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index.js
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/**
* Create, import, and export vapory keys.
* @author Jack Peterson (jack@tinybike.net)
*/
"use strict";
var path = require("path");
var fs = require("fs");
var crypto = require("crypto");
var sjcl = require("sjcl");
var uuid = require("uuid");
var secp256k1 = require("secp256k1/elliptic");
var createKeccakHash = require("keccak/js");
var scrypt = require("./lib/scrypt");
function isFunction(f) {
return typeof f === "function";
}
function keccak256(buffer) {
return createKeccakHash("keccak256").update(buffer).digest();
}
module.exports = {
version: "1.0.2",
browser: typeof process === "undefined" || !process.nextTick || Boolean(process.browser),
crypto: crypto,
constants: {
// Suppress logging
quiet: false,
// Symmetric cipher for private key encryption
cipher: "aes-128-ctr",
// Initialization vector size in bytes
ivBytes: 16,
// ECDSA private key size in bytes
keyBytes: 32,
// Key derivation function parameters
pbkdf2: {
c: 262144,
dklen: 32,
hash: "sha256",
prf: "hmac-sha256"
},
scrypt: {
memory: 280000000,
dklen: 32,
n: 262144,
r: 1,
p: 8
}
},
/**
* Check whether a string is valid hex.
* @param {string} str String to validate.
* @return {boolean} True if the string is valid hex, false otherwise.
*/
isHex: function (str) {
if (str.length % 2 === 0 && str.match(/^[0-9a-f]+$/i)) return true;
return false;
},
/**
* Check whether a string is valid base-64.
* @param {string} str String to validate.
* @return {boolean} True if the string is valid base-64, false otherwise.
*/
isBase64: function (str) {
var index;
if (str.length % 4 > 0 || str.match(/[^0-9a-z+\/=]/i)) return false;
index = str.indexOf("=");
if (index === -1 || str.slice(index).match(/={1,2}/)) return true;
return false;
},
/**
* Convert a string to a Buffer. If encoding is not specified, hex-encoding
* will be used if the input is valid hex. If the input is valid base64 but
* not valid hex, base64 will be used. Otherwise, utf8 will be used.
* @param {string} str String to be converted.
* @param {string=} enc Encoding of the input string (optional).
* @return {buffer} Buffer (bytearray) containing the input data.
*/
str2buf: function (str, enc) {
if (!str || str.constructor !== String) return str;
if (!enc && this.isHex(str)) enc = "hex";
if (!enc && this.isBase64(str)) enc = "base64";
return Buffer.from(str, enc);
},
/**
* Check if the selected cipher is available.
* @param {string} algo Encryption algorithm.
* @return {boolean} If available true, otherwise false.
*/
isCipherAvailable: function (cipher) {
return crypto.getCiphers().some(function (name) { return name === cipher; });
},
/**
* Symmetric private key encryption using secret (derived) key.
* @param {buffer|string} plaintext Data to be encrypted.
* @param {buffer|string} key Secret key.
* @param {buffer|string} iv Initialization vector.
* @param {string=} algo Encryption algorithm (default: constants.cipher).
* @return {buffer} Encrypted data.
*/
encrypt: function (plaintext, key, iv, algo) {
var cipher, ciphertext;
algo = algo || this.constants.cipher;
if (!this.isCipherAvailable(algo)) throw new Error(algo + " is not available");
cipher = crypto.createCipheriv(algo, this.str2buf(key), this.str2buf(iv));
ciphertext = cipher.update(this.str2buf(plaintext));
return Buffer.concat([ciphertext, cipher.final()]);
},
/**
* Symmetric private key decryption using secret (derived) key.
* @param {buffer|string} ciphertext Data to be decrypted.
* @param {buffer|string} key Secret key.
* @param {buffer|string} iv Initialization vector.
* @param {string=} algo Encryption algorithm (default: constants.cipher).
* @return {buffer} Decrypted data.
*/
decrypt: function (ciphertext, key, iv, algo) {
var decipher, plaintext;
algo = algo || this.constants.cipher;
if (!this.isCipherAvailable(algo)) throw new Error(algo + " is not available");
decipher = crypto.createDecipheriv(algo, this.str2buf(key), this.str2buf(iv));
plaintext = decipher.update(this.str2buf(ciphertext));
return Buffer.concat([plaintext, decipher.final()]);
},
/**
* Derive Vapory address from private key.
* @param {buffer|string} privateKey ECDSA private key.
* @return {string} Hex-encoded Vapory address.
