I use Facebook every day — probably too much for my own good — and I’ve always been tempted to dive into their internals. That is, the Javascript code that produces much of the user interface and interactions.

A few months ago, I started thinking about the little status indicator that shows up when one of your friends is writing to you. It’s such an inconsequential UI addition, and yet it seems to reveal so much about your interlocutor. When it repeatedly blinks in and out of existence, it suggests hesitation. Have it linger on for a while, and they might be writing you an essay. And there’s nothing like that excruciating feeling when you watch it disappear, never to be seen again.

Look at that smug face. It’s taunting me, I know it!

One thing that got me intrigued was figuring out whether the data needed to display this indicator was sent to all members of a conversation regardless of them having it open. My first logical step was to open my network tab and start looking for signs of activity whenever someone was typing to me.

And there it was! The theorized typ event, sent from the global Facebook long-polling /pull request. A little experimentation showed that this event was, indeed, sent for every conversation, even those I hadn’t held open, or never started.

While my snooping around could have stopped at that, I felt obligated to make something out of this discovery.

And thus I present to you my creepiest invention yet: the Facebook Sixth Sense. A Chrome extension that warns you whenever someone starts and stops typing to you. June 9: removed from the Google Web Store in compliance with a Cease and Desist.

The rest of this blog post is dedicated to explaining how I used Facebook’s own private APIs in order to build this application.

Un-minifying JavaScript

Nowadays, most big Javascript applications tend to minify their code by running it through tools such as UglifyJs or Google Closure Compiler. While this is no bytecode, the compression ratio these tools achieve without ever altering the intended behaviour of the app is impressive. The user gets to the page in record time and the company saves bandwidth money. Everybody wins! 🎉

Except us.

Most of the readability of the original source code is lost. Local variable names are mushed to single letters, losing much of their meaning in the process, and any non-critical or redundant syntax gets thrown away or replaced with shorter alternatives. Goodbye whitespace, hello obscure syntax constructs!

We end up with a few thousand characters long lines of nonsensical, jumbled mess of a code.

Don’t panic! We can restore some amount of sanity by adding back whitespace and indentation. In fact, the Chrome devtools even offer to do it for us!

This almost looks sane.

Now we’re ready to start reading some code!

Modules

Javascript still has no good module story. A standard is in the work, but none of the main browsers have implemented it. In the meantime, a few solutions have popped up, such as Asynchronous Module Definition and CommonJS.

Well, as it turns out, Facebook has its own AMD solution. Modules are defined with the usual __d(name, dependencies, factory) . There ‘s also require and a requireLazy for importing modules.

I’d tell you to try it yourself on Facebook, but they have a big warning sign telling you not to copy and paste untrusted code into your console. Which is a very good idea. Don’t do this, okay?

Wow, this Facebook person sure sounds serious. Better not mess with them.

Who am I kidding, let’s tinker!

> require('React') // Object {Children: Object, PropTypes: Object, DOM: Object, version: "16.0.0-alpha"}

Yep, Facebook always runs the master branch of React. That’s pretty bold. But also really cool.

You can search for __d( in the Sources tab to find out all the modules that are currently available to import. Use Ctrl+Shift+F or Option+Shift+F to search in all the source files. As you’ll find out, there’s a bunch of them!

Only 3000 modules? Amateurs. (and that’s only for the front page!)

React All The Things

By now you’ve probably heard about React. It’s a pretty cool library from Facebook that lets you define your view components declaratively, in full Javascript. I’m not here to sell it to you, but if you haven’t already, go check it out!

As you might have deduced from that part about modules, Facebook use React on their main website, and quite extensively so. In October 2015, they already had over 15,000 React components!

Another good thing about React components is that, when written properly, they’re very well compartmentalised. That is, their dependencies are explicit and they mostly opt to do one thing, and do it well. This property is going to be of great use to us in the rest of our adventure!

Tracking Game

In case you’ve forgotten, we’re trying to intercept the typing notifications from our (soon not to be) friends. Let’s start with where it all begins: the chat box.

I have real friends, I swear.

Remember that part about React components? Well, the Messenger chat box is one of them. And there’s one great trick to inspect it in more details: the React Devtools.

Click on the chat box, choose Inspect , then go to the React tab of your Chrome devtools. Tada! You’re in React land now!

Inspecting away. Honestly, how cool is that?

Don’t get lost in exploring the hidden world of the Facebook React components. We’re looking for one particular thing: the chat typing indicator. An elusive creature who is most often found at the bottom of the chat bubbles list.

Aye, the mighty ChatTypingIndicator.

If you don’t manage to catch it in its natural habitat, you can still find it between the <ChatTabComposerContainer /> and the <MercuryLastMessageIndicator /> .

