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1 Commits
Author | SHA1 | Date |
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Naumkin Vladimir | f58c99f231 | 2 weeks ago |
@ -0,0 +1,92 @@
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import numpy as np
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import galois
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import random
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import getpass
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import hashlib
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import pyperclip
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def main():
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try:
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menu()
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except:
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print("Error!")
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def menu():
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core = McEliece_core()
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core.generate_keys(normalhash(getpass.getpass("Password: ")))
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pyperclip.copy(bytes(core.decrypt([int(i) for i in read_file("only_password")])).decode('utf-8'))
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print("OK!")
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class McEliece_core:
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def __init__(self):
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self._order = 256
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self._n = 255
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self._k = 210
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self._GF = galois.GF(2, 8, irreducible_poly = "x^8 + x^4 + x^3 + x^2 + 1", primitive_element = "x", verify = False)
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self._rs = galois.ReedSolomon(self._n, self._k, field = self._GF)
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self._G = self._GF.Zeros((self._k, self._n))
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self._S = self._GF.Zeros((self._k, self._k))
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self._S_inv = self._GF.Zeros((self._k, self._k))
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self._P = self._GF.Zeros((self._n, self._n))
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self._P_inv = self._GF.Zeros((self._n, self._n))
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self._p = [0 for i in range(self._n)]
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def generate_keys(self, seed):
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seed %= 2**32
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self._unsafe_generate_S(seed)
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self._unsafe_generate_P(seed)
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self._G = self._S @ self._rs.G @ self._P
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def decrypt(self, msg):
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try:
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msg = [msg[i - self._n : i] for i in range(self._n, len(msg) + self._n, self._n)]
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msg = [self._decrypt_one(self._GF(i)) for i in msg]
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return [i for j in msg for i in j]
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except:
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raise
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def _unsafe_generate_S(self, seed):
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pseudo = np.random.RandomState(seed)
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S = self._GF(pseudo.randint(0, self._order, (self._k, self._k)))
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while np.linalg.det(S) == 0:
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S = self._GF(pseudo.randint(0, self._order, (self._k, self._k)))
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self._S = S
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self._S_inv = np.linalg.inv(S)
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def _unsafe_generate_P(self, seed):
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pseudo = np.random.RandomState(seed)
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p = [i for i in range(self._n)]
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pseudo.shuffle(p)
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self._p = p
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self._P = self._GF.Zeros((self._n, self._n))
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self._P_inv = self._GF.Zeros((self._n, self._n))
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for i in range(self._n):
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self._P[i, p[i]] = 1
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self._P_inv[p[i], i] = 1
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def _decrypt_one(self, msg):
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msg = msg @ self._P_inv
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msg, e = self._rs.decode(msg, errors = True)
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if e == -1:
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raise Exception()
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msg = msg @ self._S_inv
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msg = [int(i) for i in msg]
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try:
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msg = self._unpad_message(msg)
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except:
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raise
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return msg
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def _unpad_message(self, msg):
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last_value = msg[-1]
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if last_value >= self._k or last_value <= 0:
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raise Exception()
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for i in range(1, last_value + 1):
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if msg[-i] != last_value:
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raise Exception()
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return msg[: -last_value]
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def read_file(name):
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with open(name, "rb") as f:
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data = f.read()
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return data
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def normalhash(s):
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return int(hashlib.sha256(bytearray(s, 'utf-8')).hexdigest(), 16)
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if __name__ == "__main__":
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main()
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Before Width: | Height: | Size: 15 KiB After Width: | Height: | Size: 15 KiB |
@ -0,0 +1,249 @@
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import numpy as np
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import galois
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import random
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import getpass
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import hashlib
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import pyperclip
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def main():
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try:
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menu()
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except:
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print("\nUnknown error (maybe ctrl+c), emergency exit!")
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def menu():
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info = "Menu numbers: h = info, t = test clipboard, c = config;\n0 = exit, 1 = generate, 2 = encrypt, 3 = decrypt\n"
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err = "Error, try again!\n"
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ok = "Operation successful.\n"
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inp = ['h', 'c', 't'] + [str(i) for i in range (4)] + ['1337']
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core = McEliece_core()
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print("\nMcEliece password encryption by vovuas2003.\n")
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print(info)
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while True:
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s = input("Menu number: ")
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while s not in inp:
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s = input("Wrong menu number; h = help: ")
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if s == '0':
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print("\nGood luck!")
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break
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elif s == 'h':
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print(info)
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elif s == 't':
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print("Do you want to check Python ability to use clipboard in your OS?")
