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MadelineProto/ige.py
2015-03-14 01:21:27 +01:00

153 lines
8.3 KiB
Python

# -*- coding: utf-8 -*-
# THIS MODULE HAS ALL THE CONVERSIONS WE NEED! (I think)
from __future__ import print_function
from Crypto.Util import number
# trying to convert "automatically" input...
# tobytes() didnt work
# bstr() didnt work
# b() didnt work
# bord() didnt work (TypeError)
from Crypto.Cipher import AES
from sys import version_info
if version_info >= (3, 4, 0):
from binascii import hexlify
long = int
# Some color codes for printing
ENDC = '\033[0m' # To end a color
REDFAIL = '\033[91m' # RED
GREENOK = '\033[92m' # GREEN
def hex_string_to_str_bytes(val):
"""Given a String like
tmp_aes_key_str = "F011280887C7BB01DF0FC4E17830E0B91FBB8BE4B2267CB985AE25F33B527253"
Convert it to it's byte representation, stored in py2 in a str, like:
tmp_aes_key_hex = '\xf0\x11(\x08\x87\xc7\xbb\x01\xdf\x0f\xc4\xe1x0\xe0\xb9\x1f\xbb\x8b\xe4\xb2&|\xb9\x85\xae%\xf3;RrS'
"""
return val.decode("hex")
def str_bytes_to_hex_string(val):
"""Given a str_bytes (so str()) like
tmp_aes_key_hex = '\xf0\x11(\x08\x87\xc7\xbb\x01\xdf\x0f\xc4\xe1x0\xe0\xb9\x1f\xbb\x8b\xe4\xb2&|\xb9\x85\xae%\xf3;RrS'
Convert it back to it's uppercase string representation, like:
tmp_aes_key_str = "F011280887C7BB01DF0FC4E17830E0B91FBB8BE4B2267CB985AE25F33B527253" """
if version_info >= (3, 4, 0):
return str(hexlify(val).upper())
return val.encode("hex").upper()
def hex_string_to_long(val):
"""Given a String like
tmp_aes_key_str = "F011280887C7BB01DF0FC4E17830E0B91FBB8BE4B2267CB985AE25F33B527253"
Convert it to int, which is actually long"""
return int(val, 16)
def xor_strings(a, b): # xor two strings of different lengths
if version_info <= (3, 4, 0):
if len(a) > len(b):
return "".join([chr(ord(x) ^ ord(y)) for (x, y) in zip(a[:len(b)], b)])
else:
return "".join([chr(ord(x) ^ ord(y)) for (x, y) in zip(a, b[:len(a)])])
else:
return bytes(x ^ y for x, y in zip(a, b))
def ige(message, key, iv):
"""given a key, given an iv, and message, decrypt it."""
if type(message) == long:
message = number.long_to_bytes(message)
if type(key) == long:
key = number.long_to_bytes(key)
if type(iv) == long:
iv = number.long_to_bytes(iv)
cipher = AES.new(key, AES.MODE_ECB, iv)
blocksize = cipher.block_size
prev_x = iv[0:blocksize]
prev_y = iv[blocksize:] # len should be > 0
decrypted = None
for i in range(0, len(message), blocksize):
x = message[i:i+blocksize]
y = xor_strings(cipher.decrypt(xor_strings(x, prev_y)), prev_x)
prev_x = x
prev_y = y
# decrypted = sumBytes(decrypted, y);
if decrypted is None:
decrypted = y
else:
decrypted_ba = bytearray(decrypted)
decrypted_ba.extend(y)
if version_info >= (3, 4, 0):
decrypted = bytes(decrypted_ba)
else:
decrypted = str(decrypted_ba)
return decrypted
if __name__ == "__main__":
encrypted_answer_str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
tmp_aes_key_str = "F011280887C7BB01DF0FC4E17830E0B91FBB8BE4B2267CB985AE25F33B527253"
tmp_aes_iv_str = "3212D579EE35452ED23E0D0C92841AA7D31B2E9BDEF2151E80D15860311C85DB"
