WO2011038420A2 - Methods, systems, and computer readable media for adaptive packet filtering - Google Patents
Methods, systems, and computer readable media for adaptive packet filtering Download PDFInfo
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- WO2011038420A2 WO2011038420A2 PCT/US2010/054520 US2010054520W WO2011038420A2 WO 2011038420 A2 WO2011038420 A2 WO 2011038420A2 US 2010054520 W US2010054520 W US 2010054520W WO 2011038420 A2 WO2011038420 A2 WO 2011038420A2
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L63/00—Network architectures or network communication protocols for network security
- H04L63/02—Network architectures or network communication protocols for network security for separating internal from external traffic, e.g. firewalls
- H04L63/0227—Filtering policies
- H04L63/0263—Rule management
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F21/00—Security arrangements for protecting computers, components thereof, programs or data against unauthorised activity
- G06F21/50—Monitoring users, programs or devices to maintain the integrity of platforms, e.g. of processors, firmware or operating systems
- G06F21/55—Detecting local intrusion or implementing counter-measures
- G06F21/56—Computer malware detection or handling, e.g. anti-virus arrangements
- G06F21/562—Static detection
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L63/00—Network architectures or network communication protocols for network security
- H04L63/02—Network architectures or network communication protocols for network security for separating internal from external traffic, e.g. firewalls
- H04L63/0227—Filtering policies
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L63/00—Network architectures or network communication protocols for network security
- H04L63/14—Network architectures or network communication protocols for network security for detecting or protecting against malicious traffic
- H04L63/1408—Network architectures or network communication protocols for network security for detecting or protecting against malicious traffic by monitoring network traffic
- H04L63/1416—Event detection, e.g. attack signature detection
Definitions
- the subject matter described herein relates to network firewall filtering. More particularly, the subject matter described herein relates to methods, systems, and computer readable media for adaptive packet filtering.
- a firewall generally processes a packet against a list of ordered rules to find the first rule match.
- the list of ordered rules represents an aggregate security policy, and arbitrarily changing the order of the rules can result in a violation of the aggregate security policy.
- the Wake Forest University (WFU) techniques described in U.S. patent application publication nos. 2006/0248580 and 2006/0195896 provide the methods to optimally reorder the list while preserving the aggregate security policy, thereby improving the performance of the firewall.
- the WFU techniques also include methods to break apart rules into functionally independent lists containing (groups of) dependent rules such that a function parallel firewall can simultaneously process one packet against multiple lists, which can substantially improve the performance of the firewall.
- these improvements provided by WFU techniques can be dwarfed by the performance degradation as the number of rules in the list becomes very large.
- Adaptive packet filtering a set of techniques for processing firewall rules and packets, is described herein.
- APF offers improved processing performance compared to the WFU techniques in most cases, and can be combined with the WFU techniques or other parallel, pipelining and optimization techniques to achieve even greater performance.
- One method includes identifying at least one subset of rules in an ordered set of firewall packet filtering rules that defines a firewall policy such that the subset contains disjoint rules. Disjoint rules are defined as rules whose order can be changed without changing the integrity of the firewall policy. Rules in the subset are sorted to statistically decrease the number of comparisons that will be applied to each packet that a firewall encounters.
- Packets are filtered at the firewall using the sorted rules in the subset by using binary search, interpolated search, informed search, or hash lookup search algorithms to compare each packet to the sorted rules in the subset until the packet is allowed or denied and ceasing the comparing for the packet in response to the packet being allowed or denied and thereby achieving sub-linear searching for packets filtered using the sorted rules in the subset.
- the subject matter described herein for adaptive packet filtering can be implemented in a non-transitory computer readable medium having stored thereon executable instructions that when executed by the processor of a computer control the computer to perform steps.
- Exemplary computer readable media suitable for implementing the subject matter described herein include chip memory devices, disk memory devices, programmable logic devices and application specific integrated circuits.
- a computer readable medium that implements a subject matter described herein may be located on a single device or computing platform or may be distributed across multiple devices or computing platforms.
- a network firewall including one or more network interfaces for receiving packets and packet filtering hardware and software for optimizing rules as described herein and for filtering packets using the optimized arrangement of rules.
