def LoginSequence(dynamic_socket, addr, dataRecv):
global user_DHkey
global user_networkinfo
global serverprivkey
print 'LoginSequence'
# msg format greeting_msg = bytes(0x00) + bytes(iv) + bytes(cipher_key_sym) + bytes(ciphertext)
cipher_key_sym = None
ciphertext = None
iv = None
moduli = None
offset = InitOffset # Initial offset
msg_type = dataRecv[offset] # byte 0 contains the msg_type
offset += LengthType
iv = dataRecv[offset:offset + 16] # 16 bytes of IV
offset += LengthIV
cipher_key_sym = dataRecv[offset:offset +
256] # 256 bytes of the symmetric key
offset += LengthKey
ciphertext = dataRecv[offset:len(dataRecv)] # The encrypted text
# Load Private key of the server
try:
with open('serverprivkey.pem', 'rb') as f:
serverprivkey = serialization.load_pem_private_key(
f.read(), password=None, backend=default_backend())
except:
print("The file specified does not exist")
sys.exit(2)
# Decrypt key_sym with reciever's private key
key_sym = RSADecrypt(cipher_key_sym, serverprivkey)
# Decrypt the ciphertext using the key_sym and iv
plaintext = AESDecrypt(key_sym, iv, ciphertext)
N1 = bytes(plaintext)[0:32]
plaintext = str(bytes(plaintext[32:len(bytes(plaintext))]))
# Get data from plaintext
split_data = plaintext.split(',')
username = split_data[0]
# Check if the user already exists
try:
if user_networkinfo[username] != [] or user_DHkey[username] != None:
print "User has already logged in!"
return
except:
print "User doesn't exist!"
return
# DH public key - 2^a mod p and rsa public key of the client
client_dh_pub_key = split_data[1]
client_rsa_pub_key = split_data[2]
client_rsa_auth_key = serialization.load_pem_public_key(
client_rsa_pub_key, backend=default_backend())
u = DiffieHellman()
b = str(u.privateKey) # DH private key of the server
dh_key_server = str(u.publicKey) # DH public key of the server - 2^b mod p
p = str(u.prime) # p - prime number for DH
moduli = user_moduli[username] # 2^W mod p
u.genHashSecretM(moduli, client_dh_pub_key)
N2 = os.urandom(LengthN)
msg = N1 + N2 + u.hashsecret + dh_key_server
# Generate a aes key , iv and use it to encrypt the above msg
aes_key = keygen()
iv = os.urandom(LengthIV)
ciphertext = AESEncrypt(msg, aes_key, iv)
# Encrypt the symmetric key with client's rsa public key
cipher_key_sym = RSAEncrypt(aes_key, client_rsa_auth_key)
# Constant for GREETING is 0x00
server_first_msg = bytes(0x00) + bytes(iv) + bytes(cipher_key_sym) + bytes(
ciphertext)
print 'Received Greeting from: ', username
dynamic_socket.sendto(server_first_msg, (addr[0], int(addr[1])))
(dataRecv, addr) = dynamic_socket.recvfrom(4096)
print 'Verifying the hashes for ', username
_N2 = dataRecv[0:LengthN]
if _N2 != str(N2):
print "Nonce N2 doesn't match"
return
u.genHashSecretM1(moduli, client_dh_pub_key)
hash_recv = dataRecv[LengthN:len(dataRecv)]
if hash_recv == u.hashsecret1:
u.genKey(client_dh_pub_key)
else:
print 'Hashes does not match'
return
print 'Sending ACK to ', username
sym_key_shared = aeskeygen(u.key) # Generate AES key out of DH key
iv = os.urandom(LengthIV)
acknowledge = AESEncrypt('ACK', sym_key_shared,
iv) # Encrypt the ACK with the symmetric key
msg = bytes(iv) + bytes(acknowledge)
dynamic_socket.sendto(
msg, (addr[0], int(addr[1]))) # Send the ACK to the client
print 'Waiting for Network Information of ', username
(dataRecv, addr) = dynamic_socket.recvfrom(4096)
offset = InitOffset
new_iv = dataRecv[offset:offset + LengthIV]
offset += LengthIV
iv = dataRecv[offset:offset + LengthIV]
offset += LengthIV
cipher_key_new = dataRecv[offset:offset + LengthKey]
offset += LengthKey
nwciphertext = dataRecv[offset:len(dataRecv)]
# Decrypt cipher_key_new with server's private key
new_key_sym = RSADecrypt(cipher_key_new, serverprivkey)
