X-Git-Url: https://git.njae.me.uk/?a=blobdiff_plain;f=cipher.py;h=2eb89f72306e30e4db99e539e36733aa792d13c4;hb=21c390a77d42729afa23844ef2f1295106bed3de;hp=f2c6775223f726de2386c4d674c829e19922dd55;hpb=3dc63370f2be9afe868b79d836613aba24f1a06d;p=cipher-tools.git diff --git a/cipher.py b/cipher.py index f2c6775..2eb89f7 100644 --- a/cipher.py +++ b/cipher.py @@ -1,132 +1,547 @@ import string import collections +import math +from enum import Enum +from itertools import zip_longest, cycle, chain, count +import numpy as np +from numpy import matrix +from numpy import linalg +from language_models import * +import pprint -english_counts = collections.defaultdict(int) -with open('count_1l.txt', 'r') as f: - for line in f: - (letter, count) = line.split("\t") - english_counts[letter] = int(count) - -modular_division = [[0]* 26 for i in range(26)] -for i in range(26): - for j in range(26): - t = (i*j) % 26 - # therefore, i = t / j - modular_division[t][j] = i - - -def sanitise(text): - sanitised = [c.lower() for c in text if c in string.ascii_letters] - return ''.join(sanitised) - -def letter_frequencies(message): - frequencies = collections.defaultdict(int) - for letter in sanitise(message): - frequencies[letter]+=1 - return frequencies - -def scale_freq(frequencies): - total= sum(frequencies.values()) - scaled_frequencies = collections.defaultdict(int) - for letter in frequencies.keys(): - scaled_frequencies[letter] = frequencies[letter] / total - return scaled_frequencies - -def value_diff(frequencies1, frequencies2): - total= 0 - for letter in frequencies1.keys(): - total += abs(frequencies1[letter]-frequencies2[letter]) - return total - + + +from utilities import * +from segment import * + +from caesar import * +from affine import * +from keyword import * +from polybius import * +from column_transposition import * +from railfence import * + + +def make_cadenus_keycolumn(doubled_letters = 'vw', start='a', reverse=False): + """Makes the key column for a Cadenus cipher (the column down between the + rows of letters) + + >>> make_cadenus_keycolumn()['a'] + 0 + >>> make_cadenus_keycolumn()['b'] + 1 + >>> make_cadenus_keycolumn()['c'] + 2 + >>> make_cadenus_keycolumn()['v'] + 21 + >>> make_cadenus_keycolumn()['w'] + 21 + >>> make_cadenus_keycolumn()['z'] + 24 + >>> make_cadenus_keycolumn(doubled_letters='ij', start='b', reverse=True)['a'] + 1 + >>> make_cadenus_keycolumn(doubled_letters='ij', start='b', reverse=True)['b'] + 0 + >>> make_cadenus_keycolumn(doubled_letters='ij', start='b', reverse=True)['c'] + 24 + >>> make_cadenus_keycolumn(doubled_letters='ij', start='b', reverse=True)['i'] + 18 + >>> make_cadenus_keycolumn(doubled_letters='ij', start='b', reverse=True)['j'] + 18 + >>> make_cadenus_keycolumn(doubled_letters='ij', start='b', reverse=True)['v'] + 6 + >>> make_cadenus_keycolumn(doubled_letters='ij', start='b', reverse=True)['z'] + 2 + """ + index_to_remove = string.ascii_lowercase.find(doubled_letters[0]) + short_alphabet = string.ascii_lowercase[:index_to_remove] + string.ascii_lowercase[index_to_remove+1:] + if reverse: + short_alphabet = cat(reversed(short_alphabet)) + start_pos = short_alphabet.find(start) + rotated_alphabet = short_alphabet[start_pos:] + short_alphabet[:start_pos] + keycolumn = {l: i for i, l in enumerate(rotated_alphabet)} + keycolumn[doubled_letters[0]] = keycolumn[doubled_letters[1]] + return keycolumn + +def cadenus_encipher(message, keyword, keycolumn, fillvalue='a'): + """Encipher with the Cadenus cipher + + >>> cadenus_encipher(sanitise('Whoever has made a voyage up the Hudson ' \ + 'must remember the Kaatskill mountains. ' \ + 'They are a dismembered branch of the great'), \ + 'wink', \ + make_cadenus_keycolumn(doubled_letters='vw', start='a', reverse=True)) + 'antodeleeeuhrsidrbhmhdrrhnimefmthgeaetakseomehetyaasuvoyegrastmmuuaeenabbtpchehtarorikswosmvaleatned' + >>> cadenus_encipher(sanitise('a severe limitation on the usefulness of ' \ + 'the cadenus is that every message must be ' \ + 'a multiple of twenty-five letters long'), \ + 'easy', \ + make_cadenus_keycolumn(doubled_letters='vw', start='a', reverse=True)) + 'systretomtattlusoatleeesfiyheasdfnmschbhneuvsnpmtofarenuseieeieltarlmentieetogevesitfaisltngeeuvowul' + """ + rows = chunks(message, len(message) // 25, fillvalue=fillvalue) + columns = zip(*rows) + rotated_columns = [col[start:] + col[:start] for start, col in zip([keycolumn[l] for l in keyword], columns)] + rotated_rows = zip(*rotated_columns) + transpositions = transpositions_of(keyword) + transposed = [transpose(r, transpositions) for r in rotated_rows] + return cat(chain(*transposed)) + +def cadenus_decipher(message, keyword, keycolumn, fillvalue='a'): + """ + >>> cadenus_decipher('antodeleeeuhrsidrbhmhdrrhnimefmthgeaetakseomehetyaa' \ + 'suvoyegrastmmuuaeenabbtpchehtarorikswosmvaleatned', \ + 'wink', \ + make_cadenus_keycolumn(reverse=True)) + 'whoeverhasmadeavoyageupthehudsonmustrememberthekaatskillmountainstheyareadismemberedbranchofthegreat' + >>> cadenus_decipher('systretomtattlusoatleeesfiyheasdfnmschbhneuvsnpmtof' \ + 'arenuseieeieltarlmentieetogevesitfaisltngeeuvowul', \ + 'easy', \ + make_cadenus_keycolumn(reverse=True)) + 'aseverelimitationontheusefulnessofthecadenusisthateverymessagemustbeamultipleoftwentyfiveletterslong' + """ + rows = chunks(message, len(message) // 25, fillvalue=fillvalue) + transpositions = transpositions_of(keyword) + untransposed_rows = [untranspose(r, transpositions) for r in rows] + columns = zip(*untransposed_rows) + rotated_columns = [col[-start:] + col[:-start] for start, col in zip([keycolumn[l] for l in keyword], columns)] + rotated_rows = zip(*rotated_columns) + # return rotated_columns + return cat(chain(*rotated_rows)) + + +def hill_encipher(matrix, message_letters, fillvalue='a'): + """Hill cipher + + >>> hill_encipher(np.matrix([[7,8], [11,11]]), 'hellothere') + 'drjiqzdrvx' + >>> hill_encipher(np.matrix([[6, 24, 1], [13, 16, 10], [20, 17, 15]]), \ + 'hello there') + 'tfjflpznvyac' + """ + n = len(matrix) + sanitised_message = sanitise(message_letters) + if len(sanitised_message) % n != 0: + padding = fillvalue[0] * (n - len(sanitised_message) % n) + else: + padding = '' + message = [pos(c) for c in sanitised_message + padding] + message_chunks = [message[i:i+n] for i in range(0, len(message), n)] + # message_chunks = chunks(message, len(matrix), fillvalue=None) + enciphered_chunks = [((matrix * np.matrix(c).T).T).tolist()[0] + for c in message_chunks] + return cat([unpos(round(l)) + for l in sum(enciphered_chunks, [])]) + +def hill_decipher(matrix, message, fillvalue='a'): + """Hill cipher + + >>> hill_decipher(np.matrix([[7,8], [11,11]]), 'drjiqzdrvx') + 'hellothere' + >>> hill_decipher(np.matrix([[6, 24, 1], [13, 16, 10], [20, 17, 15]]), \ + 