Table of Contents
The Scala plugin extends the Java plugin to add support for Scala projects. It can deal with Scala code, mixed Scala and Java code, and even pure Java code (although we don’t necessarily recommend to use it for the latter). The plugin supports joint compilation, which allows you to freely mix and match Scala and Java code, with dependencies in both directions. For example, a Scala class can extend a Java class that in turn extends a Scala class. This makes it possible to use the best language for the job, and to rewrite any class in the other language if needed.
To use the Scala plugin, include the following in your build script:
The Scala plugin adds the following tasks to the project.
Table 57.1. Scala plugin - tasks
Task name | Depends on | Type | Description |
|
|
Compiles production Scala source files. |
|
|
|
Compiles test Scala source files. |
|
|
|
Compiles the given source set’s Scala source files. |
|
|
- |
Generates API documentation for the production Scala source files. |
The Scala plugin adds the following dependencies to tasks added by the Java plugin.
Table 57.2. Scala plugin - additional task dependencies
Task name | Depends on |
|
|
|
|
|
|
The Scala plugin assumes the project layout shown below. All the Scala source directories can contain Scala and Java code. The Java source directories may only contain Java source code. None of these directories need to exist or have anything in them; the Scala plugin will simply compile whatever it finds.
Table 57.3. Scala plugin - project layout
Directory | Meaning | |
|
Production Java source |
|
|
Production resources |
|
|
Production Scala sources. May also contain Java sources for joint compilation. |
|
|
Test Java source |
|
|
Test resources |
|
|
Test Scala sources. May also contain Java sources for joint compilation. |
|
|
Java source for the given source set |
|
|
Resources for the given source set |
|
|
Scala sources for the given source set. May also contain Java sources for joint compilation. |
Scala projects need to declare a scala-library
dependency. This dependency will then be used on compile and runtime class paths. It will also be used to get hold of the Scala compiler and Scaladoc tool, respectively.[29]
If Scala is used for production code, the scala-library
dependency should be added to the compile
configuration:
Example 57.3. Declaring a Scala dependency for production code
build.gradle
repositories { mavenCentral() } dependencies { compile 'org.scala-lang:scala-library:2.11.8' testCompile 'org.scalatest:scalatest_2.11:3.0.0' testCompile 'junit:junit:4.12' }
If Scala is only used for test code, the scala-library
dependency should be added to the testCompile
configuration:
Example 57.4. Declaring a Scala dependency for test code
build.gradle
dependencies {
testCompile "org.scala-lang:scala-library:2.11.1"
}
The ScalaCompile
and ScalaDoc
tasks consume Scala code in two ways: on their classpath
, and on their scalaClasspath
. The former is used to locate classes referenced by the source code, and will typically contain scala-library
along with other libraries. The latter is used to load and execute the Scala compiler and Scaladoc tool, respectively, and should only contain the scala-compiler
library and its dependencies.
Unless a task’s scalaClasspath
is configured explicitly, the Scala (base) plugin will try to infer it from the task’s classpath
. This is done as follows:
If a scala-library
jar is found on classpath
, and the project has at least one repository declared, a corresponding scala-compiler
repository dependency will be added to scalaClasspath
.
Otherwise, execution of the task will fail with a message saying that scalaClasspath
could not be inferred.
The Scala plugin uses a configuration named zinc
to resolve the Zinc compiler and its dependencies. Gradle will provide a default version of Zinc, but if you need to use a particular Zinc version, you can add an explicit dependency like “com.typesafe.zinc:zinc:0.3.6”
to the zinc
configuration. Gradle supports version 0.3.0 of Zinc and above; however, due to a regression in the Zinc compiler, versions 0.3.2 through 0.3.5.2 cannot be used.
Example 57.5. Declaring a version of the Zinc compiler to use
build.gradle
dependencies {
zinc 'com.typesafe.zinc:zinc:0.3.9'
}
It is important to take care when declaring your scala-library
dependency. The Zinc compiler itself needs a compatible version of scala-library
that may be different from the version required by your application. Gradle takes care of adding a compatible version of scala-library
for you, but over-broad dependency resolution rules could force an incompatible version to be used instead.
For example, using configurations.all
to force a particular version of scala-library
would also override the version used by the Zinc compiler:
Example 57.6. Forcing a scala-library dependency for all configurations
build.gradle
configurations.all {
resolutionStrategy.force "org.scala-lang:scala-library:2.11.7"
}
The best way to avoid this problem is to be more selective when configuring the scala-library
dependency (such as not using a configuration.all
rule or using a conditional to prevent the rule from being applied to the zinc
configuration). Sometimes this rule may come from a plugin or other code that you do not have control over. In such a case, you can force a correct version of the library on the zinc
configuration only:
Example 57.7. Forcing a scala-library dependency for the zinc configuration
build.gradle
configurations.zinc {
resolutionStrategy.force "org.scala-lang:scala-library:2.10.5"
}
You can diagnose problems with the version of the Zinc compiler selected by running dependencyInsight for the zinc
configuration.