answer_str = "BA0D89B53E0549828CCA27E966B301A48FECE2FCA5CF4D33F4A11EA877BA4AA57390733002000000FE000100C71CAEB9C6B1C9048E6C522F70F13F73980D40238E3E21C14934D037563D930F48198A0AA7C14058229493D22530F4DBFA336F6E0AC925139543AED44CCE7C3720FD51F69458705AC68CD4FE6B6B13ABDC9746512969328454F18FAF8C595F642477FE96BB2A941D5BCD1D4AC8CC49880708FA9B378E3C4F3A9060BEE67CF9A4A4A695811051907E162753B56B0F6B410DBA74D8A84B2A14B3144E0EF1284754FD17ED950D5965B4B9DD46582DB1178D169C6BC465B0D6FF9CA3928FEF5B9AE4E418FC15E83EBEA0F87FA9FF5EED70050DED2849F47BF959D956850CE929851F0D8115F635B105EE2E4E15D04B2454BF6F4FADF034B10403119CD8E3B92FCC5BFE000100262AABA621CC4DF587DC94CF8252258C0B9337DFB47545A49CDD5C9B8EAE7236C6CADC40B24E88590F1CC2CC762EBF1CF11DCC0B393CAAD6CEE4EE5848001C73ACBB1D127E4CB93072AA3D1C8151B6FB6AA6124B7CD782EAF981BDCFCE9D7A00E423BD9D194E8AF78EF6501F415522E44522281C79D906DDB79C72E9C63D83FB2A940FF779DFB5F2FD786FB4AD71C9F08CF48758E534E9815F634F1E3A80A5E1C2AF210C5AB762755AD4B2126DFA61A77FA9DA967D65DFD0AFB5CDF26C4D4E1A88B180F4E0D0B45BA1484F95CB2712B50BF3F5968D9D55C99C0FB9FB67BFF56D7D4481B634514FBA3488C4CDA2FC0659990E8E868B28632875A9AA703BCDCE8FCB7AE551"
if version_info < (3, 4, 0):
# Crypto.Cipher.AES needs it's parameters to be 32byte str
# So we can either give 'str' type like this ONLY WORKS ON PYTHON2.7
encrypted_answer_hex = encrypted_answer_str.decode("hex")
tmp_aes_key_hex = tmp_aes_key_str.decode("hex")
tmp_aes_iv_hex = tmp_aes_iv_str.decode("hex")
answer_hex = answer_str.decode("hex")
decrypted_answer_in_str = ige(encrypted_answer_hex, tmp_aes_key_hex, tmp_aes_iv_hex)
print("decrypted_answer using string version of input: ")
print(decrypted_answer_in_str)
# Or give it long's representing the big numbers (ige will take care of the conversion)
encrypted_answer = int(encrypted_answer_str, 16)
tmp_aes_key = int(tmp_aes_key_str, 16)
tmp_aes_iv = int(tmp_aes_iv_str, 16)
answer = int(answer_str, 16)
decrypted_answer_in_int = ige(encrypted_answer, tmp_aes_key, tmp_aes_iv)
print("decrypted_answer using int version of input: ")
print(decrypted_answer_in_int)
if version_info < (3, 4, 0):
if decrypted_answer_in_str == decrypted_answer_in_int:
print("\nBoth str input and int input give the same result")
else:
print("\nDifferent result!!")
decrypt_ans_hex_str = str_bytes_to_hex_string(decrypted_answer_in_int)
print("Human friendly view of decrypted_answer:")
print(decrypt_ans_hex_str)
print("\nAnd we should expect inside of it:")
print(answer_str)
if answer_str in decrypt_ans_hex_str:
print("\n\nanswer_str is in decrypt_ans_hex_str!")
idx = decrypt_ans_hex_str.index(answer_str)
print(decrypt_ans_hex_str[:idx], end="")
print(GREENOK + decrypt_ans_hex_str[idx:idx+len(answer_str)] + ENDC, end="")
print(decrypt_ans_hex_str[idx+len(answer_str):])
print("There are " + str(idx/2) + " bytes at the start that are not part of the answer")
print("Plus " + str(len(decrypt_ans_hex_str[len(answer_str)+idx:]) / 2) + " at the end not forming part")
print("answer_str is: " + str(len(answer_str) / 2) + " bytes")
print("decrypt_ans_hex_str is: " + str(len(decrypt_ans_hex_str) / 2) + " bytes")
print("In total: " + str( (len(decrypt_ans_hex_str) - len(answer_str)) / 2) + " bytes that do not pertain")
else:
print("answer_str is not in decrypt_ans_hex_str :(")
print("This is because the header (SHA1(answer)) is included and is 20 bytes long.")
print("And in the end there are 0 to 15 bytes random to fill up the gap.")
print("This means that we can safely ignore the starting 20bytes and all the extra bytes in the end")
# answer_with_hash := SHA1(answer) + answer + (0-15 random bytes); such that the length be divisible by 16;
# This... divisible by 16 is because of the blocksize of AES-256-ECB (yay!)