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· 2 min read
Pieter De Baets

React Native allows you to build Android and iOS apps in JavaScript using React and Relay's declarative programming model. This leads to more concise, easier-to-understand code; fast iteration without a compile cycle; and easy sharing of code across multiple platforms. You can ship faster and focus on details that really matter, making your app look and feel fantastic. Optimizing performance is a big part of this. Here is the story of how we made React Native app startup twice as fast.

Why the hurry?

With an app that runs faster, content loads quickly, which means people get more time to interact with it, and smooth animations make the app enjoyable to use. In emerging markets, where 2011 class phones on 2G networks are the majority, a focus on performance can make the difference between an app that is usable and one that isn't.

Since releasing React Native on iOS and on Android, we have been improving list view scrolling performance, memory efficiency, UI responsiveness, and app startup time. Startup sets the first impression of an app and stresses all parts of the framework, so it is the most rewarding and challenging problem to tackle.

This is an excerpt. Read the rest of the post on Facebook Code.

· 9 min read
Martín Bigio

React Native's goal is to give you the best possible developer experience. A big part of it is the time it takes between you save a file and be able to see the changes. Our goal is to get this feedback loop to be under 1 second, even as your app grows.

We got close to this ideal via three main features:

  • Use JavaScript as the language doesn't have a long compilation cycle time.
  • Implement a tool called Packager that transforms es6/flow/jsx files into normal JavaScript that the VM can understand. It was designed as a server that keeps intermediate state in memory to enable fast incremental changes and uses multiple cores.
  • Build a feature called Live Reload that reloads the app on save.

At this point, the bottleneck for developers is no longer the time it takes to reload the app but losing the state of your app. A common scenario is to work on a feature that is multiple screens away from the launch screen. Every time you reload, you've got to click on the same path again and again to get back to your feature, making the cycle multiple-seconds long.

Hot Reloading

The idea behind hot reloading is to keep the app running and to inject new versions of the files that you edited at runtime. This way, you don't lose any of your state which is especially useful if you are tweaking the UI.

A video is worth a thousand words. Check out the difference between Live Reload (current) and Hot Reload (new).

If you look closely, you can notice that it is possible to recover from a red box and you can also start importing modules that were not previously there without having to do a full reload.

Word of warning: because JavaScript is a very stateful language, hot reloading cannot be perfectly implemented. In practice, we found out that the current setup is working well for a large amount of usual use cases and a full reload is always available in case something gets messed up.

Hot reloading is available as of 0.22, you can enable it:

  • Open the developer menu
  • Tap on "Enable Hot Reloading"

Implementation in a nutshell

Now that we've seen why we want it and how to use it, the fun part begins: how it actually works.

Hot Reloading is built on top of a feature Hot Module Replacement, or HMR. It was first introduced by Webpack and we implemented it inside of React Native Packager. HMR makes the Packager watch for file changes and send HMR updates to a thin HMR runtime included on the app.

In a nutshell, the HMR update contains the new code of the JS modules that changed. When the runtime receives them, it replaces the old modules' code with the new one:

The HMR update contains a bit more than just the module's code we want to change because replacing it, it's not enough for the runtime to pick up the changes. The problem is that the module system may have already cached the exports of the module we want to update. For instance, say you have an app composed of these two modules:

// log.js
function log(message) {
const time = require('./time');
console.log(`[${time()}] ${message}`);
}

module.exports = log;
// time.js
function time() {
return new Date().getTime();
}

module.exports = time;

The module log, prints out the provided message including the current date provided by the module time.

When the app is bundled, React Native registers each module on the module system using the __d function. For this app, among many __d definitions, there will one for log:

__d('log', function() {
... // module's code
});

This invocation wraps each module's code into an anonymous function which we generally refer to as the factory function. The module system runtime keeps track of each module's factory function, whether it has already been executed, and the result of such execution (exports). When a module is required, the module system either provides the already cached exports or executes the module's factory function for the first time and saves the result.