- Figure 1 is a block diagram of a system for adaptive packet filtering according to an embodiment of the subject matter described herein;
- Figure 2 is a block diagram of application of the present subject matter to a pipelined processing approach according to an embodiment of the subject matter described herein;
- Figure 3 is a block diagram illustrating application of the present subject matter to a combination of pipelined and data parallel processing approaches according to an embodiment of the subject matter described herein;
- Figure 4 is a block diagram illustrating application of the present subject matter to a short-circuiting pipelined processing approach according to an embodiment of the subject matter described herein;
- Figure 5 is a block diagram illustrating application of the present subject matter to a combination of pipelined and function parallel processing approaches according to an embodiment of the subject matter described herein.
- FIG. 1 is a block diagram illustrating an exemplary system for adaptive packet filtering according to an embodiment of the subject matter described herein.
- a firewall 100 may function at the boundary between an external network and a protected network.
- Firewall 100 may include one or more network interfaces 102 for receiving packets from the external network.
- Firewall 100 may also include one or more network interfaces 104 for transmitting allowed packets to the protective network.
- firewall 100 may filter Internet protocol (IP) packets based on a combination of source and destination addresses in the IP headers of the packets.
- IP Internet protocol
- the subject matter described herein is not limited to filtering any particular protocol. Any packet network protocol with parameters for which firewall filtering rules can be defined is intended to be within the scope of the subject matter described herein.
- firewall includes any network security device or system of devices that inspects network traffic data that originates, terminates, or traverses the device system in any capacity and compares that traffic data (headers, payload, raw bits, etc.) to a set of one or more rules, signatures, or conditions, either inline (i.e., in real time) or offline (i.e., capture and replay of the traffic data).
- the term “firewall” is also intended to include an intrusion detection device that analyzes network traffic in real time or historically to detect the presence of intrusion events in a network.
- the term “firewall” is also intended to include a deep packet inspection device that analyzes network traffic in real time or historically to detect the presence of certain packet content in a network.
- Firewall 100 includes a firewall rule subset identifier/rule sorter 106 for identifying at least one subset of rules in an ordered set of firewall packet filtering rules that defines a firewall policy such that the subset contains disjoint rules, where disjoint rules are defined as rules whose order can be changed without changing the firewall policy.
- Firewall rule subset identifier/rule sorter 106 may sort the rules in the subset or subsets to statistically decrease the number of comparison that will be applied to each packet that the firewall encounters. Exemplary methods for grouping and sorting rules will be described below.
- rule subset identifier/rule sorter 106 is illustrated as a component of firewall 100, the subject matter described herein is not limited to such an implementation.
- Rule subset identifier/rule sorter 106 can be implemented on any computing platform capable of sorting firewall rules using the methods described herein, and the sorted rule set can be provided to firewall 100 through any suitable means, such as communication over a network.
- rule subset identifier/rule sorter 106 may be implemented on a management platform separate from firewall 100.
- Firewall 100 further includes a packet filter 108 for filtering packets at the firewall using the rules in the subset by using binary search, interpolated search, informed search, hash lookup search algorithms, or other sub-linear algorithms to compare each packet to each of the sorted rules in the subset until the packet is allowed or denied and ceasing the comparing for the packet in response to the packet being allowed or denied and thereby achieving sub-linear searching for the packets filtered using the sorted rules in the subset.
- a packet filter 108 for filtering packets at the firewall using the rules in the subset by using binary search, interpolated search, informed search, hash lookup search algorithms, or other sub-linear algorithms to compare each packet to each of the sorted rules in the subset until the packet is allowed or denied and ceasing the comparing for the packet in response to the packet being allowed or denied and thereby achieving sub-linear searching for the packets filtered using the sorted rules in the subset.
- FIG. 2 is a block diagram illustrating an exemplary pipelined approach where rules and different subsets are distributed across plural firewall processors for processing packets in a pipelined manner.
- firewalls 200 and 202 each include separate processors 204 and 206 for executing packet filters 108.
- rule subset identifier/rule sorter 106 identifies two rule subsets, subset A 208 and subset B 210.
- the rules within each subset 208 and 210 are disjoint and sorted to statistically decrease the number of comparisons that will be applied to each packet using the methods described herein.
- the rules in subset B 210 are dependent on the rules in rule subset A 208.
