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browser.js
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browser.js
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"use strict";
var EC = require("elliptic").ec;
var ec = new EC("secp256k1");
var browserCrypto = global.crypto || global.msCrypto || {};
var subtle = browserCrypto.subtle || browserCrypto.webkitSubtle;
var nodeCrypto = require('crypto');
const EC_GROUP_ORDER = Buffer.from('fffffffffffffffffffffffffffffffebaaedce6af48a03bbfd25e8cd0364141', 'hex');
const ZERO32 = Buffer.alloc(32, 0);
function assert(condition, message) {
if (!condition) {
throw new Error(message || "Assertion failed");
}
}
function isScalar (x) {
return Buffer.isBuffer(x) && x.length === 32;
}
function isValidPrivateKey(privateKey) {
if (!isScalar(privateKey))
{
return false;
}
return privateKey.compare(ZERO32) > 0 && // > 0
privateKey.compare(EC_GROUP_ORDER) < 0; // < G
}
// Compare two buffers in constant time to prevent timing attacks.
function equalConstTime(b1, b2) {
if (b1.length !== b2.length) {
return false;
}
var res = 0;
for (var i = 0; i < b1.length; i++) {
res |= b1[i] ^ b2[i]; // jshint ignore:line
}
return res === 0;
}
/* This must check if we're in the browser or
not, since the functions are different and does
not convert using browserify */
function randomBytes(size) {
var arr = new Uint8Array(size);
if (typeof browserCrypto.getRandomValues === 'undefined') {
return Buffer.from(nodeCrypto.randomBytes(size));
} else {
browserCrypto.getRandomValues(arr);
}
return Buffer.from(arr);
}
function sha512(msg) {
return new Promise(function(resolve) {
var hash = nodeCrypto.createHash('sha512');
var result = hash.update(msg).digest();
resolve(new Uint8Array(result));
});
}
function getAes(op) {
return function(iv, key, data) {
return new Promise(function(resolve) {
if (subtle) {
var importAlgorithm = {name: "AES-CBC"};
var keyp = subtle.importKey("raw", key, importAlgorithm, false, [op]);
return keyp.then(function(cryptoKey) {
var encAlgorithm = {name: "AES-CBC", iv: iv};
return subtle[op](encAlgorithm, cryptoKey, data);
}).then(function(result) {
resolve(Buffer.from(new Uint8Array(result)));
});
} else {
if (op === 'encrypt') {
var cipher = nodeCrypto.createCipheriv('aes-256-cbc', key, iv);
let firstChunk = cipher.update(data);
let secondChunk = cipher.final();
resolve(Buffer.concat([firstChunk, secondChunk]));
}
else if (op === 'decrypt') {
var decipher = nodeCrypto.createDecipheriv('aes-256-cbc', key, iv);
let firstChunk = decipher.update(data);
let secondChunk = decipher.final();
resolve(Buffer.concat([firstChunk, secondChunk]));
}
}
});
};
}
var aesCbcEncrypt = getAes("encrypt");
var aesCbcDecrypt = getAes("decrypt");
function hmacSha256Sign(key, msg) {
return new Promise(function(resolve) {
var hmac = nodeCrypto.createHmac('sha256', Buffer.from(key));
hmac.update(msg);
var result = hmac.digest();
resolve(result);
});
}
function hmacSha256Verify(key, msg, sig) {
return new Promise(function(resolve) {
var hmac = nodeCrypto.createHmac('sha256', Buffer.from(key));
hmac.update(msg);
var expectedSig = hmac.digest();
resolve(equalConstTime(expectedSig, sig));
});
}
/**
* Generate a new valid private key. Will use the window.crypto or window.msCrypto as source
* depending on your browser.
* @return {Buffer} A 32-byte private key.
* @function
*/
exports.generatePrivate = function () {
var privateKey = randomBytes(32);
while (!isValidPrivateKey(privateKey)) {
privateKey = randomBytes(32);
}
return privateKey;
};
var getPublic = exports.getPublic = function(privateKey) {
// This function has sync API so we throw an error immediately.
assert(privateKey.length === 32, "Bad private key");
assert(isValidPrivateKey(privateKey), "Bad private key");
// XXX(Kagami): `elliptic.utils.encode` returns array for every
// encoding except `hex`.
return Buffer.from(ec.keyFromPrivate(privateKey).getPublic("arr"));
};
/**
* Get compressed version of public key.
