Codegen
This documentation is still experimental and details are subject to changes as we iterate. Feel free to share your feedback on the discussion inside the working group for this page.
Moreover, it contains several manual steps. Please note that this won't be representative of the final developer experience once the New Architecture is stable. We're working on tools, templates and libraries to help you get started fast on the New Architecture, without having to go through the whole setup.
The Codegen is not a proper pillar, but it is a tool that can be used to avoid writing a lot of repetitive code. Using Codegen is not mandatory: all the code that is generated by it can also be written manually. However, it generates scaffolding code that could save you a lot of time.
The Codegen is invoked automatically by React Native every time an iOS or Android app is built. Occasionally, you would like to run the scripts that generate the code manually to know which types and files are actually generated: this is a common scenario when developing Turbo Native Modules and Fabric Native Components, for example.
This guide teaches how to configure the Codegen, and how to invoke it manually for each platform, and describes the generated code.
Prerequisites
You always need a React Native app to generate the code properly, even when invoking the Codegen manually.
The Codegen process is tightly coupled with the build of the app, and the scripts are located in the react-native
NPM package.
For the sake of this guide, create a project using the React Native CLI as follows:
npx react-native init SampleApp --version 0.70.0
This guide assumes that the React Native version in use is 0.70.0 or greater. Previous versions of React Native uses a version of Codegen that requires a slightly different setup.
Then, add the module that requires the Codegen as an NPM dependency of the app:
yarn add <path/to/your/TurboNativeModule_or_FabricNativeComponent>
See how to create a Turbo Native Module or a Fabric Native Component to get more information on how to configure them.
The rest of this guide assumes that you have a Turbo Native Module
and/or a Fabric Native Component
properly set up.
iOS
Running the Codegenβ
The Codegen for iOS relies on some Node scripts that are invoked during the build process. The scripts are located in the MyApp/node_modules/react-native/scripts/
folder.
The script that you have to run is the generate-codegen-artifacts.js
script. This searches among all the dependencies of the app, looking for JS files that respects some specific conventions (look at TurboModules and Fabric Components sections for details), and it generates the required code.
To invoke the script, you can run this command from the root folder of your app:
node node_modules/react-native/scripts/generate-codegen-artifacts.js \
--path SampleApp/ \
--outputPath <an/output/path> \
Given that the app has Turbo Native Modules
and/or Fabric Native Components
configured as a dependency, Codegen looks for all of them and generates the code in the path you provided.
The Generated Codeβ
If you run the Codegen in your app with an output path of codegen
, for example, you obtain the following structure:
codegen
βββ build
βββ generated
βββ ios
βββ MyTurboModuleSpecs
β βββ MyTurboModuleSpecs-generated.mm
β βββ MyTurboModuleSpecs.h
βββ FBReactNativeSpec
β βββ FBReactNativeSpec-generated.mm
β βββ FBReactNativeSpec.h
βββ RCTThirdPartyFabricComponentsProvider.h
βββ RCTThirdPartyFabricComponentsProvider.mm
βββ react
βββ renderer
βββ components
βββ MyFabricComponent
β βββ ComponentDescriptors.h
β βββ EventEmitters.cpp
β βββ EventEmitters.h
β βββ Props.cpp
β βββ Props.h
β βββ RCTComponentViewHelpers.h
β βββ ShadowNodes.cpp
β βββ ShadowNodes.h
βββ rncore
βββ ComponentDescriptors.h
βββ EventEmitters.cpp
βββ EventEmitters.h
βββ Props.cpp
βββ Props.h
βββ RCTComponentViewHelpers.h
βββ ShadowNodes.cpp
βββ ShadowNodes.h
The codegen
folder sits at the root of the hierarchy, as expected. Nested into it, there are two more folders: build/generated
.
Then, there is an ios
folder that contains:
- A custom folder for each TurboModule.
- The header (
.h
) and implementation (.mm
) files for theRCTThirdPartyFabricComponentsProvider
. - A base
react/renderer/components
folder which contains a custom folder for eachFabric Native Component
.
In the example above, there are both a TurboModule and a set of Fabric Native Components. These are generated by React Native itself: FBReactNativeSpec
and rncore
. These modules will always appear even if you don't have any extra TurboModule or Fabric Native Component: React Native requires them in order to work properly.
Turbo Native Modulesβ
Each folder contains two files: an interface file and an implementation file.
The interface files have the same name as that of the Turbo Native Module and contain methods to initialize the JSI interface.
The implementation files, instead, have the -generated
suffix and contain the logic to invoke the native methods from JS and vice-versa.
