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trying to decrypt, this IGE is not implemented in python anywhere

This commit is contained in:
Sammy Pfeiffer 2015-03-13 22:01:19 +01:00
parent 0c6aa6f2fe
commit a7d0b8c378
3 changed files with 230 additions and 20 deletions

3
ige.js Normal file
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/**
* Created by sam on 13/03/15.
*/

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# -*- coding: utf-8 -*-
# Inspiration: http://passingcuriosity.com/2009/aes-encryption-in-python-with-m2crypto/
# sudo apt-get install swig
# sudo pip install M2Crypto
def vis(bs):
"""
Function to visualize byte streams. Split into bytes, print to console.
:param bs: BYTE STRING
"""
bs = bytearray(bs)
symbols_in_one_line = 8
n = len(bs) // symbols_in_one_line
for i in range(n):
print(str(i*symbols_in_one_line)+" | "+" ".join(["%02X" % b for b in bs[i*symbols_in_one_line:(i+1)*symbols_in_one_line]])) # for every 8 symbols line
if not len(bs) % symbols_in_one_line == 0:
print(str((i+1)*symbols_in_one_line)+" | "+" ".join(["%02X" % b for b in bs[(i+1)*symbols_in_one_line:]])+"\n") # for last line
# Got from https://core.telegram.org/mtproto/samples-auth_key#conversion-of-encrypted-answer-into-answer
# They say they use AES 256 IGE
# Infinite Garble Extension (IGE) is a block cipher mode. (http://www.links.org/files/openssl-ige.pdf)
encrypted_answer_str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
tmp_aes_key_str = "F011280887C7BB01DF0FC4E17830E0B91FBB8BE4B2267CB985AE25F33B527253"
tmp_aes_iv_str = "3212D579EE35452ED23E0D0C92841AA7D31B2E9BDEF2151E80D15860311C85DB"
answer_str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
# Convert them to strings
# http://stackoverflow.com/questions/5649407/hexadecimal-string-to-byte-array-in-python
encrypted_answer = encrypted_answer_str.decode("hex") # int(encrypted_answer_str, 16) for py3
tmp_aes_key = tmp_aes_key_str.decode("hex")
tmp_aes_iv = tmp_aes_iv_str.decode("hex")
answer = answer_str.decode("hex")
print("len(encrypted_answer): " + str(len(encrypted_answer)))
print("len(answer): " + str(len(answer)))