'tfjflpznvyac') + 'hellothereaa' + """ + adjoint = linalg.det(matrix)*linalg.inv(matrix) + inverse_determinant = modular_division_table[int(round(linalg.det(matrix))) % 26][1] + inverse_matrix = (inverse_determinant * adjoint) % 26 + return hill_encipher(inverse_matrix, message, fillvalue) + + +# Where each piece of text ends up in the AMSCO transpositon cipher. +# 'index' shows where the slice appears in the plaintext, with the slice +# from 'start' to 'end' +AmscoSlice = collections.namedtuple('AmscoSlice', ['index', 'start', 'end']) + +class AmscoFillStyle(Enum): + continuous = 1 + same_each_row = 2 + reverse_each_row = 3 + +def amsco_transposition_positions(message, keyword, + fillpattern=(1, 2), + fillstyle=AmscoFillStyle.continuous, + fillcolumnwise=False, + emptycolumnwise=True): + """Creates the grid for the AMSCO transposition cipher. Each element in the + grid shows the index of that slice and the start and end positions of the + plaintext that go to make it up. + + >>> amsco_transposition_positions(string.ascii_lowercase, 'freddy', \ + fillpattern=(1, 2)) # doctest: +NORMALIZE_WHITESPACE + [[AmscoSlice(index=3, start=4, end=6), + AmscoSlice(index=2, start=3, end=4), + AmscoSlice(index=0, start=0, end=1), + AmscoSlice(index=1, start=1, end=3), + AmscoSlice(index=4, start=6, end=7)], + [AmscoSlice(index=8, start=12, end=13), + AmscoSlice(index=7, start=10, end=12), + AmscoSlice(index=5, start=7, end=9), + AmscoSlice(index=6, start=9, end=10), + AmscoSlice(index=9, start=13, end=15)], + [AmscoSlice(index=13, start=19, end=21), + AmscoSlice(index=12, start=18, end=19), + AmscoSlice(index=10, start=15, end=16), + AmscoSlice(index=11, start=16, end=18), + AmscoSlice(index=14, start=21, end=22)], + [AmscoSlice(index=18, start=27, end=28), + AmscoSlice(index=17, start=25, end=27), + AmscoSlice(index=15, start=22, end=24), + AmscoSlice(index=16, start=24, end=25), + AmscoSlice(index=19, start=28, end=30)]] + """ + transpositions = transpositions_of(keyword) + fill_iterator = cycle(fillpattern) + indices = count() + message_length = len(message) + + current_position = 0 + grid = [] + current_fillpattern = fillpattern + while current_position < message_length: + row = [] + if fillstyle == AmscoFillStyle.same_each_row: + fill_iterator = cycle(fillpattern) + if fillstyle == AmscoFillStyle.reverse_each_row: + fill_iterator = cycle(current_fillpattern) + for _ in range(len(transpositions)): + index = next(indices) + gap = next(fill_iterator) + row += [AmscoSlice(index, current_position, current_position + gap)] + current_position += gap + grid += [row] + if fillstyle == AmscoFillStyle.reverse_each_row: + current_fillpattern = list(reversed(current_fillpattern)) + return [transpose(r, transpositions) for r in grid] + +def amsco_transposition_encipher(message, keyword, + fillpattern=(1,2), fillstyle=AmscoFillStyle.reverse_each_row): + """AMSCO transposition encipher. + + >>> amsco_transposition_encipher('hellothere', 'abc', fillpattern=(1, 2)) + 'hoteelhler' + >>> amsco_transposition_encipher('hellothere', 'abc', fillpattern=(2, 1)) + 'hetelhelor' + >>> amsco_transposition_encipher('hellothere', 'acb', fillpattern=(1, 2)) + 'hotelerelh' + >>> amsco_transposition_encipher('hellothere', 'acb', fillpattern=(2, 1)) + 'hetelorlhe' + >>> amsco_transposition_encipher('hereissometexttoencipher', 'encode') + 