*/
privateKeyToAddress: function (privateKey) {
var privateKeyBuffer, publicKey;
privateKeyBuffer = this.str2buf(privateKey);
if (privateKeyBuffer.length < 32) {
privateKeyBuffer = Buffer.concat([
Buffer.alloc(32 - privateKeyBuffer.length, 0),
privateKeyBuffer
]);
}
publicKey = secp256k1.publicKeyCreate(privateKeyBuffer, false).slice(1);
return "0x" + keccak256(publicKey).slice(-20).toString("hex");
},
/**
* Calculate message authentication code from secret (derived) key and
* encrypted text. The MAC is the keccak-256 hash of the byte array
* formed by concatenating the second 16 bytes of the derived key with
* the ciphertext key's contents.
* @param {buffer|string} derivedKey Secret key derived from password.
* @param {buffer|string} ciphertext Text encrypted with secret key.
* @return {string} Hex-encoded MAC.
*/
getMAC: function (derivedKey, ciphertext) {
if (derivedKey !== undefined && derivedKey !== null && ciphertext !== undefined && ciphertext !== null) {
return keccak256(Buffer.concat([
this.str2buf(derivedKey).slice(16, 32),
this.str2buf(ciphertext)
])).toString("hex");
}
},
/**
* Derive secret key from password with key dervation function.
* @param {string|buffer} password User-supplied password.
* @param {string|buffer} salt Randomly generated salt.
* @param {Object=} options Encryption parameters.
* @param {string=} options.kdf Key derivation function (default: pbkdf2).
* @param {string=} options.cipher Symmetric cipher (default: constants.cipher).
* @param {Object=} options.kdfparams KDF parameters (default: constants.<kdf>).
* @param {function=} cb Callback function (optional).
* @return {buffer} Secret key derived from password.
*/
deriveKey: function (password, salt, options, cb) {
var prf, self = this;
if (typeof password === "undefined" || password === null || !salt) {
throw new Error("Must provide password and salt to derive a key");
}
options = options || {};
options.kdfparams = options.kdfparams || {};
// convert strings to buffers
password = this.str2buf(password, "utf8");
salt = this.str2buf(salt);
// use scrypt as key derivation function
if (options.kdf === "scrypt") {
if (isFunction(scrypt)) {
scrypt = scrypt(options.kdfparams.memory || self.constants.scrypt.memory);
}
if (isFunction(cb)) {
setTimeout(function () {
cb(Buffer.from(scrypt.to_hex(scrypt.crypto_scrypt(
password,
salt,
options.kdfparams.n || self.constants.scrypt.n,
options.kdfparams.r || self.constants.scrypt.r,
options.kdfparams.p || self.constants.scrypt.p,
options.kdfparams.dklen || self.constants.scrypt.dklen
)), "hex"));
}, 0);
} else {
return Buffer.from(scrypt.to_hex(scrypt.crypto_scrypt(
password,
salt,
options.kdfparams.n || this.constants.scrypt.n,
options.kdfparams.r || this.constants.scrypt.r,
options.kdfparams.p || this.constants.scrypt.p,
options.kdfparams.dklen || this.constants.scrypt.dklen
)), "hex");
}
// use default key derivation function (PBKDF2)
} else {
prf = options.kdfparams.prf || this.constants.pbkdf2.prf;
if (prf === "hmac-sha256") prf = "sha256";
if (!isFunction(cb)) {
if (!this.crypto.pbkdf2Sync) {
return Buffer.from(sjcl.codec.hex.fromBits(sjcl.misc.pbkdf2(
password.toString("utf8"),
sjcl.codec.hex.toBits(salt.toString("hex")),
options.kdfparams.c || self.constants.pbkdf2.c,
(options.kdfparams.dklen || self.constants.pbkdf2.dklen)*8
)), "hex");
}
return crypto.pbkdf2Sync(
password,
salt,
options.kdfparams.c || this.constants.pbkdf2.c,
options.kdfparams.dklen || this.constants.pbkdf2.dklen,
prf
);
}
if (!this.crypto.pbkdf2) {
setTimeout(function () {
cb(Buffer.from(sjcl.codec.hex.fromBits(sjcl.misc.pbkdf2(
password.toString("utf8"),
sjcl.codec.hex.toBits(salt.toString("hex")),
options.kdfparams.c || self.constants.pbkdf2.c,
(options.kdfparams.dklen || self.constants.pbkdf2.dklen)*8
)), "hex"));
}, 0);
} else {
crypto.pbkdf2(
password,
salt,
options.kdfparams.c || this.constants.pbkdf2.c,
options.kdfparams.dklen || this.constants.pbkdf2.dklen,
prf,
function (ex, derivedKey) {
if (ex) return cb(ex);
cb(derivedKey);
}
);
}
}
},
/**
* Generate random numbers for private key, initialization vector,
* and salt (for key derivation).
* @param {Object=} params Encryption options (defaults: constants).