*/
var getPublicCompressed = exports.getPublicCompressed = function(privateKey) { // jshint ignore:line
assert(privateKey.length === 32, "Bad private key");
assert(isValidPrivateKey(privateKey), "Bad private key");
// See https://github.com/wanderer/secp256k1-node/issues/46
let compressed = true;
return Buffer.from(ec.keyFromPrivate(privateKey).getPublic(compressed, "arr"));
};
// NOTE(Kagami): We don't use promise shim in Browser implementation
// because it's supported natively in new browsers (see
// <http://caniuse.com/#feat=promises>) and we can use only new browsers
// because of the WebCryptoAPI (see
// <http://caniuse.com/#feat=cryptography>).
exports.sign = function(privateKey, msg) {
return new Promise(function(resolve) {
assert(privateKey.length === 32, "Bad private key");
assert(isValidPrivateKey(privateKey), "Bad private key");
assert(msg.length > 0, "Message should not be empty");
assert(msg.length <= 32, "Message is too long");
resolve(Buffer.from(ec.sign(msg, privateKey, {canonical: true}).toDER()));
});
};
exports.verify = function(publicKey, msg, sig) {
return new Promise(function(resolve, reject) {
assert(publicKey.length === 65 || publicKey.length === 33, "Bad public key");
if (publicKey.length === 65)
{
assert(publicKey[0] === 4, "Bad public key");
}
if (publicKey.length === 33)
{
assert(publicKey[0] === 2 || publicKey[0] === 3, "Bad public key");
}
assert(msg.length > 0, "Message should not be empty");
assert(msg.length <= 32, "Message is too long");
if (ec.verify(msg, sig, publicKey)) {
resolve(null);
} else {
reject(new Error("Bad signature"));
}
});
};
var derive = exports.derive = function(privateKeyA, publicKeyB) {
return new Promise(function(resolve) {
assert(Buffer.isBuffer(privateKeyA), "Bad private key");
assert(Buffer.isBuffer(publicKeyB), "Bad public key");
assert(privateKeyA.length === 32, "Bad private key");
assert(isValidPrivateKey(privateKeyA), "Bad private key");
assert(publicKeyB.length === 65 || publicKeyB.length === 33, "Bad public key");
if (publicKeyB.length === 65)
{
assert(publicKeyB[0] === 4, "Bad public key");
}
if (publicKeyB.length === 33)
{
assert(publicKeyB[0] === 2 || publicKeyB[0] === 3, "Bad public key");
}
var keyA = ec.keyFromPrivate(privateKeyA);
var keyB = ec.keyFromPublic(publicKeyB);
var Px = keyA.derive(keyB.getPublic()); // BN instance
resolve(Buffer.from(Px.toArray()));
});
};
exports.encrypt = function(publicKeyTo, msg, opts) {
opts = opts || {};
// Tmp variables to save context from flat promises;
var iv, ephemPublicKey, ciphertext, macKey;
return new Promise(function(resolve) {
var ephemPrivateKey = opts.ephemPrivateKey || randomBytes(32);
// There is a very unlikely possibility that it is not a valid key
while(!isValidPrivateKey(ephemPrivateKey))
{
ephemPrivateKey = opts.ephemPrivateKey || randomBytes(32);
}
ephemPublicKey = getPublic(ephemPrivateKey);
resolve(derive(ephemPrivateKey, publicKeyTo));
}).then(function(Px) {
return sha512(Px);
}).then(function(hash) {
iv = opts.iv || randomBytes(16);
var encryptionKey = hash.slice(0, 32);
macKey = hash.slice(32);
return aesCbcEncrypt(iv, encryptionKey, msg);
}).then(function(data) {
ciphertext = data;
var dataToMac = Buffer.concat([iv, ephemPublicKey, ciphertext]);
return hmacSha256Sign(macKey, dataToMac);
}).then(function(mac) {
return {
iv: iv,
ephemPublicKey: ephemPublicKey,
ciphertext: ciphertext,
mac: mac,
};
});
};
exports.decrypt = function(privateKey, opts) {
// Tmp variable to save context from flat promises;
var encryptionKey;
return derive(privateKey, opts.ephemPublicKey).then(function(Px) {
return sha512(Px);
}).then(function(hash) {
encryptionKey = hash.slice(0, 32);
var macKey = hash.slice(32);
var dataToMac = Buffer.concat([
opts.iv,
opts.ephemPublicKey,
opts.ciphertext
]);
return hmacSha256Verify(macKey, dataToMac, opts.mac);
}).then(function(macGood) {
assert(macGood, "Bad MAC");
return aesCbcDecrypt(opts.iv, encryptionKey, opts.ciphertext);
}).then(function(msg) {
return Buffer.from(new Uint8Array(msg));
});
};