Exemplo n.º 1
0
 def test_encrypt(self):
     """Tests encrypt function for Playfair cipher"""
     password = '******'
     self.assertEqual(Playfair.encrypt(ALPHABET, password),
             'BIHCFGFYSAKEUCANQSATLZWXWBUZ')
     with self.assertRaises(Playfair.PlayfairError):
         Playfair.encrypt(521, password)
     with self.assertRaises(Playfair.PlayfairError):
         Playfair.encrypt(ALPHABET, range(5))
Exemplo n.º 2
0
 def test_generate_grid(self):
     """Tests grid generation for Playfair Cipher
     """
     monarchy_grid = {
 'A': (0, 3), 'B': (1, 3), 'C': (1, 0), 'D': (1, 4), 'E': (2, 0),
 'F': (2, 1), 'G': (2, 2), 'H': (1, 1), 'I': (2, 3), 'K': (2, 4),
 'L': (3, 0), 'M': (0, 0), 'N': (0, 2), 'O': (0, 1), 'P': (3, 1),
 'Q': (3, 2), 'R': (0, 4), 'S': (3, 3), 'T': (3, 4), 'U': (4, 0),
 'V': (4, 1), 'W': (4, 2), 'X': (4, 3), 'Y': (1, 2), 'Z': (4, 4)}
     self.assertEqual(Playfair.generate_grid('monarchy')[0], monarchy_grid)
     grid, rev_grid = Playfair.generate_grid('monarchy')
     self.assertEqual([rev_grid[value] == key for key, value
              in grid.iteritems()], [True] * 25)
Exemplo n.º 3
0
def playfair_menu():
    while True:
        print("-----Playfair密码-----")
        print("请选择你要进行的操作:")
        print("1.Playfair密码简介")
        print("2.Playfair密码加密")
        print("3.Playfair密码解密")
        print("4.返回上一级")
        crypto_operating = input("->")
        if crypto_operating == '1':
            Playfair.playfair_info()
        elif crypto_operating == '2':
            print("-----------------Playfair密码加密---------------")
            print("[Input]请输入您的明文:(加密结束后会丢失大小写与空格)")
            plain_text = input()
            print("[Input]请输入您的密钥:")
            key = input()
            print("[Info]加密正在进行。。。")
            try:
                enc_text = Playfair.playfair_encrypt(plain_text, key)
                print("[Success]加密成功!")
                print("[Info]密文为:" + enc_text)
            except BaseException as e:
                print("[ERROR]加密失败!")
                if EXE_MODE == 'DEBUG':
                    print(e)
                pass
        elif crypto_operating == '3':
            print("-----------------Playfair密码解密---------------")
            print("[Input]请输入您的密文:")
            enc_text = input()
            print("[Input]请输入您的密钥:")
            key = input()
            print("[Info]解密正在进行。。。")
            try:
                info = Playfair.playfair_decrypt(enc_text, key)
                if info == 40001:
                    print("[ERROR]解密失败!")
                    print("[ERR_info]请检查密文长度!密文必须为偶长度!")
                else:
                    print("[Success]解密成功!(大小写与空格需要自行根据语义恢复)")
                    print("[Info]明文为:" + info)
            except BaseException as e:
                print("[ERROR]解密失败!")
                if EXE_MODE == 'DEBUG':
                    print(e)
                pass
        elif crypto_operating == '4':
            return
        else:
            print("[ERROR]选择出错!")
Exemplo n.º 4
0
def main():
    print()
    cipher = None

    # Determine which type of cipher
    if cipher_name == 'PLF':
        cipher = Playfair()
    elif cipher_name == 'RTS':
        cipher = RowTransposition()
    elif cipher_name == 'RFC' or cipher_name == 'CES':
        try:
            shift_amt = int(key)
        except ValueError:
            print("ERR: Please enter a number as the key for a Caesar/Railfence cipher!\n")
            return
        cipher = Railfence() if cipher_name == 'RFC' else Caesar()
    elif cipher_name == 'VIG':
        cipher = Vigenere()
    else:
        print("ERR: Not a valid cipher type! Please use:")
        print("\tPLF, RTS, RFC, VIG, or CES\n")
        return
    
    # Set the key
    if not cipher.setKey(key):
        print("ERR: Invalid key, try again.\n")
        return

    inFile = None
    outFile = None
    
    # Attempt to read in the text the user wants to encrypt/decrypt
    try:
        inFile = open(input_file, "r")
    except FileNotFoundError:
        print("ERR: '", input_file, "' cannot be opened! Try a valid file\n")
        return

    outFile = open(output_file, 'w')
    
