Fast and Portable Cryptography Extension Library for Pyrogram
TgCrypto2 is a Cryptography Library written in C as a Python extension. It is designed to be portable, fast, easy to install and use. TgCrypto2 is intended for Pyrogram and implements the cryptographic algorithms Telegram requires, namely:
AES-256-IGE
- used in MTProto v2.0.AES-256-CTR
- used for CDN encrypted files.AES-256-CBC
- used for encrypted passport credentials.
- Python 3.7 or higher.
$ pip3 install -U tgcrypto2
TgCrypto2 API consists of these six methods:
def ige256_encrypt(data: bytes, key: bytes, iv: bytes) -> bytes: ...
def ige256_decrypt(data: bytes, key: bytes, iv: bytes) -> bytes: ...
def ctr256_encrypt(data: bytes, key: bytes, iv: bytes, state: bytes) -> bytes: ...
def ctr256_decrypt(data: bytes, key: bytes, iv: bytes, state: bytes) -> bytes: ...
def cbc256_encrypt(data: bytes, key: bytes, iv: bytes) -> bytes: ...
def cbc256_decrypt(data: bytes, key: bytes, iv: bytes) -> bytes: ...
Note: Data must be padded to match a multiple of the block size (16 bytes).
import os
import tgcrypto2
data = os.urandom(10 * 1024 * 1024 + 7) # 10 MB of random data + 7 bytes to show padding
key = os.urandom(32) # Random Key
iv = os.urandom(32) # Random IV
# Pad with zeroes: -7 % 16 = 9
data += bytes(-len(data) % 16)
ige_encrypted = tgcrypto2.ige256_encrypt(data, key, iv)
ige_decrypted = tgcrypto2.ige256_decrypt(ige_encrypted, key, iv)
print(data == ige_decrypted) # True
import os
import tgcrypto2
data = os.urandom(10 * 1024 * 1024) # 10 MB of random data
key = os.urandom(32) # Random Key
enc_iv = bytearray(os.urandom(16)) # Random IV
dec_iv = enc_iv.copy() # Keep a copy for decryption
ctr_encrypted = tgcrypto2.ctr256_encrypt(data, key, enc_iv, bytes(1))
ctr_decrypted = tgcrypto2.ctr256_decrypt(ctr_encrypted, key, dec_iv, bytes(1))
print(data == ctr_decrypted) # True
import os
from io import BytesIO
import tgcrypto2
data = BytesIO(os.urandom(10 * 1024 * 1024)) # 10 MB of random data
key = os.urandom(32) # Random Key
enc_iv = bytearray(os.urandom(16)) # Random IV
dec_iv = enc_iv.copy() # Keep a copy for decryption
enc_state = bytes(1) # Encryption state, starts from 0
dec_state = bytes(1) # Decryption state, starts from 0
encrypted_data = BytesIO() # Encrypted data buffer
decrypted_data = BytesIO() # Decrypted data buffer
while True:
chunk = data.read(1024)
if not chunk:
break
# Write 1K encrypted bytes into the encrypted data buffer
encrypted_data.write(tgcrypto2.ctr256_encrypt(chunk, key, enc_iv, enc_state))
# Reset position. We need to read it now
encrypted_data.seek(0)
while True:
chunk = encrypted_data.read(1024)
if not chunk:
break
# Write 1K decrypted bytes into the decrypted data buffer
decrypted_data.write(tgcrypto2.ctr256_decrypt(chunk, key, dec_iv, dec_state))
print(data.getvalue() == decrypted_data.getvalue()) # True
Note: Data must be padded to match a multiple of the block size (16 bytes).
import os
import tgcrypto2
data = os.urandom(10 * 1024 * 1024 + 7) # 10 MB of random data + 7 bytes to show padding
key = os.urandom(32) # Random Key
enc_iv = bytearray(os.urandom(16)) # Random IV
dec_iv = enc_iv.copy() # Keep a copy for decryption
# Pad with zeroes: -7 % 16 = 9
data += bytes(-len(data) % 16)
cbc_encrypted = tgcrypto2.cbc256_encrypt(data, key, enc_iv)
cbc_decrypted = tgcrypto2.cbc256_decrypt(cbc_encrypted, key, dec_iv)
print(data == cbc_decrypted) # True
- Clone this repository:
git clone https://github.com/tboy1337/tgcrypto2
. - Enter the directory:
cd tgcrypto2
. - Install
tox
:pip3 install tox
- Run tests:
tox
.