import logging from random import randint, uniform from lea import Lea from scapy.layers.inet import Ether from scapy.utils import RawPcapReader from Attack import BaseAttack from Attack.AttackParameters import Parameter as Param from Attack.AttackParameters import ParameterTypes from ID2TLib.SMBLib import smb_port import ID2TLib.Utility as Util logging.getLogger("scapy.runtime").setLevel(logging.ERROR) # noinspection PyPep8 class EternalBlueExploit(BaseAttack.BaseAttack): template_scan_pcap_path = Util.RESOURCE_DIR + "Win7_eternalblue_scan.pcap" template_attack_pcap_path = Util.RESOURCE_DIR + "Win7_eternalblue_exploit.pcap" # Empirical values from Metasploit experiments minDefaultPort = 30000 maxDefaultPort = 50000 last_conn_dst_port = 4444 def __init__(self): """ Creates a new instance of the EternalBlue Exploit. """ # Initialize attack super(EternalBlueExploit, self).__init__("EternalBlue Exploit", "Injects an EternalBlue exploit'", "Privilege elevation") # Define allowed parameters and their type self.supported_params.update({ Param.MAC_SOURCE: ParameterTypes.TYPE_MAC_ADDRESS, Param.IP_SOURCE: ParameterTypes.TYPE_IP_ADDRESS, Param.PORT_SOURCE: ParameterTypes.TYPE_PORT, Param.MAC_DESTINATION: ParameterTypes.TYPE_MAC_ADDRESS, Param.IP_DESTINATION: ParameterTypes.TYPE_IP_ADDRESS, Param.PORT_DESTINATION: ParameterTypes.TYPE_PORT, Param.INJECT_AT_TIMESTAMP: ParameterTypes.TYPE_FLOAT, Param.INJECT_AFTER_PACKET: ParameterTypes.TYPE_PACKET_POSITION, Param.PACKETS_PER_SECOND: ParameterTypes.TYPE_FLOAT }) def init_params(self): """ Initialize the parameters of this attack using the user supplied command line parameters. Use the provided statistics to calculate default parameters and to process user supplied queries. :param statistics: Reference to a statistics object. """ # PARAMETERS: initialize with default utilsvalues # (values are overwritten if user specifies them) # Attacker configuration most_used_ip_address = self.statistics.get_most_used_ip_address() random_ip_address = self.statistics.get_random_ip_address() while random_ip_address == most_used_ip_address: random_ip_address = self.statistics.get_random_ip_address() self.add_param_value(Param.IP_SOURCE, random_ip_address) self.add_param_value(Param.MAC_SOURCE, self.statistics.get_mac_address(random_ip_address)) self.add_param_value(Param.PORT_SOURCE, randint(self.minDefaultPort, self.maxDefaultPort)) # Victim configuration self.add_param_value(Param.IP_DESTINATION, most_used_ip_address) destination_mac = self.statistics.get_mac_address(most_used_ip_address) if isinstance(destination_mac, list) and len(destination_mac) == 0: destination_mac = self.generate_random_mac_address() self.add_param_value(Param.MAC_DESTINATION, destination_mac) self.add_param_value(Param.PORT_DESTINATION, smb_port) # Attack configuration self.add_param_value(Param.PACKETS_PER_SECOND, (self.statistics.get_pps_sent(most_used_ip_address) + self.statistics.get_pps_received(most_used_ip_address)) / 2) self.add_param_value(Param.INJECT_AFTER_PACKET, randint(0, self.statistics.get_packet_count())) def generate_attack_packets(self): # Timestamp timestamp_next_pkt = self.get_param_value(Param.INJECT_AT_TIMESTAMP) pps = self.get_param_value(Param.PACKETS_PER_SECOND) # calculate complement packet rates of BG traffic per interval complement_interval_pps = self.statistics.calculate_complement_packet_rates(pps) # Initialize parameters self.packets = [] mac_source = self.get_param_value(Param.MAC_SOURCE) ip_source = self.get_param_value(Param.IP_SOURCE) port_source = self.get_param_value(Param.PORT_SOURCE) mac_destination = self.get_param_value(Param.MAC_DESTINATION) ip_destination = self.get_param_value(Param.IP_DESTINATION) port_destination = self.get_param_value(Param.PORT_DESTINATION) # Check ip.src == ip.dst self.ip_src_dst_equal_check(ip_source, ip_destination) self.path_attack_pcap = None # Set TTL based on TTL distribution of IP address source_ttl_dist = self.statistics.get_ttl_distribution(ip_source) if len(source_ttl_dist) > 0: source_ttl_prob_dict = Lea.fromValFreqsDict(source_ttl_dist) source_ttl_value = source_ttl_prob_dict.random() else: source_ttl_value = Util.handle_most_used_outputs(self.statistics.process_db_query("most_used(ttlValue)")) destination_ttl_dist = self.statistics.get_ttl_distribution(ip_destination) if len(destination_ttl_dist) > 0: destination_ttl_prob_dict = Lea.fromValFreqsDict(destination_ttl_dist) destination_ttl_value = destination_ttl_prob_dict.random() else: destination_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 source_win_dist = self.statistics.get_win_distribution(ip_source) if len(source_win_dist) > 0: source_win_prob_dict = Lea.fromValFreqsDict(source_win_dist) else: source_win_dist = self.statistics.get_win_distribution(self.statistics.get_most_used_ip_address()) source_win_prob_dict = Lea.fromValFreqsDict(source_win_dist) destination_win_dist = self.statistics.get_win_distribution(ip_destination) if len(destination_win_dist) > 0: destination_win_prob_dict = Lea.fromValFreqsDict(destination_win_dist) else: destination_win_dist = self.statistics.get_win_distribution(self.statistics.get_most_used_ip_address()) destination_win_prob_dict = Lea.fromValFreqsDict(destination_win_dist) # Set MSS (Maximum Segment Size) based on MSS distribution of IP address mss_value = Util.handle_most_used_outputs(self.statistics.process_db_query("most_used(mssValue)")) if not mss_value: mss_value = 1465 # Inject EternalBlue exploit packets # Read Win7_eternalblue_exploit pcap file source_origin_wins, destination_origin_wins = {}, {} exploit_raw_packets = RawPcapReader(self.template_attack_pcap_path) port_source = randint(self.minDefaultPort,self.maxDefaultPort) # experiments show this range of ports # conversations = {(ip.src, ip.dst, port.src, port.dst): packets} conversations, orderList_conversations = self.packets_to_convs(exploit_raw_packets) exploit_raw_packets.close() conv_start_timesamp = timestamp_next_pkt for conv_index, conv in enumerate(orderList_conversations): conv_start_timesamp = conv_start_timesamp + uniform(0.001,0.01) # the distance between the starts of the converstaions timestamp_next_pkt = conv_start_timesamp conv_pkts = conversations[conv] inter_arrival_times = self.get_inter_arrival_time(conv_pkts) if conv_index == len(orderList_conversations) - 2: # Not the last conversation timestamp_next_pkt = self.packets[-1].time + uniform(0.001,0.01) if conv_index != len(orderList_conversations)-1: # Not the last conversation port_source += 2 for self.pkt_num, pkt in enumerate(conv_pkts): eth_frame = Ether(pkt[0]) ip_pkt = eth_frame.payload tcp_pkt = ip_pkt.payload if self.pkt_num == 0: if tcp_pkt.getfieldval("dport") == smb_port: orig_ip_dst = ip_pkt.getfieldval("dst") # Request if ip_pkt.getfieldval("dst") == orig_ip_dst: # victim IP # Ether eth_frame.setfieldval("src", mac_source) eth_frame.setfieldval("dst", mac_destination) # IP ip_pkt.setfieldval("src", ip_source) ip_pkt.setfieldval("dst", ip_destination) ip_pkt.setfieldval("ttl", source_ttl_value) # TCP tcp_pkt.setfieldval("sport", port_source) tcp_pkt.setfieldval("dport", port_destination) ## Window Size source_origin_win = tcp_pkt.getfieldval("window") if source_origin_win not in source_origin_wins: source_origin_wins[source_origin_win] = source_win_prob_dict.random() new_win = source_origin_wins[source_origin_win] tcp_pkt.setfieldval("window", new_win) ## MSS tcp_options = tcp_pkt.getfieldval("options") if tcp_options: if tcp_options[0][0] == "MSS": tcp_options[0] = ("MSS", mss_value) tcp_pkt.setfieldval("options", tcp_options) new_pkt = (eth_frame / ip_pkt / tcp_pkt) new_pkt.time = timestamp_next_pkt pps = max(Util.get_interval_pps(complement_interval_pps, timestamp_next_pkt), 10) timestamp_next_pkt = Util.update_timestamp(timestamp_next_pkt, pps) + inter_arrival_times[self.pkt_num] #float(timeSteps.random()) # Reply else: # Ether eth_frame.setfieldval("src", mac_destination) eth_frame.setfieldval("dst", mac_source) # IP