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if(not get_yes_no()):
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continue
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try:
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print('Trying to write "Hello, world!" to clipboard.')
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mycopy("Hello, world!")
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print("Success! You can check ctrl+v.")
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except:
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print("Python cannot use clipboard. On Linux maybe you need to run command: sudo apt-get install xclip.\nOr try code below to check python error log:\nimport pyperclip #don't forget to pip install pyperclip\npyperclip.copy(\"Hello, world!\")")
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elif s == 'c':
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n, k = core.get_config()
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print("Default config is 255 210, current is " + str(n) + " " + str(k) + ". Change config? Also reset all keys!")
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if(not get_yes_no()):
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continue
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try:
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print("Config is two numbers n >= k >= 2; (3 * 5 * 17) mod n = 0. Larger values = larger keys.\nRandomly change (n - k) div 2 bytes during encryption, but add (n - k + 1) bytes to each chunk with len (k - 1).")
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n, k = map(int, input("Write n and k separated by a space: ").split())
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core.change_config(n, k)
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print(ok)
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except:
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print(err)
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elif s == '1':
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print("Reset all keys!")
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if(not get_yes_no()):
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continue
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try:
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core.generate_keys(normalhash(getpass.getpass("Password for hash: ")))
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print(ok)
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except:
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print(err)
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elif s == '2':
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print("Encrypt hided input (ONLY ONE LINE!!!) from clipboard!")
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if(not get_yes_no()):
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continue
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try:
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inp_str = getpass.getpass("Hided string to encrypt: ")
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out_name = input("Filename to save: ")
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if not out_name:
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print("Using default name ciphered_string.bin")
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out_name = "ciphered_string.bin"
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write_file(out_name, bytes(core.encrypt([int(i) for i in inp_str.encode('utf-8')])))
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print(ok)
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except:
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print(err)
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elif s == '3':
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print("Decrypt string from file and copy to clipboard!")
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if(not get_yes_no()):
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continue
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try:
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inp_name = input("Filename to decrypt: ")
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if not inp_name:
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print("Using default name ciphered_string.bin")
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inp_name = "ciphered_string.bin"
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mycopy(bytes(core.decrypt([int(i) for i in read_file(inp_name)])).decode('utf-8'))
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print(ok)
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except:
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print(err)
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elif s == '1337':
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mycopy(PT())
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else:
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print("Impossible behaviour, mistake in source code, emergency exit!\nThe string allowed in the inp array is not bound to the call of any function!")
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break
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class McEliece_core:
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def __init__(self):
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self._order = 256
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self._n = 255
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self._k = 210
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self._t = (self._n - self._k) // 2
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self._GF = galois.GF(2, 8, irreducible_poly = "x^8 + x^4 + x^3 + x^2 + 1", primitive_element = "x", verify = False)
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self._rs = galois.ReedSolomon(self._n, self._k, field = self._GF)
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self._G = self._GF.Zeros((self._k, self._n))
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self._S = self._GF.Zeros((self._k, self._k))
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self._S_inv = self._GF.Zeros((self._k, self._k))
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self._P = self._GF.Zeros((self._n, self._n))
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self._P_inv = self._GF.Zeros((self._n, self._n))
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self._p = [0 for i in range(self._n)]
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def change_config(self, n, k):
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try:
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if k < 2:
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raise Exception()
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rs = galois.ReedSolomon(n, k, field = self._GF)
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except:
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raise
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else:
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self._n = n
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self._k = k
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self._t = (n - k) // 2
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self._rs = rs
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self._G = self._GF.Zeros((self._k, self._n))
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self._S = self._GF.Zeros((self._k, self._k))
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self._S_inv = self._GF.Zeros((self._k, self._k))
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self._P = self._GF.Zeros((self._n, self._n))
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self._P_inv = self._GF.Zeros((self._n, self._n))
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self._p = [0 for i in range(self._n)]
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def get_config(self):
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return self._n, self._k
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def generate_keys(self, seed):
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seed %= 2**32
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self._unsafe_generate_S(seed)
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self._unsafe_generate_P(seed)
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self._G = self._S @ self._rs.G @ self._P
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def encrypt(self, text):
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try:
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out = []
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while len(text) > self._k - 1:
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tmp = text[: self._k - 1]
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text = text[self._k - 1 :]
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out += self._encrypt_one(tmp)
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out += self._encrypt_one(text)
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return out
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except:
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raise
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def decrypt(self, msg):
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try:
