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Merge branch 'fixlogin' into 'master'

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Fix RSA Invalid Condition on login

Closes #10

See merge request richardARPANET/mega.py!2
This commit is contained in:
richardARPANET 2020-03-23 18:55:03 +00:00
commit 6f3f5371ce
3 changed files with 56 additions and 15 deletions
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2
HISTORY.rst
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@ -6,7 +6,7 @@ Release History
1.0.7 (unreleased)
------------------
- Nothing changed yet.
- Fix login by calculating public RSA exponent instead of hardcoding.
1.0.6 (2020-02-03)

22
src/mega/crypto.py
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@ -104,8 +104,30 @@ def str_to_a32(b):
def mpi_to_int(s):
"""
A Multi-precision integer is encoded as a series of bytes in big-endian
order. The first two bytes are a header which tell the number of bits in
the integer. The rest of the bytes are the integer.
"""
return int(binascii.hexlify(s[2:]), 16)
def extended_gcd(a, b):
if a == 0:
return (b, 0, 1)
else:
g, y, x = extended_gcd(b % a, a)
return (g, x - (b // a) * y, y)
def modular_inverse(a, m):
"""
Thank you Mart Bakhoff for this solution.
https://stackoverflow.com/a/9758173
"""
g, x, y = extended_gcd(a, m)
if g != 1:
raise Exception('modular inverse does not exist')
else:
return x % m
def base64_url_decode(data):
data += '==' [(2 - len(data) * 3) % 4:]

47
src/mega/mega.py
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@ -1,3 +1,4 @@
import math
import re
import json
import logging
@ -20,7 +21,8 @@ from .errors import ValidationError, RequestError
from .crypto import (
a32_to_base64, encrypt_key, base64_url_encode, encrypt_attr, base64_to_a32,
base64_url_decode, decrypt_attr, a32_to_str, get_chunks, str_to_a32,
decrypt_key, mpi_to_int, stringhash, prepare_key, make_id, makebyte
decrypt_key, mpi_to_int, stringhash, prepare_key, make_id, makebyte,
modular_inverse
)
logger = logging.getLogger(__name__)
@ -119,22 +121,39 @@ class Mega:
)
private_key = a32_to_str(rsa_private_key)
self.rsa_private_key = [0, 0, 0, 0]
# The private_key contains 4 MPI integers concatenated together.
rsa_private_key = [0, 0, 0, 0]
for i in range(4):
l = int(
((private_key[0]) * 256 + (private_key[1]) + 7) / 8
) + 2
self.rsa_private_key[i] = mpi_to_int(private_key[:l])
private_key = private_key[l:]
# An MPI integer has a 2-byte header which describes the number
# of bits in the integer.
bitlength = (private_key[0] * 256) + private_key[1]
bytelength = math.ceil(bitlength / 8)
# Add 2 bytes to accommodate the MPI header
bytelength += 2
rsa_private_key[i] = mpi_to_int(private_key[:bytelength])
private_key = private_key[bytelength:]
first_factor_p = rsa_private_key[0]
second_factor_q = rsa_private_key[1]
private_exponent_d = rsa_private_key[2]
# In MEGA's webclient javascript, they assign [3] to a variable
# called u, but I do not see how it corresponds to pycryptodome's
# RSA.construct and it does not seem to be necessary.
rsa_modulus_n = first_factor_p * second_factor_q
phi = (first_factor_p - 1) * (second_factor_q - 1)
public_exponent_e = modular_inverse(private_exponent_d, phi)
rsa_components = (
rsa_modulus_n,
public_exponent_e,
private_exponent_d,
first_factor_p,
second_factor_q,
)
rsa_decrypter = RSA.construct(rsa_components)
encrypted_sid = mpi_to_int(base64_url_decode(resp['csid']))
rsa_decrypter = RSA.construct(
(
self.rsa_private_key[0] * self.rsa_private_key[1], 257,
self.rsa_private_key[2], self.rsa_private_key[0],
self.rsa_private_key[1]
)
)
sid = '%x' % rsa_decrypter._decrypt(encrypted_sid)
sid = binascii.unhexlify('0' + sid if len(sid) % 2 else sid)
self.sid = base64_url_encode(sid[:43])