Network security is becoming increasingly important as the information age continues to unfold. Network threats may take a variety of forms (e.g., unauthorized requests or data transfers, viruses, malware, large volumes of network traffic designed to overwhelm network resources, and the like). Many organizations subscribe to network-threat services that periodically provide information associated with network threats, for example, reports that include listings of network-threat indicators (e.g., network addresses, uniform resources identifiers (URIs), and the like). The information provided by such services may be utilized by organizations to identify network threats. For example, logs generated by the organization's network devices may be reviewed for data corresponding to the network-threat indicators provided by such services. But because the logs are generated based on the traffic processed by the network devices without regard to the network-threat indicators, this process is often tedious and time consuming and is exacerbated by the continuously evolving nature of potential threats. Accordingly, there is a need for rule-based network-threat detection.
The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosure. It is intended neither to identify key or critical elements of the disclosure nor to delineate the scope of the disclosure. The following summary merely presents some concepts of the disclosure in a simplified form as a prelude to the description below.
Aspects of this disclosure relate to rule-based network-threat detection. In accordance with embodiments of the disclosure, a packet-filtering device may receive packet-filtering rules configured to cause the packet-filtering device to identify packets corresponding to network-threat indicators. The packet-filtering device may receive packets and, for each packet, may determine that the packet corresponds to criteria specified by a packet-filtering rule. The criteria may correspond to one or more of the network-threat indicators. The packet-filtering device may apply an operator specified by the packet-filtering rule. The operator may be configured to cause the packet-filtering device to either prevent the packet from continuing toward its destination or allow the packet to continue toward its destination. The packet-filtering device may generate a log entry comprising information from the packet-filtering rule that identifies the one or more network-threat indicators and indicating whether the packet-filtering device prevented the packet from continuing toward its destination or allowed the packet to continue toward its destination.
In some embodiments, the packet-filtering device may generate and communicate to a user device data indicating whether the packet-filtering device prevented the packet from continuing toward its destination or allowed the packet to continue toward its destination. The user device may receive the data and indicate in an interface displayed by the user device whether the packet-filtering device prevented the packet from continuing toward its destination or allowed the packet to continue toward its destination. The interface may comprise an element that when invoked by a user of the user device causes the user device to instruct the packet-filtering device to reconfigure the operator to prevent future packets corresponding to the criteria from continuing toward their respective destinations.
The present disclosure is pointed out with particularity in the appended claims. Features of the disclosure will become more apparent upon a review of this disclosure in its entirety, including the drawing figures provided herewith.
Some features herein are illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings, in which like reference numerals refer to similar elements, and wherein:
In the following description of various illustrative embodiments, reference is made to the accompanying drawings, which form a part hereof, and in which is shown, by way of illustration, various embodiments in which aspects of the disclosure may be practiced. It is to be understood that other embodiments may be utilized, and structural and functional modifications may be made, without departing from the scope of the disclosure.
Various connections between elements are discussed in the following description. These connections are general and, unless specified otherwise, may be direct or indirect, wired or wireless. In this respect, the specification is not intended to be limiting.
Environment 100 may also include one or more hosts, such as computing or network devices (e.g., servers, desktop computers, laptop computers, tablet computers, mobile devices, smartphones, routers, gateways, switches, access points, or the like). For example, network 102 may include hosts 110, 112, and 114, network 104 may include hosts 116, 118, and 120, network 106 may include hosts 122, 124, and 126, and network 108 may interface networks 102, 104, and 106 with one or more hosts associated with rule provider 128 or network-threat-intelligence providers 130, 132, and 134, threat hosts 136, 138, and 140, and benign host 142. Network-threat-intelligence providers 130, 132, and 134 may be associated with services that monitor network threats (e.g., threats associated with threat hosts 136, 138, and 140) and disseminate (e.g., to subscribers) network-threat-intelligence reports that include network-threat indicators (e.g., network addresses, ports, fully qualified domain names (FQDNs), uniform resource locators (URLs), uniform resource identifiers (URIs), or the like) associated with the network threats, as well as other information associated with the network threats, for example, the type of threat (e.g., phishing malware, botnet malware, or the like), geographic information (e.g., International Traffic in Arms Regulations (ITAR) country, Office of Foreign Assets Control (OFAC) country, or the like), anonymous proxies (e.g., Tor network, or the like), actors (e.g., the Russian Business Network (RBN), or the like).
