
@Override
public Set<String> getSupportedOptions() {
    return Collections.singleton("org.gradle.annotation.processing.aggregating");
}

Both categories have the following limitations:

  • They can only read CLASS or RUNTIME retention annotations.

  • They can only read parameter names if the user passes the -parameters compiler argument.

  • They must generate their files using the Filer API. Writing files any other way will result in silent failures later on, as these files won’t be cleaned up correctly. If your processor does this, it cannot be incremental.

  • They must not depend on compiler-specific APIs like com.sun.source.util.Trees. Gradle wraps the processing APIs, so attempts to cast to compiler-specific types will fail. If your processor does this, it cannot be incremental, unless you have some fallback mechanism.

  • If they use Filer#createResource, the location argument must be one of these values from StandardLocation: CLASS_OUTPUT, SOURCE_OUTPUT, or NATIVE_HEADER_OUTPUT. Any other argument will disable incremental processing.

"Isolating" annotation processors

The fastest category, these look at each annotated element in isolation, creating generated files or validation messages for it. For instance an EntityProcessor could create a <TypeName>Repository for each type annotated with @Entity.

Example: An isolated annotation processor

processor/src/main/java/org/gradle/EntityProcessor.java
Set<? extends Element> entities = roundEnv.getElementsAnnotatedWith(entityAnnotation);
for (Element entity : entities) {
    createRepository((TypeElement) entity);
}

"Isolating" processors have the following additional limitations:

  • They must make all decisions (code generation, validation messages) for an annotated type based on information reachable from its AST. This means you can analyze the types' super-class, method return types, annotations etc., even transitively. But you cannot make decisions based on unrelated elements in the RoundEnvironment. Doing so will result in silent failures because too few files will be recompiled later. If your processor needs to make decisions based on a combination of otherwise unrelated elements, mark it as "aggregating" instead.

  • They must provide exactly one originating element for each file generated with the Filer API. If zero or many originating elements are provided, Gradle will recompile all source files.

When a source file is recompiled, Gradle will recompile all files generated from it. When a source file is deleted, the files generated from it are deleted.

"Aggregating" annotation processors

These can aggregate several source files into one or more output files or validation messages. For instance, a ServiceRegistryProcessor could create a single ServiceRegistry with one method for each type annotated with @Service.

Example: An aggregating annotation processor

processor/src/main/java/org/gradle/ServiceRegistryProcessor.java
JavaFileObject serviceRegistry = filer.createSourceFile("ServiceRegistry");
Writer writer = serviceRegistry.openWriter();
writer.write("public class ServiceRegistry {");
for (Element service : roundEnv.getElementsAnnotatedWith(serviceAnnotation)) {
    addServiceCreationMethod(writer, (TypeElement) service);
}
writer.write("}");
writer.close();

Gradle will always reprocess (but not recompile) all annotated files that the processor was registered for. Gradle will always recompile any files the processor generates.

Many popular annotation processors support incremental annotation processing (see the table below). Check with the annotation processor project directly for the most up-to-date information and documentation.
Annotation Processor Supported since Details

N/A

N/A

Partly supported.

N/A

N/A

DataBinding

Hidden behind a feature toggle

Dagger

2.18 Feature toggle support, 2.24 Enabled by default

kapt

Hidden behind a feature toggle

Toothpick

2.0

N/A

Glide

N/A

Android-State

N/A

Parceler

N/A

Dart and Henson

N/A

N/A

N/A

N/A

Requery

N/A

N/A

EclipseLink

N/A

N/A

Immutables

N/A

2.2.0 Feature toggle support, 2.3.0-alpha02 Enabled by default

N/A

N/A

DBFlow

N/A

AndServer

N/A

N/A

2.0

N/A

N/A

N/A

Hidden behind a feature toggle

N/A

Compilation avoidance

If a dependent project has changed in an ABI-compatible way (only its private API has changed), then Java compilation tasks will be up-to-date. This means that if project A depends on project B and a class in B is changed in an ABI-compatible way (typically, changing only the body of a method), then Gradle won’t recompile A.

Some of the types of changes that do not affect the public API and are ignored:

  • Changing a method body

  • Changing a comment

  • Adding, removing or changing private methods, fields, or inner classes

  • Adding, removing or changing a resource

  • Changing the name of jars or directories in the classpath

  • Renaming a parameter

Since implementation details matter for annotation processors, they must be declared separately on the annotation processor path. Gradle ignores annotation processors on the compile classpath.

build.gradle.kts
dependencies {
    // The dagger compiler and its transitive dependencies will only be found on annotation processing classpath
    annotationProcessor("com.google.dagger:dagger-compiler:2.44")

    // And we still need the Dagger library on the compile classpath itself
    implementation("com.google.dagger:dagger:2.44")
}
build.gradle
dependencies {
    // The dagger compiler and its transitive dependencies will only be found on annotation processing classpath
    annotationProcessor 'com.google.dagger:dagger-compiler:2.44'

    // And we still need the Dagger library on the compile classpath itself
    implementation 'com.google.dagger:dagger:2.44'
}

Variant aware selection

The whole set of JVM plugins leverage variant aware resolution for the dependencies used. They also install a set of attributes compatibility and disambiguation rules to configure the Gradle attributes for the specifics of the JVM ecosystem.