# Decrypt the nwciphertext using symmetric key decryption
plaintext = AESDecrypt(new_key_sym, new_iv, nwciphertext)
user = plaintext.split(',')[0]
enc_nwinfo = plaintext[len(user) + 1:len(plaintext)]
# Decrypt the nwinfo using DH key
plaintext = AESDecrypt(sym_key_shared, iv, enc_nwinfo)
ip_address = plaintext.split(',')[0]
port_num = plaintext.split(',')[1]
#print('Received common port and ip')
# Register the client's network info along with the client rsa public key into user_networkinfo table
user_networkinfo[username].append(ip_address)
user_networkinfo[username].append(port_num)
user_networkinfo[username].append(client_rsa_pub_key)
# Register the DH shared key in the user_DHkey table
user_DHkey[username] = sym_key_shared
print('LOGIN SUCCESSFUL')
print('------------------------------------------------------------------')
pass
def LoginSequence(username, password):
global server_socket
global serverIP
global serverPort
global client_socket
global commonPort
global dh_aes_key
global serverpubkey
global Dport
global sender_private_key
# Compute the nonce, a random no. of 32 bit
nonce = os.urandom(LengthN)
u = DiffieHellman()
# modular prime and private key for DH exchange
p = str(u.prime)
a = str(u.privateKey)
# public key g^a mod p
dh_pub_key = str(u.publicKey)
# Generate client rsa auth key pair
try:
sender_private_key = rsa.generate_private_key(
public_exponent=65537,
key_size=2048,
backend=default_backend())
except:
print("The provided backend does not implement RSABackend")
# Obtain the public key from the private key generated using RSA
sender_public_key = sender_private_key.public_key()
try:
pem = sender_public_key.public_bytes(
encoding=serialization.Encoding.PEM,
format=serialization.PublicFormat.SubjectPublicKeyInfo)
except:
print("Serialization failed")
# Get the server public key from the file
try:
with open('serverpubkey.pem', 'rb') as f1:
serverpubkey = serialization.load_pem_public_key(f1.read(), backend=default_backend())
except:
print("The destination public key file is not present")
sys.exit(2)
msg = str(nonce) + username + ',' + str(dh_pub_key) + ',' + str(pem)
# Encrypt using aes key
key_sym=keygen()
iv = os.urandom(16)
ciphertext = AESEncrypt(msg, key_sym, iv)
# Encrypt the symmetric key with rsa public key
cipher_key_sym = serverpubkey.encrypt(key_sym, padding.OAEP( mgf=padding.MGF1(algorithm=hashes.SHA1()),algorithm=hashes.SHA1(),label=None))
# Constant for GREETING is 0x00
greeting_msg = bytes(0x00) + bytes(iv) + bytes(cipher_key_sym) + bytes(ciphertext)
server_socket.sendto(greeting_msg, (serverIP, int(serverPort)))
(Dport, addr) = server_socket.recvfrom(4096)
(dataRecv, addr) = server_socket.recvfrom(4096)
# Use Dport to finish the rest of sequence server_socket.sendto(other_msg, (serverIP, Dport))
# Server_first_msg = bytes(0x00) + bytes(iv) + bytes(cipher_key_sym) + bytes(ciphertext)
# msg = nonce + dh_key_server + ',' + u.hashsecret
cipher_key_sym = None
ciphertext = None
iv = None
offset = InitOffset
msg_type = dataRecv[offset]
offset += 1
iv = dataRecv[offset:offset+LengthIV]
offset += LengthIV
cipher_key_sym = dataRecv[offset:offset+LengthKey]
offset += LengthKey
ciphertext = dataRecv[offset:len(dataRecv)]
# Decrypt key_sym with sender's private key
key_sym = RSADecrypt(cipher_key_sym, sender_private_key)
# Decrypt the ciphertext using the key_sym and iv
plaintext = AESDecrypt(key_sym, iv, ciphertext)
plaintext = bytes(plaintext)
offset = InitOffset
nonce1 = plaintext[offset:offset+LengthN]
offset += LengthN
nonce2 = plaintext[offset:offset+LengthN]
offset += LengthN
if nonce1 != nonce:
print "Nonce N1 doesn't match"
exit(2)
# Get data from plaintext
hash_secret = plaintext[offset:offset+LengthN]