'etecstthhomoerereenisxip' + >>> amsco_transposition_encipher('hereissometexttoencipher', 'cipher', fillpattern=(1, 2)) + 'hetcsoeisterereipexthomn' + >>> amsco_transposition_encipher('hereissometexttoencipher', 'cipher', fillpattern=(1, 2), fillstyle=AmscoFillStyle.continuous) + 'hecsoisttererteipexhomen' + >>> amsco_transposition_encipher('hereissometexttoencipher', 'cipher', fillpattern=(2, 1)) + 'heecisoosttrrtepeixhemen' + >>> amsco_transposition_encipher('hereissometexttoencipher', 'cipher', fillpattern=(1, 3, 2)) + 'hxtomephescieretoeisnter' + >>> amsco_transposition_encipher('hereissometexttoencipher', 'cipher', fillpattern=(1, 3, 2), fillstyle=AmscoFillStyle.continuous) + 'hxomeiphscerettoisenteer' + """ + grid = amsco_transposition_positions(message, keyword, + fillpattern=fillpattern, fillstyle=fillstyle) + ct_as_grid = [[message[s.start:s.end] for s in r] for r in grid] + return combine_every_nth(ct_as_grid) + + +def amsco_transposition_decipher(message, keyword, + fillpattern=(1,2), fillstyle=AmscoFillStyle.reverse_each_row): + """AMSCO transposition decipher + + >>> amsco_transposition_decipher('hoteelhler', 'abc', fillpattern=(1, 2)) + 'hellothere' + >>> amsco_transposition_decipher('hetelhelor', 'abc', fillpattern=(2, 1)) + 'hellothere' + >>> amsco_transposition_decipher('hotelerelh', 'acb', fillpattern=(1, 2)) + 'hellothere' + >>> amsco_transposition_decipher('hetelorlhe', 'acb', fillpattern=(2, 1)) + 'hellothere' + >>> amsco_transposition_decipher('etecstthhomoerereenisxip', 'encode') + 'hereissometexttoencipher' + >>> amsco_transposition_decipher('hetcsoeisterereipexthomn', 'cipher', fillpattern=(1, 2)) + 'hereissometexttoencipher' + >>> amsco_transposition_decipher('hecsoisttererteipexhomen', 'cipher', fillpattern=(1, 2), fillstyle=AmscoFillStyle.continuous) + 'hereissometexttoencipher' + >>> amsco_transposition_decipher('heecisoosttrrtepeixhemen', 'cipher', fillpattern=(2, 1)) + 'hereissometexttoencipher' + >>> amsco_transposition_decipher('hxtomephescieretoeisnter', 'cipher', fillpattern=(1, 3, 2)) + 'hereissometexttoencipher' + >>> amsco_transposition_decipher('hxomeiphscerettoisenteer', 'cipher', fillpattern=(1, 3, 2), fillstyle=AmscoFillStyle.continuous) + 'hereissometexttoencipher' + """ + + grid = amsco_transposition_positions(message, keyword, + fillpattern=fillpattern, fillstyle=fillstyle) + transposed_sections = [s for c in [l for l in zip(*grid)] for s in c] + plaintext_list = [''] * len(transposed_sections) + current_pos = 0 + for slice in transposed_sections: + plaintext_list[slice.index] = message[current_pos:current_pos-slice.start+slice.end][:len(message[slice.start:slice.end])] + current_pos += len(message[slice.start:slice.end]) + return cat(plaintext_list) + + +def bifid_grid(keyword, wrap_alphabet, letter_mapping): + """Create the grids for a Bifid cipher + """ + cipher_alphabet = keyword_cipher_alphabet_of(keyword, wrap_alphabet) + if letter_mapping is None: + letter_mapping = {'j': 'i'} + translation = ''.maketrans(letter_mapping) + cipher_alphabet = cat(collections.OrderedDict.fromkeys(cipher_alphabet.translate(translation))) + f_grid = {k: ((i // 5) + 1, (i % 5) + 1) + for i, k in enumerate(cipher_alphabet)} + r_grid = {((i // 5) + 1, (i % 5) + 1): k + for i, k in enumerate(cipher_alphabet)} + return translation, f_grid, r_grid + +def bifid_encipher(message, keyword, wrap_alphabet=KeywordWrapAlphabet.from_a, + letter_mapping=None, period=None, fillvalue=None): + """Bifid