The Scala plugin adds the following convention properties to each source set in the project. You can use these properties in your build script as though they were properties of the source set object.
Table 57.4. Scala plugin - source set properties
Property name | Type | Default value | Description |
|
|
Not null |
The Scala source files of this source set. Contains all |
|
|
|
The source directories containing the Scala source files of this source set. May also contain Java source files for joint compilation. |
|
|
Not null |
All Scala source files of this source set. Contains only the |
These convention properties are provided by a convention object of type ScalaSourceSet
.
The Scala plugin also modifies some source set properties:
Table 57.5. Scala plugin - source set properties
Property name | Change |
|
Adds all |
|
Adds all source files found in the Scala source directories. |
Scala compilation takes place in an external process.
Memory settings for the external process default to the defaults of the JVM. To adjust memory settings, configure the scalaCompileOptions.forkOptions
property as needed:
Example 57.8. Adjusting memory settings
build.gradle
tasks.withType(ScalaCompile) { configure(scalaCompileOptions.forkOptions) { memoryMaximumSize = '1g' jvmArgs = ['-XX:MaxPermSize=512m'] } }
By compiling only classes whose source code has changed since the previous compilation, and classes affected by these changes, incremental compilation can significantly reduce Scala compilation time. It is particularly effective when frequently compiling small code increments, as is often done at development time.
The Scala plugin defaults to incremental compilation by integrating with Zinc, a standalone version of sbt's incremental Scala compiler. If you want to disable the incremental compilation, set force = true
in your build file:
Example 57.9. Forcing all code to be compiled
build.gradle
tasks.withType(ScalaCompile) { scalaCompileOptions.with { force = true } }
Note: This will only cause all classes to be recompiled if at least one input source file has changed. If there are no changes to the source files, the compileScala
task will still be considered UP-TO-DATE
as usual.
The Zinc-based Scala Compiler supports joint compilation of Java and Scala code. By default, all Java and Scala code under src/main/scala
will participate in joint compilation. Even Java code will be compiled incrementally.
Incremental compilation requires dependency analysis of the source code. The results of this analysis are stored in the file designated by scalaCompileOptions.incrementalOptions.analysisFile
(which has a sensible default). In a multi-project build, analysis files are passed on to downstream ScalaCompile
tasks to enable incremental compilation across project boundaries. For ScalaCompile
tasks added by the Scala plugin, no configuration is necessary to make this work. For other ScalaCompile
tasks that you might add, the property scalaCompileOptions.incrementalOptions.publishedCode
needs to be configured to point to the classes folder or Jar archive by which the code is passed on to compile class paths of downstream ScalaCompile
tasks. Note that if publishedCode
is not set correctly, downstream tasks may not recompile code affected by upstream changes, leading to incorrect compilation results.
Note that Zinc’s Nailgun based daemon mode is not supported. Instead, we plan to enhance Gradle’s own compiler daemon to stay alive across Gradle invocations, reusing the same Scala compiler. This is expected to yield another significant speedup for Scala compilation.
The Scala compiler ignores Gradle’s targetCompatibility
and sourceCompatibility
settings. In Scala 2.11, the Scala compiler always compiles to Java 6 compatible bytecode. In Scala 2.12, the Scala compiler always compiles to Java 8 compatible bytecode. If you also have Java sources, you can follow the same steps as for the Java plugin to ensure the correct Java compiler is used.
Example 57.10. Configure Java 6 build for Scala
gradle.properties
# in $HOME/.gradle/gradle.properties java6Home=/Library/Java/JavaVirtualMachines/1.6.0.jdk/Contents/Home
build.gradle
sourceCompatibility = 1.6 assert hasProperty('java6Home') : "Set the property 'java6Home' in your your gradle.properties pointing to a Java 6 installation" def javaExecutablesPath = new File(java6Home, 'bin') def javaExecutables = [:].withDefault { execName -> def executable = new File(javaExecutablesPath, execName) assert executable.exists() : "There is no ${execName} executable in ${javaExecutablesPath}" executable } tasks.withType(AbstractCompile) { options.with { fork = true forkOptions.javaHome = file(java6Home) } } tasks.withType(Test) { executable = javaExecutables.java } tasks.withType(JavaExec) { executable = javaExecutables.java } tasks.withType(Javadoc) { executable = javaExecutables.javadoc }
When the Eclipse plugin encounters a Scala project, it adds additional configuration to make the project work with Scala IDE out of the box. Specifically, the plugin adds a Scala nature and dependency container.
When the IDEA plugin encounters a Scala project, it adds additional configuration to make the project work with IDEA out of the box. Specifically, the plugin adds a Scala SDK (IntelliJ IDEA 14+) and a Scala compiler library that matches the Scala version on the project’s class path. The Scala plugin is backwards compatible with earlier versions of IntelliJ IDEA and it is possible to add a Scala facet instead of the default Scala SDK by configuring targetVersion
on IdeaModel
.
Example 57.11. Explicitly specify a target IntelliJ IDEA version
build.gradle
idea {
targetVersion = "13"
}