Environment 100 may further include packet-filtering devices 144, 146, and 148. Packet-filtering device 144 may be located at boundary 150 between networks 102 and 108. Similarly, packet-filtering device 146 may be located at boundary 152 between networks 104 and 108, and packet-filtering device 148 may be located at boundary 154 between networks 106 and 108.
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At step 17, three packets may be communicated by host 112 to threat host 136, and packet-filtering device 144 may receive each of the three packets, apply one or more of packet-filtering rules 218 to the three packets, determine that each of the three packets corresponds to criteria specified by a packet-filtering rule of packet-filtering rules 404 (e.g., Rule: TI003), apply an operator specified by the packet-filtering rule (e.g., an ALLOW operator) to each of the three packets, allow each of the three packets to continue toward its respective destination (e.g., toward threat host 136), and generate log data for each of the three packets (as designated by the triangles over the line extending downward from packet-filtering device 144).
At step 18, packet-filtering device 144 may begin processing the log data generated in step 17. For example, referring to
Returning to
At step 20, packet-filtering device 144 may continue processing the log data generated in step 17 and may begin processing the log data generated in step 19. In some embodiments, packet-filtering device 144 may be configured in accordance with work-conserving scheduling in order to minimize latency (e.g., the time between when a packet corresponding to a network threat crosses boundary 150 and the time when an administrator associated with network 102 is presented with an interface indicating that the packet corresponding to the network threat has crossed boundary 150). For example, referring to
Returning to
Interface 600 may also include listing 606, which may comprise entries corresponding to network threats and, for each threat, associated information derived by packet-filtering device 144 from flow log 504 (e.g., a description of the threat, information derived from the consolidated information stored in flow log 504, the time of the last associated packet hit, a count of associated packet hits, a count of associated packets allowed by packet-filtering device 144 to continue toward their respective destinations, a count of associated packets prevented by packet-filtering device 144 from continuing toward their respective destinations) and a status of the operator included in the rule associated with the threat.
Packet-filtering device 144 may be configured to determine an ordering of the network threats, and listing 606 may be displayed in accordance with the ordering determined by packet-filtering device 144. In some embodiments, packet-filtering device 144 may be configured to determine a score for each of the network threats and the ordering may be determined based on the scores. In such embodiments, the scores may be determined based on a number of associated packet hits, times associated with the packet hits (e.g., time of day, time since last hit, or the like), whether the packet was destined for a network address associated with a host in network 102 or a host in network 108, one or more network-threat-intelligence providers that provided the network-threat indicators associated with the threat, the number of network-threat intelligence providers that provided the network-threat indicators associated with the threat, other information associated with the network threat (e.g., type of network threat, geographic information, anonymous proxies, actors, or the like).
For example, as illustrated in
Returning to
At step 23, packet-filtering device 144 may continue processing the log data generated in step 19 and may begin processing the log data generated in step 22. For example, referring to
Returning to
Interface 600 may include one or more block options that when invoked by a user of host 110 (e.g., the administrator of network 102) cause host 110 to instruct packet-filtering device 144 to reconfigure an operator of a packet-filtering rule included in packet-filtering rules 404 to prevent packets corresponding to the criteria specified by the packet-filtering rule from continuing toward their respective destinations. In some embodiments, listing 606 may include such a block option alongside each entry, and, when invoked, the block option may cause host 110 to instruct packet-filtering device 144 to reconfigure an operator of packet-filtering rules 404 that corresponds to the network threat associated with the entry. For example, interface 600 may include block option 608, which, when invoked, may cause host 110 to instruct packet-filtering device 144 to reconfigure an operator associated with Rule: TI003 (e.g., to reconfigure the operator to cause packet-filtering device 144 to prevent packets corresponding to the one or more criteria specified by Rule: TI003 (e.g., packets corresponding to the network-threat-indicators associated with Threat ID: Threat_3) from continuing toward their respective destinations).