# Got from testing.py
encrypted_answer = 'L\xd7\xddI\x0b\xc3\xeay\xf1\x07]\x93\x7fY\x0cmVAX\x03\xeb\n}\x99\xd6\x99\xaa\xba\x05\x9d\xaaB\xe2\x97\xb3\xf2\xf8\xd8\x9f\xa6\x13\x177a\xb45A\x0f}\xb3\x99\xa3D?L\x94\xa3\xbcG\xe8\xf2\x14 \xb9.\x8b\xa0\xf1\xa5\xf1\x18\x9aZ2\x8f\xae\x05\xd9\x84H\xa3&\xad\x84\x82w\x9e\xe8\xba\x8a\x87QT\xdd\x12\x8c\x86\xde\xd8\x7fLM\xb9\x81H;JX\x85\x14\x1af!\xb20\xea)\xa8>(\xa9\xce5,\x96\x14\xd7P\x0c\xb3\x02\x9a\x16\xfc\x94\xacT\xa0\xd4\x82\xe5S1\xf4\xe1\x8cB\xad\x89\xc3C\xa6\rt)\xfa\x0b\xfe3\t\xdd\x02\xbe\xecP\xd6\xd7p\xf6\xf3\xb5\xdf6\xfc\x90l\xaa\x06\x8a\xc0XO\x96>\x85\x18\xebN\x08\x13x\xc0\x1ah\xbd\xedO\x99T\xfd\xed\x87C}\x89!\x99Oz\xfe\x927z~ &"\x0e/\x01N\x13\xfa\xd1\x96\x87\x0f\x83\x98d\x12X\xa7\x8c\xa8\x1c/\xbc\xab\xb2:\x07\xa6\x14\xfa\xe3\xd2\x8cG\xd6\x84\xe4[\x8f\x9e\x8f\xbb\x9c\x8a\x80\xbd\xcf\xaf!\xf7E\x1b\x1f\x91\x18\xc2\x8eBE\xfb\x84\xb6\xc5e5Q\xfd\xb8\xcb\xbc\xb4\x9f\xb7\x92\xfe\xae\xda,\xfaA\x94\x7fq\x1e\xd1\x05\xe8=\x9d#,\xe6\xb7y1\xe6\xc7!\xa0\x0bx\xd1\xb3\xad9\xc4\xdd\x99Y\xca\r\x07+\x903\x1e?\x1d_\x8b\xb0M\xff\x14\xc3:\x95\xa8\xee\xc1\xb5\xff\xfb1\x95\xe1\xcaT\xe4D\xcf\xd2%\x11\xeb@`Att\xbe\x11\xfc/\x05\x9a\xd2\x15\r\xb6\x9d\x88\xae\xa8\xd1q\xe5\x9b\x05A\x8d[\xbf\xaaN\x1b\xee\xbf#4\x1c\xd5\xa4\x1f\x0fo\xaf\xd0\x00g\xc1\x9a\x82\x00\x8c_\xd4\xac!{K\xca\x89x\xde\xf9\x8d\x19\xec\x12\x8epY\xdb\x9f\x98\xe6\x88\xe7\xc1\x92\x90\x17\x80\x03Ry\xf1n\x97e\xe2\x8c\xe9\x8c\xd6<\xba2:\x9f\x06g\x05\xaa#\xf4\xca1\x16o\xb5\x8b\xcd\xfe\x814h\xac\xcd\x0e\xd0\x1c\x0c\xc71\x11\xbe\xa5\xb3#\xcfh\x07)\x91\xc7\xc8iy!\x03\xc8\xf0\xb2\x02\xf3\xc7\xdf\xafXm\xf5\xaf\xdd\xc8\xeb\xb3n7\xe34\xa7R\x8c\xaf\xa3\xb7y\xe7\x12\x0f\x0c\xc2\xa8v\x12E\xc3u\xc8Y\x1fh.\xcf\x01\xae\x8c\x00"v\x99V\xad>\xaf\x08)\x83V*\x9b\xad\xc0\x9c\x94\xa5D[\x08s\x88\xd1\xcb\xf6\xf8j\xa1c\xc1yb\xda\x12\xa1~\xf6\xd1"\x14\x11a\x02\xc1\xd3\xf5'
tmp_aes_key = b'\x82\xeb\x12\x0e\xbeT\x80>!\xaa\x01\xac\xc8\xe1u#d\x1b\x08\xf5G\xc7\xe5g\xa9\xc3\x1d*BC;6'
tmp_aes_iv = b'r\xbb/\xe8\x0bb,T\x19\x17\xf20WsTf\x1d_C\x83|2h\xd3s\x82\xaeVW\x10v\xff'
# encrypted_answer = 'L\xd7\xddI\x0b\xc3\xeay\xf1\x07]\x93\x7fY\x0cmVAX\x03\xeb\n}\x99\xd6\x99\xaa\xba\x05\x9d\xaaB\xe2\x97\xb3\xf2\xf8\xd8\x9f\xa6\x13\x177a\xb45A\x0f}\xb3\x99\xa3D?L\x94\xa3\xbcG\xe8\xf2\x14 \xb9.\x8b\xa0\xf1\xa5\xf1\x18\x9aZ2\x8f\xae\x05\xd9\x84H\xa3&\xad\x84\x82w\x9e\xe8\xba\x8a\x87QT\xdd\x12\x8c\x86\xde\xd8\x7fLM\xb9\x81H;JX\x85\x14\x1af!