Prerequisites for Libraries
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 that are provided by each native module. They defines all APIs that are provided by the native module, along with the types of those constants and functions. Using a typed spec file allows to be intentional and declare all the input arguments and outputs of your native module’s methods.
Currently, this guide is written under the assumption that you will be using Flow. The react-native-codegen
package is also currently working only with Flow source as input. 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 prior to actually 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 syntax as well as TypeScript.
- Flow
- TypeScript
// @flow
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);
import type {TurboModule} from 'react-native';
import {TurboModuleRegistry} from 'react-native';
export interface Spec extends TurboModule {
readonly getConstants: () => {};
// your module methods go here, for example:
getString(id: string): Promise<string>;
}
export default TurboModuleRegistry.get<Spec>('<MODULE_NAME>');
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
- 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>);
import type {ViewProps} from 'ViewPropTypes';
import type {HostComponent} from 'react-native';
import codegenNativeComponent from 'react-native/Libraries/Utilities/codegenNativeComponent';
export interface NativeProps extends ViewProps {
// add other props here
}
export default codegenNativeComponent<NativeProps>(
'<FABRIC COMPONENT>',
) as 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), as well as 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 I. Flow Type to Native Type Mapping. See Appendix II. 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 typeBubblingEventHandler<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 will need to ensure your methods are consistent across platforms. This is something you will realize 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, you will also need to find a way to resolve this type ambiguity as type unions are intentionally not supported.
Make sure autolinking is enabled
Autolinking is a feature of the React Native CLI that simplifies the installation of third-party React Native libraries. Instructions to enable autolinking are available at https://github.com/react-native-community/cli/blob/master/docs/autolinking.md.
Android
On Android, this generally requires you to include native_modules.gradle
in both your settings.gradle[.kts]
and build.gradle[.kts]
.
If you used the default template provided with React Native (i.e. you used yarn react-native init <Project>
), then you have autolinking already enabled.
You can anyway verify that you have it enabled with:
$ grep -r "native_modules.gradle" android
android/app/build.gradle:apply from: file("../../node_modules/@react-native-community/cli-platform-android/native_modules.gradle"); applyNativeModulesAppBuildGradle(project)
android/settings.gradle:apply from: file("../node_modules/@react-native-community/cli-platform-android/native_modules.gradle"); applyNativeModulesSettingsGradle(settings)
...
If you don't, open the settings.gradle
file and add this line:
rootProject.name = <Your App Name>
+ apply from: file("../node_modules/@react-native-community/cli-platform-android/native_modules.gradle"); applyNativeModulesSettingsGradle(settings)
Then, open your android/app/build.gradle
file and add this line at the end of the file:
apply from: file("../../node_modules/@react-native-community/cli-platform-android/native_modules.gradle"); applyNativeModulesAppBuildGradle(project)
iOS
On iOS, make sure that your library provides a Podspec (see react-native-webview
for an example).
To determine if your library is set up for autolinking, check the CocoaPods output after running pod install
(or arch -x86_64 pod install
in case of a Mac M1) on an iOS project. If you see "auto linking library name", you are all set to go.
Configure Codegen
Codegen is a tool that runs when you build an Android app or when you 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. Our suggestion is to keepall
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 wil end up.
Android also requires to have the React Gradle Plugin properly configured in your app.
Preparing your JavaScript codebase for the new React Native Renderer (Fabric)
The new renderer also known as Fabric doesn’t use the UIManager so direct calls to UIManager will need to be migrated. Historically, calls to UIManager had some pretty complicated patterns. Fortunately, we’ve created new APIs that are much cleaner. These new APIs are forwards compatible with Fabric so you can migrate your code today and they will work properly when you turn on Fabric!
Fabric will be providing new type safe JS APIs that are much more ergonomic than some of the patterns we've seen in product code today. These APIs require references to the underlying component, no longer using the result of findNodeHandle
. findNodeHandle
is used to search the tree for a native component given a class instance. This was breaking the React abstraction model. findNodeHandle
is not compatible with React 18. Deprecation of findNodeHandle
in React Native is similar to the deprecation of findDOMNode
in React DOM.
