MetaMask has been under continuous development for nearly two years now, and we’ve gradually discovered some very useful abstractions, that have allowed us to grow more easily. A couple of those layers together allow MetaMask to be ported to new environments and contexts increasingly easily.
The core functionality of MetaMask all lives in what we call The MetaMask Controller. Our goal for this file is for it to eventually be its own javascript module that can be imported into any JS-compatible context, allowing it to fully manage an app's relationship to Ethereum.
When calling new MetaMask(opts)
, many platform-specific options are configured. The keys on opts
are as follows:
- initState: The last emitted state, used for restoring persistent state between sessions.
- platform: The
platform
object defines a variety of platform-specific functions, including opening the confirmation view, and opening web sites. - encryptor - An object that provides access to the desired encryption methods.
An object that provides two simple methods, which can encrypt in any format you prefer. This parameter is optional, and will default to the browser-native WebCrypto API.
- encrypt(password, object) - returns a Promise of a string that is ready for storage.
- decrypt(password, encryptedString) - Accepts the encrypted output of
encrypt
and returns a Promise of a restoredobject
as it was encrypted.
The platform
object has a variety of options:
- reload (function) - Will be called when MetaMask would like to reload its own context.
- openWindow ({ url }) - Will be called when MetaMask would like to open a web page. It will be passed a single
options
object with aurl
key, with a string value. - getVersion() - Should return the current MetaMask version, as described in the current
CHANGELOG.md
orapp/manifest.json
.
This method returns a javascript object representing the current MetaMask state. This includes things like known accounts, sent transactions, current exchange rates, and more! The controller is also an event emitter, so you can subscribe to state updates via metamask.on('update', handleStateUpdate)
. State examples available here under the metamask
key. (Warning: some are outdated)
Returns a JavaScript object filled with callback functions representing every operation our user interface ever performs. Everything from creating new accounts, changing the current network, to sending a transaction, is provided via these API methods. We export this external API on an object because it allows us to easily expose this API over a port using dnode, which is how our WebExtension's UI works!
The MetaMask UI is essentially just a website that can be configured by passing it the API and state subscriptions from above. Anyone could make a UI that consumes these, effectively reskinning MetaMask.
You can see this in action in our file ui/index.js. There you can see an argument being passed in named accountManager
, which is essentially a MetaMask controller (forgive its really outdated parameter name!). With access to that object, the UI is able to initialize a whole React/Redux app that relies on this API for its account/blockchain-related/persistent states.
As an example, a WebExtension is always defined by a manifest.json
file. In ours, you can see that background.js is defined as a script to run in the background, and this is the file that we use to initialize the MetaMask controller.
In that file, there's a lot going on, so it's maybe worth focusing on our MetaMask controller constructor to start. It looks something like this:
const controller = new MetamaskController({
// User confirmation callbacks:
showUnconfirmedMessage: triggerUi,
unlockAccountMessage: triggerUi,
showUnapprovedTx: triggerUi,
// initial state
initState,
// platform specific api
platform,
})
Since background.js
is essentially the Extension setup file, we can see it doing all the things specific to the extension platform:
- Defining how to open the UI for new messages, transactions, and even requests to unlock (reveal to the site) their account.
- Provide the instance's initial state, leaving MetaMask persistence to the platform.
- Providing a
platform
object. This is becoming our catch-all adapter for platforms to define a few other platform-variant features we require, like opening a web link. (Soon we will be moving encryption out here too, since our browser-encryption isn't portable enough!)
Everything so far has been enough to create a MetaMask wallet on virtually any platform that runs JS, but MetaMask's most unique feature isn't being a wallet, it's providing an Ethereum-enabled JavaScript context to websites.
MetaMask has two kinds of duplex stream APIs that it exposes:
- metamask.setupTrustedCommunication(connectionStream, originDomain) - This stream is used to connect the user interface over a remote port, and may not be necessary for contexts where the interface and the metamask-controller share a process.
- metamask.setupUntrustedCommunication(connectionStream, originDomain) - This method is used to connect a new web site's web3 API to MetaMask's blockchain connection. Additionally, the
originDomain
is used to block detected phishing sites.
If you are making a MetaMask-powered browser for a new platform, one of the trickiest tasks will be injecting the Web3 API into websites that are visited. On WebExtensions, we actually have to pipe data through a total of three JS contexts just to let sites talk to our background process (site -> contentscript -> background).
To make this as easy as possible, we use one of our favorite internal tools, web3-provider-engine to construct a custom web3 provider object whose source of truth is a stream that we connect to remotely.
To see how we do that, you can refer to the inpage script that we inject into every website. There you can see it creates a multiplex stream to the background, and uses it to initialize what we call the inpage-provider, which you can see stubs a few methods out, but mostly just passes calls to sendAsync
through the stream it's passed! That's really all the magic that's needed to create a web3-like API in a remote context, once you have a stream to MetaMask available.
In inpage.js
you can see we create a PortStream
, that's just a class we use to wrap WebExtension ports as streams, so we can reuse our favorite stream abstraction over the more irregular API surface of the WebExtension. In a new platform, you will probably need to construct this stream differently. The key is that you need to construct a stream that talks from the site context to the background. Once you have that set up, it works like magic!
If streams seem new and confusing to you, that's ok, they can seem strange at first. To help learn them, we highly recommend reading Substack's Stream Handbook, or going through NodeSchool's interactive command-line class Stream Adventure, also maintained by Substack.
I hope this has been helpful to you! If you have any other questionsm, or points you think need clarification in this guide, please open an issue on our GitHub!