Implementation of different cryptographic algorithms with z3 solver sat. Thanks to that, we transform the AES into different equations. We add the intermediate values (Output of the Sbox, ...) retrieved during side-channel attacks in the system of equations. We resolve the system in order to retrieve the key. Other attack are implemented (Square Attack on round 4).
Multiple primary classes are implemented:
- AES
- SHA224, 256, 384 and 512
- RSA
Other composed classes are implemented to preform some attacks:
- AES with CBC, OFB, CFB or CTR mode (based on AES)
- AES with Hamming Weight (attack based on Hamming Weigth)
- DFA (Differntial Fault Analysis based on AES)
key_test = ["000102030405060708090a0b0c0d0e0f",
"d6aa74fdd2af72fadaa678f1d6ab76fe",
"b692cf0b643dbdf1be9bc5006830b3fe",
"b6ff744ed2c2c9bf6c590cbf0469bf41",
"47f7f7bc95353e03f96c32bcfd058dfd",
"3caaa3e8a99f9deb50f3af57adf622aa",
"5e390f7df7a69296a7553dc10aa31f6b",
"14f9701ae35fe28c440adf4d4ea9c026",
"47438735a41c65b9e016baf4aebf7ad2",
"549932d1f08557681093ed9cbe2c974e",
"13111d7fe3944a17f307a78b4d2b30c5"
]
s = 128
aes = Aes(s, "message")
aes.reset()
for l in range(10,11):
for i in range(0,4):
# Add 8 bytes of 10th round key
for j in range(0,2):
aes.addPartialKey(l, j, i, int(key_test[l][2*(j*4+i):2*(j*4+i+1)], 16))
# Add 8 bytes of 9th round key
for j in range(2,4):
aes.addPartialKey(l-1, j, i, int(key_test[l-1][2*(j*4+i):2*(j*4+i+1)], 16))
# Resolver equation to find master key
solution = aes.check()
print(solution)