Utility.py 14 KB

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  1. import calendar as cal
  2. import datetime as dt
  3. import ipaddress
  4. import os
  5. import random as rnd
  6. import matplotlib
  7. import scipy.stats as stats
  8. matplotlib.use('Agg', force=True)
  9. import lea
  10. import xdg.BaseDirectory as BaseDir
  11. import scapy.layers.inet as inet
  12. CACHE_DIR = os.path.join(BaseDir.xdg_cache_home, 'id2t')
  13. CODE_DIR = os.path.dirname(os.path.abspath(__file__)) + "/../"
  14. ROOT_DIR = CODE_DIR + "../"
  15. RESOURCE_DIR = ROOT_DIR + "resources/"
  16. TEST_DIR = RESOURCE_DIR + "test/"
  17. # List of common operation systems
  18. platforms = {"win7", "win10", "winxp", "win8.1", "macos", "linux", "win8", "winvista", "winnt", "win2000"}
  19. # Distribution of common operation systems
  20. platform_probability = {"win7": 48.43, "win10": 27.99, "winxp": 6.07, "win8.1": 6.07, "macos": 5.94, "linux": 3.38,
  21. "win8": 1.35, "winvista": 0.46, "winnt": 0.31}
  22. # List of no-ops
  23. x86_nops = {b'\x90', b'\xfc', b'\xfd', b'\xf8', b'\xf9', b'\xf5', b'\x9b'}
  24. # List of pseudo no-ops (includes ops which won't change the state e.g. read access)
  25. x86_pseudo_nops = {b'\x97', b'\x96', b'\x95', b'\x93', b'\x92', b'\x91', b'\x99', b'\x4d', b'\x48', b'\x47', b'\x4f',
  26. b'\x40', b'\x41', b'\x37', b'\x3f', b'\x27', b'\x2f', b'\x46', b'\x4e', b'\x98', b'\x9f', b'\x4a',
  27. b'\x44', b'\x42', b'\x43', b'\x49', b'\x4b', b'\x45', b'\x4c', b'\x60', b'\x0e', b'\x1e', b'\x50',
  28. b'\x55', b'\x53', b'\x51', b'\x57', b'\x52', b'\x06', b'\x56', b'\x54', b'\x16', b'\x58', b'\x5d',
  29. b'\x5b', b'\x59', b'\x5f', b'\x5a', b'\x5e', b'\xd6'}
  30. # Characters which result in operational behaviour (e.g. FTPWinaXeExploit.py)
  31. forbidden_chars = [b'\x00', b'\x0a', b'\x0d']
  32. # Used in get_attacker_config
  33. attacker_port_mapping = {}
  34. # Used in get_attacker_config
  35. attacker_ttl_mapping = {}
  36. # Identifier for attacks
  37. generic_attack_names = {"attack", "exploit"}
  38. def update_timestamp(timestamp, pps, delay=0):
  39. """
  40. Calculates the next timestamp to be used based on the packet per second rate (pps) and the maximum delay.
  41. :return: Timestamp to be used for the next packet.
  42. """
  43. if delay == 0:
  44. # Calculate request timestamp
  45. # To imitate the bursty behavior of traffic
  46. randomdelay = lea.Lea.fromValFreqsDict({1 / pps: 70, 2 / pps: 20, 5 / pps: 7, 10 / pps: 3})
  47. return timestamp + rnd.uniform(1 / pps, randomdelay.random())
  48. else:
  49. # Calculate reply timestamp
  50. randomdelay = lea.Lea.fromValFreqsDict({2 * delay: 70, 3 * delay: 20, 5 * delay: 7, 10 * delay: 3})
  51. return timestamp + rnd.uniform(1 / pps + delay, 1 / pps + randomdelay.random())
  52. def get_interval_pps(complement_interval_pps, timestamp):
  53. """
  54. Gets the packet rate (pps) for a specific time interval.
  55. :param complement_interval_pps: an array of tuples (the last timestamp in the interval, the packet rate in the
  56. corresponding interval).
