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kerberos.py
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kerberos.py
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#!/usr/bin/env python3 -tt
import hashlib
import hmac
from pyasn1.type import univ, char, useful, tag
from pyasn1.codec.ber import encoder, decoder
import datetime
import base64
import sys
#REF: http://tools.ietf.org/id/draft-brezak-win2k-krb-rc4-hmac-03.txt
#T = 1 for TS-ENC-TS in the AS-Request
#T = 8 for the AS-Reply
#T = 7 for the Authenticator in the TGS-Request
#T = 8 for the TGS-Reply
#T = 2 for the Server Ticket in the AP-Request
#T = 11 for the Authenticator in the AP-Request
#T = 12 for the Server returned AP-Reply
#T = 15 in the generation of checksum for the MIC token
#T = 0 in the generation of sequence number for the MIC token
#T = 13 in the generation of checksum for the WRAP token
#T = 0 in the generation of sequence number for the WRAP token
#T = 0 in the generation of encrypted data for the WRAPPED token
def ntlmhash(s):
hash = hashlib.new('md4', s.encode('utf-16le')).digest()
return hash
#return binascii.hexlify(hash)
def rc4crypt(key, data):
x = 0
box = list(range(256))
for i in range(256):
x = (x + box[i] + (key[i % len(key)])) % 256
box[i], box[x] = box[x], box[i]
x = 0
y = 0
out = b''
for char in data:
x = (x + 1) % 256
y = (y + box[x]) % 256
box[x], box[y] = box[y], box[x]
out += bytes([char ^ box[(box[x] + box[y]) % 256]])
return out
#print decoder.decode(enc)
#define KERB_ETYPE_RC4_HMAC 23
KERB_ETYPE_RC4_HMAC = 23
#define KERB_ETYPE_RC4_HMAC_EXP 24
def decrypt(key, messagetype, edata):
#DECRYPT (K, fRC4_EXP, T, edata, edata_len, data, data_len)
#{
# if (fRC4_EXP){
# *((DWORD *)(L40+10)) = T;
# HMAC (K, L40, 14, K1);
# }else{
# HMAC (K, &T, 4, K1);
# }
#K1 = hmac.new(key, chr(messagetype) + "\x00\x00\x00", hashlib.md5).digest() # \x0b = 11
K1 = hmac.new(key, bytes([messagetype]) + b"\x00\x00\x00", hashlib.md5).digest() # \x0b = 11
# memcpy (K2, K1, 16);
K2 = K1
# if (fRC4_EXP) memset (K1+7, 0xAB, 9);
# HMAC (K1, edata, 16, K3); // checksum is at edata
K3 = hmac.new(K1, edata[:16], hashlib.md5).digest()
# RC4(K3, edata + 16, edata_len - 16, edata + 16);
ddata = rc4crypt(K3, edata[16:])
# data_len = edata_len - 16 - 8;
# memcpy (data, edata + 16 + 8, data_len);
#
# // verify generated and received checksums
# HMAC (K2, edata + 16, edata_len - 16, checksum);
checksum = hmac.new(K2, ddata, hashlib.md5).digest()
# if (memcmp(edata, checksum, 16) != 0)
# printf("CHECKSUM ERROR !!!!!!\n");
#}
if checksum == edata[:16]:
#print "Decrypt Checksum: %s" % str(checksum).encode('hex') # == edata[:16])
#print "Checksum Calc: %s" % str(checksum).encode('hex')
#print "Checksum Pkct: %s" % str(edata[:16]).encode('hex')
#print messagetype
#print data
#print "Nonce: %s" % ddata[:8].encode('hex')
#return ddata[8:] # first 8 bytes are nonce, the rest is data
#return {
# 'data': ddata[8:],
# 'nonce': ddata[:8]
#}
return ddata[8:], ddata[:8]
else:
#print "CHECKSUM ERROR!"
