""" Wikipedia: https://en.wikipedia.org/wiki/Enigma_machine Video explanation: https://youtu.be/QwQVMqfoB2E Also check out Numberphile's and Computerphile's videos on this topic This module contains function 'enigma' which emulates the famous Enigma machine from WWII. Module includes: - enigma function - showcase of function usage - 9 randnomly generated rotors - reflector (aka static rotor) - original alphabet Created by TrapinchO """ # used alphabet -------------------------- # from string.ascii_uppercase abc = 'ABCDEFGHIJKLMNOPQRSTUVWXYZ' # -------------------------- default selection -------------------------- # rotors -------------------------- rotor1 = 'EGZWVONAHDCLFQMSIPJBYUKXTR' rotor2 = 'FOBHMDKEXQNRAULPGSJVTYICZW' rotor3 = 'ZJXESIUQLHAVRMDOYGTNFWPBKC' # reflector -------------------------- reflector = {'A': 'N', 'N': 'A', 'B': 'O', 'O': 'B', 'C': 'P', 'P': 'C', 'D': 'Q', 'Q': 'D', 'E': 'R', 'R': 'E', 'F': 'S', 'S': 'F', 'G': 'T', 'T': 'G', 'H': 'U', 'U': 'H', 'I': 'V', 'V': 'I', 'J': 'W', 'W': 'J', 'K': 'X', 'X': 'K', 'L': 'Y', 'Y': 'L', 'M': 'Z', 'Z': 'M'} # -------------------------- extra rotors -------------------------- rotor4 = 'RMDJXFUWGISLHVTCQNKYPBEZOA' rotor5 = 'SGLCPQWZHKXAREONTFBVIYJUDM' rotor6 = 'HVSICLTYKQUBXDWAJZOMFGPREN' rotor7 = 'RZWQHFMVDBKICJLNTUXAGYPSOE' rotor8 = 'LFKIJODBEGAMQPXVUHYSTCZRWN' rotor9 = 'KOAEGVDHXPQZMLFTYWJNBRCIUS' def _validator(rotpos: tuple, rotsel: tuple, pb: str) -> tuple: """ Checks if the values can be used for the 'enigma' function >>> _validator((1,1,1), (rotor1, rotor2, rotor3), 'POLAND') ((1, 1, 1), ('EGZWVONAHDCLFQMSIPJBYUKXTR', 'FOBHMDKEXQNRAULPGSJVTYICZW', \ 'ZJXESIUQLHAVRMDOYGTNFWPBKC'), \ {'P': 'O', 'O': 'P', 'L': 'A', 'A': 'L', 'N': 'D', 'D': 'N'}) :param rotpos: rotor_positon :param rotsel: rotor_selection :param pb: plugb -> validated and transformed :return: (rotpos, rotsel, pb) """ # Checks if there are 3 unique rotors unique_rotsel = len(set(rotsel)) if unique_rotsel < 3: raise Exception(f'Please use 3 unique rotors (not {unique_rotsel})') # Checks if rotor positions are valid rotorpos1, rotorpos2, rotorpos3 = rotpos if not 0 < rotorpos1 <= len(abc): raise ValueError(f'First rotor position is not within range of 1..26 (' f'{rotorpos1}') if not 0 < rotorpos2 <= len(abc): raise ValueError(f'Second rotor position is not within range of 1..26 (' f'{rotorpos2})') if not 0 < rotorpos3 <= len(abc): raise ValueError(f'Third rotor position is not within range of 1..26 (' f'{rotorpos3})') # Validates string and returns dict pb = _plugboard(pb) return rotpos, rotsel, pb def _plugboard(pbstring: str) -> dict: """ https://en.wikipedia.org/wiki/Enigma_machine#Plugboard >>> _plugboard('PICTURES') {'P': 'I', 'I': 'P', 'C': 'T', 'T': 'C', 'U': 'R', 'R': 'U', 'E': 'S', 'S': 'E'} >>> _plugboard('POLAND') {'P': 'O', 'O': 'P', 'L': 'A', 'A': 'L', 'N': 'D', 'D': 'N'} In the code, 'pb' stands for 'plugboard' Pairs can be separated by spaces :param pbstring: string containing plugboard setting for the Enigma machine :return: dictionary containing converted pairs """ # tests the input string if it # a) is type string # b) has even length (so pairs can be made) if not isinstance(pbstring, str): raise TypeError(f'Plugboard setting isn\'t type string ({type(pbstring)})') elif len(pbstring) % 2 != 0: raise Exception(f'Odd number of symbols ({len(pbstring)})') elif pbstring == '': return {} pbstring.replace(' ', '') # Checks if all characters are unique tmppbl = set() for i in pbstring: if i not in abc: raise Exception(f'\'{i}\' not in list of symbols') elif i in tmppbl: raise Exception(f'Duplicate symbol ({i})') else: tmppbl.add(i) del tmppbl # Created the dictionary pb = {} for i in range(0, len(pbstring) - 1, 2): pb[pbstring[i]] = pbstring[i + 1] pb[pbstring[i + 1]] = pbstring[i] return pb def enigma(text: str, rotor_position: tuple, rotor_selection: tuple = (rotor1, rotor2, rotor3), plugb: str = '') -> str: """ The only difference with real-world enigma is that I allowed string input. All characters are converted to uppercase. (non-letter symbol are ignored) How it works: (for every letter in the message) - Input letter goes into the plugboard. If it is connected to another one, switch it. - Letter goes through 3 rotors. Each rotor can be represented as 2 sets of symbol, where one is shuffled. Each symbol from the first set has corresponding symbol in the second set and vice versa. example: | ABCDEFGHIJKLMNOPQRSTUVWXYZ | e.g. F=D and D=F | VKLEPDBGRNWTFCJOHQAMUZYIXS | - Symbol then goes through reflector (static rotor). There it is switched with paired symbol The reflector can be represented as2 sets, each with half of the alphanet. There are usually 10 pairs of letters. Example: | ABCDEFGHIJKLM | e.g. E is paired to X | ZYXWVUTSRQPON | so when E goes in X goes out and vice versa - Letter then goes through the rotors again - If the letter is connected to plugboard, it is switched. - Return the letter >>> enigma('Hello World!', (1, 2, 1), plugb='pictures') 'KORYH JUHHI!' >>> enigma('KORYH, juhhi!', (1, 2, 1), plugb='pictures') 'HELLO, WORLD!' >>> enigma('hello world!', (1, 1, 1), plugb='pictures') 'FPNCZ QWOBU!' >>> enigma('FPNCZ QWOBU', (1, 1, 1), plugb='pictures') 'HELLO WORLD' :param text: input message :param rotor_position: tuple with 3 values in range 1..26 :param rotor_selection: tuple with 3 rotors () :param plugb: string containing plugboard configuration (default '') :return: en/decrypted string """ text = text.upper() rotor_position, rotor_selection, plugboard = _validator( rotor_position, rotor_selection, plugb.upper()) rotorpos1, rotorpos2, rotorpos3 = rotor_position rotor1, rotor2, rotor3 = rotor_selection rotorpos1 -= 1 rotorpos2 -= 1 rotorpos3 -= 1 plugboard = plugboard result = [] # encryption/decryption process -------------------------- for symbol in text: if symbol in abc: # 1st plugboard -------------------------- if symbol in plugboard: symbol = plugboard[symbol] # rotor ra -------------------------- index = abc.index(symbol) + rotorpos1 symbol = rotor1[index % len(abc)] # rotor rb -------------------------- index = abc.index(symbol) + rotorpos2 symbol = rotor2[index % len(abc)] # rotor rc -------------------------- index = abc.index(symbol) + rotorpos3 symbol = rotor3[index % len(abc)] # reflector -------------------------- # this is the reason you don't need another machine to decipher symbol = reflector[symbol] # 2nd rotors symbol = abc[rotor3.index(symbol) - rotorpos3] symbol = abc[rotor2.index(symbol) - rotorpos2] symbol = abc[rotor1.index(symbol) - rotorpos1] # 2nd plugboard if symbol in plugboard: symbol = plugboard[symbol] # moves/resets rotor positions rotorpos1 += 1 if rotorpos1 >= len(abc): rotorpos1 = 0 rotorpos2 += 1 if rotorpos2 >= len(abc): rotorpos2 = 0 rotorpos3 += 1 if rotorpos3 >= len(abc): rotorpos3 = 0 # else: # pass # Error could be also raised # raise ValueError( # 'Invalid symbol('+repr(symbol)+')') result.append(symbol) return "".join(result) if __name__ == '__main__': message = 'This is my Python script that emulates the Enigma machine from WWII.' rotor_pos = (1, 1, 1) pb = 'pictures' rotor_sel = (rotor2, rotor4, rotor8) en = enigma(message, rotor_pos, rotor_sel, pb) print('Encrypted message:', en) print('Decrypted message:', enigma(en, rotor_pos, rotor_sel, pb))