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var aes = require('browserify-aes')
var assert = require('assert')
var Buffer = require('safe-buffer').Buffer
var bs58check = require('bs58check')
var createHash = require('create-hash')
var scrypt = require('scryptsy')
var xor = require('buffer-xor/inplace')
var ecurve = require('ecurve')
var curve = ecurve.getCurveByName('secp256k1')
var BigInteger = require('bigi')
// constants
var SCRYPT_PARAMS = {
N: 16384, // specified by BIP38
r: 8,
p: 8
}
var NULL = Buffer.alloc(0)
function hash160 (buffer) {
var hash
try {
hash = createHash('rmd160')
} catch (e) {
hash = createHash('ripemd160')
}
return hash.update(
createHash('sha256').update(buffer).digest()
).digest()
}
function hash256 (buffer) {
return createHash('sha256').update(
createHash('sha256').update(buffer).digest()
).digest()
}
function getAddress (d, compressed) {
var Q = curve.G.multiply(d).getEncoded(compressed)
var hash = hash160(Q)
var payload = Buffer.allocUnsafe(21)
payload.writeUInt8(0x00, 0) // XXX TODO FIXME bitcoin only??? damn you BIP38
hash.copy(payload, 1)
return bs58check.encode(payload)
}
function encryptRaw (buffer, compressed, passphrase, progressCallback, scryptParams) {
if (buffer.length !== 32) throw new Error('Invalid private key length')
scryptParams = scryptParams || SCRYPT_PARAMS
var d = BigInteger.fromBuffer(buffer)
var address = getAddress(d, compressed)
var secret = Buffer.from(passphrase, 'utf8')
var salt = hash256(address).slice(0, 4)
var N = scryptParams.N
var r = scryptParams.r
var p = scryptParams.p
var scryptBuf = scrypt(secret, salt, N, r, p, 64, progressCallback)
var derivedHalf1 = scryptBuf.slice(0, 32)
var derivedHalf2 = scryptBuf.slice(32, 64)
var xorBuf = xor(derivedHalf1, buffer)
var cipher = aes.createCipheriv('aes-256-ecb', derivedHalf2, NULL)
cipher.setAutoPadding(false)
cipher.end(xorBuf)
var cipherText = cipher.read()
// 0x01 | 0x42 | flagByte | salt (4) | cipherText (32)
var result = Buffer.allocUnsafe(7 + 32)
result.writeUInt8(0x01, 0)
result.writeUInt8(0x42, 1)
result.writeUInt8(compressed ? 0xe0 : 0xc0, 2)
salt.copy(result, 3)
cipherText.copy(result, 7)
return result
}
function encrypt (buffer, compressed, passphrase, progressCallback, scryptParams) {
return bs58check.encode(encryptRaw(buffer, compressed, passphrase, progressCallback, scryptParams))
}
// some of the techniques borrowed from: https://github.com/pointbiz/bitaddress.org
function decryptRaw (buffer, passphrase, progressCallback, scryptParams) {
// 39 bytes: 2 bytes prefix, 37 bytes payload
if (buffer.length !== 39) throw new Error('Invalid BIP38 data length')
if (buffer.readUInt8(0) !== 0x01) throw new Error('Invalid BIP38 prefix')
scryptParams = scryptParams || SCRYPT_PARAMS
// check if BIP38 EC multiply
var type = buffer.readUInt8(1)
if (type === 0x43) return decryptECMult(buffer, passphrase, progressCallback, scryptParams)
if (type !== 0x42) throw new Error('Invalid BIP38 type')
passphrase = Buffer.from(passphrase, 'utf8')
var flagByte = buffer.readUInt8(2)
var compressed = flagByte === 0xe0
if (!compressed && flagByte !== 0xc0) throw new Error('Invalid BIP38 compression flag')
var N = scryptParams.N
var r = scryptParams.r
var p = scryptParams.p
var salt = buffer.slice(3, 7)
var scryptBuf = scrypt(passphrase, salt, N, r, p, 64, progressCallback)
var derivedHalf1 = scryptBuf.slice(0, 32)
var derivedHalf2 = scryptBuf.slice(32, 64)
var privKeyBuf = buffer.slice(7, 7 + 32)
var decipher = aes.createDecipheriv('aes-256-ecb', derivedHalf2, NULL)
decipher.setAutoPadding(false)
decipher.end(privKeyBuf)
var plainText = decipher.read()
var privateKey = xor(derivedHalf1, plainText)
// verify salt matches address
var d = BigInteger.fromBuffer(privateKey)
var address = getAddress(d, compressed)
var checksum = hash256(address).slice(0, 4)
assert.deepStrictEqual(salt, checksum)
return {
privateKey: privateKey,
compressed: compressed
}
}
function decrypt (string, passphrase, progressCallback, scryptParams) {
return decryptRaw(bs58check.decode(string), passphrase, progressCallback, scryptParams)
}
function decryptECMult (buffer, passphrase, progressCallback, scryptParams) {
passphrase = Buffer.from(passphrase, 'utf8')
buffer = buffer.slice(1) // FIXME: we can avoid this
scryptParams = scryptParams || SCRYPT_PARAMS
var flag = buffer.readUInt8(1)
var compressed = (flag & 0x20) !== 0
var hasLotSeq = (flag & 0x04) !== 0
assert.strictEqual((flag & 0x24), flag, 'Invalid private key.')