Fabric Native Componentsβ
The content of each Fabric Native Component folder contains several files. The basic element for a Fabric Native Component is the ShadowNode
: it represents a node in the React abstract tree. The ShadowNode
represents a React entity; therefore, it could need some props, which are defined in the Props
files and, sometimes, an EventEmitter
, defined in the corresponding file.
Additionally, the Codegen also creates a ComponentDescriptor.h
and an RCTComponentViewHelpers.h
files: the first one is used by React Native and Fabric to properly get a reference to the Fabric Native Component, while the latter contains some helper methods and protocols that can be implemented by the Native View to properly respond to JSI invocations.
For further details about how Fabric works, have a look at the Renderer section.
RCTThirdPartyFabricComponentsProviderβ
These are interface and implementation files for a registry. React Native uses this registry at runtime to retrieve the right class for a required Fabric Native Component. Once React Native has a handle to that class, it can instantiate it.
Android
Running the Codegenβ
Android Codegen
relies on a Gradle task to generate the required code. First, you need to configure the Android app to work with the New Architecture; otherwise, the Gradle task fails.
- Open the
MyApp/android/gradle.properties
file. - Flip the
newArchEnabled
flag fromfalse
totrue
.
After that, you can navigate into the SampleApp/android
folder and run:
./gradlew generateCodegenArtifactsFromSchema
These tasks invoke the generateCodegenArtifactsFromSchema
on all the the imported projects of the app (the app and all the node modules which are linked to it). It generates the code in the corresponding node_modules/<dependency>
folder. So, for example, if you have a Fabric Native Component whose node module is called my-fabric-component
, the generated code is located in the SampleApp/node_modules/my-fabric-component/android/build/generated/source/codegen
path.
The Generated Codeβ
Once the Gradle task completes, you can see different structures for a Turbo Native Module or for a Fabric Native Component. The following tab shows how they appear:
- turbomodules
- fabric-components
codegen
βββ java
β βββ com
β βββ MyTurbomodule
β βββ MyTurbomodule.java
βββ jni
β βββ Android.mk
β βββ CMakeLists.txt
β βββ MyTurbomodule-generated.cpp
β βββ MyTurbomodule.h
β βββ react
β βββ renderer
β βββ components
β βββ MyTurbomodule
β βββ ComponentDescriptors.h
β βββ EventEmitters.cpp
β βββ EventEmitters.h
β βββ Props.cpp
β βββ Props.h
β βββ ShadowNodes.cpp
β βββ ShadowNodes.h
βββ schema.json
codegen
βββ java
β βββ com
β βββ facebook
β βββ react
β βββ viewmanagers
β βββ MyFabricComponentManagerDelegate.java
β βββ MyFabricComponentManagerInterface.java
βββ jni
β βββ Android.mk
β βββ CMakeLists.txt
β βββ MyFabricComponent-generated.cpp
β βββ MyFabricComponent.h
β βββ react
β βββ renderer
β βββ components
β βββ MyFabricComponent
β βββ ComponentDescriptors.h
β βββ EventEmitters.cpp
β βββ EventEmitters.h
β βββ Props.cpp
β βββ Props.h
β βββ ShadowNodes.cpp
β βββ ShadowNodes.h
βββ schema.json
Java can't interoperate seamlessly with C++ as Objective-C++ does. To work properly, Codegen creates some bridging between the Java and the C++ world in the jni
folder, where the Java Native Interfaces are defined.
Notice that both Turbo Native Modules and Fabric Native Components come with two build file descriptors: the Android.mk
and the CMakeLists.txt
. These are used by the Android app to actually build the external modules.
Turbo Native Moduleβ
The Codegen generates a Java abstract class in the java
package with the same name as that of the TurboModule. This abstract class has to be implemented by the JNI C++ implementation.
Then, it generates the C++ files in the jni
folder. They follow the same iOS convention: there is an interface called MyTurbomodule.h
and an implementation file called MyTurbomodule-generated.cpp
. The former is an interface that allows React Native to initialize the JSI interface for the TurboModule. The latter is the implementation file which contains the logic to invoke the native method from JS and vice-versa.
Fabric Native Componentβ
The Codegen for a Fabric Native Component contains a MyFabricComponentManagerInterface.java
and a MyFabricComponentManagerDelegate.java
in the java
package. They are implemented and used by the native MyFabricComponentManager
required to properly load the component at runtime (See the guide on how to create a Fabric Native Component for details).
Then, there is a layer of JNI C++ files that are used by Fabric to render the components. The basic element for a Fabric Component is the ShadowNode
: it represents a node in the React abstract tree. The ShadowNode
represents a React entity; therefore it could need some props, which are defined in the Props
files and, sometimes, an EventEmitter
, defined in the corresponding file.
The Codegen also creates a ComponentDescriptor.h
, which is required to get a proper handle on the Fabric Native Component.