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This file contains hidden or bidirectional Unicode text that may be interpreted or compiled differently than what appears below. To review, open the file in an editor that reveals hidden Unicode characters. Learn more about bidirectional Unicode charactersOriginal file line number Diff line number Diff line change @@ -0,0 +1,119 @@ ''' 620031587 Net-Centric Computing Assignment Part A - RSA Encryption ''' import random ''' Euclid's algorithm for determining the greatest common divisor Use iteration to make it faster for larger integers ''' def gcd(a, b): while b != 0: a, b = b, a % b return a ''' Euclid's extended algorithm for finding the multiplicative inverse of two numbers ''' def multiplicative_inverse(e, phi): d = 0 x1 = 0 x2 = 1 y1 = 1 temp_phi = phi while e > 0: temp1 = temp_phi/e temp2 = temp_phi - temp1 * e temp_phi = e e = temp2 x = x2- temp1* x1 y = d - temp1 * y1 x2 = x1 x1 = x d = y1 y1 = y if temp_phi == 1: return d + phi ''' Tests to see if a number is prime. ''' def is_prime(num): if num == 2: return True if num < 2 or num % 2 == 0: return False for n in xrange(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 = pq 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 = gcd(e, phi) while g != 1: e = random.randrange(1, phi) g = gcd(e, phi) #Use Extended Euclid's Algorithm to generate the private key d = multiplicative_inverse(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(pk, plaintext): #Unpack the key into it's components key, n = pk #Convert each letter in the plaintext to numbers based on the character using a^b mod m cipher = [(ord(char) ** key) % n for char in plaintext] #Return the array of bytes return cipher def decrypt(pk, ciphertext): #Unpack the key into its components key, n = pk #Generate the plaintext based on the ciphertext and key using a^b mod m plain = [chr((char ** key) % n) for char in ciphertext] #Return the array of bytes as a string return ''.join(plain) if __name__ == '__main__': ''' Detect if the script is being run directly by the user ''' print "RSA Encrypter/ Decrypter" p = int(raw_input("Enter a prime number (17, 19, 23, etc): ")) q = int(raw_input("Enter another prime number (Not one you entered above): ")) 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 = raw_input("Enter a message to encrypt with your private key: ") encrypted_msg = encrypt(private, message) print "Your encrypted message is: " print ''.join(map(lambda x: str(x), encrypted_msg)) print "Decrypting message with public key ", public ," . . ." print "Your message is:" print decrypt(public, encrypted_msg)