offset += LengthN
dh_key_server_public = plaintext[offset:len(plaintext)]
# Generate hash secret
W = hash32(password)
u.genHashSecret(W, dh_key_server_public)
if hash_secret == u.hashsecret:
# Generate DH shared key
u.genKey(dh_key_server_public)
u.genHashSecret1(W, dh_key_server_public)
server_socket.sendto(str(nonce2)+u.hashsecret1, (serverIP, int(Dport)))
else:
print('Hashes do not match' )
sys.exit(2)
(dataRecv, addr) = server_socket.recvfrom(4096)
offset =InitOffset
iv = dataRecv[offset:offset+LengthIV]
offset += LengthIV
ciphertext = dataRecv[offset:len(dataRecv)]
dh_aes_key = aeskeygen(u.key)
# Decrypt the ciphertext using the key_sym and iv
plaintext = AESDecrypt(dh_aes_key, iv, ciphertext)
msg = str(bytes(plaintext))
print('Received ACK')
networkinfo = client_socket.getsockname()[0] + ',' + str(client_socket.getsockname()[1])
# Encrypt the network info using DH Key
iv = os.urandom(LengthIV)
nwinfo = AESEncrypt(networkinfo, dh_aes_key, iv)
# Encrypt username and encrypted networkinfo using new aes key , and encrypt sym key using rsa server ublic key
new_iv = os.urandom(LengthIV)
new_sym_key = keygen()
msg_nwinfo = username + ',' + bytes(nwinfo)
encrypted_msg = AESEncrypt(msg_nwinfo, new_sym_key, new_iv)
# Encrypt the symmetric key with rsa public key
cipher_new_key = RSAEncrypt(new_sym_key, serverpubkey)
info_msg = bytes(new_iv) + bytes(iv) + bytes(cipher_new_key) + bytes(encrypted_msg)
print('Sending common port info and peer AuthKey')
server_socket.sendto(info_msg, (serverIP, int(Dport)))
pass
def LoginSequence(username, password):
global server_socket
global serverIP
global serverPort
global client_socket
global commonPort
global dh_aes_key
global serverpubkey
global Dport
global sender_private_key
# Compute the nonce, a random no. of 32 bit
nonce = os.urandom(LengthN)
u = DiffieHellman()
# modular prime and private key for DH exchange
p = str(u.prime)
a = str(u.privateKey)
# public key g^a mod p
dh_pub_key = str(u.publicKey)
# Generate client rsa auth key pair
try:
sender_private_key = rsa.generate_private_key(
public_exponent=65537, key_size=2048, backend=default_backend())
except:
print("The provided backend does not implement RSABackend")
# Obtain the public key from the private key generated using RSA
sender_public_key = sender_private_key.public_key()
try:
pem = sender_public_key.public_bytes(
encoding=serialization.Encoding.PEM,
format=serialization.PublicFormat.SubjectPublicKeyInfo)
except:
print("Serialization failed")
# Get the server public key from the file
try:
with open('serverpubkey.pem', 'rb') as f1:
serverpubkey = serialization.load_pem_public_key(
f1.read(), backend=default_backend())
except:
print("The destination public key file is not present")
sys.exit(2)
msg = str(nonce) + username + ',' + str(dh_pub_key) + ',' + str(pem)
# Encrypt using aes key
key_sym = keygen()
iv = os.urandom(16)
ciphertext = AESEncrypt(msg, key_sym, iv)
# Encrypt the symmetric key with rsa public key
cipher_key_sym = serverpubkey.encrypt(
key_sym,
padding.OAEP(mgf=padding.MGF1(algorithm=hashes.SHA1()),
algorithm=hashes.SHA1(),
label=None))
# Constant for GREETING is 0x00
greeting_msg = bytes(0x00) + bytes(iv) + bytes(cipher_key_sym) + bytes(
ciphertext)
server_socket.sendto(greeting_msg, (serverIP, int(serverPort)))
(Dport, addr) = server_socket.recvfrom(4096)
(dataRecv, addr) = server_socket.recvfrom(4096)
# Use Dport to finish the rest of sequence server_socket.sendto(other_msg, (serverIP, Dport))
# Server_first_msg = bytes(0x00) + bytes(iv) + bytes(cipher_key_sym) + bytes(ciphertext)
# msg = nonce + dh_key_server + ',' + u.hashsecret
cipher_key_sym = None
ciphertext = None
iv = None
