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Gratatouille 🐘🤝🐭👉🧑‍🍳#

Gratatouille is an opinionated framework to build Gradle plugins. Write pure Kotlin functions and the Gratatouille KSP processor generates tasks, workers, and wiring code for you.

Gratatouille enforces a clear separation between your plugin logic (implementation) and your plugin wiring (gradle-plugin) making your plugin immune to classloader issues 🛡️

Features: * Pure functions * Kotlinx serialization support * Comprehensive input/output types * Non overlapping task outputs * Classloader isolation * Build cache * Documentation * Parallel execution * Compile-time task wiring

Check out the sample-plugin and sample-app.

Quick Start#

Step 1/2: com.gradleup.gratatouille.implementation#

Create an implementation module for your plugin implementation and apply the com.gradleup.gratatouille.implementation plugin:

// implementation/build.gradle.kts
plugins {
    id("com.gradleup.gratatouille.implementation").version("0.0.1")
}

dependencies {
    // Add the gratatouille annotations
    implementation("com.gradleup.gratatouille:gratatouille-core:0.0.1")
    // Add other dependencies
    implementation("com.squareup:kotlinpoet:1.14.2")
    implementation("org.ow2.asm:asm-commons:9.6")
    // do **not** add gradleApi() here
}

Write your task action as a pure top-level Kotlin function annotated with @GTaskAction:

@GTaskAction
internal fun prepareIngredients(persons: Int): Ingredients {
    return Ingredients(
        tomatoes = (persons * 0.75).roundToInt(),
        zucchinis = (persons * 0.3).roundToInt(),
        eggplants = (persons * 0.3).roundToInt(),
    )
}

// kotlinx.serialization is supported out of the box
@Serializable
internal data class Ingredients(
    val tomatoes: Int,
    val zucchinis: Int,
    val eggplants: Int,
)

Gratatouille automatically maps function parameters to Gradle inputs and the return value to a Gradle output (more on outputs below).

Gratatouille generates entry points, tasks, workers and Gradle wiring code that you can then use to cook your plugin.

Step 2/2 com.gradleup.gratatouille.plugin#

To use the generated code in your plugin, create a gradle-plugin module next to your implementation module.

[!IMPORTANT] By using two different modules, Gratatouille ensures that Gradle classes do not leak in your plugin implementation and vice-versa.

Apply the com.gradleup.gratatouille.plugin plugin in your gradle-plugin module:

// gradle-plugin/build.gradle.kts
plugins {
    id("java-gradle-plugin")
    id("com.gradleup.gratatouille.plugin").version("0.0.1")
}

dependencies {
    // Add your implementation module to the "gratatouille" configuration.
    // This does not add `:implementation` to your plugin classpath.
    // Instead, the generated code uses reflection and a separate classloader to run
    // your implementation
    gratatouille(project(":implementation"))
}

// Create your plugin as usual, see https://docs.gradle.org/current/userguide/java_gradle_plugin.html 
gradlePlugin {
    // ... 
}

In your plugin code, use Project.register${TaskAction}Task() to register the task:

override fun apply(project: Project) {
    val extension = project.extensions.create("recipes", RecipesExtension::class.java)

    // Register your "PrepareIngredients" task
    val prepareIngredients = project.registerPrepareIngredientsTask(
        persons = extension.persons
    )

    // Register other tasks
    project.registerCookTask(
        recipe = extension.recipe,
        // Wire tasks together
        ingredients = prepareIngredients.flatMap { it.outputFile }
    )
}

Features#

Pure functions#

Your task code is a side-effect-free function, making it easier to parallelize and reason about.

Nullable parameters are generated as optional task properties. Calls to Provider.get() or Provider.orNull are automated.

Built-in kotlinx.serialization support#

Gratatouille has builtin support for kotlinx.serialization. Models are serialized and deserialized as needed.

Supported input and output types#

Inputs: * Any type annotated with @Serializable (serialized to a File) * Kotlin Int, Boolean, Float, Double, String * Kotlin Set, List, Map * Single File using the GInputFile typealias * FileCollection using the GInputFiles typealias * Directory using the GInputDirectory typealias

Outputs: * Any type annotated with @Serializable (serialized to a File) * Single File using the GOutputFile typealias * Directory using the GOutputDirectory typealias

Non-overlapping task outputs by default#

Gratatouille allocates paths for output files and directories automatically. Each output gets a dedicated filesystem location at "build/gtask/${taskName}/${outputName}".

This way: * you don't have to think about what path to use. * the outputs are consistent and discoverable. * issues like #26091 are avoided by construction.

If your function has a single return value, Gratatouille uses outputFile as output name.

If your function needs multiple return values, wrap them in a non-serializable class.

If you need to control the output location of an output, you can do so using @GManuallyWired and using GOutputFile/GOutputDirectory as parameters.

In your implementation:

@GTaskAction
internal fun cook(
    recipe: GInputFile,
    ingredients: Ingredients,
    // ratatouille is exposed in registerCookTask(outputFile) so you can configure it 
    @GManuallyWired ratatouille: GOutputFile,
    // leftovers is set to "build/gtask/cook/leftovers" 
    leftovers: GOutputFile,
) {
    ratatouille.writeText(/* cook here! */)
}

In your plugin:

project.registerCookTask(
    recipe = extension.recipe,
    ingredients = prepareIngredients.flatMap { it.outputFile },
    // Set outputFile location explicitly
    ratatouille = project.layout.buildDirectory.file("ratatouille")
    // No need to set lefovers
)

Classloader isolation by default#

Gratatouille creates a separate classloader for each task and calls your pure functions using reflection.

This means your plugin can depend on popular dependencies such as the Kotlin stdlib, KotlinPoet or ASM without risking conflicts with other plugins or the Gradle classpath itself.

Build cache by default#

@CacheableTask is added by default. All input files use PathSensitivity.RELATIVE making your tasks relocatable.

Easy documentation#

@GTaskAction takes a description and a group argument making it easy to colocate your documentation with your implementation:

@GTaskAction(
    description = "cooks the most delicious ratatouille with the help of the tiniest chef",
    group = "recipes"
)
internal fun cook(
    recipe: GInputFile,
    ingredients: Ingredients,
    outputFile: GOutputFile
) { 
    TODO()
}

Parallel task execution by default#

By default, Gradle tasks execute serially in a single module (unless using the configuration cache).

Because your task actions are pure Kotlin function, no state is shared, making them perfect candidates for parallelization.

Gratatouille uses the Worker API to allow parallel execution making your build faster overall. Use org.gradle.workers.max to control the maximum number of workers.

Compile time task wiring#

Finally, Gratatouille encourages exposing extensions to users instead of task classes directly. All generated code is generated as internal. This makes it easier to have some inputs user configurable while some others are an implementation details and more generally makes it easier to evolve the public API of your plugin.

When a task has a high number of inputs, it can become hard to track which ones have been wired and which ones haven't. By using a central registration point, Gratatouille enforces at build time that all inputs/outputs have been properly wired.