Created
October 5, 2016 08:28
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Simple Python RSA for digital signature with hashing implementation. For hashing SHA-256 from hashlib library is used.
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import random | |
from hashlib import sha256 | |
def coprime(a, b): | |
while b != 0: | |
a, b = b, a % b | |
return a | |
def extended_gcd(aa, bb): | |
lastremainder, remainder = abs(aa), abs(bb) | |
x, lastx, y, lasty = 0, 1, 1, 0 | |
while remainder: | |
lastremainder, (quotient, remainder) = remainder, divmod(lastremainder, remainder) | |
x, lastx = lastx - quotient*x, x | |
y, lasty = lasty - quotient*y, y | |
return lastremainder, lastx * (-1 if aa < 0 else 1), lasty * (-1 if bb < 0 else 1) | |
#Euclid's extended algorithm for finding the multiplicative inverse of two numbers | |
def modinv(a, m): | |
g, x, y = extended_gcd(a, m) | |
if g != 1: | |
raise Exception('Modular inverse does not exist') | |
return x % m | |
def is_prime(num): | |
if num == 2: | |
return True | |
if num < 2 or num % 2 == 0: | |
return False | |
for n in range(3, int(num**0.5)+2, 2): | |
if num % n == 0: | |
return False | |
return True | |
def generate_keypair(p, q): | |
if not (is_prime(p) and is_prime(q)): | |
raise ValueError('Both numbers must be prime.') | |
elif p == q: | |
raise ValueError('p and q cannot be equal') | |
n = p * q | |
#Phi is the totient of n | |
phi = (p-1) * (q-1) | |
#Choose an integer e such that e and phi(n) are coprime | |
e = random.randrange(1, phi) | |
#Use Euclid's Algorithm to verify that e and phi(n) are comprime | |
g = coprime(e, phi) | |
while g != 1: | |
e = random.randrange(1, phi) | |
g = coprime(e, phi) | |
#Use Extended Euclid's Algorithm to generate the private key | |
d = modinv(e, phi) | |
#Return public and private keypair | |
#Public key is (e, n) and private key is (d, n) | |
return ((e, n), (d, n)) | |
def encrypt(privatek, plaintext): | |
#Unpack the key into it's components | |
key, n = privatek | |
#Convert each letter in the plaintext to numbers based on the character using a^b mod m | |
numberRepr = [ord(char) for char in plaintext] | |
print("Number representation before encryption: ", numberRepr) | |
cipher = [pow(ord(char),key,n) for char in plaintext] | |
#Return the array of bytes | |
return cipher | |
def decrypt(publick, ciphertext): | |
#Unpack the key into its components | |
key, n = publick | |
#Generate the plaintext based on the ciphertext and key using a^b mod m | |
numberRepr = [pow(char, key, n) for char in ciphertext] | |
plain = [chr(pow(char, key, n)) for char in ciphertext] | |
print("Decrypted number representation is: ", numberRepr) | |
#Return the array of bytes as a string | |
return ''.join(plain) | |
def hashFunction(message): | |
hashed = sha256(message.encode("UTF-8")).hexdigest() | |
return hashed | |
def verify(receivedHashed, message): | |
ourHashed = hashFunction(message) | |
if receivedHashed == ourHashed: | |
print("Verification successful: ", ) | |
print(receivedHashed, " = ", ourHashed) | |
else: | |
print("Verification failed") | |
print(receivedHashed, " != ", ourHashed) | |
def main(): | |
p = int(input("Enter a prime number (17, 19, 23, etc): ")) | |
q = int(input("Enter another prime number (Not one you entered above): ")) | |
#p = 17 | |
#q=23 | |
print("Generating your public/private keypairs now . . .") | |
public, private = generate_keypair(p, q) | |
print("Your public key is ", public ," and your private key is ", private) | |
message = input("Enter a message to encrypt with your private key: ") | |
print("") | |
hashed = hashFunction(message) | |
print("Encrypting message with private key ", private ," . . .") | |
encrypted_msg = encrypt(private, hashed) | |
print("Your encrypted hashed message is: ") | |
print(''.join(map(lambda x: str(x), encrypted_msg))) | |
#print(encrypted_msg) | |
print("") | |
print("Decrypting message with public key ", public ," . . .") | |
decrypted_msg = decrypt(public, encrypted_msg) | |
print("Your decrypted message is:") | |
print(decrypted_msg) | |
print("") | |
print("Verification process . . .") | |
verify(decrypted_msg, message) | |
main() | |
Your code is awesome!!
It's easy to modify to meet up my needs!
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Hi ErbaAitbayev ,
Based on your work,I did a coding assignment :
and youtube demo :
This assignment is about : * Image Encryption , * Image Compression , * Huffman Coding & * RSA Algorithm .
Thank You.
Best Regards,
Albert T.