ip_pkt.setfieldval("src", ip_destination) ip_pkt.setfieldval("dst", ip_source) ip_pkt.setfieldval("ttl", destination_ttl_value) # TCP tcp_pkt.setfieldval("dport", port_source) tcp_pkt.setfieldval("sport", port_destination) ## Window Size destination_origin_win = tcp_pkt.getfieldval("window") if destination_origin_win not in destination_origin_wins: destination_origin_wins[destination_origin_win] = destination_win_prob_dict.random() new_win = destination_origin_wins[destination_origin_win] tcp_pkt.setfieldval("window", new_win) ## MSS tcp_options = tcp_pkt.getfieldval("options") if tcp_options: if tcp_options[0][0] == "MSS": tcp_options[0] = ("MSS", mss_value) tcp_pkt.setfieldval("options", tcp_options) new_pkt = (eth_frame / ip_pkt / tcp_pkt) pps = max(Util.get_interval_pps(complement_interval_pps, timestamp_next_pkt), 10) timestamp_next_pkt = Util.update_timestamp(timestamp_next_pkt, pps) + inter_arrival_times[self.pkt_num]#float(timeSteps.random()) new_pkt.time = timestamp_next_pkt self.packets.append(new_pkt) else: # Last conversation where the victim start a connection with the attacker timestamp_next_pkt = self.packets[-1].time + uniform(0.001, 0.01) port_source = randint(self.minDefaultPort,self.maxDefaultPort) for self.pkt_num, pkt in enumerate(conv_pkts): eth_frame = Ether(pkt[0]) ip_pkt = eth_frame.payload tcp_pkt = ip_pkt.payload # Request if tcp_pkt.getfieldval("dport") == self.last_conn_dst_port: # Ether eth_frame.setfieldval("src", mac_destination) eth_frame.setfieldval("dst", mac_source) # IP ip_pkt.setfieldval("src", ip_destination) ip_pkt.setfieldval("dst", ip_source) ip_pkt.setfieldval("ttl", destination_ttl_value) # TCP tcp_pkt.setfieldval("sport", port_source) # destination port is fixed 4444 ## Window Size destination_origin_win = tcp_pkt.getfieldval("window") if destination_origin_win not in destination_origin_wins: destination_origin_wins[destination_origin_win] = destination_win_prob_dict.random() new_win = destination_origin_wins[destination_origin_win] tcp_pkt.setfieldval("window", new_win) ## MSS tcp_options = tcp_pkt.getfieldval("options") if tcp_options: if tcp_options[0][0] == "MSS": tcp_options[0] = ("MSS", mss_value) tcp_pkt.setfieldval("options", tcp_options) new_pkt = (eth_frame / ip_pkt / tcp_pkt) new_pkt.time = timestamp_next_pkt pps = max(Util.get_interval_pps(complement_interval_pps, timestamp_next_pkt), 10) timestamp_next_pkt = Util.update_timestamp(timestamp_next_pkt, pps) + inter_arrival_times[self.pkt_num]# float(timeSteps.random()) # Reply else: # Ether eth_frame.setfieldval("src", mac_source) eth_frame.setfieldval("dst", mac_destination) # IP ip_pkt.setfieldval("src", ip_source) ip_pkt.setfieldval("dst", ip_destination) ip_pkt.setfieldval("ttl", source_ttl_value) # TCP tcp_pkt.setfieldval("dport", port_source) # source port is fixed 4444 ## Window Size source_origin_win = tcp_pkt.getfieldval("window") if source_origin_win not in source_origin_wins: source_origin_wins[source_origin_win] = source_win_prob_dict.random() new_win = source_origin_wins[source_origin_win] tcp_pkt.setfieldval("window", new_win) ## MSS tcp_options = tcp_pkt.getfieldval("options") if tcp_options: if tcp_options[0][0] == "MSS": tcp_options[0] = ("MSS", mss_value) tcp_pkt.setfieldval("options", tcp_options) new_pkt = (eth_frame / ip_pkt / tcp_pkt) pps = max(Util.get_interval_pps(complement_interval_pps, timestamp_next_pkt), 10) timestamp_next_pkt = Util.update_timestamp(timestamp_next_pkt, pps) + inter_arrival_times[self.pkt_num]# float(timeSteps.random()) new_pkt.time = timestamp_next_pkt self.packets.append(new_pkt) def generate_attack_pcap(self): # Store timestamp of first packet (for attack label) self.attack_start_utime = self.packets[0].time self.attack_end_utime = self.packets[-1].time if len(self.packets) > 0: self.packets = sorted(self.packets, key=lambda pkt: pkt.time) self.path_attack_pcap = self.write_attack_pcap(self.packets, True, self.path_attack_pcap) # return packets sorted by packet time_sec_start # pkt_num+1: because pkt_num starts at 0 return self.pkt_num + 1, self.path_attack_pcap