Пример #1
0
def affineDecrypt():
    text = request.form["affine-decrypt"]
    m = int(request.form["multKeyAffineDec"])
    a = int(request.form["addKeyAffineDec"])
    key = [m, a]
    sending = decrypt(text, key)
    return render_template(affineHTML, decrypted=sending)
Пример #2
0
def crackAffine(raw_text):
    stats = []  #will hold the error statistics
    alphabeta = []  #track the alpha beta combinations
    for a in xrange(26):
        if affine.verifyAlpha(a):
            for b in xrange(26):
                text = affine.decrypt(raw_text, a,
                                      b)  #decrypt the text with all options

                #count the number of occurances of each unique letter
                letter_count = {}
                for i in xrange(len(text)):
                    if text[i] in letter_count.keys():
                        letter_count[text[i]] += 1
                    elif text[i] not in letter_count.keys():
                        letter_count[text[i]] = 1

                #calculate the frequency of the letters
                letter_freq = {}
                for key in letter_count.keys():
                    letter_freq[key] = round(
                        float(letter_count[key]) / len(text) * 100, 5)

                #count the number of occurances of digrams in the text
                digram_count = {}
                n = 0
                while n < len(text):
                    if text[n:n + 2] in digram_count.keys():
                        digram_count[text[n:n + 2]] += 1
                    elif text[n:n + 2] not in digram_count.keys():
                        digram_count[text[n:n + 2]] = 1
                    n += 2

                #calculate the frequency of the digrams
                digram_freq = {}
                for key in digram_count.keys():
                    digram_freq[key] = round(
                        float(digram_count[key]) / len(text) / 2 * 100, 5)

                #calculate errors
                monogram_error = round(
                    meanSquaredError(monogram_freq, letter_freq), 5)
                digram_error = round(
                    meanSquaredError(bigram_freq, digram_freq), 5)

                print "a =", a, "b =", b, (monogram_error + digram_error) / 2
                stats.append((monogram_error + digram_error) / 2)
                alphabeta.append((a, b))

    #make a prediction about what values were used to encrypt the text
    predicted_index, predicted_min = findMinOfList(stats)
    print "Predicted Alpha =", alphabeta[predicted_index][
        0], "Predicted Beta =", alphabeta[predicted_index][
            1], "Error:", predicted_min
Пример #3
0
def Affine():
  scroll = False
  msg = ''
  output = ''
  set1 = 'opt1'
  set2 = 'opt4'
  a = '1'
  b = '0'
  if request.method == 'POST':
    scroll = 'out'
    task = request.form.get('task')
    msg = request.form.get('original-text')
    set1 = request.form.get('set1')
    set2 = request.form.get('set2')
    a = request.form.get('value-of-a')
    b = request.form.get('value-of-b')
    if task == 'encrypt':
      output = affine.encrypt(msg, int(a), int(b))
      if set1 == 'opt1':
        pass
      elif set1 == 'opt2':
        output = removeAllSpecialCharactersExcludingSpaces(output)
      elif set1 == 'opt3':
        output = removeAllSpecialCharactersIncludingSpaces(output)
    elif task == 'decrypt':
      output = affine.decrypt(msg, int(a), int(b))
      if set1 == 'opt1':
        pass
      elif set1 == 'opt2':
        output = removeAllSpecialCharactersExcludingSpaces(output)
      elif set1 == 'opt3':
        output = removeAllSpecialCharactersIncludingSpaces(output)
    if set2 == 'opt4':
        pass
    elif set2 == 'opt5':
      output = output.upper()
    elif set2 == 'opt6':
      output = output.lower()
  print(scroll)
  return render_template('affine.html', title='Affine Cipher', msg=msg, output=output, set1=set1, set2=set2, a=a, b=b, scroll=scroll)
Пример #4
0
def decrypt(ciphertext):
        return affine.decrypt(25, 25, ciphertext)
Пример #5
0
def fetch(entries):
    # for entry in entries:
    #     field = entry[0]
    #     text  = entry[1].get()
    #     print('%s: "%s"' % (field, text))
    # print(getKey(entries), getText(entries), entries[0][1].get(), entries[3][1].get())

    res = ""

    if (entries[2][1].get() == "Vigenere Cipher"):
        if (entries[1][1].get() == "Encrypt"):
            res = vigenere.encryptStandard(getText(entries),
                                           getKey(entries)[0][0])
        elif (entries[1][1].get() == "Decrypt"):
            res = vigenere.decryptStandard(getText(entries),
                                           getKey(entries)[0][0])

    elif (entries[2][1].get() == "Full Vigenere Cipher"):
        if (entries[1][1].get() == "Encrypt"):
            res = vigenere.encryptFull(getText(entries),
                                       getKey(entries)[0][0],
                                       int(getKey(entries)[1][0]))
        elif (entries[1][1].get() == "Decrypt"):
            res = vigenere.decryptFull(getText(entries),
                                       getKey(entries)[0][0],
                                       int(getKey(entries)[1][0]))

    elif (entries[2][1].get() == "Auto Vigenere Cipher"):
        if (entries[1][1].get() == "Encrypt"):
            res = vigenere.encryptAutoKey(getText(entries),
                                          getKey(entries)[0][0])
        elif (entries[1][1].get() == "Decrypt"):
            res = vigenere.decryptAutoKey(getText(entries),
                                          getKey(entries)[0][0])

