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Version: 0.72

Prerequisites for Libraries

caution

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 following steps will help ensure your modules and components are ready for the New Architecture.

Define Specs in JavaScript

The JavaScript specs serve as the source of truth for the methods provided by each native module. They define all APIs provided by the native module, along with the types of those constants and functions. Using a typed spec file allows you to be intentional and declare all the input arguments and outputs of your native module’s methods.

info

TypeScript support is in beta right now.

To adopt the New Architecture, you start by creating these specs for your native modules and native components. You can do this before migrating to the New Architecture: the specs will be used later on to generate native interface code for all the supported platforms as a way to enforce uniform APIs across platforms.

Turbo Native Modules

JavaScript spec files must be named Native<MODULE_NAME>.js, and they export a TurboModuleRegistry Spec object. The name convention is important because the Codegen process looks for modules whose js (jsx, ts, or tsx) spec file starts with the keyword Native.

The following is a basic JavaScript spec template, written using the Flow and TypeScript syntax.

// @flow strict

import type {TurboModule} from 'react-native/Libraries/TurboModule/RCTExport';
import {TurboModuleRegistry} from 'react-native';

export interface Spec extends TurboModule {
+getConstants: () => {||};

// your module methods go here, for example:
getString(id: string): Promise<string>;
}

export default (TurboModuleRegistry.get<Spec>(
'<MODULE_NAME>',
): ?Spec);

Fabric Native Components

JavaScript spec files must be named <FABRIC COMPONENT>NativeComponent.js (for TypeScript use extension .ts or .tsx) and they export a HostComponent object. The name convention is important: the Codegen process looks for components whose spec file (either JavaScript or TypeScript) ends with the suffix NativeComponent.

The following snippet shows a basic JavaScript spec template, written in Flow as well as TypeScript.

// @flow strict-local

import type {ViewProps} from 'react-native/Libraries/Components/View/ViewPropTypes';
import type {HostComponent} from 'react-native';
import codegenNativeComponent from 'react-native/Libraries/Utilities/codegenNativeComponent';

type NativeProps = $ReadOnly<{|
...ViewProps,
// add other props here
|}>;

export default (codegenNativeComponent<NativeProps>(
'<FABRIC COMPONENT>',
): HostComponent<NativeProps>);

Supported Types

When using Flow or TypeScript, you will be using type annotations to define your spec. Keeping in mind that the goal of defining a JavaScript spec is to ensure the generated native interface code is type-safe, the set of supported types will be those that can be mapped one-to-one to a corresponding type on the native platform.

In general, this means you can use primitive types (strings, numbers, booleans), function types, object types, and array types. Union types, on the other hand, are not supported. All types must be read-only. For Flow: either + or $ReadOnly<> or {||} objects. For TypeScript: readonly for properties, Readonly<> for objects, and ReadonlyArray<> for arrays.

See Appendix II. Flow Type to Native Type Mapping. See Appendix III. TypeScript to Native Type Mapping.

Codegen Helper Types

You can use predefined types for your JavaScript spec, here is a list of them:

  • Double
  • Float
  • Int32
  • UnsafeObject
  • WithDefault<Type, Value> - Sets default value for type
  • BubblingEventHandler<T> - For events that are propagated (bubbled) up the component tree from child to parent up to the root (eg: onStartShouldSetResponder).
  • DirectEventHandler<T> - For events that are called only on element recieving the event (eg: onClick) and don't bubble.

Later on those types are compiled to coresponding equivalents on target platforms.

Be Consistent Across Platforms and Eliminate Type Ambiguity

Before adopting the New Architecture in your native module, you should ensure your methods are consistent across platforms. You will realize this as you set out to write the JavaScript spec for your native module - remember that JavaScript spec defines what the methods will look like on all supported platforms.

If your existing native module has methods with the same name on multiple platforms, but with different numbers or types of arguments across platforms, you will need to find a way to make these consistent. If you have methods that can take two or more different types for the same argument, then you need to find a way to resolve this type of ambiguity as type unions are intentionally not supported.

Configure Codegen

Codegen is a tool that runs when you build an Android app or install the dependencies of an iOS app. It creates some scaffolding code that you won't have to create manually.

Codegen can be configured in the package.json file of your Library. Add the following JSON object at the end of it.

  },
+ "codegenConfig": {
+ "name": "<library name>",
+ "type": "all",
+ "jsSrcsDir": ".",
+ "android": {
+ "javaPackageName": "com.facebook.fbreact.specs"
+ }
+ }
}
  • The codegenConfig is the key used by the Codegen to verify that there is some code to generate.
  • The name field is the name of the library.
  • The type field is used to identify the type of module we want to create. We suggest keeping all to support libraries that contain both Turbo Native Module and Fabric Native Components.
  • The jsSrcsDir is the directory where the codegen will start looking for JavaScript specs.
  • The android.javaPackageName is the name of the package where the generated code ends up.

Android also requires to have the React Gradle Plugin properly configured in your app.

Migrating from UIManager JavaScript APIs

In the New Architecture, most UIManager methods will become available as instance methods on native component instances obtained via ref:

function MyComponent(props: Props) {
const viewRef = useRef(null);

useEffect(() => {
viewRef.current.measure(((left, top, width, height, pageX, pageY) => {
// ...
});
}, []);

return <View ref={viewRef} />;
}

This new API design provides several benefits:

  • Better developer ergonomics by removing the need for separately importing UIManager or calling findNodeHandle.
  • Better performance by avoiding the node handle lookup step.
  • Directionally aligned with the analogous deprecation of findDOMNode.

