import abc import csv import ipaddress import os import random import random as rnd import re import socket import sys import tempfile import time # TODO: double check this import # does it complain because libpcapreader is not a .py? import ID2TLib.libpcapreader as pr import lea import numpy as np import scapy.layers.inet as inet import scapy.utils import Attack.AttackParameters as atkParam import ID2TLib.Utility as Util class BaseAttack(metaclass=abc.ABCMeta): """ Abstract base class for all attack classes. Provides basic functionalities, like parameter validation. """ def __init__(self, name, description, attack_type): """ To be called within the individual attack class to initialize the required parameters. :param name: The name of the attack class. :param description: A short description of the attack. :param attack_type: The type the attack belongs to, like probing/scanning, malware. """ # Reference to statistics class self.statistics = None # Class fields self.attack_name = name self.attack_description = description self.attack_type = attack_type self.params = {} self.supported_params = {} self.attack_start_utime = 0 self.attack_end_utime = 0 self.start_time = 0 self.finish_time = 0 self.packets = [] self.path_attack_pcap = "" def set_statistics(self, statistics): """ Specify the statistics object that will be used to calculate the parameters of this attack. The statistics are used to calculate default parameters and to process user supplied queries. :param statistics: Reference to a statistics object. """ self.statistics = statistics @abc.abstractmethod def init_params(self): """ Initialize all required parameters taking into account user supplied values. If no value is supplied, or if a user defined query is supplied, use a statistics object to do the calculations. A call to this function requires a call to 'set_statistics' first. """ pass @abc.abstractmethod def generate_attack_packets(self): """ Creates the attack packets. """ pass @abc.abstractmethod def generate_attack_pcap(self): """ Creates a pcap containing the attack packets. :return: The location of the generated pcap file. """ pass ################################################ # HELPER VALIDATION METHODS # Used to validate the given parameter values ################################################ @staticmethod def _is_mac_address(mac_address: str): """ Verifies if the given string is a valid MAC address. Accepts the formats 00:80:41:ae:fd:7e and 00-80-41-ae-fd-7e. :param mac_address: The MAC address as string. :return: True if the MAC address is valid, otherwise False. """ pattern = re.compile('^([0-9A-Fa-f]{2}[:-]){5}([0-9A-Fa-f]{2})$', re.MULTILINE) if isinstance(mac_address, list): for mac in mac_address: if re.match(pattern, mac) is None: return False else: if re.match(pattern, mac_address) is None: return False return True @staticmethod def _is_ip_address(ip_address: str): """ Verifies that the given string or list of IP addresses (strings) is a valid IPv4/IPv6 address. Accepts comma-separated lists of IP addresses, like "192.169.178.1, 192.168.178.2" :param ip_address: The IP address(es) as list of strings, comma-separated or dash-separated string. :return: True if all IP addresses are valid, otherwise False. And a list of IP addresses as string. """ def append_ips(ip_address_input): """ Recursive appending function to handle lists and ranges of IP addresses. :param ip_address_input: The IP address(es) as list of strings, comma-separated or dash-separated string. :return: List of all given IP addresses. """ ip_list = [] is_valid = True for ip in ip_address_input: if '-' in ip: ip_range = ip.split('-') ip_range = Util.get_ip_range(ip_range[0], ip_range[1]) is_valid, ips = append_ips(ip_range) ip_list.extend(ips) else: try: ipaddress.ip_address(ip) ip_list.append(ip) except ValueError: return False, ip_list return is_valid, ip_list # a comma-separated list of IP addresses must be split first if isinstance(ip_address, str): ip_address = ip_address.split(',') result, ip_address_output = append_ips(ip_address) if len(ip_address_output) == 