cipher + + >>> bifid_encipher("indiajelly", 'iguana') + 'ibidonhprm' + >>> bifid_encipher("indiacurry", 'iguana', period=4) + 'ibnhgaqltm' + >>> bifid_encipher("indiacurry", 'iguana', period=4, fillvalue='x') + 'ibnhgaqltzml' + """ + translation, f_grid, r_grid = bifid_grid(keyword, wrap_alphabet, letter_mapping) + + t_message = message.translate(translation) + pairs0 = [f_grid[l] for l in sanitise(t_message)] + if period: + chunked_pairs = [pairs0[i:i+period] for i in range(0, len(pairs0), period)] + if len(chunked_pairs[-1]) < period and fillvalue: + chunked_pairs[-1] += [f_grid[fillvalue]] * (period - len(chunked_pairs[-1])) + else: + chunked_pairs = [pairs0] + + pairs1 = [] + for c in chunked_pairs: + items = sum(list(list(i) for i in zip(*c)), []) + p = [(items[i], items[i+1]) for i in range(0, len(items), 2)] + pairs1 += p + return cat(r_grid[p] for p in pairs1) -def caesar_cipher_letter(letter, shift): - if letter in string.ascii_letters: - if letter in string.ascii_lowercase: - return chr((ord(letter) - ord('a') + shift) % 26 + ord('a')) - else: - new_letter = letter.lower() - yolo = chr((ord(new_letter) - ord('a') + shift) % 26 + ord('a')) - return yolo.upper() + +def bifid_decipher(message, keyword, wrap_alphabet=KeywordWrapAlphabet.from_a, + letter_mapping=None, period=None, fillvalue=None): + """Decipher with bifid cipher + + >>> bifid_decipher('ibidonhprm', 'iguana') + 'indiaielly' + >>> bifid_decipher("ibnhgaqltm", 'iguana', period=4) + 'indiacurry' + >>> bifid_decipher("ibnhgaqltzml", 'iguana', period=4) + 'indiacurryxx' + """ + translation, f_grid, r_grid = bifid_grid(keyword, wrap_alphabet, letter_mapping) + + t_message = message.translate(translation) + pairs0 = [f_grid[l] for l in sanitise(t_message)] + if period: + chunked_pairs = [pairs0[i:i+period] for i in range(0, len(pairs0), period)] + if len(chunked_pairs[-1]) < period and fillvalue: + chunked_pairs[-1] += [f_grid[fillvalue]] * (period - len(chunked_pairs[-1])) else: - return letter + chunked_pairs = [pairs0] + + pairs1 = [] + for c in chunked_pairs: + items = [j for i in c for j in i] + gap = len(c) + p = [(items[i], items[i+gap]) for i in range(gap)] + pairs1 += p -def caesar_decipher_letter(letter, shift): - return caesar_cipher_letter(letter, -shift) + return cat(r_grid[p] for p in pairs1) -def caesar_cipher_message(message, shift): - big_cipher = [caesar_cipher_letter(l, shift) for l in message] - return ''.join(big_cipher) -def caesar_decipher_message(message, shift): - return caesar_cipher_message(message, -shift) +def autokey_encipher(message, keyword): + """Encipher with the autokey cipher -def affine_cipher_letter(letter, multiplier, shift, one_based=True): - if letter in string.ascii_letters: - if letter in string.ascii_lowercase: - alphastart = ord('a') + >>> autokey_encipher('meetatthefountain', 'kilt') + 'wmpmmxxaeyhbryoca' + """ + shifts = [pos(l) for l in keyword + message] + pairs = zip(message, shifts) + return cat([caesar_encipher_letter(l, k) for l, k in pairs]) + +def autokey_decipher(ciphertext, keyword): + """Decipher with the autokey cipher + + >>> autokey_decipher('wmpmmxxaeyhbryoca', 'kilt') + 'meetatthefountain' + """ + plaintext = [] + keys = list(keyword) + for c in ciphertext: + plaintext_letter = caesar_decipher_letter(c, pos(keys[0])) + plaintext += [plaintext_letter] + keys = keys[1:] + [plaintext_letter] + return cat(plaintext) + + +class PocketEnigma(object): + """A pocket enigma machine + The wheel is internally represented as a 26-element list self.wheel_map, + where wheel_map[i] == j shows that the position i places on from the arrow + maps to the position j places on. + """ + def __init__(self, wheel=1, position='a'): + """initialise the pocket enigma, including which wheel to use and the + starting position of the wheel. + + The wheel is either 1 or 2 (the predefined wheels) or a list of letter + pairs. + + The position is the letter pointed to by the arrow on the wheel. + + >>> pe.wheel_map + [25, 4, 23, 10, 1, 7, 9, 5, 12, 6, 3, 17, 8, 14, 13, 21, 19, 11, 20, 16, 18, 15, 24, 2, 22, 0] + >>> pe.position + 0 + """ + self.wheel1 = [('a', 'z'), ('b', 'e'), ('c', 'x'), ('d', 'k'), + ('f', 'h'), ('g', 'j'), ('i', 'm'), ('l', 'r'), ('n', 'o'), + ('p', 'v'), ('q', 't'), ('s', 'u'), ('w', 'y')] + self.wheel2 = [('a', 'c'), ('b', 'd'), ('e', 'w'), ('f', 'i'), + ('g', 'p'), ('h', 'm'), ('j', 'k'), ('l', 'n'), ('o', 'q'), + ('r', 'z'), ('s', 'u'), ('t', 'v'), ('x', 'y')] + if wheel == 1: + self.make_wheel_map(self.wheel1) + elif wheel == 2: + self.make_wheel_map(self.wheel2) else: - alphastart = ord('A') - letter_number = ord(letter) - alphastart - if one_based: letter_number += 1 - enciphered_letter_number = letter_number * multiplier + shift - if one_based: enciphered_letter_number -=1 - enciphered_letter = chr(enciphered_letter_number % 26 + alphastart) - return enciphered_letter - else: - return letter - -def affine_decipher_letter(letter, multiplier, shift, one_based=True): - if letter in string.ascii_letters: + self.validate_wheel_spec(wheel) + self.make_wheel_map(wheel) + if position in string.ascii_lowercase: + self.position = pos(position) + else: + self.position = position + + def make_wheel_map(self, wheel_spec): + """Expands a wheel specification from a list of letter-letter pairs + into a full wheel_map. + + >>> pe.make_wheel_map(pe.wheel2) + [2, 3, 0, 1, 22, 8, 15, 12, 5, 10, 9, 13, 7, 11, 16, 6, 14, 25, 20, 21, 18, 19, 4, 24, 23, 17] + """ + self.validate_wheel_spec(wheel_spec) + self.wheel_map = [0] * 26 + for p in wheel_spec: + self.wheel_map[pos(p[0])] = pos(p[1]) + self.wheel_map[pos(p[1])] = pos(p[0]) + return self.wheel_map + + def validate_wheel_spec(self, wheel_spec): + """Validates that a wheel specificaiton will turn into a valid wheel + map. + + >>> pe.validate_wheel_spec([]) + Traceback (most recent call last): + ... + ValueError: Wheel specification has 0 pairs, requires 13 + >>> pe.validate_wheel_spec([('a', 'b', 'c')]*13) + Traceback (most recent call last): + ... + ValueError: Not all mappings in wheel specificationhave two elements + >>> pe.validate_wheel_spec([('a', 'b')]*13) + Traceback (most recent call last): + ... + ValueError: Wheel specification does not contain 26 letters + """ + if len(wheel_spec) != 13: + raise ValueError("Wheel specification has {} pairs, requires 13". + format(len(wheel_spec))) + for p in wheel_spec: + if len(p) != 2: + raise ValueError("Not all mappings in wheel specification" + "have two elements") + if len(set([p[0] for p in wheel_spec] + + [p[1] for p in wheel_spec])) != 26: + raise ValueError("Wheel specification does not contain 26 letters") + + def encipher_letter(self, letter): + """Enciphers a single letter, by