offset = InitOffset
msg_type = dataRecv[offset]
offset += 1
iv = dataRecv[offset:offset + LengthIV]
offset += LengthIV
cipher_key_sym = dataRecv[offset:offset + LengthKey]
offset += LengthKey
ciphertext = dataRecv[offset:len(dataRecv)]
# Decrypt key_sym with sender's private key
key_sym = RSADecrypt(cipher_key_sym, sender_private_key)
# Decrypt the ciphertext using the key_sym and iv
plaintext = AESDecrypt(key_sym, iv, ciphertext)
plaintext = bytes(plaintext)
offset = InitOffset
nonce1 = plaintext[offset:offset + LengthN]
offset += LengthN
nonce2 = plaintext[offset:offset + LengthN]
offset += LengthN
if nonce1 != nonce:
print "Nonce N1 doesn't match"
exit(2)
# Get data from plaintext
hash_secret = plaintext[offset:offset + LengthN]
offset += LengthN
dh_key_server_public = plaintext[offset:len(plaintext)]
# Generate hash secret
W = hash32(password)
u.genHashSecret(W, dh_key_server_public)
if hash_secret == u.hashsecret:
# Generate DH shared key
u.genKey(dh_key_server_public)
u.genHashSecret1(W, dh_key_server_public)
server_socket.sendto(
str(nonce2) + u.hashsecret1, (serverIP, int(Dport)))
else:
print('Hashes do not match')
sys.exit(2)
(dataRecv, addr) = server_socket.recvfrom(4096)
offset = InitOffset
iv = dataRecv[offset:offset + LengthIV]
offset += LengthIV
ciphertext = dataRecv[offset:len(dataRecv)]
dh_aes_key = aeskeygen(u.key)
# Decrypt the ciphertext using the key_sym and iv
plaintext = AESDecrypt(dh_aes_key, iv, ciphertext)
msg = str(bytes(plaintext))
print('Received ACK')
networkinfo = client_socket.getsockname()[0] + ',' + str(
client_socket.getsockname()[1])
# Encrypt the network info using DH Key
iv = os.urandom(LengthIV)
nwinfo = AESEncrypt(networkinfo, dh_aes_key, iv)
# Encrypt username and encrypted networkinfo using new aes key , and encrypt sym key using rsa server ublic key
new_iv = os.urandom(LengthIV)
new_sym_key = keygen()
msg_nwinfo = username + ',' + bytes(nwinfo)
encrypted_msg = AESEncrypt(msg_nwinfo, new_sym_key, new_iv)
# Encrypt the symmetric key with rsa public key
cipher_new_key = RSAEncrypt(new_sym_key, serverpubkey)
info_msg = bytes(new_iv) + bytes(iv) + bytes(cipher_new_key) + bytes(
encrypted_msg)
print('Sending common port info and peer AuthKey')
server_socket.sendto(info_msg, (serverIP, int(Dport)))
pass
def LoginSequence(dynamic_socket, addr, dataRecv):
global user_DHkey
global user_networkinfo
global serverprivkey
print 'LoginSequence'
# msg format greeting_msg = bytes(0x00) + bytes(iv) + bytes(cipher_key_sym) + bytes(ciphertext)
cipher_key_sym = None
ciphertext = None
iv = None
moduli = None
offset = InitOffset # Initial offset
msg_type = dataRecv[offset] # byte 0 contains the msg_type
offset += LengthType
iv = dataRecv[offset:offset+16] # 16 bytes of IV
offset += LengthIV
cipher_key_sym = dataRecv[offset:offset+256] # 256 bytes of the symmetric key
offset += LengthKey
ciphertext = dataRecv[offset:len(dataRecv)] # The encrypted text
# Load Private key of the server
try:
with open('serverprivkey.pem', 'rb') as f:
serverprivkey = serialization.load_pem_private_key(f.read(), password=None, backend=default_backend())
except:
print("The file specified does not exist")
sys.exit(2)
# Decrypt key_sym with reciever's private key
key_sym = RSADecrypt(cipher_key_sym, serverprivkey)
# Decrypt the ciphertext using the key_sym and iv
plaintext = AESDecrypt(key_sym, iv , ciphertext)
N1 = bytes(plaintext)[0:32]
plaintext = str(bytes(plaintext[32:len(bytes(plaintext))]))
# Get data from plaintext
split_data = plaintext.split(',')
username = split_data[0]
# Check if the user already exists
try:
if user_networkinfo[username] != [] or user_DHkey[username] != None:
print "User has already logged in!"