- rule subset identifier/rule sorter 106 distributes the rule across firewall processors 204 such that the rules in rule subset A 208 are applied before the rules in rule subset B 210. Because the rules in different subsets are distributed across plural processors in a pipeline manner, packet filtering efficiency is improved over a single-processor approach because the different processors can simultaneously apply rules to different packets. In the example illustrated in Figure 2, packets that pass the filtering of rule subset A 208 are processed by processor 206, which applies rule subset B 210, at the same time that processor 204 applies rule subset A to new incoming packets.
- rule subset identifier/rule sorter 106 may distribute the grouped, sorted rules across firewall processors such that a combination of pipelined and data parallel processing techniques are used.
- Figure 3 illustrates an example where firewalls 300, 302, 304, and 306 each include separate processors 308, 310, 312, and 314 for applying their respective packet filters.
- rule subset identifier/rule sorter 106 distributes rule subset A 316 to firewall 300, rule subset B 318 to firewalls 302 and 304, and rule subset C 320 to firewall 306.
- the rules within each subset A, B and C are disjoint.
- the rules in subset B are dependent upon the rules in subset A.
- the rules in subset C are dependent upon the rules in subsets A and B.
- packets entering firewall 300 are filtered using rule subset A 316.
- the packets that are allowed by rule subset A 316 are divided between firewalls 302 and 304 such that the application of the rules in rule subset B 318 to different packets is performed in parallel. This is referred to as a data parallel approach.
- the packets that pass the filtering by rule subset B 318 are passed to firewall 306 for application of the rules in rule subset C 320.
- Figure 3 illustrates an example where the rule subsets that are identified and sorted by rule subset identifier/rule sorter 106 are distributed across the firewall processors for a combination of pipelined and data parallel processing.
- the rules subsets that are identified and in which the rules are sorted using rule subset identifier/rule sorter 106 may be distributed across firewall processors in a short-circuiting pipelined manner.
- Figure 4 is an example of short-circuiting pipelined filtering using rule subsets that are identified and sorted by rule subset identifier/rule sorter 106.
- packet filter 108 uses rule subset A 408 and packet filter 108 uses rule subset B 410.
- Rule subsets A and B 408 and 410 may respectively implement different levels of a firewall hierarchy such that packets that pass the filtering by rule subset A 408 are allowed into the protected network. Packets that are identified by rule subset A 408 is requiring further filtering are distributed to rule subset B 410 for that filtering.
- rule subset identifier/rule sorter 106 can also be used with short-circuiting pipelined firewall techniques without departing from the scope of the subject matter described herein.
- rule subset identifier/rule sorter 106 may distribute the grouped, sorted rules across firewall processors such that a combination of pipelined and function parallel processing techniques are used.
- Figure 5 illustrates an example where firewalls 500, 502, 504, and 506 each include separate processors 508, 510, 512, and 514 for applying their respective packet filters.
- rule subset identifier/rule sorter 106 distributes rule subset A 516 to firewall 500, rule subset B 518 to firewalls 502, and rule subset C 520 to firewall 504, and rule subset D 522 to firewall 506.
- the rules within each subset A, B, C and D are disjoint.
- the rules in subset B and C are dependent upon the rules in subset A.
- the rules in subset D are dependent upon the rules in subsets A, B and C.
- packets entering firewall 500 are filtered using rule subset A 516.
- the packets that are allowed by rule subset A 516 are copied to both firewalls 502 and 504 such that the application of the rules in rule subsets B 518 and C 520 to the packets is performed in parallel. This is referred to as a function parallel approach.
- the packets that pass the filtering by rule subsets B 518 and C 520 are passed to firewall 506 for application of the rules in rule subset D 522.
- Figure 5 illustrates an example where the rule subsets that are identified and sorted by rule subset identifier/rule sorter 106 are distributed across the firewall processors for a combination of pipelined and function parallel processing.
- APF analyzes and orders the list of firewall rules in-place to contain functionally dependent groups, where each group contains a subset of rules that are disjoint, dependent or both, without substantially changing the underlying representation of rules and while preserving the aggregate security policy.
- APF then uses varying criteria to sort each group containing disjoint rules, then uses sub-linear search algorithms when comparing packets against the rules within that group.
- APF uses linear search algorithms when comparing packets within a group containing dependent rules or when otherwise appropriate.
- a detailed computational complexity analysis of APF would need to be completed. However, on average, it is hypothesized that only 0(log(N)) comparisons would be needed to process a rule list of size N.
- the following table shows preliminary results comparing a single linear search firewall) with a single APF core as the number of rules is increased.