1: return result, ip_address_output[0] else: return result, ip_address_output @staticmethod def _is_port(ports_input: str): """ Verifies if the given value is a valid port. Accepts port ranges, like 80-90, 80..99, 80...99. :param ports_input: The port number as int or string. :return: True if the port number is valid, otherwise False. If a single port or a comma-separated list of ports was given, a list of int is returned. If a port range was given, the range is resolved and a list of int is returned. """ def _is_invalid_port(num): """ Checks whether the port number is invalid. :param num: The port number as int. :return: True if the port number is invalid, otherwise False. """ return num < 1 or num > 65535 if ports_input is None or ports_input is "": return False if isinstance(ports_input, str): ports_input = ports_input.replace(' ', '').split(',') elif isinstance(ports_input, int): ports_input = [ports_input] elif len(ports_input) is 0: return False ports_output = [] for port_entry in ports_input: if isinstance(port_entry, int): if _is_invalid_port(port_entry): return False ports_output.append(port_entry) # TODO: validate last condition elif isinstance(port_entry, str) and port_entry.isdigit(): # port_entry describes a single port port_entry = int(port_entry) if _is_invalid_port(port_entry): return False ports_output.append(port_entry) elif '-' in port_entry or '..' in port_entry: # port_entry describes a port range # allowed format: '1-49151', '1..49151', '1...49151' match = re.match(r'^([0-9]{1,5})(?:-|\.{2,3})([0-9]{1,5})$', str(port_entry)) # check validity of port range # and create list of ports derived from given start and end port (port_start, port_end) = int(match.group(1)), int(match.group(2)) if _is_invalid_port(port_start) or _is_invalid_port(port_end): return False else: ports_list = [i for i in range(port_start, port_end + 1)] # append ports at ports_output list ports_output += ports_list if len(ports_output) == 1: return True, ports_output[0] else: return True, ports_output @staticmethod def _is_timestamp(timestamp: str): """ Checks whether the given value is in a valid timestamp format. The accepted format is: YYYY-MM-DD h:m:s, whereas h, m, s may be one or two digits. :param timestamp: The timestamp to be checked. :return: True if the timestamp is valid, otherwise False. """ is_valid = re.match(r'[0-9]{4}(?:-[0-9]{1,2}){2} (?:[0-9]{1,2}:){2}[0-9]{1,2}', timestamp) return is_valid is not None @staticmethod def _is_boolean(value): """ Checks whether the given value (string or bool) is a boolean. Strings are valid booleans if they are in: {y, yes, t, true, on, 1, n, no, f, false, off, 0}. :param value: The value to be checked. :return: True if the value is a boolean, otherwise false. And the casted boolean. """ # If value is already a boolean if isinstance(value, bool): return True, value # If value is a string # True values are y, yes, t, true, on and 1; # False values are n, no, f, false, off and 0. # Raises ValueError if value is anything else. try: import distutils.core import distutils.util value = distutils.util.strtobool(value.lower()) is_bool = True except ValueError: is_bool = False return is_bool, value @staticmethod def _is_float(value): """ Checks whether the given value is a float. :param value: The value to be checked. :return: True if the value is a float, otherwise False. And the casted float. """ try: value = float(value) return True, value except ValueError: return False, value @staticmethod def _is_domain(val: str): """ Verifies that the given string is a valid URI. :param val: The URI as string. :return: True if URI is valid, otherwise False. """ domain = re.match(r'^(?:[a-zA-Z]|[0-9]|[$-_@.&+]|[!