import hashlib import binascii p = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F n = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141 # Points are tuples of X and Y coordinates and the point at infinity is # represented by the None keyword. G = (0x79BE667EF9DCBBAC55A06295CE870B07029BFCDB2DCE28D959F2815B16F81798, 0x483ADA7726A3C4655DA4FBFC0E1108A8FD17B448A68554199C47D08FFB10D4B8) # This implementation can be sped up by storing the midstate after hashing # tag_hash instead of rehashing it all the time. def tagged_hash(tag, msg): tag_hash = hashlib.sha256(tag.encode()).digest() return hashlib.sha256(tag_hash + tag_hash + msg).digest() def is_infinity(P): return P is None def x(P): return P[0] def y(P): return P[1] def point_add(P1, P2): if (P1 is None): return P2 if (P2 is None): return P1 if (x(P1) == x(P2) and y(P1) != y(P2)): return None if (P1 == P2): lam = (3 * x(P1) * x(P1) * pow(2 * y(P1), p - 2, p)) % p else: lam = ((y(P2) - y(P1)) * pow(x(P2) - x(P1), p - 2, p)) % p x3 = (lam * lam - x(P1) - x(P2)) % p return (x3, (lam * (x(P1) - x3) - y(P1)) % p) def point_mul(P, n): R = None for i in range(256): if ((n >> i) & 1): R = point_add(R, P) P = point_add(P, P) return R def bytes_from_int(x): return x.to_bytes(32, byteorder="big") def bytes_from_point(P): return bytes_from_int(x(P)) def point_from_bytes(b): x = int_from_bytes(b) y_sq = (pow(x, 3, p) + 7) % p y = pow(y_sq, (p + 1) // 4, p) if pow(y, 2, p) != y_sq: return None return [x, y] def int_from_bytes(b): return int.from_bytes(b, byteorder="big") def hash_sha256(b): return hashlib.sha256(b).digest() def is_square(x): return pow(x, (p - 1) // 2, p) == 1 def has_square_y(P): return not is_infinity(P) and is_square(y(P)) def pubkey_gen(seckey): x = int_from_bytes(seckey) if not (1 <= x <= n - 1): raise ValueError('The secret key must be an integer in the range 1..n-1.') P = point_mul(G, x) return bytes_from_point(P) def schnorr_sign(msg, seckey0): if len(msg) != 32: raise ValueError('The message must be a 32-byte array.') seckey0 = int_from_bytes(seckey0) if not (1 <= seckey0 <= n - 1): raise ValueError('The secret key must be an integer in the range 1..n-1.') P = point_mul(G, seckey0) seckey = seckey0 if has_square_y(P) else n - seckey0 k0 = int_from_bytes(tagged_hash("BIPSchnorrDerive", bytes_from_int(seckey) + msg)) % n if k0 == 0: raise RuntimeError('Failure. This happens only with negligible probability.') R = point_mul(G, k0) k = n - k0 if not has_square_y(R) else k0 e = int_from_bytes(tagged_hash("BIPSchnorr", bytes_from_point(R) + bytes_from_point(P) + msg)) % n return bytes_from_point(R) + bytes_from_int((k + e * seckey) % n) def schnorr_verify(msg, pubkey, sig): if len(msg) != 32: raise ValueError('The message must be a 32-byte array.') if len(pubkey) != 32: raise ValueError('The public key must be a 32-byte array.') if len(sig) != 64: raise ValueError('The signature must be a 64-byte array.') P = point_from_bytes(pubkey) if (P is None): return False r = int_from_bytes(sig[0:32]) s = int_from_bytes(sig[32:64]) if (r >= p or s >= n): return False e = int_from_bytes(tagged_hash("BIPSchnorr", sig[0:32] + pubkey + msg)) % n R = point_add(point_mul(G, s), point_mul(P, n - e)) if R is None or not has_square_y(R) or x(R) != r: return False return True # # The following code is only used to verify the test vectors. # import csv def test_vectors(): all_passed = True with open('test-vectors.csv', newline='') as csvfile: reader = csv.reader(csvfile) reader.__next__() for row in reader: (index, seckey, pubkey, msg, sig, result, comment) = row pubkey = bytes.fromhex(pubkey) msg = bytes.fromhex(msg) sig = bytes.fromhex(sig) result = result == 'TRUE' print('\nTest vector #%-3i: ' % int(index)) if seckey != '': seckey = bytes.fromhex(seckey) pubkey_actual = pubkey_gen(seckey) if pubkey != pubkey_actual: print(' * Failed key generation.') print(' Expected key:', pubkey.hex().upper()) print(' Actual key:', pubkey_actual.hex().upper()) sig_actual = schnorr_sign(msg, seckey) if sig == sig_actual: print(' * Passed signing test.') else: print(' * Failed signing test.') print(' Expected signature:', sig.hex().upper()) print(' Actual signature:', sig_actual.hex().upper()) all_passed = False result_actual = schnorr_verify(msg, pubkey, sig) if result == result_actual: print(' * Passed verification test.') else: print(' * Failed verification test.') print(' Expected verification result:', result) print(' Actual verification result:', result_actual) if comment: print(' Comment:', comment) all_passed = False print() if all_passed: print('All test vectors passed.') else: print('Some test vectors failed.') return all_passed if __name__ == '__main__': test_vectors()