  57. :param timestamp: the timestamp at which the packet rate is required.
  58. :return: the corresponding packet rate (pps) .
  59. """
  60. for row in complement_interval_pps:
  61. if timestamp <= row[0]:
  62. return row[1]
  63. return complement_interval_pps[-1][1] # in case the timestamp > capture max timestamp
  64. def get_nth_random_element(*element_list):
  65. """
  66. Returns the n-th element of every list from an arbitrary number of given lists.
  67. For example, list1 contains IP addresses, list 2 contains MAC addresses. Use of this function ensures that
  68. the n-th IP address uses always the n-th MAC address.
  69. :param element_list: An arbitrary number of lists.
  70. :return: A tuple of the n-th element of every list.
  71. """
  72. if len(element_list) <= 0:
  73. return None
  74. elif len(element_list) == 1 and len(element_list[0]) > 0:
  75. return rnd.choice(element_list[0])
  76. else:
  77. range_max = min([len(x) for x in element_list])
  78. if range_max > 0:
  79. range_max -= 1
  80. n = rnd.randint(0, range_max)
  81. return tuple(x[n] for x in element_list)
  82. else:
  83. return None
  84. def get_rnd_os():
  85. """
  86. Chooses random platform over an operating system probability distribution
  87. :return: random platform as string
  88. """
  89. os_dist = lea.Lea.fromValFreqsDict(platform_probability)
  90. return os_dist.random()
  91. def check_platform(platform: str):
  92. """
  93. Checks if the given platform is currently supported
  94. if not exits with error
  95. :param platform: the platform, which should be validated
  96. """
  97. if platform not in platforms:
  98. print("\nERROR: Invalid platform: " + platform + "." +
  99. "\n Please select one of the following platforms: ", platforms)
  100. exit(1)
  101. def get_ip_range(start_ip: str, end_ip: str):
  102. """
  103. Generates a list of IPs of a given range. If the start_ip is greater than the end_ip, the reverse range is generated
  104. :param start_ip: the start_ip of the desired IP-range
  105. :param end_ip: the end_ip of the desired IP-range
  106. :return: a list of all IPs in the desired IP-range, including start-/end_ip
  107. """
  108. start = ipaddress.ip_address(start_ip)
  109. end = ipaddress.ip_address(end_ip)
  110. ips = []
  111. if start < end:
  112. while start <= end:
  113. ips.append(start.exploded)
  114. start = start + 1
  115. elif start > end:
  116. while start >= end:
  117. ips.append(start.exploded)
  118. start = start - 1
  119. else:
  120. ips.append(start_ip)
  121. return ips
  122. def generate_source_port_from_platform(platform: str, previous_port=0):
  123. """
  124. Generates the next source port according to the TCP-port-selection strategy of the given platform
  125. :param platform: the platform for which to generate source ports
  126. :param previous_port: the previously used/generated source port. Must be 0 if no port was generated before
  127. :return: the next source port for the given platform
  128. """
  129. check_platform(platform)
  130. if platform in {"winnt", "winxp", "win2000"}:
  131. if (previous_port == 0) or (previous_port + 1 > 5000):
  132. return rnd.randint(1024, 5000)
  133. else:
  134. return previous_port + 1
  135. elif platform == "linux":
  136. return rnd.randint(32768, 61000)
  137. else:
  138. if (previous_port == 0) or (previous_port + 1 > 65535):
  139. return rnd.randint(49152, 65535)