advancing the wheel before looking up + the letter on the wheel. + + >>> pe.set_position('f') + 5 + >>> pe.encipher_letter('k') + 'h' + """ + self.advance() + return self.lookup(letter) + decipher_letter = encipher_letter + + def lookup(self, letter): + """Look up what a letter enciphers to, without turning the wheel. + + >>> pe.set_position('f') + 5 + >>> cat([pe.lookup(l) for l in string.ascii_lowercase]) + 'udhbfejcpgmokrliwntsayqzvx' + >>> pe.lookup('A') + '' + """ if letter in string.ascii_lowercase: - alphastart = ord('a') + return unpos( + (self.wheel_map[(pos(letter) - self.position) % 26] + + self.position)) else: - alphastart = ord('A') - letter_number = ord(letter) - alphastart - if one_based: letter_number +=1 - after_unshift = letter_number - shift - deciphered_letter_number = modular_division[after_unshift % 26][multiplier] - if one_based: deciphered_letter_number -=1 - deciphered_letter = chr(deciphered_letter_number % 26 + alphastart) - return deciphered_letter - else: - return letter - -def affine_cipher_message(message, multiplier, shift, one_based=True): - big_cipher = [affine_cipher_letter(l, multiplier, shift, one_based) for l in message] - return ''.join(big_cipher) - -def affine_decipher_message(message, multiplier, shift, one_based=True): - big_decipher = [affine_decipher_letter(l, multiplier, shift, one_based) for l in message] - return ''.join(big_decipher) - - -def caesar_break(message): - best_key = 0 - best_fit = float("inf") - for shift in range(26): - plaintxt = caesar_decipher_message(message, shift) - lettertxt = letter_frequencies(plaintxt) - total1 = scale_freq(lettertxt) - total2 = scale_freq(english_counts) - fit = value_diff(total2, total1) - if fit < best_fit: - best_key = shift - best_fit = fit - return best_key - -def affine_break(message): - best_key = (0, 0, 0) - best_fit = float("inf") - for multiplier in range(1, 26, 2): - for shift in range(26): - for one_based in [True, False]: - plaintxt = affine_decipher_message(message, multiplier, shift, one_based) - lettertxt = letter_frequencies(plaintxt) - total1 = scale_freq(lettertxt) - total2 = scale_freq(english_counts) - fit = value_diff(total2, total1)c - if fit < best_fit: - best_key = (multiplier, shift, one_based) - best_fit = fit - return best_key + return '' + + def advance(self): + """Advances the wheel one position. + + >>> pe.set_position('f') + 5 + >>> pe.advance() + 6 + """ + self.position = (self.position + 1) % 26 + return self.position + + def encipher(self, message, starting_position=None): + """Enciphers a whole message. + + >>> pe.set_position('f') + 5 + >>> pe.encipher('helloworld') + 'kjsglcjoqc' + >>> pe.set_position('f') + 5 + >>> pe.encipher('kjsglcjoqc') + 'helloworld' + >>> pe.encipher('helloworld', starting_position = 'x') + 'egrekthnnf' + """ + if starting_position: + self.set_position(starting_position) + transformed = '' + for l in message: + transformed += self.encipher_letter(l) + return transformed + decipher = encipher + + def set_position(self, position): + """Sets the position of the wheel, by specifying the letter the arrow + points to. + + >>> pe.set_position('a') + 0 + >>> pe.set_position('m') + 12 + >>> pe.set_position('z') + 25 + """ + self.position = pos(position) + return self.position + + +if __name__ == "__main__": + import doctest + doctest.testmod(extraglobs={'pe': PocketEnigma(1, 'a')})