    elif (entries[2][1].get() == "Extended Vigenere Cipher"):
        if (entries[1][1].get() == "Encrypt"):
            res = vigenere.encryptExtended(getText(entries),
                                           getKey(entries)[0][0])
        elif (entries[1][1].get() == "Decrypt"):
            res = vigenere.decryptExtended(getText(entries),
                                           getKey(entries)[0][0])

    elif (entries[2][1].get() == "Playfair Cipher"):
        if (entries[1][1].get() == "Encrypt"):
            res = playfair.encrypt(getText(entries), getKey(entries))
        elif (entries[1][1].get() == "Decrypt"):
            res = playfair.decrypt(getText(entries), getKey(entries))

    elif (entries[2][1].get() == "Super Enkripsi"):
        if (entries[1][1].get() == "Encrypt"):
            res = supere.encrypt(getText(entries), getKey(entries)[0][0])
        elif (entries[1][1].get() == "Decrypt"):
            res = supere.decrypt(getText(entries), getKey(entries)[0][0])

    elif (entries[2][1].get() == "Affine Cipher"):
        if (entries[1][1].get() == "Encrypt"):
            res = affine.encrypt(getText(entries), int(getKey(entries)[0][0]),
                                 int(getKey(entries)[1][0]))
        elif (entries[1][1].get() == "Decrypt"):
            res = affine.decrypt(getText(entries), int(getKey(entries)[0][0]),
                                 int(getKey(entries)[1][0]))

    elif (entries[2][1].get() == "Hill Cipher"):
        if (entries[1][1].get() == "Encrypt"):
            res = hill.encrypt(getText(entries), getKey(entries))
        elif (entries[1][1].get() == "Decrypt"):
            res = hill.decrypt(getText(entries), getKey(entries))

    printResult(res)
Пример #6
0
def  main(): 
    parser = argparse.ArgumentParser(description='Image encriprition tool Uses the affine cipher or the Tiny Encryption Algorithm. Can also display ppm images for convenience.')
    parser.add_argument('image', help='Path to PPM image to be processed.')
    parser.add_argument('output', help='Output path to the result.')
    parser.add_argument('-e', '--encrypt', action="count", help='Set to encription mode.')
    parser.add_argument('-d', '--decrypt', action="count", help='Set to decription mode.')
    parser.add_argument('--cipher', required=True, type=str, choices=['affine', 'tea', 'none'], default='none', help='''Sets the cipher to be used by the program. If 'none' is chosen, the specified image will be displayed. Defaults to 'none'.''')
    args = parser.parse_args()

    if(args.encrypt == 0 and args.decrypt == 0 and args.cipher != 'none'):
        print('You have to either set decrypt or encrypt on to run the script.')
        parser.print_help()
        return
    elif(args.encrypt == 0 and args.decrypt == 0):
        print("You can't set both modes on.")
        parser.print_help()
        return

 
    image = Image.open(args.image)

    imData = image.getdata()

    if(args.cipher != 'none'):
        pixelData = []
        for pixel in list(imData):
            pixelData.append(list(pixel))

        result = []

    if args.cipher == 'affine':
        ''' Affine cipher call '''
        if(args.encrypt):
            print('Insert keys "a" and "b", respectively.')
            keyA = int(input('Key "a": '))
            keyB = int(input('Key "b": '))
            if not affine.checkKeys(keyA, keyB):
                print('Invalid keys, try again.')
                keyA = int(input('Key "a": '))
                keyB = int(input('Key "b": '))

            print('Starting encription...')
            result = affine.encrypt(pixelData, keyA, keyB)
            print('Encription successfull.')
        elif(args.decrypt):
            print('Insert keys "a" and "b", respectively.')
            keyA = int(input('Key "a": '))
            keyB = int(input('Key "b": '))
            if not affine.checkKeys(keyA, keyB):
                print('Invalid keys, try again.')
                keyA = int(input('Key "a": '))
                keyB = int(input('Key "b": '))

            print('Starting decription...')
            result = affine.decrypt(pixelData, keyA, keyB)
            print('Decription successfull.')

    elif args.cipher == 'tea':
        '''TEA cipher call'''

        key = []

        print('Insert the four parts of the key in hexadecimal (32 bits, e.g.: 0x943abc12).')
        for i in range(4):
            keypart = input("Part [" + str(i) + "]: 0x" )
            try:
                decimal = int(keypart, 16)
                key.append(decimal)
            except:
                print('Invalid value, try again.')
                i = i - 1

        mode = input("Enter the mode of operation ('ecb'/'cfb'): ")


        if(args.encrypt):      
            print('Starting encription...')
            if(mode == 'ecb'):
                result = tea.encrypt_ECB(pixelData, key)
            elif(mode == 'cfb'):
                result = tea.encrypt_CFB(pixelData, key)
            print('Encription successfull.')

        elif(args.decrypt):
            print('Starting decription...')
            if(mode == 'ecb'):
                result = tea.decrypt_ECB(pixelData, key)
            elif(mode == 'cfb'):
                result = tea.decrypt_CFB(pixelData, key)
            print('Decription successfull.')

    elif args.cipher == 'none':
        '''Just shows image and exits'''
        image.show()
        return

    #print(str(result))

    print('Saving image as ' + args.output + '...')
    resultImage = Image.new(image.mode, image.size)
    resultImage.putdata(result)
    resultImage.show()

    if(args.encrypt):
        resultImage.save(args.output)
    elif(args.decrypt):
        resultImage.save(args.output)
    
    print('Image saved as ' + args.output + '...')
    return