Gradle Implementation vs API configuration

Question

I'm trying to figure out what is the difference between api and implementation configuration while building my dependencies.

In the documentation, it says that implementation has better build time, but, seeing this comment in a similar question I got to wonder if is it true.

Since I'm no expert in Gradle, I hope someone can help. I've read the documentation already but I was wondering about an easy-to-understand explanation.

Answer 1

Gradle compile keyword was deprecated in favor of the api and implementation keywords to configure dependencies.

Using api is the equivalent of using the deprecated compile, so if you replace all compile with api everything will works as always.

To understand the implementation keyword consider the following example.

EXAMPLE

Suppose you have a library called MyLibrary that internally uses another library called InternalLibrary. Something like this:

// 'InternalLibrary' module
public class InternalLibrary {
    public static String giveMeAString(){
        return "hello";
    }
}

// 'MyLibrary' module
public class MyLibrary {
    public String myString(){
        return InternalLibrary.giveMeAString();
    }
}

Suppose the MyLibrary build.gradle uses api configuration in dependencies{} like this:

dependencies {
    api project(':InternalLibrary')
}

You want to use MyLibrary in your code so in your app's build.gradle you add this dependency:

dependencies {
    implementation project(':MyLibrary')
}

Using the api configuration (or deprecated compile) you can access InternalLibrary in your application code:

// Access 'MyLibrary' (granted)
MyLibrary myLib = new MyLibrary();
System.out.println(myLib.myString());

// Can ALSO access the internal library too (but you shouldn't)
System.out.println(InternalLibrary.giveMeAString());

In this way the module MyLibrary is potentially "leaking" the internal implementation of something. You shouldn't (be able to) use that because it's not directly imported by you.

The implementation configuration was introduced to prevent this. So now if you use implementation instead of api in MyLibrary:

dependencies {
    implementation project(':InternalLibrary')
}

you won't be able to call InternalLibrary.giveMeAString() in your app code anymore.

This sort of boxing strategy allows Android Gradle plugin to know that if you edit something in InternalLibrary, it must only trigger the recompilation of MyLibrary and not the recompilation of your entire app, because you don't have access to InternalLibrary.

When you have a lot of nested dependencies this mechanism can speed up the build a lot. (Watch the video linked at the end for a full understanding of this)

CONCLUSIONS

• When you switch to the new Android Gradle plugin 3.X.X, you should replace all your compile with the implementation keyword *(1). Then try to compile and test your app. If everything it's ok leave the code as is, if you have problems you probably have something wrong with your dependencies or you used something that now is private and not more accessible. *Suggestion by Android Gradle plugin engineer Jerome Dochez (1))

• If you are a library mantainer you should use api for every dependency which is needed for the public API of your library, while use implementation for test dependencies or dependencies which must not be used by the final users.

Useful article Showcasing the difference between implementation and api

REFERENCES (This is the same video splitted up for time saving)

Google I/O 2017 - How speed up Gradle builds (FULL VIDEO)

Google I/O 2017 - How speed up Gradle builds (NEW GRADLE PLUGIN 3.0.0 PART ONLY)

Google I/O 2017 - How speed up Gradle builds (reference to 1*)

Android documentation

Answer 2

I like to think about an api dependency as public (seen by other modules) while implementation dependency as private (only seen by this module).

Note, that unlike public/private variables and methods, api/implementation dependencies are not enforced by the runtime. This is merely a build-time optimization, that allows Gradle to know which modules it needs to recompile when one of the dependencies changes its API.

Answer 3

Consider you have app module which uses lib1 as a library and lib1 uses lib2 as a library. Something like this: app -> lib1 -> lib2.

Now when using api lib2 in lib1, then app can see lib2 codes when using: api lib1 or implementation lib1 in the app module.

BUT when using implementation lib2 in lib1, then app can not see the lib2 codes.

Answer 4

From gradle documentation:

Let’s have a look at a very simple build script for a JVM-based project.

plugins {
    id 'java-library'
}

repositories {
    mavenCentral()
}

dependencies {
    implementation 'org.hibernate:hibernate-core:3.6.7.Final'
    api 'com.google.guava:guava:23.0'
    testImplementation 'junit:junit:4.+'
}

implementation

The dependencies required to compile the production source of the project which are not part of the API exposed by the project. For example the project uses Hibernate for its internal persistence layer implementation.

api

The dependencies required to compile the production source of the project which are part of the API exposed by the project. For example the project uses Guava and exposes public interfaces with Guava classes in their method signatures.