*\(\),]|(?:%[0-9a-fA-F][0-9a-fA-F]))+$', val) return domain is not None ######################################### # HELPER METHODS ######################################### @staticmethod def set_seed(seed: int): """ :param seed: The random seed to be set. """ if isinstance(seed, int): random.seed(seed) def set_start_time(self): """ Set the current time as global starting time. """ self.start_time = time.time() def set_finish_time(self): """ Set the current time as global finishing time. """ self.finish_time = time.time() def get_packet_generation_time(self): """ :return difference between starting and finishing time. """ return self.finish_time - self.start_time def add_param_value(self, param, value): """ Adds the pair param : value to the dictionary of attack parameters. Prints and error message and skips the parameter if the validation fails. :param param: Name of the parameter that we wish to modify. :param value: The value we wish to assign to the specified parameter. :return: None. """ # This function call is valid only if there is a statistics object available. if self.statistics is None: print('Error: Attack parameter added without setting a statistics object first.') exit(1) # by default no param is valid is_valid = False # get AttackParameters instance associated with param # for default values assigned in attack classes, like Parameter.PORT_OPEN if isinstance(param, atkParam.Parameter): param_name = param # for values given by user input, like port.open else: # Get Enum key of given string identifier param_name = atkParam.Parameter(param) # Get parameter type of attack's required_params param_type = self.supported_params.get(param_name) # Verify validity of given value with respect to parameter type if param_type is None: print('Parameter ' + str(param_name) + ' not available for chosen attack. Skipping parameter.') # If value is query -> get value from database elif self.statistics.is_query(value): value = self.statistics.process_db_query(value, False) if value is not None and value is not "": is_valid = True else: print('Error in given parameter value: ' + str(value) + '. Data could not be retrieved.') # Validate parameter depending on parameter's type elif param_type == atkParam.ParameterTypes.TYPE_IP_ADDRESS: is_valid, value = self._is_ip_address(value) elif param_type == atkParam.ParameterTypes.TYPE_PORT: is_valid, value = self._is_port(value) elif param_type == atkParam.ParameterTypes.TYPE_MAC_ADDRESS: is_valid = self._is_mac_address(value) elif param_type == atkParam.ParameterTypes.TYPE_INTEGER_POSITIVE: if isinstance(value, int) and int(value) >= 0: is_valid = True elif isinstance(value, str) and value.isdigit() and int(value) >= 0: is_valid = True value = int(value) elif param_type == atkParam.ParameterTypes.TYPE_STRING: if isinstance(value, str): is_valid = True elif param_type == atkParam.ParameterTypes.TYPE_FLOAT: is_valid, value = self._is_float(value) # this is required to avoid that the timestamp's microseconds of the first attack packet is '000000' # but microseconds are only chosen randomly if the given parameter does not already specify it # e.g. inject.at-timestamp=123456.987654 -> is not changed # e.g. inject.at-timestamp=123456 -> is changed to: 123456.[random digits] if param_name == atkParam.Parameter.INJECT_AT_TIMESTAMP and is_valid and ((value - int(value)) == 0): value = value + random.uniform(0, 0.999999) elif param_type == atkParam.ParameterTypes.TYPE_TIMESTAMP: is_valid = self._is_timestamp(value) elif param_type == atkParam.ParameterTypes.TYPE_BOOLEAN: is_valid, value = self._is_boolean(value) elif param_type == atkParam.ParameterTypes.TYPE_PACKET_POSITION: ts = pr.pcap_processor(self.statistics.pcap_filepath, "False").get_timestamp_mu_sec(int(value)) if 0 <= int(value) <= self.statistics.get_packet_count() and ts >= 0: is_valid = True param_name = atkParam.Parameter.INJECT_AT_TIMESTAMP value = (ts / 1000000) # convert microseconds from getTimestampMuSec into seconds elif param_type == atkParam.ParameterTypes.TYPE_DOMAIN: is_valid = self._is_domain(value) # add value iff validation was successful if is_valid: self.params[param_name] = value else: print("ERROR: Parameter " + str(param) + " or parameter value " + str(value) + " not valid. Skipping parameter.") def get_param_value(self, param: atkParam.Parameter): """ Returns the parameter value for a given parameter. :param param: The parameter whose value is wanted. :return: The parameter's