var assert = require('assert')
var crypto = require('../src/crypto')
var ecdsa = require('../src/ecdsa')
var message = require('../src/message')
var networks = require('../src/networks')
var BigInteger = require('bigi')
var ECSignature = require('../src/ecsignature')
var ecurve = require('ecurve')
var curve = ecurve.getCurveByName('secp256k1')
var fixtures = require('./fixtures/ecdsa.json')
describe('ecdsa', function() {
describe('deterministicGenerateK', function() {
fixtures.valid.forEach(function(f) {
it('determines k for \"' + f.message + '\"', function() {
var d = BigInteger.fromHex(f.d)
var h1 = crypto.sha256(f.message)
var k = ecdsa.deterministicGenerateK(curve, h1, d)
assert.equal(k.toHex(), f.k)
})
})
})
describe('recoverPubKey', function() {
fixtures.valid.forEach(function(f) {
it('recovers the pubKey for ' + f.d, function() {
var d = BigInteger.fromHex(f.d)
var Q = curve.G.multiply(d)
var signature = {
r: new BigInteger(f.signature.r),
s: new BigInteger(f.signature.s)
}
var h1 = crypto.sha256(f.message)
var e = BigInteger.fromBuffer(h1)
var Qprime = ecdsa.recoverPubKey(curve, e, signature, f.i)
assert(Qprime.equals(Q))
})
})
describe('with i ∈ {0,1,2,3}', function() {
var hash = message.magicHash('1111', networks.bitcoin)
var e = BigInteger.fromBuffer(hash)
var signatureBuffer = new Buffer('INcvXVVEFyIfHLbDX+xoxlKFn3Wzj9g0UbhObXdMq+YMKC252o5RHFr0/cKdQe1WsBLUBi4morhgZ77obDJVuV0=', 'base64')
var signature = ECSignature.parseCompact(signatureBuffer).signature
var points = [
'03e3a8c44a8bf712f1fbacee274fb19c0239b1a9e877eff0075ea335f2be8ff380',
'0279be667ef9dcbbac55a06295ce870b07029bfcdb2dce28d959f2815b16f81798',
'03d49e765f0bc27525c51a1b98fb1c99dacd59abe85a203af90f758260550b56c5',
'027eea09d46ac7fb6aa2e96f9c576677214ffdc238eb167734a9b39d1eb4c3d30d'
]
points.forEach(function(expectedHex, i) {
it('recovers an expected point for i of ' + i, function() {
var Qprime = ecdsa.recoverPubKey(curve, e, signature, i)
var QprimeHex = Qprime.getEncoded().toString('hex')
assert.equal(QprimeHex, expectedHex)
})
})
})
fixtures.invalid.recoverPubKey.forEach(function(f) {
it('throws on ' + f.description, function() {
var e = BigInteger.fromHex(f.e)
var signature = new ECSignature(new BigInteger(f.signature.r), new BigInteger(f.signature.s))
assert.throws(function() {
ecdsa.recoverPubKey(curve, e, signature, f.i)
}, new RegExp(f.exception))
})
})
})
describe('sign', function() {
fixtures.valid.forEach(function(f) {
it('produces a deterministic signature for \"' + f.message + '\"', function() {
var d = BigInteger.fromHex(f.d)
var hash = crypto.sha256(f.message)
var signature = ecdsa.sign(curve, hash, d)
assert.equal(signature.r.toString(), f.signature.r)
assert.equal(signature.s.toString(), f.signature.s)
})
})
it('should sign with low S value', function() {
var hash = crypto.sha256('Vires in numeris')
var sig = ecdsa.sign(curve, hash, BigInteger.ONE)
// See BIP62 for more information
var N_OVER_TWO = curve.n.shiftRight(1)
assert(sig.s.compareTo(N_OVER_TWO) <= 0)
})
})
describe('verifyRaw', function() {
fixtures.valid.forEach(function(f) {
it('verifies a valid signature for \"' + f.message + '\"', function() {
var d = BigInteger.fromHex(f.d)
var e = BigInteger.fromBuffer(crypto.sha256(f.message))
var signature = new ECSignature(
new BigInteger(f.signature.r),
new BigInteger(f.signature.s)
)
var Q = curve.G.multiply(d)
assert(ecdsa.verifyRaw(curve, e, signature, Q))
})
})
fixtures.invalid.verifyRaw.forEach(function(f) {
it('fails to verify with ' + f.description, function() {
var d = BigInteger.fromHex(f.d)
var e = BigInteger.fromHex(f.e)
var signature = new ECSignature(
new BigInteger(f.signature.r),
new BigInteger(f.signature.s)
)
var Q = curve.G.multiply(d)
assert.equal(ecdsa.verifyRaw(curve, e, signature, Q), false)
})
})
})
})