return
except:
print "User doesn't exist!"
return
# DH public key - 2^a mod p and rsa public key of the client
client_dh_pub_key = split_data[1]
client_rsa_pub_key = split_data[2]
client_rsa_auth_key = serialization.load_pem_public_key(client_rsa_pub_key, backend=default_backend())
u = DiffieHellman()
b = str(u.privateKey) # DH private key of the server
dh_key_server = str(u.publicKey) # DH public key of the server - 2^b mod p
p = str(u.prime) # p - prime number for DH
moduli = user_moduli[username] # 2^W mod p
u.genHashSecretM(moduli ,client_dh_pub_key)
N2 = os.urandom(LengthN)
msg = N1 + N2 + u.hashsecret + dh_key_server
# Generate a aes key , iv and use it to encrypt the above msg
aes_key = keygen()
iv = os.urandom(LengthIV)
ciphertext = AESEncrypt(msg, aes_key, iv)
# Encrypt the symmetric key with client's rsa public key
cipher_key_sym = RSAEncrypt(aes_key, client_rsa_auth_key)
# Constant for GREETING is 0x00
server_first_msg = bytes(0x00) + bytes(iv) + bytes(cipher_key_sym) + bytes(ciphertext)
print 'Received Greeting from: ',username
dynamic_socket.sendto(server_first_msg, (addr[0], int(addr[1])))
(dataRecv, addr) = dynamic_socket.recvfrom(4096)
print 'Verifying the hashes for ', username
_N2 = dataRecv[0:LengthN]
if _N2!=str(N2):
print "Nonce N2 doesn't match"
return
u.genHashSecretM1(moduli ,client_dh_pub_key)
hash_recv = dataRecv[LengthN:len(dataRecv)]
if hash_recv == u.hashsecret1:
u.genKey(client_dh_pub_key)
else:
print 'Hashes does not match'
return
print 'Sending ACK to ' , username
sym_key_shared = aeskeygen(u.key) # Generate AES key out of DH key
iv = os.urandom(LengthIV)
acknowledge = AESEncrypt('ACK', sym_key_shared, iv) # Encrypt the ACK with the symmetric key
msg = bytes(iv) + bytes(acknowledge)
dynamic_socket.sendto(msg, (addr[0], int(addr[1]))) # Send the ACK to the client
print 'Waiting for Network Information of ',username
(dataRecv, addr) = dynamic_socket.recvfrom(4096)
offset = InitOffset
new_iv = dataRecv[offset:offset+LengthIV]
offset += LengthIV
iv = dataRecv[offset:offset+LengthIV]
offset += LengthIV
cipher_key_new = dataRecv[offset:offset+LengthKey]
offset += LengthKey
nwciphertext = dataRecv[offset:len(dataRecv)]
# Decrypt cipher_key_new with server's private key
new_key_sym = RSADecrypt(cipher_key_new, serverprivkey)
# Decrypt the nwciphertext using symmetric key decryption
plaintext = AESDecrypt(new_key_sym, new_iv, nwciphertext)
user = plaintext.split(',')[0]
enc_nwinfo = plaintext[len(user)+1:len(plaintext)]
# Decrypt the nwinfo using DH key
plaintext = AESDecrypt(sym_key_shared, iv, enc_nwinfo)
ip_address = plaintext.split(',')[0]
port_num = plaintext.split(',')[1]
#print('Received common port and ip')
# Register the client's network info along with the client rsa public key into user_networkinfo table
user_networkinfo[username].append(ip_address)
user_networkinfo[username].append(port_num)
user_networkinfo[username].append(client_rsa_pub_key)
# Register the DH shared key in the user_DHkey table
user_DHkey[username] = sym_key_shared
print('LOGIN SUCCESSFUL')
print('------------------------------------------------------------------')
pass