  140. else:
  141. return previous_port + 1
  142. def get_filetime_format(timestamp):
  143. """
  144. Converts a timestamp into MS FILETIME format
  145. :param timestamp: a timestamp in seconds
  146. :return: MS FILETIME timestamp
  147. """
  148. boot_datetime = dt.datetime.fromtimestamp(timestamp)
  149. if boot_datetime.tzinfo is None or boot_datetime.tzinfo.utcoffset(boot_datetime) is None:
  150. boot_datetime = boot_datetime.replace(tzinfo=boot_datetime.tzname())
  151. boot_filetime = 116444736000000000 + (cal.timegm(boot_datetime.timetuple()) * 10000000)
  152. return boot_filetime + (boot_datetime.microsecond * 10)
  153. def get_rnd_boot_time(timestamp, platform="winxp"):
  154. """
  155. Generates a random boot time based on a given timestamp and operating system
  156. :param timestamp: a timestamp in seconds
  157. :param platform: a platform as string as specified in check_platform above. default is winxp. this param is optional
  158. :return: timestamp of random boot time in seconds since EPOCH
  159. """
  160. check_platform(platform)
  161. if platform is "linux":
  162. uptime_in_days = lea.Lea.fromValFreqsDict({3: 50, 7: 25, 14: 12.5, 31: 6.25, 92: 3.125, 183: 1.5625,
  163. 365: 0.78125, 1461: 0.390625, 2922: 0.390625})
  164. elif platform is "macos":
  165. uptime_in_days = lea.Lea.fromValFreqsDict({7: 50, 14: 25, 31: 12.5, 92: 6.25, 183: 3.125, 365: 3.076171875,
  166. 1461: 0.048828125})
  167. else:
  168. uptime_in_days = lea.Lea.fromValFreqsDict({3: 50, 7: 25, 14: 12.5, 31: 6.25, 92: 3.125, 183: 1.5625,
  169. 365: 0.78125, 1461: 0.78125})
  170. timestamp -= rnd.randint(0, uptime_in_days.random() * 86400)
  171. return timestamp
  172. def get_rnd_x86_nop(count=1, side_effect_free=False, char_filter=set()):
  173. """
  174. Generates a specified number of x86 single-byte (pseudo-)NOPs
  175. :param count: The number of bytes to generate
  176. :param side_effect_free: Determines whether NOPs with side-effects (to registers or the stack) are allowed
  177. :param char_filter: A set of bytes which are forbidden to generate
  178. :return: Random x86 NOP bytestring
  179. """
  180. result = b''
  181. nops = x86_nops.copy()
  182. if not side_effect_free:
  183. nops |= x86_pseudo_nops.copy()
  184. if not isinstance(char_filter, set):
  185. char_filter = set(char_filter)
  186. nops = list(nops - char_filter)
  187. for i in range(0, count):
  188. result += nops[rnd.randint(0, len(nops) - 1)]
  189. return result
  190. def get_rnd_bytes(count=1, ignore=None):
  191. """
  192. Generates a specified number of random bytes while excluding unwanted bytes
  193. :param count: Number of wanted bytes
  194. :param ignore: The bytes, which should be ignored, as an array
  195. :return: Random bytestring
  196. """
  197. if ignore is None:
  198. ignore = []
  199. result = b''
  200. for i in range(0, count):
  201. char = os.urandom(1)
  202. while char in ignore:
  203. char = os.urandom(1)
  204. result += char
  205. return result
  206. def check_payload_len(payload_len: int, limit: int):
  207. """
  208. Checks if the len of the payload exceeds a given limit
  209. :param payload_len: The length of the payload
  210. :param limit: The limit of the length of the payload which is allowed
  211. """
  212. if payload_len > limit:
  213. print("\nCustom payload too long: ", payload_len, " bytes. Should be a maximum of ", limit, " bytes.")