\xb20\xea)\xa8>(\xa9\xce5,\x96\x14\xd7P\x0c\xb3\x02\x9a\x16\xfc\x94\xacT\xa0\xd4\x82\xe5S1\xf4\xe1\x8cB\xad\x89\xc3C\xa6\rt)\xfa\x0b\xfe3\t\xdd\x02\xbe\xecP\xd6\xd7p\xf6\xf3\xb5\xdf6\xfc\x90l\xaa\x06\x8a\xc0XO\x96>\x85\x18\xebN\x08\x13x\xc0\x1ah\xbd\xedO\x99T\xfd\xed\x87C}\x89!\x99Oz\xfe\x927z~ &"\x0e/\x01N\x13\xfa\xd1\x96\x87\x0f\x83\x98d\x12X\xa7\x8c\xa8\x1c/\xbc\xab\xb2:\x07\xa6\x14\xfa\xe3\xd2\x8cG\xd6\x84\xe4[\x8f\x9e\x8f\xbb\x9c\x8a\x80\xbd\xcf\xaf!\xf7E\x1b\x1f\x91\x18\xc2\x8eBE\xfb\x84\xb6\xc5e5Q\xfd\xb8\xcb\xbc\xb4\x9f\xb7\x92\xfe\xae\xda,\xfaA\x94\x7fq\x1e\xd1\x05\xe8=\x9d#,\xe6\xb7y1\xe6\xc7!\xa0\x0bx\xd1\xb3\xad9\xc4\xdd\x99Y\xca\r\x07+\x903\x1e?\x1d_\x8b\xb0M\xff\x14\xc3:\x95\xa8\xee\xc1\xb5\xff\xfb1\x95\xe1\xcaT\xe4D\xcf\xd2%\x11\xeb@`Att\xbe\x11\xfc/\x05\x9a\xd2\x15\r\xb6\x9d\x88\xae\xa8\xd1q\xe5\x9b\x05A\x8d[\xbf\xaaN\x1b\xee\xbf#4\x1c\xd5\xa4\x1f\x0fo\xaf\xd0\x00g\xc1\x9a\x82\x00\x8c_\xd4\xac!{K\xca\x89x\xde\xf9\x8d\x19\xec\x12\x8epY\xdb\x9f\x98\xe6\x88\xe7\xc1\x92\x90\x17\x80\x03Ry\xf1n\x97e\xe2\x8c\xe9\x8c\xd6<\xba2:\x9f\x06g\x05\xaa#\xf4\xca1\x16o\xb5\x8b\xcd\xfe\x814h\xac\xcd\x0e\xd0\x1c\x0c\xc71\x11\xbe\xa5\xb3#\xcfh\x07)\x91\xc7\xc8iy!\x03\xc8\xf0\xb2\x02\xf3\xc7\xdf\xafXm\xf5\xaf\xdd\xc8\xeb\xb3n7\xe34\xa7R\x8c\xaf\xa3\xb7y\xe7\x12\x0f\x0c\xc2\xa8v\x12E\xc3u\xc8Y\x1fh.\xcf\x01\xae\x8c\x00"v\x99V\xad>\xaf\x08)\x83V*\x9b\xad\xc0\x9c\x94\xa5D[\x08s\x88\xd1\xcb\xf6\xf8j\xa1c\xc1yb\xda\x12\xa1~\xf6\xd1"\x14\x11a\x02\xc1\xd3\xf5'
# tmp_aes_key = b'\x82\xeb\x12\x0e\xbeT\x80>!\xaa\x01\xac\xc8\xe1u#d\x1b\x08\xf5G\xc7\xe5g\xa9\xc3\x1d*BC;6'
# tmp_aes_iv = b'r\xbb/\xe8\x0bb,T\x19\x17\xf20WsTf\x1d_C\x83|2h\xd3s\x82\xaeVW\x10v\xff'
from Crypto.Cipher import AES
# try all modes
aes_modes = [AES.MODE_CBC, AES.MODE_CFB, AES.MODE_CTR, AES.MODE_ECB, AES.MODE_OFB, AES.MODE_OPENPGP, AES.MODE_PGP]
aes_modes_names = ["AES.MODE_CBC", "AES.MODE_CFB", "AES.MODE_CTR", "AES.MODE_ECB", "AES.MODE_OFB", "AES.MODE_OPENPGP", "AES.MODE_PGP"]
# # try all modes
# aes_modes = [AES.MODE_CBC, AES.MODE_CFB, AES.MODE_CTR, AES.MODE_ECB, AES.MODE_OFB, AES.MODE_OPENPGP, AES.MODE_PGP]
# aes_modes_names = ["AES.MODE_CBC", "AES.MODE_CFB", "AES.MODE_CTR", "AES.MODE_ECB", "AES.MODE_OFB", "AES.MODE_OPENPGP", "AES.MODE_PGP"]