* @param {string=} params.keyBytes Private key size in bytes.
* @param {string=} params.ivBytes Initialization vector size in bytes.
* @param {function=} cb Callback function (optional).
* @return {Object<string,buffer>} Private key, IV and salt.
*/
create: function (params, cb) {
var keyBytes, ivBytes, self = this;
params = params || {};
keyBytes = params.keyBytes || this.constants.keyBytes;
ivBytes = params.ivBytes || this.constants.ivBytes;
function checkBoundsAndCreateObject(randomBytes) {
var privateKey = randomBytes.slice(0, keyBytes);
if (!secp256k1.privateKeyVerify(privateKey)) return self.create(params, cb);
return {
privateKey: privateKey,
iv: randomBytes.slice(keyBytes, keyBytes + ivBytes),
salt: randomBytes.slice(keyBytes + ivBytes)
};
}
// synchronous key generation if callback not provided
if (!isFunction(cb)) {
return checkBoundsAndCreateObject(crypto.randomBytes(keyBytes + ivBytes + keyBytes));
}
// asynchronous key generation
crypto.randomBytes(keyBytes + ivBytes + keyBytes, function (err, randomBytes) {
if (err) return cb(err);
cb(checkBoundsAndCreateObject(randomBytes));
});
},
/**
* Assemble key data object in secret-storage format.
* @param {buffer} derivedKey Password-derived secret key.
* @param {buffer} privateKey Private key.
* @param {buffer} salt Randomly generated salt.
* @param {buffer} iv Initialization vector.
* @param {Object=} options Encryption parameters.
* @param {string=} options.kdf Key derivation function (default: pbkdf2).
* @param {string=} options.cipher Symmetric cipher (default: constants.cipher).
* @param {Object=} options.kdfparams KDF parameters (default: constants.<kdf>).
* @return {Object}
*/
marshal: function (derivedKey, privateKey, salt, iv, options) {
var ciphertext, keyObject, algo;
options = options || {};
options.kdfparams = options.kdfparams || {};
algo = options.cipher || this.constants.cipher;
// encrypt using first 16 bytes of derived key
ciphertext = this.encrypt(privateKey, derivedKey.slice(0, 16), iv, algo).toString("hex");
keyObject = {
address: this.privateKeyToAddress(privateKey).slice(2),
crypto: {
cipher: options.cipher || this.constants.cipher,
ciphertext: ciphertext,
cipherparams: { iv: iv.toString("hex") },
mac: this.getMAC(derivedKey, ciphertext)
},
id: uuid.v4(), // random 128-bit UUID
version: 3
};
if (options.kdf === "scrypt") {
keyObject.crypto.kdf = "scrypt";
keyObject.crypto.kdfparams = {
dklen: options.kdfparams.dklen || this.constants.scrypt.dklen,
n: options.kdfparams.n || this.constants.scrypt.n,
r: options.kdfparams.r || this.constants.scrypt.r,
p: options.kdfparams.p || this.constants.scrypt.p,
salt: salt.toString("hex")
};
} else {
keyObject.crypto.kdf = "pbkdf2";
keyObject.crypto.kdfparams = {
c: options.kdfparams.c || this.constants.pbkdf2.c,
dklen: options.kdfparams.dklen || this.constants.pbkdf2.dklen,
prf: options.kdfparams.prf || this.constants.pbkdf2.prf,
salt: salt.toString("hex")
};
}
return keyObject;
},
/**
* Export private key to keystore secret-storage format.
* @param {string|buffer} password User-supplied password.
* @param {string|buffer} privateKey Private key.
* @param {string|buffer} salt Randomly generated salt.
* @param {string|buffer} iv Initialization vector.
* @param {Object=} options Encryption parameters.
* @param {string=} options.kdf Key derivation function (default: pbkdf2).
* @param {string=} options.cipher Symmetric cipher (default: constants.cipher).
* @param {Object=} options.kdfparams KDF parameters (default: constants.<kdf>).
* @param {function=} cb Callback function (optional).
* @return {Object}
*/
dump: function (password, privateKey, salt, iv, options, cb) {
options = options || {};
iv = this.str2buf(iv);
privateKey = this.str2buf(privateKey);
// synchronous if no callback provided
if (!isFunction(cb)) {
return this.marshal(this.deriveKey(password, salt, options), privateKey, salt, iv, options);
}
// asynchronous if callback provided
this.deriveKey(password, salt, options, function (derivedKey) {
cb(this.marshal(derivedKey, privateKey, salt, iv, options));
}.bind(this));
},
/**
* Recover plaintext private key from secret-storage key object.
* @param {Object} keyObject Keystore object.
* @param {function=} cb Callback function (optional).