return None, None
def encrypt(key, messagetype, data, nonce):
# if (fRC4_EXP){
# *((DWORD *)(L40+10)) = T;
# HMAC (K, L40, 10 + 4, K1);
# }else{
# HMAC (K, &T, 4, K1);
# }
K1 = hmac.new(key, bytes(messagetype) + b'\x00\x00\x00', hashlib.md5).digest() # \x0b = 11
# memcpy (K2, K1, 16);
K2 = K1
# if (fRC4_EXP) memset (K1+7, 0xAB, 9);
# add_8_random_bytes(data, data_len, conf_plus_data);
ddata = nonce + data
# HMAC (K2, conf_plus_data, 8 + data_len, checksum);
checksum = hmac.new(K2, ddata, hashlib.md5).digest()
# HMAC (K1, checksum, 16, K3);
K3 = hmac.new(K1, checksum, hashlib.md5).digest()
#print "K3: %s" % K3.encode('hex')
# RC4(K3, conf_plus_data, 8 + data_len, edata + 16);
# print "EN DDATA: %s" % ddata[:32].encode('hex')
edata = rc4crypt(K3, ddata)
# memcpy (edata, checksum, 16);
# edata_len = 16 + 8 + data_len;
return checksum + edata
def zerosigs(data):
d = list(map(ord, str(data)))
for i in range(5, 21): # zero out the 16 char sig, KDC
d[len(d) - i] = 0
for i in range(29, 45): # zero out the 16 char sig, Server
d[len(d) - i] = 0
retval = "".join(map(chr, d))
#print retval.encode('hex')
return bytearray(retval,"utf-8")
def chksum(K, T, data):
data = zerosigs(data)
# K = the Key
#T = the message type, encoded as a little-endian four-byte integer
#Ksign = HMAC(K, "signaturekey") //includes zero octet at end
SIGNATUREKEY = b'signaturekey\x00'
Ksign = hmac.new(K, SIGNATUREKEY, hashlib.md5).digest()
#tmp = MD5(concat(T, data))
tmp = hashlib.md5(T + data).digest()
#CHKSUM = HMAC(Ksign, tmp)
chksum = hmac.new(Ksign, tmp, hashlib.md5).digest()
return chksum
def getservsig(encchunk):
return str(encchunk[-44:-28])
def getprivsig(encchunk):
return str(encchunk[-20:-4])
def printdecode(kerbpayload, ktype=2):
d = decoder.decode(kerbpayload)
if ktype == 32:
#print "Protocol Version (pvno): " + str(d[0][0])
print("Message Type: " + str(d[0][1]))
print("Realm: " + str(d[0][2]))
print("Principal: " + str(d[0][3][1][0]))
print("Ticket Version (tkt-vno): " + str(d[0][4][0]))
print("Ticket Realm: " + str(d[0][4][1]))
#print "Name-Type (Service & Instance): " + str(d[0][4][2][0])
print("Server, Name: " + str(d[0][4][2][1][0]))
print("Server, Name: " + str(d[0][4][2][1][1]))
#print "Data: " + str(d[0][4][3][2]).encode('hex')
#print "Encryption Type: : " + str(d[0][5][0])
#print "Data: " + str(d[0])
#print "Server Realm: " + str(d[0][4][2][4])
elif ktype == 2:
print("a")
def extract_ticket_from_kirbi(filename):
with open(filename, 'rb') as fd:
data = fd.read()
return extract_ticket(data)
def extract_ticket(data):
if data[0] == 0x76:
# ram dump
#enctickets.append(((decoder.decode(data)[0][2][0][3][2]).asOctets(), i, f))
return (decoder.decode(data)[0][2][0][3][2]).asOctets()
elif data[:2] == b'6d':
# honestly, i completely forgot. I think this is from a pcap -Tim
#enctickets.append(((decoder.decode(ticket.decode('hex'))[0][4][3][2]).asOctets(), i, f))
return (decoder.decode(ticket.decode('hex'))[0][4][3][2]).asOctets()