Additionally or alternatively, when invoked, such a block option may cause host 110 to display another interface (e.g., an overlay, pop-up interface, or the like) associated with packet-filtering device 144. For example, referring to
Interface 610 may also include rule-preview listing 624, which may display a listing of rules that will be implemented by packet-filtering device 144 in response to the user invoking modify option 620. Rule-preview listing 624 may include one or more entries corresponding to each of specific block options 612, 614, 616, and 618. For example, entry 626 may correspond to, and display a rule configured to implement, specific block option 612 (e.g., Rule: TI003 with its operator reconfigured to BLOCK). Similarly, entries 628, 630, and 632 may correspond to, and display rules configured to implement, specific block options 614, 616, and 618 (e.g., one or more new rules generated by packet-filtering device 144 based on data derived from flow log 504 (e.g., a network address associated with host 112)). Responsive to a user invoking one or more of specific block options 612, 614, 616, or 618, the interface may select the corresponding rules, and responsive to a user invoking modify option 620, host 110 may instruct packet-filtering device 144 to implement the selected rules. Responsive to a user invoking cancel option 620, host 110 may redisplay interface 600.
Returning to
At step 27, three packets destined for threat host 136 may be communicated by host 112, and packet-filtering device 144 may receive each of the three packets, apply one or more of packet-filtering rules 218 to the three packets, determine that each of the three packets corresponds to criteria specified by a packet-filtering rule of packet-filtering rules 404 (e.g., Rule: TI003), apply an operator specified by the packet-filtering rule (e.g., the BLOCK operator) to each of the three packets, prevent each of the three packets from continuing toward its respective destination (e.g., toward threat host 136), and generate log data for each of the three packets.
At step 28, packet-filtering device 144 may continue processing the log data generated in step 22 and may begin processing the log data generated in step 27. For example, referring to
Returning to
Referring to
At step 32, three packets destined for host 118 may be communicated by threat host 140, and packet-filtering device 146 may receive each of the three packets, apply one or more of its packet-filtering rules to the three packets, determine that each of the three packets corresponds to criteria specified by a packet-filtering rule (e.g., the rule corresponding to Threat ID: Threat_1), apply an operator specified by the packet-filtering rule (e.g., an ALLOW operator) to each of the three packets, allow each of the three packets to continue toward its respective destination (e.g., toward host 118), and generate log data for each of the three packets.
At step 33, packet-filtering device 146 may continue processing the log data generated in step 30 and may begin processing the log data generated in step 33. At step 34, packet-filtering device 146 may generate data comprising an update for an interface associated with packet-filtering device 146 and displayed by host 116 (e.g., an interface similar to interface 600) and may communicate the data comprising the update to host 116.
At step 35, three packets destined for host 120 may be communicated by threat host 140, and packet-filtering device 146 may receive each of the three packets, apply one or more of its packet-filtering rules to the three packets, determine that each of the three packets corresponds to criteria specified by a packet-filtering rule (e.g., the rule corresponding to Threat ID: Threat_1), apply an operator specified by the packet-filtering rule (e.g., an ALLOW operator) to each of the three packets, allow each of the three packets to continue toward its respective destination (e.g., toward host 120), and generate log data for each of the three packets. At step 36, packet-filtering device 146 may continue processing the log data generated in step 32 and may begin processing the log data generated in step 35.