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msg = [msg[i - self._n : i] for i in range(self._n, len(msg) + self._n, self._n)]
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msg = [self._decrypt_one(self._GF(i)) for i in msg]
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return [i for j in msg for i in j]
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except:
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raise
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def _unsafe_generate_S(self, seed):
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pseudo = np.random.RandomState(seed)
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S = self._GF(pseudo.randint(0, self._order, (self._k, self._k)))
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while np.linalg.det(S) == 0:
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S = self._GF(pseudo.randint(0, self._order, (self._k, self._k)))
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self._S = S
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self._S_inv = np.linalg.inv(S)
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def _unsafe_generate_P(self, seed):
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pseudo = np.random.RandomState(seed)
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p = [i for i in range(self._n)]
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pseudo.shuffle(p)
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self._p = p
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self._P = self._GF.Zeros((self._n, self._n))
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self._P_inv = self._GF.Zeros((self._n, self._n))
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for i in range(self._n):
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self._P[i, p[i]] = 1
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self._P_inv[p[i], i] = 1
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def _encrypt_one(self, text):
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msg = self._pad_message(text)
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m = self._GF(msg)
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c = m.T @ self._G
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z = np.zeros(self._n, dtype = int)
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p = [i for i in range(self._n)]
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for i in range(self._t):
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ind = p.pop(random.randint(0, self._n - 1 - i))
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z[ind] = random.randint(1, self._order - 1)
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c = c + self._GF(z)
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return [int(i) for i in c]
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def _decrypt_one(self, msg):
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msg = msg @ self._P_inv
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msg, e = self._rs.decode(msg, errors = True)
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if e == -1:
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raise Exception()
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msg = msg @ self._S_inv
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msg = [int(i) for i in msg]
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try:
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msg = self._unpad_message(msg)
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except:
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raise
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return msg
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def _pad_message(self, msg):
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last_value = self._k - (len(msg) % self._k)
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return msg + [last_value] * last_value
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def _unpad_message(self, msg):
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last_value = msg[-1]
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if last_value >= self._k or last_value <= 0:
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raise Exception()
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for i in range(1, last_value + 1):
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if msg[-i] != last_value:
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raise Exception()
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return msg[: -last_value]
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def write_file(name, data):
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with open(name, "wb") as f:
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f.write(data)
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def read_file(name):
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with open(name, "rb") as f:
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data = f.read()
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return data
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def get_yes_no():
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s = input("Confirm (0 = go back, 1 = continue): ")
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while s not in ['0', '1']:
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s = input("Try again, 0 or 1: ")
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return int(s)
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def normalhash(s):
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return int(hashlib.sha256(bytearray(s, 'utf-8')).hexdigest(), 16)
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def PT(m = -3, M = 3):
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if m == 0 or abs(m) > M:
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return "PT!"
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s = "PT!"
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p = " "
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f = False
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if m < 0:
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s, p = p, s
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m *= -1
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f = True
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out = "\n"
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if f:
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out += p * (10 * m + 1) + "\n"
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out += p + (s * 3 + p + s * 3 + p + s + p) * m + "\n"
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out += p + (s + p + s + p * 2 + s + p * 2 + s + p) * m + "\n"
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out += p + (s * 3 + p * 2 + s + p * 2 + s + p) * m + "\n"
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out += p + (s + p * 4 + s + p * 4) * m + "\n"
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out += p + (s + p * 4 + s + p * 2 + s + p) * m + "\n"
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if f:
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out += p * (10 * m + 1) + "\n"
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out += "\n"
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return out
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def mycopy(s):
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pyperclip.copy(s)
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if __name__ == "__main__":
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main()
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@ -1,15 +1,5 @@
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McEliece cryptosystem implementation by vovuas2003
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Required Python libraries: numpy, galois.
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Required additional Python libraries: numpy, galois (numpy extension).
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UPDATE: version 2 is available. Check cryptosystem_core_v2 and McEliece_console_v2.
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All cryptosystem functions are implemented in cryptosystem_core.py, just import it into your project and enjoy!
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For example, I coded a console menu (that works with text in txt files and also with any files in binary mode) and a GUI app (for text encryption).
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It is possible to build portable exe with pyinstaller and run code on a computer that does not have Python installed.
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But it is NOT compilation, so exe file will be quite large.
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The pdf presentation in Russian contains a bit of theory about the Mceliece cryptosystem.
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icon.ico is an optional file for pyinstaller
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old_portable.py can support another order of galois field, but saves raw integers and does not specify utf-8 encoding for strings and txt files
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Version 2 is the latest. Check cryptosystem_core_v2 and McEliece_console_v2.
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