var addressHash = buffer.slice(2, 6)
var ownerEntropy = buffer.slice(6, 14)
var ownerSalt
// 4 bytes ownerSalt if 4 bytes lot/sequence
if (hasLotSeq) {
ownerSalt = ownerEntropy.slice(0, 4)
// else, 8 bytes ownerSalt
} else {
ownerSalt = ownerEntropy
}
var encryptedPart1 = buffer.slice(14, 22) // First 8 bytes
var encryptedPart2 = buffer.slice(22, 38) // 16 bytes
var N = scryptParams.N
var r = scryptParams.r
var p = scryptParams.p
var preFactor = scrypt(passphrase, ownerSalt, N, r, p, 32, progressCallback)
var passFactor
if (hasLotSeq) {
var hashTarget = Buffer.concat([preFactor, ownerEntropy])
passFactor = hash256(hashTarget)
} else {
passFactor = preFactor
}
var passInt = BigInteger.fromBuffer(passFactor)
var passPoint = curve.G.multiply(passInt).getEncoded(true)
var seedBPass = scrypt(passPoint, Buffer.concat([addressHash, ownerEntropy]), 1024, 1, 1, 64)
var derivedHalf1 = seedBPass.slice(0, 32)
var derivedHalf2 = seedBPass.slice(32, 64)
var decipher = aes.createDecipheriv('aes-256-ecb', derivedHalf2, Buffer.alloc(0))
decipher.setAutoPadding(false)
decipher.end(encryptedPart2)
var decryptedPart2 = decipher.read()
var tmp = xor(decryptedPart2, derivedHalf1.slice(16, 32))
var seedBPart2 = tmp.slice(8, 16)
var decipher2 = aes.createDecipheriv('aes-256-ecb', derivedHalf2, Buffer.alloc(0))
decipher2.setAutoPadding(false)
decipher2.write(encryptedPart1) // first 8 bytes
decipher2.end(tmp.slice(0, 8)) // last 8 bytes
var seedBPart1 = xor(decipher2.read(), derivedHalf1.slice(0, 16))
var seedB = Buffer.concat([seedBPart1, seedBPart2], 24)
var factorB = BigInteger.fromBuffer(hash256(seedB))
// d = passFactor * factorB (mod n)
var d = passInt.multiply(factorB).mod(curve.n)
return {
privateKey: d.toBuffer(32),
compressed: compressed
}
}
function verify (string) {
var decoded = bs58check.decodeUnsafe(string)
if (!decoded) return false
if (decoded.length !== 39) return false
if (decoded.readUInt8(0) !== 0x01) return false
var type = decoded.readUInt8(1)
var flag = decoded.readUInt8(2)
// encrypted WIF
if (type === 0x42) {
if (flag !== 0xc0 && flag !== 0xe0) return false
// EC mult
} else if (type === 0x43) {
if ((flag & ~0x24)) return false
} else {
return false
}
return true
}
module.exports = {
decrypt: decrypt,
decryptECMult: decryptECMult,
decryptRaw: decryptRaw,
encrypt: encrypt,
encryptRaw: encryptRaw,
verify: verify
}
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