So say you start your app and require log. At this point, neither log nor time's factory functions have been executed so no exports have been cached. Then, the user modifies time to return the date in MM/DD:

// time.js
function bar() {
const date = new Date();
return `${date.getMonth() + 1}/${date.getDate()}`;
}

module.exports = bar;

The Packager will send time's new code to the runtime (step 1), and when log gets eventually required the exported function gets executed it will do so with time's changes (step 2):

Now say the code of log requires time as a top level require:

const time = require('./time'); // top level require

// log.js
function log(message) {
console.log(`[${time()}] ${message}`);
}

module.exports = log;

When log is required, the runtime will cache its exports and time's one. (step 1). Then, when time is modified, the HMR process cannot simply finish after replacing time's code. If it did, when log gets executed, it would do so with a cached copy of time (old code).

For log to pick up time changes, we'll need to clear its cached exports because one of the modules it depends on was hot swapped (step 3). Finally, when log gets required again, its factory function will get executed requiring time and getting its new code.

HMR API

HMR in React Native extends the module system by introducing the hot object. This API is based on Webpack's one. The hot object exposes a function called accept which allows you to define a callback that will be executed when the module needs to be hot swapped. For instance, if we would change time's code as follows, every time we save time, we'll see “time changed” in the console:

// time.js
function time() {
... // new code
}

module.hot.accept(() => {
console.log('time changed');
});

module.exports = time;

Note that only in rare cases you would need to use this API manually. Hot Reloading should work out of the box for the most common use cases.

HMR Runtime

As we've seen before, sometimes it's not enough only accepting the HMR update because a module that uses the one being hot swapped may have been already executed and its imports cached. For instance, suppose the dependency tree for the movies app example had a top-level MovieRouter that depended on the MovieSearch and MovieScreen views, which depended on the log and time modules from the previous examples:

If the user accesses the movies' search view but not the other one, all the modules except for MovieScreen would have cached exports. If a change is made to module time, the runtime will have to clear the exports of log for it to pick up time's changes. The process wouldn't finish there: the runtime will repeat this process recursively up until all the parents have been accepted. So, it'll grab the modules that depend on log and try to accept them. For MovieScreen it can bail, as it hasn't been required yet. For MovieSearch, it will have to clear its exports and process its parents recursively. Finally, it will do the same thing for MovieRouter and finish there as no modules depends on it.

In order to walk the dependency tree, the runtime receives the inverse dependency tree from the Packager on the HMR update. For this example the runtime will receive a JSON object like this one:

{
modules: [
{
name: 'time',
code: /* time's new code */
}
],
inverseDependencies: {
MovieRouter: [],
MovieScreen: ['MovieRouter'],
MovieSearch: ['MovieRouter'],
log: ['MovieScreen', 'MovieSearch'],
time: ['log'],
}
}

React Components

React components are a bit harder to get to work with Hot Reloading. The problem is that we can't simply replace the old code with the new one as we'd loose the component's state. For React web applications, Dan Abramov implemented a babel transform that uses Webpack's HMR API to solve this issue. In a nutshell, his solution works by creating a proxy for every single React component on transform time. The proxies hold the component's state and delegate the lifecycle methods to the actual components, which are the ones we hot reload:

Besides creating the proxy component, the transform also defines the accept function with a piece of code to force React to re-render the component. This way, we can hot reload rendering code without losing any of the app's state.

The default transformer that comes with React Native uses the babel-preset-react-native, which is configured to use react-transform the same way you'd use it on a React web project that uses Webpack.

Redux Stores

To enable Hot Reloading on Redux stores you will just need to use the HMR API similarly to what you'd do on a web project that uses Webpack:

// configureStore.js
import { createStore, applyMiddleware, compose } from 'redux';
import thunk from 'redux-thunk';
import reducer from '../reducers';

export default function configureStore(initialState) {
const store = createStore(
reducer,
initialState,
applyMiddleware(thunk),
);

if (module.hot) {
module.hot.accept(() => {
const nextRootReducer = require('../reducers/index').default;
store.replaceReducer(nextRootReducer);
});
}

return store;
};

When you change a reducer, the code to accept that reducer will be sent to the client. Then the client will realize that the reducer doesn't know how to accept itself, so it will look for all the modules that refer it and try to accept them. Eventually, the flow will get to the single store, the configureStore module, which will accept the HMR update.