#
# working_modes = []
# working_modenames = []
# for mode, modename in zip(aes_modes, aes_modes_names):
# print("\n\nTrying mode: " + modename + "(" + str(mode) + ")")
# try:
# crypting_object = AES.new(tmp_aes_key, mode, tmp_aes_iv) # encrypter thing
# decrypted_answer = crypting_object.decrypt(encrypted_answer)
# print("decrypted_answer: ")
# print(decrypted_answer.__repr__())
# vis(decrypted_answer)
# working_modes.append(mode)
# working_modenames.append(modename)
# print("Which should look the same than: ")
# print(answer.__repr__())
# vis(answer)
# if answer == decrypted_answer:
# print("THEY ARE THE SAME!!")
# else:
# print("THEY ARE DIFFERENT :(((((")
# except Exception as e:
# print("Exception: " + str(e))
#
# print("\n\nModes " + str(working_modenames) + " (" + str(working_modes) + ") succesfully unencrypted the answer!")
working_modes = []
working_modenames = []
for mode, modename in zip(aes_modes, aes_modes_names):
print("\n\nTrying mode: " + modename + "(" + str(mode) + ")")
try:
crypting_object = AES.new(tmp_aes_key, mode, tmp_aes_iv) # encrypter thing
decrypted_answer = crypting_object.decrypt(encrypted_answer)
print("decrypted_answer: ")
print(decrypted_answer.__repr__())
working_modes.append(mode)
working_modenames.append(modename)
except Exception as e:
print("Exception: " + str(e))
print("\n\nModes " + str(working_modenames) + " (" + str(working_modes) + ") succesfully unencrypted the answer!")
# From http://stackoverflow.com/questions/17797582/java-aes-256-decrypt-with-ige
# public static final byte[] ige(final byte[] key, final byte[] IV,
# final byte[] Message) throws Exception {
def ige(key, iv, message, blocksize=16):#32):
"""given a key, ive and message, decrypt it. blocksize is the default one used in the javascript implementation"""
print("len(key): " + str(len(key)))
print("len(iv): " + str(len(iv)))
print("len(message): " + str(len(message)))
# key = bytearray(key)
# iv = bytearray(iv)
# message = bytearray(message)
#
# final Cipher cipher = Cipher.getInstance("AES/ECB/NoPadding");
cipher = AES.new(key, AES.MODE_ECB, iv)
blocksize = cipher.block_size
# cipher.init(Cipher.DECRYPT_MODE, new SecretKeySpec(key, "AES"));
#
# final int blocksize = cipher.getBlockSize();
#
# byte[] xPrev = Arrays.copyOfRange(IV, 0, blocksize);
xPrev = iv[0:blocksize]
# byte[] yPrev = Arrays.copyOfRange(IV, blocksize, IV.length);
yPrev = iv[blocksize:]
#
# byte[] decrypted = new byte[0];
decrypted = None
#
# byte[] y, x;
# y = bytearray()
# x = bytearray()
# for (int i = 0; i < Message.length; i += blocksize) {
def xor_strings(a, b): # xor two strings of different lengths
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)])])
def add_strings(a, b):
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)])])
#return sum([a, b]) & 0xFFFFFFFF
for i in range(0, len(message), blocksize):
print("i: " + str(i))
# x = java.util.Arrays.copyOfRange(Message, i, i + blocksize);
x = message[i:i+blocksize]
#print(" x: " + x.__repr__())
# y = xor(cipher.doFinal(xor(x, yPrev)), xPrev);
y = xor_strings(cipher.decrypt(xor_strings(x, yPrev)), xPrev)
#print(" y: " + y.__repr__())
#y = xor(cipher.decrypt(xor(x, yPrev)), xPrev)
# xPrev = x;
xPrev = x
# yPrev = y;
yPrev = y
#
# decrypted = sumBytes(decrypted, y);
if decrypted is None:
decrypted = y
else:
decrypted_ba = bytearray(decrypted)
decrypted_ba.extend(y)
decrypted = str(decrypted_ba)
# all this did not work
#decrypted = int(decrypted, 16) + int(y, 16)
#decrypted.append(y)
#add_strings(decrypted, y)
#decrypted = decrypted + y # this is wrong
#print(" decrypted: " + decrypted.__repr__())
# }
#
# return decrypted;
print("len(key): " + str(len(key)))
print("len(iv): " + str(len(iv)))
print("len(message): " + str(len(message)))
print("!!!!!!!!!!!!!!!!!!!!!! ---> cipher.block_size: " + str(cipher.block_size))
return decrypted
# }
result = ige(tmp_aes_key, tmp_aes_iv, encrypted_answer)
print("result:")
print(result)
vis(result)
if answer == result:
print("THEY ARE THE SAME!!")