At step 37, packet-filtering device 146 may generate data comprising an update for the interface associated with packet-filtering device 146 and displayed by host 116 and may communicate the data comprising the update to host 116. At step 38, host 116 may communicate instructions to packet-filtering device 146 instructing packet-filtering device 146 to reconfigure one or more of its packet-filtering rules (e.g., to reconfigure the operator of the rule corresponding to Threat ID: Threat_1 to BLOCK), and, at step 39, packet-filtering device 146 may reconfigure its packet-filtering rules accordingly.
At step 40, three packets destined for host 118 and three packets destined for host 120 may be communicated by threat host 140, and packet-filtering device 146 may receive each of the six packets, apply one or more of its packet-filtering rules to the six packets, determine that each of the six packets corresponds to criteria specified by a packet-filtering rule (e.g., the rule corresponding to Threat ID: Threat_1), apply an operator specified by the packet-filtering rule (e.g., the BLOCK operator) to each of the six packets, prevent each of the six packets from continuing toward its respective destination, and generate log data for each of the six packets. At step 41, packet-filtering device 146 may continue processing the log data generated in step 35 and may begin processing the log data generated in step 40.
At step 42, packet-filtering device 146 may communicate data to rule provider 128 (e.g., data indicating that fifteen packets corresponding to Threat ID: Threat_1 were received by packet-filtering device 146, packet-filtering device 146 allowed nine of the fifteen packets to continue toward hosts in network 104, and packet-filtering device 146 prevented six of the fifteen packets from continuing toward hosts in network 104).
Referring to
At step 44, three packets destined for host 126 may be communicated by threat host 140, and packet-filtering device 148 may receive each of the three packets, apply one or more of its packet-filtering rules to the three packets, determine that each of the three packets corresponds to criteria specified by a packet-filtering rule (e.g., a rule corresponding to Threat ID: Threat_1), apply an operator specified by the packet-filtering rule (e.g., an ALLOW operator) to each of the three packets, allow each of the three packets to continue toward its respective destination (e.g., toward host 126), and generate log data for each of the three packets. At step 45, packet-filtering device 148 may begin processing the log data generated in step 44.
At step 46, three packets destined for host 126 may be communicated by threat host 140, and packet-filtering device 148 may receive each of the three packets, apply one or more of its packet-filtering rules to the three packets, determine that each of the three packets corresponds to criteria specified by a packet-filtering rule (e.g., the rule corresponding to Threat ID: Threat_1), apply an operator specified by the packet-filtering rule (e.g., an ALLOW operator) to each of the three packets, allow each of the three packets to continue toward its respective destination (e.g., toward host 126), and generate log data for each of the three packets.
At step 47, packet-filtering device 148 may continue processing the log data generated in step 44 and may begin processing the log data generated in step 47. At step 48, packet-filtering device 148 may generate data comprising an update for an interface associated with packet-filtering device 148 and displayed by host 122 (e.g., an interface similar to interface 600) and may communicate the data comprising the update to host 122.
At step 49, two packets may be communicated between host 124 and threat host 138 (e.g., a packet originating from host 124 and destined for threat host 138 and a packet originating from threat host 138 and destined for host 124), and packet-filtering device 148 may receive each of the two packets, apply one or more of its packet-filtering rules to the two packets, determine that each of the two packets corresponds to criteria specified by a packet-filtering rule (e.g., a rule corresponding to Threat ID: Threat_5), apply an operator specified by the packet-filtering rule (e.g., an ALLOW operator) to each of the two packets, allow each of the two packets to continue toward its respective destination, and generate log data for each of the two packets. At step 50, packet-filtering device 148 may continue processing the log data generated in step 46 and may begin processing the log data generated in step 49.
At step 51, packet-filtering device 148 may generate data comprising an update for the interface associated with packet-filtering device 148 and displayed by host 122 and may communicate the data comprising the update to host 122. At step 52, host 122 may communicate instructions to packet-filtering device 148 instructing packet-filtering device 148 to reconfigure one or more of its packet-filtering rules to block all packets corresponding to the network-threat indicators associated with Threat ID: Threat_1 (e.g., to reconfigure the operator of the rule corresponding to Threat ID: Threat_1 to BLOCK), and to implement one or more new packet-filtering rules configured to block all packets originating from host 126, and, at step 53, packet-filtering device 148 may reconfigure its packet-filtering rules accordingly.