Conclusion

If you are interested in helping making hot reloading better, I encourage you to read Dan Abramov's post around the future of hot reloading and to contribute. For example, Johny Days is going to make it work with multiple connected clients. We're relying on you all to maintain and improve this feature.

With React Native, we have the opportunity to rethink the way we build apps in order to make it a great developer experience. Hot reloading is only one piece of the puzzle, what other crazy hacks can we do to make it better?

· 2 min read
Georgiy Kassabli

With the recent launch of React on web and React Native on mobile, we've provided a new front-end framework for developers to build products. One key aspect of building a robust product is ensuring that anyone can use it, including people who have vision loss or other disabilities. The Accessibility API for React and React Native enables you to make any React-powered experience usable by someone who may use assistive technology, like a screen reader for the blind and visually impaired.

For this post, we're going to focus on React Native apps. We've designed the React Accessibility API to look and feel similar to the Android and iOS APIs. If you've developed accessible applications for Android, iOS, or the web before, you should feel comfortable with the framework and nomenclature of the React AX API. For instance, you can make a UI element accessible (therefore exposed to assistive technology) and use accessibilityLabel to provide a string description for the element:

<View accessible={true} accessibilityLabel=”This is simple view”>

Let's walk through a slightly more involved application of the React AX API by looking at one of Facebook's own React-powered products: the Ads Manager app.

This is an excerpt. Read the rest of the post on Facebook Code.

· One min read

Earlier this year, we introduced React Native for iOS. React Native brings what developers are used to from React on the web — declarative self-contained UI components and fast development cycles — to the mobile platform, while retaining the speed, fidelity, and feel of native applications. Today, we're happy to release React Native for Android.

At Facebook we've been using React Native in production for over a year now. Almost exactly a year ago, our team set out to develop the Ads Manager app. Our goal was to create a new app to let the millions of people who advertise on Facebook manage their accounts and create new ads on the go. It ended up being not only Facebook's first fully React Native app but also the first cross-platform one. In this post, we'd like to share with you how we built this app, how React Native enabled us to move faster, and the lessons we learned.

This is an excerpt. Read the rest of the post on Facebook Code.

· 2 min read
Tom Occhino

We introduced React to the world two years ago, and since then it's seen impressive growth, both inside and outside of Facebook. Today, even though no one is forced to use it, new web projects at Facebook are commonly built using React in one form or another, and it's being broadly adopted across the industry. Engineers are choosing to use React every day because it enables them to spend more time focusing on their products and less time fighting with their framework. It wasn't until we'd been building with React for a while, though, that we started to understand what makes it so powerful.

React forces us to break our applications down into discrete components, each representing a single view. These components make it easier to iterate on our products, since we don't need to keep the entire system in our head in order to make changes to one part of it. More important, though, React wraps the DOM's mutative, imperative API with a declarative one, which raises the level of abstraction and simplifies the programming model. What we've found is that when we build with React, our code is a lot more predictable. This predictability makes it so we can iterate more quickly with confidence, and our applications are a lot more reliable as a result. Additionally, it's not only easier to scale our applications when they're built with React, but we've found it's also easier to scale the size of our teams themselves.

Together with the rapid iteration cycle of the web, we've been able to build some awesome products with React, including many components of Facebook.com. Additionally, we've built amazing frameworks in JavaScript on top of React, like Relay, which allows us to greatly simplify our data fetching at scale. Of course, web is only part of the story. Facebook also has widely used Android and iOS apps, which are built on top of disjointed, proprietary technology stacks. Having to build our apps on top of multiple platforms has bifurcated our engineering organization, but that's only one of the things that makes native mobile application development hard.

This is an excerpt. Read the rest of the post on Facebook Code.