else:
print("THEY ARE DIFFERENT :(((((")
print("len(result): " + str(len(result)))
print("len(answer):" + str(len(answer)))
vis(encrypted_answer)
# This DOES NOT work. openssl wrapper m2crypto does not have IGE available
# from base64 import b64encode, b64decode
# from M2Crypto.EVP import Cipher
# ENC=1
# DEC=0
#
# def build_cipher(key, iv, op=ENC):
# """"""""
# #return Cipher(alg='aes_256_ecb', key=key, iv=iv, op=op)
# return Cipher(alg='aes_256 ige', key=key, iv=iv, op=op)
#
# def encryptor(key, iv=None):
# """"""
# # Decode the key and iv
# key = b64decode(key)
# if iv is None:
# iv = '\0' * 16
# else:
# iv = b64decode(iv)
#
# # Return the encryption function
# def encrypt(data):
# cipher = build_cipher(key, iv, ENC)
# v = cipher.update(data)
# v = v + cipher.final()
# del cipher
# v = b64encode(v)
# return v
# return encrypt
#
# def decryptor(key, iv=None):
# """"""
# # Decode the key and iv
# #key = b64decode(key)
# if iv is None:
# iv = '\0' * 16
# else:
# #iv = b64decode(iv)
# pass
#
# # Return the decryption function
# def decrypt(data):
# #data = b64decode(data)
# cipher = build_cipher(key, iv, DEC)
# v = cipher.update(data)
# v = v + cipher.final()
# del cipher
# return v
# return decrypt
#
# print("Decrypting with m2...")
# decryptor_m2= decryptor(tmp_aes_key, tmp_aes_iv)
# m2_decrypt_ans =decryptor_m2(encrypted_answer)
# vis(m2_decrypt_ans)
# Output was:
# Trying mode: AES.MODE_CBC(2)
# Exception: IV must be 16 bytes long

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@ -4,6 +4,7 @@ import os
import io
import prime
import struct
from Crypto.Cipher import AES
# Deal with py2 and py3 differences
try:
import configparser
@ -75,11 +76,23 @@ z = Session.method_call('req_DH_params',
encrypted_data=encrypted_data)
encrypted_answer = z['encrypted_answer']
print("encrypted_answer:")
print(encrypted_answer.__repr__())
tmp_aes_key = SHA.new(new_nonce + server_nonce).digest() + SHA.new(server_nonce + new_nonce).digest()[0:12]
tmp_aes_iv = SHA.new(server_nonce + new_nonce).digest()[12:20] + SHA.new(new_nonce + new_nonce).digest() + new_nonce[0:4]
print("\ntmp_aes_key:")
mtproto.vis(tmp_aes_key)
print(tmp_aes_key.__repr__())
print("\ntmp_aes_iv:")
mtproto.vis(tmp_aes_iv)
print(tmp_aes_iv.__repr__())
# From using research_decrypt_mode.py I got to unencrypt the answer
crypting_object = AES.new(tmp_aes_key, AES.MODE_ECB, tmp_aes_iv) # encrypter thing
decrypted_answer = crypting_object.decrypt(encrypted_answer)
print("decrypted_answer: ")
print(decrypted_answer.__repr__())
mtproto.vis(decrypted_answer)