While we know that all deprecations are a hassle, this guide is intended to help people update components as smoothly as possible. Here are the steps you need to take to get your JS codebase ready for Fabric:
- Migrating findNodeHandle / getting a HostComponent
- Migrating
.measure*()
- Migrating off
setNativeProps
- Move the call to
requireNativeComponent
to a separate file - Migrating off
dispatchViewManagerCommand
- Creating NativeCommands with
codegenNativeCommands
Migrating findNodeHandle
/ getting a HostComponent
Much of the migration work requires a HostComponent ref to access certain APIs that are only attached to host components (like View, Text, or ScrollView). HostComponents are the return value of calls to requireNativeComponent
. findNodeHandle
tunnels through multiple levels of component hierarchy to find the nearest native component.
As a concrete example, this code uses findNodeHandle
to tunnel from ParentComponent
through to the View
rendered by ChildComponent
.
class ParentComponent extends React.Component<Props> {
_ref: ?React.ElementRef<typeof ChildComponent>;
render() {
return <ChildComponent ref={this._captureRef} onSubmit={this._onSubmit} />
}
_captureRef: (ref) => {
this._ref = ref;
}
_onSubmit: () => {
const nodeHandle = findNodeHandle(this._ref);
if (nodeHandle) {
UIManager.measure(nodeHandle, () => {});
}
}
}
class ChildComponent extends React.Component<Props> {
render() {
return (
<View>
<SubmitButton onSubmit={props.onSubmit} />
</View>
);
}
}
We can’t convert this call to this._ref.measure
because this._ref
is an instance to ChildComponent
, which is not a HostComponent and thus does not have a measure
function.
ChildComponent
renders a View
, which is a HostComponent, so we need to get a reference to View
instead. There are typically two approaches to get what we need. If the component we need to get the ref from is a function component using forwardRef
is probably the right choice. If it is a class component with other public methods, adding a public method for getting the ref is an option. Here are examples of those two forms:
Using forwardRef
class ParentComponent extends React.Component<Props> {
_ref: ?React.ElementRef<typeof ChildComponent>;
render() {
return <ChildComponent ref={this._captureRef} onSubmit={this._onSubmit} />
}
_captureRef: (ref) => {
this._ref = ref;
}
_onSubmit: () => {
if (this._ref != null)
this._ref.measure(() => {});
}
}
}
const ChildComponent = React.forwardRef((props, forwardedRef) => {
return (
<View ref={forwardedRef}>
<SubmitButton onSubmit={props.onSubmit} />
</View>
);
});
Using a getter, (note the addition of getViewRef
)
class ParentComponent extends React.Component<Props> {
_ref: ?React.ElementRef<typeof ChildComponent>;
render() {
return <ChildComponent ref={this._captureRef} onSubmit={this._onSubmit} />
}
_captureRef: (ref) => {
this._ref = ref;
}
_onSubmit: () => {
if (this._ref != null)
this._ref.getViewRef().measure(() => {});
}
}
}
class ChildComponent extends React.Component<Props> {
_ref: ?React.ElementRef<typeof View>;
render() {
return (
<View ref={this._captureRef}>
<SubmitButton onSubmit={props.onSubmit} />
</View>
);
}
getViewRef(): ?React.ElementRef<typeof View> {
return this._ref;
}
_captureRef: (ref) => {
this._ref = ref;
}
}
Migrating .measure*()
Let’s take a look at an example calling UIManager.measure
. This code might look something like this
const viewRef: React.ElementRef<typeof View> = /* ... */;
const viewHandle = ReactNative.findNodeHandle(viewRef);
UIManager.measure(viewHandle, (x, y, width, height) => {
// Use layout metrics.
});
In order to call UIManager.measure*
we need to call findNodeHandle
first and pass in those handles. With the new API, we instead call measure
directly on native refs without findNodeHandle
. The example above with the new API looks like this:
const viewRef: React.ElementRef<typeof View> = /* ... */;
viewRef.measure((x, y, width, height) => {
// Use layout metrics.
});
findNodeHandle
can be called with any component as an argument, but the new .measure*
can only be called on native refs. If the ref originally passed into findNodeHandle
is not a native ref to start with, use the strategies above in getting a HostComponent to find the native ref.