  214. exit(1)
  215. def get_bytes_from_file(filepath):
  216. """
  217. Converts the content of a file into its byte representation
  218. The content of the file can either be a string or hexadecimal numbers/bytes (e.g. shellcode)
  219. The file must have the keyword "str" or "hex" in its first line to specify the rest of the content
  220. If the content is hex, whitespaces, backslashes, "x", quotation marks and "+" are removed
  221. Example for a hexadecimal input file:
  222. hex
  223. "abcd ef \xff10\ff 'xaa' x \ ab"
  224. Output: b'\xab\xcd\xef\xff\x10\xff\xaa\xab'
  225. :param filepath: The path of the file from which to get the bytes
  226. :return: The bytes of the file (either a byte representation of a string or the bytes contained in the file)
  227. """
  228. try:
  229. file = open(filepath)
  230. result_bytes = b''
  231. header = file.readline().strip()
  232. content = file.read()
  233. if header == "hex":
  234. content = content.replace(" ", "").replace("\n", "").replace("\\", "").replace("x", "").replace("\"", "") \
  235. .replace("'", "").replace("+", "").replace("\r", "")
  236. try:
  237. result_bytes = bytes.fromhex(content)
  238. except ValueError:
  239. print("\nERROR: Content of file is not all hexadecimal.")
  240. file.close()
  241. exit(1)
  242. elif header == "str":
  243. result_bytes = content.strip().encode()
  244. else:
  245. print("\nERROR: Invalid header found: " + header + ". Try 'hex' or 'str' followed by endline instead.")
  246. file.close()
  247. exit(1)
  248. for forbidden_char in forbidden_chars:
  249. if forbidden_char in result_bytes:
  250. print("\nERROR: Forbidden character found in payload: ", forbidden_char)
  251. file.close()
  252. exit(1)
  253. file.close()
  254. return result_bytes
  255. except FileNotFoundError:
  256. print("\nERROR: File not found: ", filepath)
  257. exit(1)
  258. def handle_most_used_outputs(most_used_x):
  259. """
  260. :param most_used_x: Element or list (e.g. from SQL-query output) which should only be one element
  261. :return: most_used_x if it's not a list. The first element of most_used_x after being sorted if it's a list.
  262. None if that list is empty.
  263. """
  264. if isinstance(most_used_x, list):
  265. if len(most_used_x) == 0:
  266. return None
  267. most_used_x.sort()
  268. return most_used_x[0]
  269. else:
  270. return most_used_x
  271. def get_attacker_config(ip_source_list, ip_address: str):
  272. """
  273. Returns the attacker configuration depending on the IP address, this includes the port for the next
  274. attacking packet and the previously used (fixed) TTL value.
  275. :param ip_source_list: List of source IPs
  276. :param ip_address: The IP address of the attacker
  277. :return: A tuple consisting of (port, ttlValue)
  278. """
  279. # Gamma distribution parameters derived from MAWI 13.8G dataset
  280. alpha, loc, beta = (2.3261710235, -0.188306914406, 44.4853123884)
  281. gd = stats.gamma.rvs(alpha, loc=loc, scale=beta, size=len(ip_source_list))
  282. # Determine port
  283. port = attacker_port_mapping.get(ip_address)
  284. if port is not None: # use next port
  285. next_port = attacker_port_mapping.get(ip_address) + 1
  286. if next_port > (2 ** 16 - 1):
  287. next_port = 1
  288. else: # generate starting port
  289. next_port = inet.RandShort()
  290. attacker_port_mapping[ip_address] = next_port
  291. # Determine TTL value
  292. ttl = attacker_ttl_mapping.get(ip_address)
  293. if ttl is None: # determine TTL value
  294. is_invalid = True
  295. pos = ip_source_list.index(ip_address)
  296. pos_max = len(gd)
  297. while is_invalid:
  298. ttl = int(round(gd[pos]))
  299. if 0 < ttl < 256: # validity check
  300. is_invalid = False
  301. else:
  302. pos = (pos + 1) % pos_max
  303. attacker_ttl_mapping[ip_address] = ttl
  304. # return port and TTL
  305. return next_port, ttl
  306. def remove_generic_ending(string):
  307. """"
  308. Returns the input string with it's ending cut off, in case it was a generic one
  309. :param string: Input string
  310. :return: Input string with ending cut off
  311. """
  312. for end in generic_attack_names:
  313. if string.endswith(end):
  314. return string[:-len(end)]
  315. return string