Python/ciphers/affine_cipher.py

import sys, random, cryptomath_module as cryptoMath

SYMBOLS = """ !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~"""

def main():
    message = input('Enter message: ')
    key = int(input('Enter key [2000 - 9000]: '))
    mode = input('Encrypt/Decrypt [E/D]: ')

    if mode.lower().startswith('e'):
              mode = 'encrypt'
              translated = encryptMessage(key, message)
    elif mode.lower().startswith('d'):
              mode = 'decrypt'
              translated = decryptMessage(key, message)
    print('\n%sed text: \n%s' % (mode.title(), translated))

def getKeyParts(key):
    keyA = key // len(SYMBOLS)
    keyB = key % len(SYMBOLS)
    return (keyA, keyB)

def checkKeys(keyA, keyB, mode):
    if keyA == 1 and mode == 'encrypt':
        sys.exit('The affine cipher becomes weak when key A is set to 1. Choose different key')
    if keyB == 0 and mode == 'encrypt':
        sys.exit('The affine cipher becomes weak when key A is set to 1. Choose different key')
    if keyA < 0 or keyB < 0 or keyB > len(SYMBOLS) - 1:
        sys.exit('Key A must be greater than 0 and key B must be between 0 and %s.' % (len(SYMBOLS) - 1))
    if cryptoMath.gcd(keyA, len(SYMBOLS)) != 1:
        sys.exit('Key A %s and the symbol set size %s are not relatively prime. Choose a different key.' % (keyA, len(SYMBOLS)))

def encryptMessage(key, message):
    '''
    >>> encryptMessage(4545, 'The affine cipher is a type of monoalphabetic substitution cipher.')
    'VL}p MM{I}p~{HL}Gp{vp pFsH}pxMpyxIx JHL O}F{~pvuOvF{FuF{xIp~{HL}Gi'
    '''
    keyA, keyB = getKeyParts(key)
    checkKeys(keyA, keyB, 'encrypt')
    cipherText = ''
    for symbol in message:
        if symbol in SYMBOLS:
            symIndex = SYMBOLS.find(symbol)
            cipherText += SYMBOLS[(symIndex * keyA + keyB) % len(SYMBOLS)]
        else:
            cipherText += symbol
    return cipherText

def decryptMessage(key, message):
    '''
    >>> decryptMessage(4545, 'VL}p MM{I}p~{HL}Gp{vp pFsH}pxMpyxIx JHL O}F{~pvuOvF{FuF{xIp~{HL}Gi')
    'The affine cipher is a type of monoalphabetic substitution cipher.'
    '''
    keyA, keyB = getKeyParts(key)
    checkKeys(keyA, keyB, 'decrypt')
    plainText = ''
    modInverseOfkeyA = cryptoMath.findModInverse(keyA, len(SYMBOLS))
    for symbol in message:
        if symbol in SYMBOLS:
            symIndex = SYMBOLS.find(symbol)
            plainText += SYMBOLS[(symIndex - keyB) * modInverseOfkeyA % len(SYMBOLS)]
        else:
            plainText += symbol
    return plainText

def getRandomKey():
    while True:
        keyA = random.randint(2, len(SYMBOLS))
        keyB = random.randint(2, len(SYMBOLS))
    if cryptoMath.gcd(keyA, len(SYMBOLS)) == 1:
        return keyA * len(SYMBOLS) + keyB

if __name__ == '__main__':
    import doctest
    doctest.testmod()
    main()
Initial 2016-08-07 15:48:46 +00:00			`import sys, random, cryptomath_module as cryptoMath`

			SYMBOLS = """ !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{\|}~"""

			`def main():`
			`message = input('Enter message: ')`
			`key = int(input('Enter key [2000 - 9000]: '))`
			`mode = input('Encrypt/Decrypt [E/D]: ')`

			`if mode.lower().startswith('e'):`
			`mode = 'encrypt'`
			`translated = encryptMessage(key, message)`
			`elif mode.lower().startswith('d'):`
			`mode = 'decrypt'`
			`translated = decryptMessage(key, message)`
			`print('\n%sed text: \n%s' % (mode.title(), translated))`

			`def getKeyParts(key):`
			`keyA = key // len(SYMBOLS)`
			`keyB = key % len(SYMBOLS)`
			`return (keyA, keyB)`

			`def checkKeys(keyA, keyB, mode):`
			`if keyA == 1 and mode == 'encrypt':`
			`sys.exit('The affine cipher becomes weak when key A is set to 1. Choose different key')`
			`if keyB == 0 and mode == 'encrypt':`
			`sys.exit('The affine cipher becomes weak when key A is set to 1. Choose different key')`
			`if keyA < 0 or keyB < 0 or keyB > len(SYMBOLS) - 1:`
			`sys.exit('Key A must be greater than 0 and key B must be between 0 and %s.' % (len(SYMBOLS) - 1))`
			`if cryptoMath.gcd(keyA, len(SYMBOLS)) != 1:`
			`sys.exit('Key A %s and the symbol set size %s are not relatively prime. Choose a different key.' % (keyA, len(SYMBOLS)))`

			`def encryptMessage(key, message):`
			`'''`
			`>>> encryptMessage(4545, 'The affine cipher is a type of monoalphabetic substitution cipher.')`
			`'VL}p MM{I}p~{HL}Gp{vp pFsH}pxMpyxIx JHL O}F{~pvuOvF{FuF{xIp~{HL}Gi'`
			`'''`
			`keyA, keyB = getKeyParts(key)`
			`checkKeys(keyA, keyB, 'encrypt')`
			`cipherText = ''`
			`for symbol in message:`
			`if symbol in SYMBOLS:`
			`symIndex = SYMBOLS.find(symbol)`
			`cipherText += SYMBOLS[(symIndex * keyA + keyB) % len(SYMBOLS)]`
			`else:`
			`cipherText += symbol`
			`return cipherText`

			`def decryptMessage(key, message):`
			`'''`
			`>>> decryptMessage(4545, 'VL}p MM{I}p~{HL}Gp{vp pFsH}pxMpyxIx JHL O}F{~pvuOvF{FuF{xIp~{HL}Gi')`
			`'The affine cipher is a type of monoalphabetic substitution cipher.'`
			`'''`
			`keyA, keyB = getKeyParts(key)`
			`checkKeys(keyA, keyB, 'decrypt')`
			`plainText = ''`
			`modInverseOfkeyA = cryptoMath.findModInverse(keyA, len(SYMBOLS))`
			`for symbol in message:`
			`if symbol in SYMBOLS:`
			`symIndex = SYMBOLS.find(symbol)`
			`plainText += SYMBOLS[(symIndex - keyB) * modInverseOfkeyA % len(SYMBOLS)]`
			`else:`
			`plainText += symbol`
			`return plainText`

			`def getRandomKey():`
			`while True:`
			`keyA = random.randint(2, len(SYMBOLS))`
			`keyB = random.randint(2, len(SYMBOLS))`
			`if cryptoMath.gcd(keyA, len(SYMBOLS)) == 1:`
			`return keyA * len(SYMBOLS) + keyB`

			`if __name__ == '__main__':`
			`import doctest`
			`doctest.testmod()`
			`main()`