from random import choice from Core import Statistics from ID2TLib.IPv4 import IPAddress is_ipv4 = IPAddress.is_ipv4 class PcapAddressOperations(): def __init__(self, statistics: Statistics, uncertain_ip_mult: int=3): """ Initializes a pcap information extractor that uses the provided statistics for its operations. :param statistics: The statistics of the pcap file :param uncertain_ip_mult: the mutliplier to create new address space when the remaining observed space has been drained """ self.statistics = statistics self.UNCERTAIN_IPSPACE_MULTIPLIER = uncertain_ip_mult self._init_ipaddress_ops() def get_probable_router_mac(self): """ Returns the most probable router MAC address based on the most used MAC address in the statistics. :return: the MAC address """ self.probable_router_mac, count = self.statistics.process_db_query("most_used(macAddress)", print_results=False)[0] return self.probable_router_mac # and count as a measure of certainty? def pcap_contains_priv_ips(self): """ Returns if the provided traffic contains private IPs. :return: True if the provided traffic contains private IPs, otherwise False """ return self.contains_priv_ips def get_local_address_range(self): """ Returns a tuple with the start and end of the observed local IP range. :return: The IP range as tuple """ return str(self.min_local_ip), str(self.max_local_ip) def get_count_rem_local_ips(self): """ Returns the number of local IPs in the pcap file that have not aldready been returned by get_existing_local_ips. :return: the not yet assigned local IPs """ return len(self.remaining_local_ips) def get_existing_local_ips(self, count: int=1): """ Returns the given number of local IPs that are existent in the pcap file. :param count: the number of local IPs to return :return: the chosen local IPs """ if count > len(self.remaining_local_ips): print("Warning: There are no more {} local IPs in the .pcap file. Returning all remaining local IPs.".format(count)) total = min(len(self.remaining_local_ips), count) retr_local_ips = [] local_ips = self.remaining_local_ips for _ in range(0, total): random_local_ip = choice(sorted(local_ips)) retr_local_ips.append(str(random_local_ip)) local_ips.remove(random_local_ip) return retr_local_ips def get_new_local_ips(self, count: int=1): """ Returns in the pcap not existent local IPs that are in proximity of the observed local IPs. IPs can be returned that are either between the minimum and maximum observed IP and are therefore considered certain or that are above the observed maximum address, are more likely to not belong to the local network and are therefore considered uncertain. :param count: the number of new local IPs to return :return: the newly created local IP addresses """ # add more unused local ips to the pool, if needed while len(self.unused_local_ips) < count and self.expand_unused_local_ips() == True: pass unused_local_ips = self.unused_local_ips uncertain_local_ips = self.uncertain_local_ips count_certain = min(count, len(unused_local_ips)) retr_local_ips = [] for _ in range(0, count_certain): random_local_ip = choice(sorted(unused_local_ips)) retr_local_ips.append(str(random_local_ip)) unused_local_ips.remove(random_local_ip) # retrieve uncertain local ips if count_certain < count: count_uncertain = count - count_certain # check if new uncertain IPs have to be created if len(uncertain_local_ips) < count_uncertain: ipspace_multiplier = self.UNCERTAIN_IPSPACE_MULTIPLIER max_new_ip = self.max_uncertain_local_ip.to_int() + ipspace_multiplier * count_uncertain count_new_ips = max_new_ip - self.max_uncertain_local_ip.to_int() # create ipspace_multiplier * count_uncertain new uncertain local IP addresses last_gen_ip = None for i in range(1, count_new_ips + 1): ip = IPAddress.from_int(self.max_uncertain_local_ip.to_int() + i) # exclude the definite broadcast address if self.priv_ip_segment: if ip.to_int() >= self.priv_ip_segment.last_address().to_int(): break uncertain_local_ips.add(ip) last_gen_ip = ip self.max_uncertain_local_ip = last_gen_ip # choose the uncertain IPs to return total_uncertain = min(count_uncertain, len(uncertain_local_ips)) for _ in range(0, total_uncertain): random_local_ip = choice(sorted(uncertain_local_ips)) retr_local_ips.append(str(random_local_ip)) uncertain_local_ips.remove(random_local_ip) return retr_local_ips def get_existing_external_ips(self, count: int=1): """ Returns the given number of external IPs that are existent in the pcap file. :param count: the number of external IPs to return :return: the chosen external IPs """ if not (len(self.external_ips) > 0): print("Warning: .pcap does not contain any external ips.") return [] total = min(len(self.remaining_external_ips), count) retr_external_ips = [] external_ips = self.remaining_external_ips for _ in range(0, total): random_external_ip = choice(sorted(external_ips)) retr_external_ips.append(str(random_external_ip)) external_ips.remove(random_external_ip) return retr_external_ips def _init_ipaddress_ops(self): """ Load and process data needed to perform functions on the IP addresses contained in the statistics """ # retrieve local and external IPs all_ips_str = set(self.statistics.process_db_query("all(ipAddress)", print_results=False)) external_ips_str = set(self.statistics.process_db_query("ipAddress(macAddress=%s)" % self.get_probable_router_mac(), print_results=False)) # including router local_ips_str = all_ips_str - external_ips_str external_ips = set() local_ips = set() self.contains_priv_ips = False self.priv_ip_segment = None # convert local IP strings to IPv4.IPAddress representation for ip in local_ips_str: if is_ipv4(ip): ip = IPAddress.parse(ip) if ip.is_private() and not self.contains_priv_ips: self.contains_priv_ips = True self.priv_ip_segment = ip.get_private_segment() # exclude local broadcast address and other special addresses if (not str(ip) == "255.255.255.255") and (not ip.is_localhost()) and (not ip.is_multicast()) and (not ip.is_reserved()) and (not ip.is_zero_conf()): local_ips.add(ip) # convert external IP strings to IPv4.IPAddress representation for ip in external_ips_str: if is_ipv4(ip): ip = IPAddress.parse(ip) # if router MAC can definitely be mapped to local/private IP, add it to local_ips (because at first it is stored in external_ips, see above) # this depends on whether the local network is identified by a private IP address range or not. if ip.is_private(): local_ips.add(ip) # exclude local broadcast address and other special addresses elif (not str(ip) == "255.255.255.255") and (not ip.is_localhost()) and (not ip.is_multicast()) and (not ip.is_reserved()) and (not ip.is_zero_conf()): external_ips.add(ip) # save the certain unused local IPs of the network # to do that, divide the unused local Addressspace into chunks of (chunks_size) Addresses # initally only the first chunk will be used, but more chunks can be added to the pool of unused_local_ips if needed self.min_local_ip, self.max_local_ip = min(local_ips), max(local_ips) local_ip_range = (self.max_local_ip.to_int()) - (self.min_local_ip.to_int() + 1) if local_ip_range < 0: # for min,max pairs like (1,1), (1,2) there is no free address in between, but for (1,1) local_ip_range may be -1, because 1-(1+1)=-1 local_ip_range = 0 # chunk size can be adjusted if needed self.chunk_size = 200 self.current_chunk = 1 if local_ip_range < self.chunk_size: # there are not more than chunk_size unused IP Addresses to begin with self.chunks = 0 self.chunk_remainder = local_ip_range else: # determine how many chunks of (chunk_size) Addresses there are and the save the remainder self.chunks = local_ip_range // self.chunk_size self.chunk_remainder = local_ip_range % self.chunk_size # add the first chunk of IP Addresses self.unused_local_ips = set() self.expand_unused_local_ips() # save the gathered information for efficient later use self.external_ips = frozenset(external_ips) self.remaining_external_ips = external_ips self.max_uncertain_local_ip = self.max_local_ip self.local_ips = frozenset(local_ips) self.remaining_local_ips = local_ips self.uncertain_local_ips = set() def expand_unused_local_ips(self): """ expands the set of unused_local_ips by one chunk_size to illustrate this algorithm: suppose we have a chunksize of 100 and an Address space of 1 to 1000 (1 and 1000 are unused too), we then have 10 chunks every time this method is called, one chunk (100 Addresses) is added, each chunk starts at the base_address + the number of its chunk then, every chunk_amounth'th Address is added. Therefore for 10 chunks, every 10th address is added For the above example for the first, second and last call, we get the following IPs, respectively: first Call: 1+0, 1+10, 1+20, 1+30, ..., 1+990 second Call: 2+0, 2+10, 2+20, 2+30, ..., 2+990 ten'th Call: 10+0, 10+10, 10+20, 10+30, ..., 10+990 :return: False if there are no more available unusd local IP Addresses, True otherwise """ if self.current_chunk == self.chunks+1: # all chunks are used up, therefore add the remainder remainder_base_addr = self.min_local_ip.to_int() + self.chunks*self.chunk_size + 1 for i in range(0,self.chunk_remainder): ip = IPAddress.from_int(remainder_base_addr + i) self.unused_local_ips.add(ip) self.current_chunk = self.current_chunk + 1 return True elif self.current_chunk <= self.chunks: # add another chunk # choose IPs from the whole address space, that is available base_address = self.min_local_ip.to_int() + self.current_chunk for i in range(0,self.chunk_size): ip = IPAddress.from_int(base_address + i*self.chunks) self.unused_local_ips.add(ip) self.current_chunk = self.current_chunk + 1 return True else: # no free IPs remaining return False