Alright, now that we have a better idea of what we’re hunting, let’s look into the entrails of the beast. I’ll stop the metaphor here.

Searching for __d('ChatTyping in the React codebase yields two modules: ChatTypingIndicator.react.js , and ChatTypingIndicators.react.js , which is the one we’re looking for. Note the .react prefix, which indicates that the module exports a React component.

If you can’t find the ChatTypingIndicators.react.js module, you should open a chat box and try again. Some modules are only loaded when they’re really needed.

Anatomy of a React Component

During its life, a React Component will fire a few lifecycle hooks. For instance, right after it is mounted in the DOM, the componentDidMount method is called on the component instance.

This method is the preferred place to subscribe to events and/or asynchronously load data, so that’s where we’re going to look first!

Yep, looks about right.

And here’s a full view of the code:

function ( ) { var k = c ( 'MercuryThreadInformer' ) . getForFBID ( this . props . viewer ) , l = c ( 'MercuryTypingReceiver' ) . getForFBID ( this . props . viewer ) ; this . _subscriptions = new ( c ( 'SubscriptionsHandler' ) ) ( ) ; this . _subscriptions . addSubscriptions ( l . addRetroactiveListener ( 'state-changed' , this . typingStateChanged ) , k . subscribe ( 'messages-received' , this . messagesReceived ) ) ; } ,

See that c('MercuryTypingReceiver') call? That’s the minified version of require('MercuryTypingReceiver') . So we’re retrieving a very unambiguously named MercuryTypingReceiver , and we’re telling it to call the typingStateChanged method whenever its internal state changes. Our little module here is starting to look a lot like a Flux store. But we don’t really need to know how it works, this addRetroactiveListener() method looks just like what we were looking for.

Peeking at the typingStateChanged method, we can get an idea of the structure of the state of our MercuryTypingReceiver store. It looks like a dictionary that maps thread ids to an array of typing user ids. We’ll get back to it later, for now, let’s try to use this MercuryTypingReceiver !

MercuryTypingReceiver

Using our new friend the require function, we can inspect MercuryTypingReceiver right there in our console. Let’s give it a look!

> const MercuryTypingReceiver = require ( 'MercuryTypingReceiver' ) ; > MercuryTypingReceiver

That doesn’t look too good. As we’ve seen before, MercuryTypingReceiver has a getForFBID static method. However, the Chrome devtools do not let us inspect function properties directly. To circumvent that, let’s wrap it in an object:

Much better!

And now let’s take a look at both its public static methods, get and getForFBID :

> MercuryTypingReceiver . getForFBID > MercuryTypingReceiver . get

From this, we can assert that MercuryTypingReceiver.getForFBID(fbid) retrieves a MercuryTypingReceiver instance from a FBID string, while MercuryTypingReceiver.get() is just a utility function that retrieves the MercuryTypingReceiver instance of the current user. We’re going to forget about getForFBID() and just use get() .

You’ll remember that our React component called the addRetroactiveListener(eventName, listener) method on a MercuryTypingReceiver instance. Using it is very simple:

const inst = MercuryTypingReceiver . get ( ) ; inst . addRetroactiveListener ( 'state-changed' , state => { console . log ( state ) ; } ) ;

Now, if you did receive a typing status notification while you were playing in the console, you might already see some state objects get printed out. Otherwise, a simple way to test this is to write to yourself! You can use the Messenger app on your phone to send out the typing events.

On my way to insanity.

Alright! This corroborates what we asserted before: our MercuryTypingReceiver store’s state is just an dictionary that maps a thread id to the ids of all the users currently typing in that thread.

This information is what we’re looking for, but without a way to link a thread id to the thread’s name or a user id to the user’s full name, it really doesn’t tell us much.

MercuryThreads and ShortProfiles

A little more snooping around the code reveals two very useful modules:

MercuryThreads lets use retrieve all information about a Messenger thread from its id.

lets use retrieve all information about a Messenger thread from its id. ShortProfiles does the same, but with user profiles.

We can even batch those in order to retrieve information about multiple threads and users at the same time!

I won’t go into further details regarding the API of either of those, as I think the code below is rather self-explanatory.

Finally, the Code

All 40 lines of it.

Wrapping Up

I think the biggest biggest takeaway of this blog post is how easy it is to hook into the code of a well-structured modern web application. The combination of Javascript modules, React and Flux allows us to inject our own logic into both the UI and the data flow of an app.

You’ll find the entire source code of the app on Github. June 9: removed from Github in compliance with a Cease and Desist.

That’s it! Hope you’ve enjoyed the read. If you have any questions, you can ping me on twitter @alexkirsz.