Answer 5

Answers from @matpag and @dev-bmax are clear enough to make people understand different usages between implementation and api. I just want to make an extra explaination from another angle, hopes to help for peoples that have the same question.

I created two projects for testing :

• project A as a java library project named 'frameworks-web-gradle-plugin' depends on 'org.springframework.boot:spring-boot-gradle-plugin:1.5.20.RELEASE'
• project B depends on project A by implementation 'com.example.frameworks.gradle:frameworks-web-gradle-plugin:0.0.1-SNAPSHOT'

The dependencies hierarchy descripted above looks like:

[project-b] -> [project-a] -> [spring-boot-gradle-plugin]

Then I tested following scenarios:

1. Make project A depends on 'org.springframework.boot:spring-boot-gradle-plugin:1.5.20.RELEASE' by implementation .

   Run gradle dependencies command in a terminal in poject B root dir?with following screenshot of output we can see that 'spring-boot-gradle-plugin' appears in runtimeClasspath dependencies tree, but not in compileClasspath's, I think that's exactly why we can't make use of library that declared using implementation, it just won't through compilation.

   

2. Make project A depends on 'org.springframework.boot:spring-boot-gradle-plugin:1.5.20.RELEASE' by api

   Run gradle dependencies command in a terminal in poject B root dir again. Now 'spring-boot-gradle-plugin' appears both in compileClasspath and runtimeClasspath dependencies tree.

   

A significant difference I noticed is that the dependency in producer/library project declared in implementation way won't appear in compileClasspath of consumer projects, so that we can't make use of corresponding lib in the consumer projects.

Answer 6

Please refer the link: Android Studio Dependency Configuration available at android developers' official site.

Inside the dependencies block, you can declare a library dependency using one of several different dependency configurations (such as implementation shown above). Each dependency configuration provides Gradle with different instructions about how to use the dependency.

implementation

Gradle adds the dependency to the compile classpath and packages the dependency to the build output. However, when your module configures an implementation dependency, it's letting Gradle know that you do not want the module to leak the dependency to other modules at compile time. That is, the dependency is available to other modules only at runtime. Using this dependency configuration instead of api or compile (deprecated) can result in significant build time improvements because it reduces the number of modules that the build system needs to recompile. For example, if an implementation dependency changes its API, Gradle recompiles only that dependency and the modules that directly depend on it. Most app and test modules should use this configuration.

api

Gradle adds the dependency to the compile classpath and build output. When a module includes an api dependency, it's letting Gradle know that the module wants to transitively export that dependency to other modules, so that it's available to them at both runtime and compile time. This configuration behaves just like compile (which is now deprecated), but you should use it with caution and only with dependencies that you need to transitively export to other upstream consumers. That's because, if an api dependency changes its external API, Gradle recompiles all modules that have access to that dependency at compile time. So, having a large number of api dependencies can significantly increase build time. Unless you want to expose a dependency's API to a separate module, library modules should instead use implementation dependencies.

Answer 7

One more technical note regarding api vs implementation. Suppose you have following dependencies:

dependencies {
  api "com.example:foo:1.0"
  implementation "com.example:bar:1.0"
}

If you install a generated jar file in your local Maven repository (with help of maven-publish plugin) you will see that generated pom.xml file will look like this:

    <dependency>
      <groupId>com.example</groupId>
      <artifactId>foo</artifactId>
      <version>1.0</version>
      <scope>compile</scope>
    </dependency>
    <dependency>
      <groupId>com.example</groupId>
      <artifactId>bar</artifactId>
      <version>1.0</version>
      <scope>runtime</scope>
    </dependency>

Note: api was converted to compile scope and implementation - to runtime scope.

That allows for consumers of this library to avoid having runtime dependencies in their compile classpath.

Answer 8

Now there is good explanation in the documentation

The api configuration should be used to declare dependencies which are exported by the library API, whereas the implementation configuration should be used to declare dependencies which are internal to the component.