value. """ return self.params.get(param) def check_parameters(self): """ Checks whether all parameter values are defined. If a value is not defined, the application is terminated. However, this should not happen as all attack should define default parameter values. """ # parameters which do not require default values non_obligatory_params = [atkParam.Parameter.INJECT_AFTER_PACKET, atkParam.Parameter.NUMBER_ATTACKERS] for param, param_type in self.supported_params.items(): # checks whether all params have assigned values, INJECT_AFTER_PACKET must not be considered because the # timestamp derived from it is set to Parameter.INJECT_AT_TIMESTAMP if param not in self.params.keys() and param not in non_obligatory_params: print("\033[91mCRITICAL ERROR: Attack '" + self.attack_name + "' does not define the parameter '" + str(param) + "'.\n The attack must define default values for all parameters." + "\n Cannot continue attack generation.\033[0m") import sys sys.exit(0) def write_attack_pcap(self, packets: list, append_flag: bool = False, destination_path: str = None): """ Writes the attack's packets into a PCAP file with a temporary filename. :return: The path of the written PCAP file. """ # Only check params initially when attack generation starts if append_flag is False and destination_path is None: # Check if all req. parameters are set self.check_parameters() # Determine destination path if destination_path is not None and os.path.exists(destination_path): destination = destination_path else: temp_file = tempfile.NamedTemporaryFile(delete=False, suffix='.pcap') destination = temp_file.name # Write packets into pcap file pktdump = scapy.utils.PcapWriter(destination, append=append_flag) pktdump.write(packets) # Store pcap path and close file objects pktdump.close() return destination def get_reply_delay(self, ip_dst): """ Gets the minimum and the maximum reply delay for all the connections of a specific IP. :param ip_dst: The IP to reterive its reply delay. :return minDelay: minimum delay :return maxDelay: maximum delay """ result = self.statistics.process_db_query( "SELECT AVG(minDelay), AVG(maxDelay) FROM conv_statistics WHERE ipAddressB='" + ip_dst + "';") if result[0][0] and result[0][1]: min_delay = result[0][0] max_delay = result[0][1] else: all_min_delays = self.statistics.process_db_query("SELECT minDelay FROM conv_statistics LIMIT 500;") min_delay = np.median(all_min_delays) all_max_delays = self.statistics.process_db_query("SELECT maxDelay FROM conv_statistics LIMIT 500;") max_delay = np.median(all_max_delays) min_delay = int(min_delay) * 10 ** -6 # convert from micro to seconds max_delay = int(max_delay) * 10 ** -6 return min_delay, max_delay @staticmethod def packets_to_convs(exploit_raw_packets): """ Classifies a bunch of packets to conversations groups. A conversation is a set of packets go between host A (IP,port) to host B (IP,port) :param exploit_raw_packets: A set of packets contains several conversations. :return conversations: A set of arrays, each array contains the packet of specifc conversation :return orderList_conversations: An array contains the conversations ids (IP_A,port_A, IP_b,port_B) in the order they appeared in the original packets. """ conversations = {} order_list_conversations = [] for pkt_num, pkt in enumerate(exploit_raw_packets): eth_frame = inet.Ether(pkt[0]) ip_pkt = eth_frame.payload ip_dst = ip_pkt.getfieldval("dst") ip_src = ip_pkt.getfieldval("src") tcp_pkt = ip_pkt.payload port_dst = tcp_pkt.getfieldval("dport") port_src = tcp_pkt.getfieldval("sport") conv_req = (ip_src, port_src, ip_dst, port_dst) conv_rep = (ip_dst, port_dst, ip_src, port_src) if conv_req not in conversations and conv_rep not in conversations: pkt_list = [pkt] conversations[conv_req] = pkt_list # Order list of conv order_list_conversations.append(conv_req) else: if conv_req in conversations: pkt_list = conversations[conv_req] pkt_list.append(pkt) conversations[conv_req] = pkt_list else: pkt_list = conversations[conv_rep] pkt_list.append(pkt) conversations[conv_rep] = pkt_list return