    # Perfrom the encryption/decryption
    if method == "ENC":
        plaintext = inFile.read()
        ciphertext = cipher.encrypt(plaintext)
        outFile.write(ciphertext)
        print("Encryption was successfull!")

    elif method == "DEC":
        ciphertext = inFile.read()
        plaintext = cipher.decrypt(ciphertext)
        outFile.write(plaintext)
        print("Decryption was successfull!")

    else:
        print("ERR: Incorrect method. Please enter 'ENC' or 'DEC'\n")
        return

    print("Thank you for using this program.\n")
def main():
    parser = argparse.ArgumentParser(
        description='Encrypt or decrpyt a message using Playfair Cipher')
    parser.add_argument('-k',
                        default="None",
                        help="The keyword to be used in the cipher")
    args = parser.parse_args()
    if args.k == 'None':
        keyword = input("What is your keyword?: ")
    else:
        keyword = args.k

    cipher = Playfair.Playfair(keyword)

    option = input("Would you like to encrypt or decrypt a message?: ")
    message = input("What is the message you would like to " + option + "?: ")

    if option == 'encrypt' or option == 'Encrypt' or option[0] == 'e':
        splitMessage = cipher.splitMessage(message)
        newMessage = cipher.encrypt(splitMessage)
    if option == 'decrypt' or option == 'Decrypt' or option[0] == 'd':
        newMessage = cipher.decrypt(message)

    print("Here is your " + option + "ed message:")
    print(newMessage)
Exemplo n.º 6
0
 def test_check_padding(self):
     """Tests check_padding function for Playfair cipher
     """
     self.assertEqual(Playfair.check_padding('i', 'double'), 'I')
     self.assertEqual(Playfair.check_padding('j', 'double'), 'I')
     with self.assertRaises(Playfair.PlayfairError):
         Playfair.check_padding(5, 'end')
     with self.assertRaises(Playfair.PlayfairError):
         Playfair.check_padding('ab', 'end')
     with self.assertRaises(Playfair.PlayfairError):
         Playfair.check_padding('5', 'end')
Exemplo n.º 7
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    def testWikipediaExample(self):
        wikiCipher = Playfair.Playfair("playfair example")
        message = "Hide the gold in the tree stump"
        expectedSplit = "hi de th eg ol di nt he tr ex es tu mp"
        actualSplit = wikiCipher.splitMessage(message)

        self.assertEqual(actualSplit, expectedSplit)

        expectedEncryption = "BM OD ZB XD NA BE KU DM UI XM MO UV IF"
        actualEncryption = wikiCipher.encrypt(actualSplit)

        self.assertEqual(actualEncryption, expectedEncryption)
Exemplo n.º 8
0
 def test_decrypt(self):
     """Tests decrypt function for Playfair cipher
     """
     password = '******'
     self.assertEqual(Playfair.decrypt(Playfair.encrypt(ALPHABET, password),
          password), ALPHABET[:9] + 'XI' + ALPHABET[10:] + 'X')
     with self.assertRaises(Playfair.PlayfairError):
         Playfair.decrypt(521, password)
     with self.assertRaises(Playfair.PlayfairError):
         Playfair.decrypt(ALPHABET, range(5))
Exemplo n.º 9
0
def handle_input(cipher, key, in_file, out_file, mode):
    # Standardize the cipher
    the_cipher = cipher.lower()

    # Try to open files specified
    try:
        input_file = open(in_file, "r")
        output_file = open(out_file, "w")

        text = input_file.read()
        input_file.close()
    except IOError:
        # If there was an error opening the file, abort
        print("Error opening file")
        return

    # Execute Caesar cipher
    if the_cipher == "caesar":
        CIPHER = Caesar.Caesar()

        if CIPHER.set_key(key):
            if mode == "e":
                print("Using Caesar cipher to encrypt: {}".format(in_file))
                encrypt = CIPHER.encrypt(text)
                output_file.write(encrypt)

            elif mode == "d":
                print("Using Caesar cipher to decrypt: {}".format(out_file))
                decrypt = CIPHER.decrpyt(text)
                output_file.write(decrypt)

            output_file.close()
        else:
            print("Key: \"{}\" is not a valid key.\n "
                  "No encryption will occur.".format(key))

