A Walk Through Ethereum Classic Digital Signature Code
A Walk Through Ethereum Classic Digital Signature Code
Ethereum Classic (ETC) digital signatures secure transactions. These involve elliptic curve cryptography and the Elliptic Curve Digital Signature Algorithm (ECDSA). I will describe ETC digital signatures without these topics using only small Python functions.
Basics
Signing and verifying will be implemented using the following four constants and three functions:
N = 115792089237316195423570985008687907852837564279074904382605163141518161494337
P = 115792089237316195423570985008687907853269984665640564039457584007908834671663
Gx = 55066263022277343669578718895168534326250603453777594175500187360389116729240
Gy = 32670510020758816978083085130507043184471273380659243275938904335757337482424
def invert(number, modulus):
"""
Finds the inverses of natural numbers.
"""
result = 1
power = number
for e in bin(modulus - 2)[2:][::-1]:
if int(e):
result = (result * power) % modulus
power = (power ** 2) % modulus
return result
def add(pair_1, pair_2):
"""
Finds the sums of two pairs of natural numbers.
"""
if pair_1 == [0, 0]:
result = pair_2
elif pair_2 == [0, 0]:
result = pair_1
else:
if pair_1 == pair_2:
temp = 3 * pair_1[0] ** 2
temp = (temp * invert(2 * pair_1[1], P)) % P
else:
temp = pair_2[1] - pair_1[1]
temp = (temp * invert(pair_2[0] - pair_1[0], P)) % P
result = (temp ** 2 - pair_1[0] - pair_2[0]) % P
result = [result, (temp * (pair_1[0] - result) - pair_1[1]) % P]
return result
def multiply(number, pair):
"""
Finds the products of natural numbers and pairs of natural numbers.
"""
result = [0, 0]
power = pair[:]
for e in bin(number)[2:][::-1]:
if int(e):
result = add(result, power)
power = add(power, power)
return result
The invert function defines an operation on numbers in terms of other numbers referred to as moduli. The add function defines an operation on pairs of numbers. The multiply function defines an operation on a number and a pair of numbers. Here are examples of their usage:
>>> invert(82856, 7164661)
3032150
>>> add([84672, 5768], [15684, 471346])
[98868508778765247164450388534339365517943901419260061027507991295919394382071, 110531019976596004792591549651085191890711482591841040377832420464376026143223]
>>> multiply(82716, [31616, 837454])
[82708077205483544970470074583740846828577431856187364454411787387343982212318, 30836796656275663256542662990890163662171092281704208118107591167423888588304]
Private & Public Keys
Private keys are any nonzero numbers less than the constant N. Public keys are the products of these private keys and the pair (Gx, Gy ). For example:
>>> private_key = 296921718
>>> multiply(private_key, (Gx, Gy))
[29493341745186804828936410559976490896704930101972775917156948978213464516647, 14120583959514503052816414068611328686827638581568335296615875235402122319824]
Notice that public keys are pairs of numbers.
Signing
Signing transactions involves an operation on the Keccak 256 hashes of the transactions and private keys. The following function implements this operation:
import random
def sign(hash, priv_key):
"""
Signs the hashes of transactions.
"""
result = [0, 0]
while (0 in result) or (result[1] > N / 2):
temp = random.randint(1, N - 1)
result[0] = multiply(temp, (Gx, Gy))[0] % N
result[1] = invert(temp, N) * (hash + priv_key * result[0])
result[1] = result[1] % N
return result
For example:
>>> hash = 0xf62d00f14db9521c03a39c20e94aa10a82ff5f5a614772b25e36757a95a71048
>>> private_key = 296921718
>>> sign(hash, private_key)
[12676003675279000995677412431399004760576311052126257887715931882164427686866, 17853929027942611176839390215748157599052991088042356790746129338653342477382]
>>> sign(hash, private_key)
[18783324464633387734826042295911802941026009108876130700727156896210203356179, 41959562951157235894396660120771158332032804144867595196194581439345450008533]
Notice that digital signatures are pairs of numbers. Notice also that the sign function can give different results for the same inputs!
Verifying
Verifying digital signatures involves confirming certain properties with regards to the Keccak 256 hashes and public keys. The following function implements these checks:
def verify(sig, hash, pub_key):
"""
Verifies the signatures of the hashes of transactions.
"""
temp_1 = multiply((invert(sig[1], N) * hash) % N, (Gx, Gy))
temp_2 = multiply((invert(sig[1], N) * sig[0]) % N, pub_key)
sum = add(temp_1, temp_2)
test_1 = (0 < sig[0] < N) and (0 < sig[1] < N)
test_2 = sum != [0, 0]
test_3 = sig[0] == sum[0] % N
return test_1 and test_2 and test_3
For example:
>>> hash = 0xf62d00f14db9521c03a39c20e94aa10a82ff5f5a614772b25e36757a95a71048
>>> private_key = 296921718
>>> public_key = multiply(private_key, (Gx, Gy))
>>> public_key
[29493341745186804828936410559976490896704930101972775917156948978213464516647, 14120583959514503052816414068611328686827638581568335296615875235402122319824]
>>> signature = sign(hash, private_key)
>>> signature
[54728868372105873293629977757277092827353030346967592768173610703187933361202, 18974025727476367931183775600389145833964496722266015570370178285290252701715]
>>> verify(signature, hash, public_key)
True
To verify that public keys correspond to specific ETC account addresses, confirm that the rightmost 20 bytes of the public key Keccak 256 hashes equal those addresses.
Recovery Identifiers
Strictly speaking, ETC digital signatures include additional small numbers referred to as recovery identifiers. These allow public keys to be determined solely from the signed transactions.
Conclusion
I have explained ETC digital signatures using code rather than mathematics. Hopefully seeing how signing and verifying can be implemented with these tiny functions has been useful.
Feedback
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Acknowledgements
I would like to thank IOHK (Input Output Hong Kong) for funding this effort.
License
This work is licensed under the Creative Commons Attribution ShareAlike 4.0 International License.