We will eventually deprecate UIManager. However, we recognize that migrations demand a high cost for many application and library authors. In order to minimize this cost, we plan to continue supporting as many of the methods on UIManager as possible in the New Architecture.

Support for UIManager methods in the New Architecture is actively being developed. While we make progress here, early adopters can still experiment with the New Architecture by following these steps to migrate off common UIManager APIs:

  1. Move the call to requireNativeComponent to a separate file
  2. Migrating off dispatchViewManagerCommand
  3. Creating NativeCommands with codegenNativeCommands

Move the call to requireNativeComponent to a separate file

This will prepare for the JS to be ready for the new codegen system for the New Architecture. The new file should be named <ComponentName>NativeComponent.js.

Old way

const RNTMyNativeView = requireNativeComponent('RNTMyNativeView');

[...]

return <RNTMyNativeView />;

New way

RNTMyNativeNativeComponent.js
import RNTMyNativeViewNativeComponent from './RNTMyNativeViewNativeComponent';

[...]

return <RNTMyNativeViewNativeComponent />;
RNTMyNativeViewNativeComponent.js
import {requireNativeComponent} from 'react-native';

const RNTMyNativeViewNativeComponent = requireNativeComponent(
'RNTMyNativeView',
);

export default RNTMyNativeViewNativeComponent;

Flow support

If requireNativeComponent is not typed, you can temporarily use the mixed type to fix the Flow warning, for example:

// @flow strict-local

import type {HostComponent} from 'react-native/Libraries/Renderer/shims/ReactNativeTypes';
// ...
const RCTWebViewNativeComponent: HostComponent<mixed> =
requireNativeComponent<mixed>('RNTMyNativeView');

Later on you can replace requireNativeComponent

When you are ready to migrate to Fabric you can replace requireNativeComponent with codegenNativeComponent:

RNTMyNativeViewNativeComponent.js
// @flow strict-local

export default (codegenNativeComponent<NativeProps>(
'RNTMyNativeView',
): HostComponent<NativeProps>);

And update the main file:

RNTMyNativeNativeComponent.js
// @flow strict-local

export default require('./RNTMyNativeViewNativeComponent')
.default;

Migrating off dispatchViewManagerCommand

Similar to the one above, in an effort to avoid calling methods on the UIManager, all view manager methods are now called through an instance of NativeCommands. codegenNativeCommands is a new API to code-generate NativeCommands given an interface of your view manager’s commands.

Before

class MyComponent extends React.Component<Props> {
_moveToRegion: (region: Region, duration: number) => {
UIManager.dispatchViewManagerCommand(
ReactNative.findNodeHandle(this),
'moveToRegion',
[region, duration]
);
}

render() {
return <MyCustomMapNativeComponent onPress={this._moveToRegion} />
}
}

Creating NativeCommands with codegenNativeCommands

MyCustomMapNativeComponent.js
// @flow strict-local

import codegenNativeCommands from 'react-native/Libraries/Utilities/codegenNativeCommands';
import type {HostComponent} from 'react-native/Libraries/Renderer/shims/ReactNativeTypes';

type MyCustomMapNativeComponentType = HostComponent<NativeProps>;

interface NativeCommands {
+moveToRegion: (
viewRef: React.ElementRef<MyCustomMapNativeComponentType>,
region: MapRegion,
duration: number,
) => void;
}

export const Commands: NativeCommands =
codegenNativeCommands<NativeCommands>({
supportedCommands: ['moveToRegion'],
});

Note:

  • The first argument in the moveToRegion command is a HostComponent ref of the native component
  • The arguments to the moveToRegion command are enumerated in the signature
  • The command definition is co-located with the native component. This is an encouraged pattern
  • Ensure you have included your command name in the supportedCommands array

Using Your Command

// @flow strict-local

import {Commands, ...} from './MyCustomMapNativeComponent';

class MyComponent extends React.Component<Props> {
_ref: ?React.ElementRef<typeof MyCustomMapNativeComponent>;

_captureRef: (ref: React.ElementRef<typeof MyCustomMapNativeComponent>) => {
this._ref = ref;
}

_moveToRegion: (region: Region, duration: number) => {
if (this._ref != null) {
Commands.moveToRegion(this._ref, region, duration);
}
}

render() {
return <MyCustomMapNativeComponent
ref={this._captureRef}
onPress={this._moveToRegion} />
}
}

Updating Native Implementation

In the example, the code-generated Commands will dispatch moveToRegion call to the native component’s view manager. In addition to writing the JS interface, you’ll need to update your native implementation signatures to match the dispatched method call. See the mapping for Android argument types andiOS argument types for reference.

iOS

RCT_EXPORT_METHOD(moveToRegion:(nonnull NSNumber *)reactTag
region:(NSDictionary *)region
duration:(double)duration
{
...
}

Android

// receiveCommand signature has changed to receive String commandId
@Override
public void receiveCommand(
ReactMapDrawerView view, String commandId, @Nullable ReadableArray args) {
switch (commandId) {
case "moveToRegion":
if (args == null) {
break;
}

ReadableMap region = args.getMap(0);
int durationMs = args.getInt(1);
// ... act on the view...
break;
}
}