Migrating off setNativeProps
setNativeProps
will not be supported in the post-Fabric world. To migrate, move all setNativeProp
values to component state.
Example
class MyComponent extends React.Component<Props> {
_viewRef: ?React.ElementRef<typeof View>;
render() {
const {somePropValue} = this.props;
return <View
onPress={this._onSubmit}
ref={this._captureRef}
someProp={somePropValue}
style={styles.view} />
}
_captureRef: (ref) => {
this._viewRef = ref;
}
_onSubmit: () => {
this._viewRef.setNativeProps({
style: styles.submittedView,
accessibility: true
});
// ...other logic for onSubmit
}
}
const styles = StyleSheet.create({
view: { backgroundColor: 'white'},
submittedView: {borderWidth: 1}
});
In this example when the View is pressed there is a setNativeProps
call to update the style and accessibility props of the component. To migrate this component it’s important to understand its current behavior using setNativeProps
.
Pre-Fabric, Component Props Persist
On first render, the component props are those declared in the render function. After the View is pressed _onSubmit
calls setNativeProps
with updated prop values.
The resulting component can be represented as such:
<View
accessibility={true}
onPress={this._onSubmit}
ref={this._captureRef}
someProp={somePropValue}
style={[styles.view, styles.submittedView]}
/>
Note that all prop values set in the render function are unchanged even though setNativeProps
didn’t pass those props. Also, style
is now the merged value of its value prior to _onSubmit
and styles.submittedView
. This is the important takeaway: in our current pre-Fabric world, component props persist. The platform view caches the prop values its passed from the JS side. If this wasn’t the case then following the setNativeProps call, React Native would have rendered a component like this:
<View accessibility={true} style={styles.submittedView} />
The fact that React Native stores some internal state of each component that isn’t explicitly declared in last render is what Fabric intends to fix.
Moving setNativeProps
to state
Taking those caveats into account, a proper migration would look like this:
class MyComponent extends React.Component<Props> {
state = {
hasSubmitted: false,
accessibility: false
};
render() {
const {somePropValue} = this.props;
const submittedStyle = this.state.hasSubmitted ? styles.submittedView: null;
return <View
accessibility={this.state.accessibility}
onPress={this._onSubmit}
someProp={somePropValue}
style={[styles.view, submittedStyle]} />
}
_onSubmit: () => {
this.setState(state => ({ ...state, hasSubmitted: true }));
// ...other logic for onSubmit
}
}
const styles = StyleSheet.create({
view: { backgroundColor: 'white'},
submittedView: {borderWidth: 1}
});
- We are using the
hasSubmitted
flag to represent whether or not we want to applystyles.submittedView
. If the style was dynamic then it makes sense to store the style object in state accessibility
is now explicitly passed to the View component as a boolean. This differs from the prior implementation whereaccessibility
wasn’t passed as a prop in initial render but in this case we know the non-specification ofaccessibility
is handled in the same way asaccessibilty={false}
Be wary of your assumptions as uncaught subtleties can introduce differences in behavior! It’s a good idea to have snapshot tests of your component as they will highlight any differences pre and post your migration.
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
import RNTMyNativeViewNativeComponent from './RNTMyNativeViewNativeComponent';
[...]
return <RNTMyNativeViewNativeComponent />;
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:
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
:
export default (codegenNativeComponent<NativeProps>(
'RNTMyNativeView',
): HostComponent<NativeProps>);
And update the main file:
export default require('./RNTMyNativeViewNativeComponent')
.default;
Migrating off dispatchViewManagerCommand
Similar to 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
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
supportedCommands
array
Using Your Command
import {Commands, ... } from './MyCustomMapNativeComponent';
class MyComponent extends React.Component<Props> {
_ref: ?React.ElementRef<typeof MyCustomMapNativeComponent>;
_captureRef: (ref) => {
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
- Java
- Kotlin
fun receiveCommand(
view: ReactMapDrawerView?, commandId: String?, args: ReadableArray?
) {
when (commandId) {
"moveToRegion" -> {
if (args != null) {
val region: ReadableMap = args.getMap(0)
val durationMs: Int = args.getInt(1)
// ... act on the view...
}
}
}
}
// 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;
}
}