    # Execute Playfair cipher
    elif the_cipher == "playfair":
        CIPHER = Playfair.Playfair()

        if CIPHER.set_key(key):
            CIPHER.construct_key_matrix(key)
            if mode == "e":
                print("Using Playfair cipher to encrypt: {}".format(in_file))
                encrypt = CIPHER.encrypt(text)
                output_file.write(encrypt)

            elif mode == "d":
                print("Using Playfair cipher to decrypt: {}".format(out_file))
                decrypt = CIPHER.decrpyt(text)
                output_file.write(decrypt)

            output_file.close()
        else:
            print("Key: \"{}\" is not a valid key.\n "
                  "No encryption will occur.".format(key))

    # Execute Railfence cipher
    elif the_cipher == "railfence":
        CIPHER = Railfence.Railfence()

        if CIPHER.set_key(key):
            if mode == "e":
                print("Using Railfence cipher to encrypt: {}".format(in_file))
                encrypt = CIPHER.encrypt(text)
                output_file.write(encrypt)

            elif mode == "d":
                print("Using Railfence cipher to decrypt: {}".format(out_file))
                decrypt = CIPHER.decrpyt(text)
                output_file.write(decrypt)

            output_file.close()
        else:
            print("Key: \"{}\" is not a valid key.\n "
                  "No encryption will occur.".format(key))

    # Execute Row Transposition cipher
    elif the_cipher == "rowtransposition":
        CIPHER = RowTransposition.RowTransposition()

        if CIPHER.set_key(key):
            if mode == "e":
                print("Using Row Transposition cipher to encrypt: {}".format(
                    in_file))
                encrypt = CIPHER.encrypt(text)
                output_file.write(encrypt)

            elif mode == "d":
                print("Using Row Transposition cipher to decrypt: {}".format(
                    out_file))
                decrypt = CIPHER.decrpyt(text)
                output_file.write(decrypt)

            output_file.close()
        else:
            print("Key: \"{}\" is not a valid key.\n "
                  "No encryption will occur.".format(key))

    # Execute Vigenre cipher
    elif the_cipher == "vigenre":
        CIPHER = Vigenre.Vigenre()

        if CIPHER.set_key(key):
            CIPHER.build_rows()
            if mode == "e":
                print("Using Vigenre cipher to encrypt: {}".format(in_file))
                encrypt = CIPHER.encrypt(text)
                output_file.write(encrypt)

            elif mode == "d":
                print("Using Vigenre cipher to decrypt: {}".format(out_file))
                decrypt = CIPHER.decrpyt(text)
                output_file.write(decrypt)

            output_file.close()
        else:
            print("Key: \"{}\" is not a valid key.\n "
                  "No encryption will occur.".format(key))

    # User didn't enter a correct cipher
    else:
        print("Unknown cipher entered...")
Exemplo n.º 10
0
 def setUp(self):
     self.cipher = Playfair.Playfair(self.keyword)
Exemplo n.º 11
0
# Make sure we have enough arguments, if not print the help message
if len(sys.argv) < 5:
	parser.print_help()
	sys.exit(1)

# Actually parse the arguments
arguments = parser.parse_args()


cipher = CipherInterface()

assert arguments.cipher in valid_ciphers, "Cipher not recognized. Use --help for more info."

# set cipher to specified cipher
if(arguments.cipher == "PLF"):
	cipher = Playfair()
elif(arguments.cipher == "RTS"):
	cipher = RowTransposition()
elif(arguments.cipher == "RFC"):
	cipher = Railfence()
elif(arguments.cipher == "VIG"):
	cipher = Vigenre()
elif(arguments.cipher == "CES"):
	cipher = Caesar()
elif(arguments.cipher == "HIL"):
	cipher = Hill()
elif(arguments.cipher == "EGM"):
	cipher = Enigma()

# Normalize and set the cipher key
if arguments.cipher in ["VIG", "PLF", "EGM", "HIL"]:
Exemplo n.º 12
0
#Main program

import sys
import Caesar
import RailFence
import Row_Transposition
import Playfair
import Vigenere

#Checking user input
if len(sys.argv) < 6:
    print("You are missing arguments, check your input.")
else:
    #Playfair Cipher
    if str(sys.argv[1]) == 'PLF':
        cipher_type = Playfair.Playfair()
    #Row_Transposition Cipher
    elif str(sys.argv[1]) == 'RTS':
        cipher_type = Row_Transposition.Row_Transposition()
    #RailFence Cipher
    elif str(sys.argv[1]) == 'RFC':
        cipher_type = RailFence.Railfence()
    #Vigenere Cipher
    elif str(sys.argv[1]) == 'VIG':
        cipher_type = Vigenere.Vigenere()
    #Caesar Cipher
    elif str(sys.argv[1]) == 'CES':
        cipher_type = Caesar.Caesar()
    #Invalid Input
    else:
        print("Unrecognized cipher type, check your spelling and try again.")