At step 54, threat host 140 may generate a packet destined for host 124 and a packet destined for host 126, host 126 may generate a packet destined for benign host 142 and a packet destined for host 124, and packet-filtering device 148 may receive each of the four packets, apply one or more of its packet-filtering rules to the four packets, determine that the packets generated by threat host 140 correspond to criteria specified by the packet-filtering rule corresponding to Threat ID: Threat_1, apply an operator specified by the packet-filtering rule corresponding to Threat ID: Threat_1 (e.g., the BLOCK operator) to each of the two packets generated by threat host 140, determine that the packets generated by host 126 correspond to criteria specified by the new packet-filtering rules (e.g., a network address associated with host 126), apply an operator specified by the new packet-filtering rules (e.g., the BLOCK operator) to each of the two packets generated by host 126, prevent each of the four packets from continuing toward its respective destination, and generate log data for each of the four packets.
At step 55, packet-filtering device 148 may continue processing the log data generated in step 49 and may begin processing the log data generated in step 54. At step 56, packet-filtering device 148 may communicate data to rule provider 128 (e.g., data indicating that eight packets corresponding to Threat ID: Threat_1 were received by packet-filtering device 148, packet-filtering device 148 allowed six of the eight packets to continue toward hosts in network 106, packet-filtering device 148 prevented two of the eight packets from continuing toward hosts in network 106, two packets corresponding to Threat ID: Threat_5 were received by packet-filtering device 148, and packet-filtering device 148 allowed both of the two packets to continue toward their respective destinations).
Referring to
At step 60, four packets may be communicated between host 114 and benign host 142 (e.g., two packets originating from host 114 and destined for benign host 142 and two packets originating from benign host 142 and destined for host 114), and packet-filtering device 144 may receive each of the four packets, apply one or more of packet-filtering rules 218 to the four packets, and allow the four packets to continue toward their respective destinations.
At step 61, three packets destined for threat host 136 may be communicated by host 112, and packet-filtering device 144 may receive each of the three packets, apply one or more of packet-filtering rules 218 to the three packets, determine that each of the three packets corresponds to criteria specified by a packet-filtering rule of packet-filtering rules 404 (e.g., Rule: TI003), apply an operator specified by the packet-filtering rule (e.g., the BLOCK operator) to each of the three packets, prevent each of the three packets from continuing toward its respective destination (e.g., toward threat host 136), and generate log data for each of the three packets.
At step 62, packet-filtering device 144 may continue processing the log data generated in step 27 and may begin processing the log data generated in step 62. For example, referring to
At step 63, packet-filtering device 144 may utilize flow log 504 to generate data comprising an update for interface 600 and may communicate the data to host 110. For example, referring to
At step 64, three packets destined for host 112 and three packets destined for host 114 may be communicated by threat host 140, and packet-filtering device 144 may receive each of the six packets, apply one or more of packet-filtering rules 218 to the three packets, determine that each of the three packets corresponds to criteria specified by a packet-filtering rule of packet-filtering rules 404 (e.g., Rule: TI001), apply an operator specified by the packet-filtering rule (e.g., the BLOCK operator) to each of the six packets, prevent each of the six packets from continuing toward its respective destination, and generate log data for each of the six packets.