* @return {buffer} Plaintext private key.
*/
recover: function (password, keyObject, cb) {
var keyObjectCrypto, iv, salt, ciphertext, algo, self = this;
keyObjectCrypto = keyObject.Crypto || keyObject.crypto;
// verify that message authentication codes match, then decrypt
function verifyAndDecrypt(derivedKey, salt, iv, ciphertext, algo) {
var key;
if (self.getMAC(derivedKey, ciphertext) !== keyObjectCrypto.mac) {
throw new Error("message authentication code mismatch");
}
if (keyObject.version === "1") {
key = keccak256(derivedKey.slice(0, 16)).slice(0, 16);
} else {
key = derivedKey.slice(0, 16);
}
return self.decrypt(ciphertext, key, iv, algo);
}
iv = this.str2buf(keyObjectCrypto.cipherparams.iv);
salt = this.str2buf(keyObjectCrypto.kdfparams.salt);
ciphertext = this.str2buf(keyObjectCrypto.ciphertext);
algo = keyObjectCrypto.cipher;
if (keyObjectCrypto.kdf === "pbkdf2" && keyObjectCrypto.kdfparams.prf !== "hmac-sha256") {
throw new Error("PBKDF2 only supported with HMAC-SHA256");
}
// derive secret key from password
if (!isFunction(cb)) {
return verifyAndDecrypt(this.deriveKey(password, salt, keyObjectCrypto), salt, iv, ciphertext, algo);
}
this.deriveKey(password, salt, keyObjectCrypto, function (derivedKey) {
cb(verifyAndDecrypt(derivedKey, salt, iv, ciphertext, algo));
});
},
/**
* Generate filename for a keystore file.
* @param {string} address Vapory address.
* @return {string} Keystore filename.
*/
generateKeystoreFilename: function (address) {
var filename = "UTC--" + new Date().toISOString() + "--" + address;
// Windows does not permit ":" in filenames, replace all with "-"
if (process.platform === "win32") filename = filename.split(":").join("-");
return filename;
},
/**
* Export formatted JSON to keystore file.
* @param {Object} keyObject Keystore object.
* @param {string=} keystore Path to keystore folder (default: "keystore").
* @param {function=} cb Callback function (optional).
* @return {string} JSON filename (Node.js) or JSON string (browser).
*/
exportToFile: function (keyObject, keystore, cb) {
var self = this;
var outfile, outpath, json;
function instructions(outpath) {
if (!self.constants.quiet) {
console.log(
"Saved to file:\n" + outpath + "\n"+
"To use with gvap, copy this file to your Vapory "+
"keystore folder (usually ~/.vapory/keystore)."
);
}
}
keystore = keystore || "keystore";
outfile = this.generateKeystoreFilename(keyObject.address);
outpath = path.join(keystore, outfile);
json = JSON.stringify(keyObject);
if (this.browser) {
if (!isFunction(cb)) return json;
return cb(json);
}
if (!isFunction(cb)) {
fs.writeFileSync(outpath, json);
instructions(outpath);
return outpath;
}
fs.writeFile(outpath, json, function (ex) {
if (ex) throw ex;
instructions(outpath);
cb(outpath);
});
},
/**
* Import key data object from keystore JSON file.
* (Note: Node.js only!)
* @param {string} address Vapory address to import.
* @param {string=} datadir Vapory data directory (default: ~/.vapory).
* @param {function=} cb Callback function (optional).
* @return {Object} Keystore data file's contents.
*/
importFromFile: function (address, datadir, cb) {
var keystore, filepath;
address = address.replace("0x", "");
address = address.toLowerCase();
function findKeyfile(keystore, address, files) {
var i, len, filepath = null;
for (i = 0, len = files.length; i < len; ++i) {
if (files[i].indexOf(address) > -1) {
filepath = path.join(keystore, files[i]);
if (fs.lstatSync(filepath).isDirectory()) {
filepath = path.join(filepath, files[i]);
}
break;
}
}
return filepath;
}
if (this.browser) throw new Error("method only available in Node.js");
datadir = datadir || path.join(process.env.HOME, ".vapory");
keystore = path.join(datadir, "keystore");
if (!isFunction(cb)) {
filepath = findKeyfile(keystore, address, fs.readdirSync(keystore));
if (!filepath) {
throw new Error("could not find key file for address " + address);
}
return JSON.parse(fs.readFileSync(filepath));
}
fs.readdir(keystore, function (ex, files) {
var filepath;
if (ex) return cb(ex);
filepath = findKeyfile(keystore, address, files);
if (!filepath) {
return new Error("could not find key file for address " + address);
}
return cb(JSON.parse(fs.readFileSync(filepath)));
});
}
};