conversations, order_list_conversations @staticmethod def is_valid_ip_address(addr): """ Checks if the IP address family is supported. :param addr: IP address to be checked. :return: Boolean """ try: socket.inet_aton(addr) return True except socket.error: return False @staticmethod def ip_src_dst_equal_check(ip_source, ip_destination): """ Checks if the source IP and destination IP are equal. :param ip_source: source IP address. :param ip_destination: destination IP address. """ equal = False if isinstance(ip_source, list): if ip_destination in ip_source: equal = True else: if ip_source == ip_destination: equal = True if equal: print("\nERROR: Invalid IP addresses; source IP is the same as destination IP: " + ip_destination + ".") sys.exit(0) @staticmethod def get_inter_arrival_time(packets, distribution: bool = False): """ Gets the inter-arrival times array and its distribution of a set of packets. :param packets: the packets to extract their inter-arrival time. :param distribution: build distribution dictionary or not :return inter_arrival_times: array of the inter-arrival times :return dict: the inter-arrival time distribution as a histogram {inter-arrival time:frequency} """ inter_arrival_times = [] prvs_pkt_time = 0 for index, pkt in enumerate(packets): timestamp = pkt[2][0] + pkt[2][1] / 10 ** 6 if index == 0: prvs_pkt_time = timestamp inter_arrival_times.append(0) else: inter_arrival_times.append(timestamp - prvs_pkt_time) prvs_pkt_time = timestamp if distribution: # Build a distribution dictionary freq, values = np.histogram(inter_arrival_times, bins=20) dist_dict = {} for i, val in enumerate(values): if i < len(freq): dist_dict[str(val)] = freq[i] return inter_arrival_times, dist_dict else: return inter_arrival_times @staticmethod def clean_white_spaces(str_param): """ Delete extra backslash from white spaces. This function is used to process the payload of packets. :param str_param: the payload to be processed. """ str_param = str_param.replace("\\n", "\n") str_param = str_param.replace("\\r", "\r") str_param = str_param.replace("\\t", "\t") str_param = str_param.replace("\\\'", "\'") return str_param def modify_http_header(self, str_tcp_seg, orig_target_uri, target_uri, orig_ip_dst, target_host): """ Substitute the URI and HOST in a HTTP header with new values. :param str_tcp_seg: the payload to be processed. :param orig_target_uri: old URI :param target_uri: new URI :param orig_ip_dst: old host :param target_host: new host """ if len(str_tcp_seg) > 0: # convert payload bytes to str => str = "b'..\\r\\n..'" str_tcp_seg = str_tcp_seg[2:-1] str_tcp_seg = str_tcp_seg.replace(orig_target_uri, target_uri) str_tcp_seg = str_tcp_seg.replace(orig_ip_dst, target_host) str_tcp_seg = self.clean_white_spaces(str_tcp_seg) return str_tcp_seg def get_ip_data(self, ip_address: str): """ :param ip_address: the ip of which (packet-)data shall be returned :return: MSS, TTL and Window Size values of the given IP """ # Set MSS (Maximum Segment Size) based on MSS distribution of IP address mss_dist = self.statistics.get_mss_distribution(ip_address) if len(mss_dist) > 0: mss_prob_dict = lea.Lea.fromValFreqsDict(mss_dist) mss_value = mss_prob_dict.random() else: mss_value = Util.handle_most_used_outputs(self.statistics.process_db_query("most_used(mssValue)")) # Set TTL based on TTL distribution of IP address ttl_dist = self.statistics.get_ttl_distribution(ip_address) if len(ttl_dist) > 0: ttl_prob_dict = lea.Lea.fromValFreqsDict(ttl_dist) ttl_value = ttl_prob_dict.random() else: ttl_value = Util.handle_most_used_outputs(self.statistics.process_db_query("most_used(ttlValue)")) # Set Window Size based on Window Size distribution of IP address win_dist = self.statistics.get_win_distribution(ip_address) if len(win_dist) > 0: win_prob_dict = lea.Lea.fromValFreqsDict(win_dist) win_value = win_prob_dict.random() else: win_value = Util.handle_most_used_outputs(self.statistics.process_db_query("most_used(winSize)")) return mss_value, ttl_value, win_value ######################################### # RANDOM IP/MAC ADDRESS GENERATORS ######################################### @staticmethod def generate_random_ipv4_address(ip_class, n: int = 1): # TODO: document ip_class """ Generates n random IPv4 addresses. :param ip_class: :param n: The number of IP addresses to be generated :return: A single IP address, or if n>1, a list of IP addresses """ def is_invalid(ip_address_param: ipaddress.IPv4Address): return ip_address_param.is_multicast or ip_address_param.is_unspecified or ip_address_param.is_loopback or \ ip_address_param.is_link_local or ip_address_param.is_reserved or ip_address_param.is_private # Generate a random IP from specific class def generate_address(ip_class_param): if ip_class_param == "Unknown": return ipaddress.IPv4Address(random.randint(0, 2 ** 32 - 1)) else: # For DDoS attack, we do not generate private IPs if "private" in ip_class_param: ip_class_param = ip_class_param[0] # convert A-private to A ip_classes_byte1 = {"A": {1, 126}, "B": {128, 191}, "C": {192, 223}, "D": {224, 239}, "E": {240, 254}} temp = list(ip_classes_byte1[ip_class_param]) min_b1 = temp[0] max_b1 = temp[1] b1 = random.randint(min_b1, max_b1) b2 = random.randint(1, 255) b3 = random.randint(1, 255) b4 = random.randint(1, 255) ip_address = ipaddress.IPv4Address(str(b1) + "." + str(b2) + "." + str(b3) + "." + str(b4)) return ip_address ip_addresses = [] for i in range(0, n): address = generate_address(ip_class) while is_invalid(address): address = generate_address(ip_class) ip_addresses.append(str(address)) if n == 1: return ip_addresses[0] else: return ip_addresses @staticmethod def generate_random_ipv6_address(n: int = 1): """ Generates n random IPv6 addresses. :param n: The number of IP addresses to be generated :return: A single IP address, or if n>1, a list of IP addresses """ def is_invalid(ip_address: ipaddress.IPv6Address): return ip_address.is_multicast or ip_address.is_unspecified or ip_address.is_loopback or \ ip_address.is_link_local or ip_address.is_private or ip_address.is_reserved def generate_address(): return ipaddress.IPv6Address(random.randint(0, 2 ** 128 - 1)) ip_addresses = [] for i in range(0, n): address = generate_address() while is_invalid(address): address = generate_address() ip_addresses.append(str(address)) if n == 1: return ip_addresses[0] else: return ip_addresses @staticmethod def generate_random_mac_address(n: int = 1): """ Generates n random MAC addresses. :param n: The number of MAC addresses to be generated. :return: A single MAC addres, or if n>1, a list of MAC addresses """ def is_invalid(address_param: str): first_octet = int(address_param[0:2], 16) is_multicast_address = bool(first_octet & 0b01) is_locally_administered = bool(first_octet & 0b10) return is_multicast_address or is_locally_administered def generate_address(): # FIXME: cleanup mac = [random.randint(0x00, 0xff) for i in range(0, 6)] return ':'.join(map(lambda x: "%02x" % x, mac)) mac_addresses = [] for i in range(0, n): address = generate_address() while is_invalid(address): address = generate_address() mac_addresses.append(address) if n == 1: return mac_addresses[0] else: return mac_addresses @staticmethod def get_ports_from_nmap_service_dst(ports_num): """ Read the most ports_num frequently open ports from nmap-service-tcp file to be used in the port scan. :return: Ports numbers to be used as default destination ports or default open ports in the port scan. """ ports_dst = [] file = open(Util.RESOURCE_DIR + 'nmap-services-tcp.csv', 'rt') spamreader = csv.reader(file, delimiter=',') for count in range(ports_num): # escape first row (header) next(spamreader) # save ports numbers ports_dst.append(next(spamreader)[0]) file.close() # rnd.shuffle ports numbers partially if ports_num == 1000: # used for port.dst # FIXME: cleanup temp_array = [[0 for i in range(10)] for i in range(100)] port_dst_shuffled = [] for count in range(0, 10): temp_array[count] = ports_dst[count * 100:(count + 1) * 100] rnd.shuffle(temp_array[count]) port_dst_shuffled += temp_array[count] else: # used for port.open rnd.shuffle(ports_dst) port_dst_shuffled = ports_dst return port_dst_shuffled