At step 65, packet-filtering device 144 may continue processing the log data generated in step 61 and may begin processing the log data generated in step 64. For example, referring to
At step 66, packet-filtering device 144 may utilize flow log 504 to generate data comprising an update for interface 600 and may communicate the data to host 110. For example, referring to
At step 67, packet-filtering device 144 may continue processing the log data generated in step 64. For example, referring to
At step 68, packet-filtering device 144 may utilize flow log 504 to generate data comprising an update for interface 600 and may communicate the data to host 110. For example, referring to
At step 710, the packet-filtering device may generate a log entry comprising information from the packet-filtering rule that is distinct from the criteria and identifies the one or more network-threat indicators. For example, packet-filtering device 144 may generate an entry in packet log 502 comprising Threat ID: Threat_3 for the packet generated by host 112. At step 712, the packet-filtering device may generate data indicating whether the packet-filtering device prevented the packet from continuing toward its destination (e.g., blocked the packet) or allowed the packet to continue toward its destination. For example, packet-filtering device 144 may generate data comprising an update for interface 600 that indicates that packet-filtering device 144 allowed the packet generated by host 112 to continue toward threat host 136. At step 714, the packet-filtering device may communicate the data to a user device. For example, packet-filtering device 144 may communicate the data comprising the update for interface 600 to host 110. At step 716, the packet-filtering device may indicate in an interface whether the packet-filtering device prevented the packet from continuing toward its destination or allowed the packet to continue toward its destination. For example, communicating the data comprising the update for interface 600 may cause host 110 to indicate in interface 600 that packet-filtering device 144 allowed the packet generated by host 112 to continue toward threat host 136.
The functions and steps described herein may be embodied in computer-usable data or computer-executable instructions, such as in one or more program modules, executed by one or more computers or other devices to perform one or more functions described herein. Generally, program modules include routines, programs, objects, components, data structures, etc. that perform particular tasks or implement particular abstract data types when executed by one or more processors in a computer or other data-processing device. The computer-executable instructions may be stored on a computer-readable medium such as a hard disk, optical disk, removable storage media, solid-state memory, RAM, etc. As will be appreciated, the functionality of the program modules may be combined or distributed as desired. In addition, the functionality may be embodied in whole or in part in firmware or hardware equivalents, such as integrated circuits, application-specific integrated circuits (ASICs), field-programmable gate arrays (FPGA), and the like. Particular data structures may be used to more effectively implement one or more aspects of the disclosure, and such data structures are contemplated to be within the scope of computer-executable instructions and computer-usable data described herein.
Although not required, one of ordinary skill in the art will appreciate that various aspects described herein may be embodied as a method, system, apparatus, or one or more computer-readable media storing computer-executable instructions. Accordingly, aspects may take the form of an entirely hardware embodiment, an entirely software embodiment, an entirely firmware embodiment, or an embodiment combining software, hardware, and firmware aspects in any combination.
As described herein, the various methods and acts may be operative across one or more computing devices and networks. The functionality may be distributed in any manner or may be located in a single computing device (e.g., a server, client computer, or the like).
Aspects of the disclosure have been described in terms of illustrative embodiments thereof. Numerous other embodiments, modifications, and variations within the scope and spirit of the appended claims will occur to persons of ordinary skill in the art from a review of this disclosure. For example, one of ordinary skill in the art will appreciate that the steps illustrated in the illustrative figures may be performed in other than the recited order and that one or more illustrated steps may be optional. Any and all features in the following claims may be combined or rearranged in any way possible.
This application is a continuation of co-pending U.S. patent application Ser. No. 16/813,220 which is a continuation of U.S. patent application Ser. No. 16/706,388 (now U.S. Pat. No. 10,609,062), filed Dec. 6, 2019 which is a continuation of U.S. patent application Ser. No. 16/217,720 (now U.S. Pat. No. 10,567,413), filed Dec. 12, 2018, which is a continuation of U.S. patent application Ser. No. 15/827,477 (now U.S. Pat. No. 10,193,917), filed Nov. 30, 2017, which is a continuation of U.S. patent application Ser. No. 14/690,302 (now U.S. Pat. No. 9,866,576), filed Apr. 17, 2015, the content of which are hereby incorporated by reference into the present application.
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20200389479 A1 | Dec 2020 | US |
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