A ratcheting forward secrecy protocol that works in synchronous and asynchronous messaging environments.
All code in this repository is FOR RESEARCH PURPOSES ONLY!
This repository is based on WhisperSystem's own libsignal-protocol-javascript, modified to support react native. I use isomorphic-webcrypto as a drop-in replacement for WebCrypto API.
WARNING: This code has NOT been reviewed by an experienced cryptographer. IT IS FOR RESEARCH ONLY!!!!!
You can read more about the signal protocol (formerly /axolotl/ for its self-healing abilities) here.
This package is not hosted on npm yet so to try it with React Native you can use wml to add this directory to your node_modules
folder. You can then use it like:
var signal = require('signal-protocol')
The following steps will walk you through the lifecycle of the signal protocol
This protocol uses a concept called 'PreKeys'. A PreKey is an ECPublicKey and an associated unique ID which are stored together by a server. PreKeys can also be signed.
At install time, clients generate a single signed PreKey, as well as a large list of unsigned PreKeys, and transmit all of them to the server.
Please note that before running any command that involved crypto.getRandomValues
you must first call and await KeyHelper.ensureSecure
(see isomorphic-webcrypto) for more details.
var signal = require('signal-protocol')
var KeyHelper = signal.KeyHelper;
var registrationId = KeyHelper.generateRegistrationId();
// Store registrationId somewhere durable and safe.
KeyHelper.generateIdentityKeyPair().then(function(identityKeyPair) {
// keyPair -> { pubKey: ArrayBuffer, privKey: ArrayBuffer }
// Store identityKeyPair somewhere durable and safe.
});
KeyHelper.generatePreKey(keyId).then(function(preKey) {
store.storePreKey(preKey.keyId, preKey.keyPair);
});
KeyHelper.generateSignedPreKey(identityKeyPair, keyId).then(function(signedPreKey) {
store.storeSignedPreKey(signedPreKey.keyId, signedPreKey.keyPair);
});
// Register preKeys and signedPreKey with the server
Signal Protocol is session-oriented. Clients establish a "session," which is then used for all subsequent encrypt/decrypt operations. There is no need to ever tear down a session once one has been established.
Sessions are established in one of two ways:
- PreKeyBundles. A client that wishes to send a message to a recipient can establish a session by retrieving a PreKeyBundle for that recipient from the server.
- PreKeySignalMessages. A client can receive a PreKeySignalMessage from a recipient and use it to establish a session.
An established session encapsulates a lot of state between two clients. That state is maintained in durable records which need to be kept for the life of the session.
State is kept in the following places:
- Identity State. Clients will need to maintain the state of their own identity key pair, as well as identity keys received from other clients.
- PreKey State. Clients will need to maintain the state of their generated PreKeys.
- Signed PreKey States. Clients will need to maintain the state of their signed PreKeys.
- Session State. Clients will need to maintain the state of the sessions they have established.
A signal client needs to implement a storage interface that will manage
loading and storing of identity, prekeys, signed prekeys, and session state.
See test/InMemorySignalProtocolStore.js
for an example.
Once your storage interface is implemented, building a session is fairly straightforward:
var store = new MySignalProtocolStore();
var address = new signal.SignalProtocolAddress(recipientId, deviceId);
// Instantiate a SessionBuilder for a remote recipientId + deviceId tuple.
var sessionBuilder = new signal.SessionBuilder(store, address);
// Process a prekey fetched from the server. Returns a promise that resolves
// once a session is created and saved in the store, or rejects if the
// identityKey differs from a previously seen identity for this address.
var promise = sessionBuilder.processPreKey({
registrationId: <Number>,
identityKey: <ArrayBuffer>,
signedPreKey: {
keyId : <Number>,
publicKey : <ArrayBuffer>,
signature : <ArrayBuffer>
},
preKey: {
keyId : <Number>,
publicKey : <ArrayBuffer>
}
});
promise.then(function onsuccess() {
// encrypt messages
});
promise.catch(function onerror(error) {
// handle identity key conflict
});
Once you have a session established with an address, you can encrypt messages using SessionCipher.
var plaintext = "Hello world";
var sessionCipher = new signal.SessionCipher(store, address);
sessionCipher.encrypt(plaintext).then(function(ciphertext) {
// ciphertext -> { type: <Number>, body: <string> }
handle(ciphertext.type, ciphertext.body);
});
Ciphertexts come in two flavors: WhisperMessage and PreKeyWhisperMessage.
var address = new signal.SignalProtocolAddress(recipientId, deviceId);
var sessionCipher = new signal.SessionCipher(store, address);
// Decrypt a PreKeyWhisperMessage by first establishing a new session.
// Returns a promise that resolves when the message is decrypted or
// rejects if the identityKey differs from a previously seen identity for this
// address.
sessionCipher.decryptPreKeyWhisperMessage(ciphertext).then(function(plaintext) {
// handle plaintext ArrayBuffer
}).catch(function(error) {
// handle identity key conflict
});
// Decrypt a normal message using an existing session
var sessionCipher = new signal.SessionCipher(store, address);
sessionCipher.decryptWhisperMessage(ciphertext).then(function(plaintext) {
// handle plaintext ArrayBuffer
});
A number of nations restrict the use or export of cryptography. If you are potentially subject to such restrictions you should seek competent professional legal advice before attempting to develop or distribute cryptographic code.
I (elsehow) release copyright to Copyright 2015-2016 Open Whisper Systems under the GPLv3: http://www.gnu.org/licenses/gpl-3.0.html