- a firewall rule is defined as an n-tuple criteria and an associated action for matching packets.
- IPv4 Internet Protocol version 4
- a 5-tuple rule that matches Internet Protocol version 4 (IPv4) packets might consist of 5 IPv4 header fields (source address, source port, destination address, destination port and protocol) and an action (allow, deny), and might specify the rule R1 as:
- a firewall rule set is defined as an ordered list of n rules R1 ,R2,R3,... ,Rn where the / in Ri is the index of the rule in the list. Packets that traverse the firewall are checked against each rule in the rule set until the first matching rule is found and its associated action is applied.
- An example rule set is S1 which contains:
- An example TCP packet from source 192.168.4.4 port 54321 to destination 10.1.1.1 port 80 would be checked against but not match R1, R2 and R3; would be checked against and match R4 and be allowed; and, would not be checked against R5 because R4 was the first matching rule.
- a firewall security policy is defined as the set of all possible packets that can traverse the firewall along with their specified outcomes as defined by the rule set. Changing the rules in a rule set usually results in a change of its security policy.
- a firewall rule is dependent on another rule if swapping the order of the two rules results in a change in the security policy of the rule set. Otherwise, the two rules are disjoint if swapping the order does not result in a change the security policy.
- rules R1 and R4 are dependent because placing R4 ahead of R1 would render R1 ineffective, thereby changing the security policy.
- Rules R1 and R2 are disjoint because placing R2 ahead of R1 does not change the security policy.
- a permutation of a rule set is defined as a new rule set which contains the same rules as the original rule set, but which lists a different ordering of the rules from the original rule set without changing the original security policy. For example, in the rule set S1 above, swapping the order of the disjoint rules R1 and R2 would result in a permutation rule set S1':
- rules R1 and R2 are disjoint but not spatially disjoint because the source ports 12345 and ANY overlap.
- rules R2 and R3 are both disjoint and spatially disjoint because the source ports ANY and ANY are identical, and the other 4 tuples do not overlap. (Other examples follow.)
- a transform function is an algorithm that can be applied to a rule to create a sortable key for that rule, which can then be used to sort the rules by their keys using a key comparison function.
- the transform function Tfn could concatenate the tuples of a rule into a bit array that is interpreted as a large integer, and a corresponding comparison function Cfn could be a simple integer comparison function. (Other examples follow.)
- a rule subset is defined as an ordered grouping of one or more rules within a rule set.
- the rule subsets might be:
- a rule group is defined as a rule subset with a group type (dependent, disjoint), transform function, comparison function, and a search algorithm hint (linear, sub-linear).
- the group type can be dependent if the group contains dependent rules, or can be disjoint if the group strictly contains disjoint rules.
- the rule set S1 above might contain the following disjoint rule group:
- a rule set may be partitioned into a list of ordered rule groups such that the security policy of the rule set is not changed when each rule group is decomposed in the listed order. This partitioning is accomplished by applying a rule subset identification method to a given rule set.
- An example of such a method is:
- Ri is disjoint from rules in Gj and placing Ri into Gj does not modify the security policy of S, then place Ri into Gj. ii. Otherwise, leave Ri ungrouped.
- the rule set S now contains m disjoint rule groups G1 ,G2,G3,...,Gm which group together the n (possibly reordered) rules R1 ,R2, ...,Rn.
- rule set S1 might result in its partitioning into the following list of disjoint ordered rule groups:
- a partitioned rule set containing disjoint rule groups may then be sorted by applying a transform function to each rule within each disjoint group to derive a sortable key for each rule. Then, the rules may be reordered within their disjoint groups using their sortable keys. The resulting sorted groups may be searched using sub-linear searching algorithms.
- An example of the sorting method is:
- the permutated rule set containing disjoint rule groups may be consolidated to reduce the number of groups that contain a rule count at or below a certain threshold, such as 1 rule, by merging two or more consecutive disjoint groups into a larger dependent group that may be searched using linear searching algorithms.
- a certain threshold such as 1 rule
- the rule set S now contains m or fewer rule groups of both dependent and disjoint types.
- the APF packet filtering method matches packets against a given rule set by sequentially iterating over each of the ordered rule groups, then performing the specified sub-linear or linear search within each group.
- An example of a rule filtering method is: For each packet that traverses the firewall:
- Gj is a dependent group, then perform linear search within that group until there is a first rule match.
- the primary purpose of the partitioning of rules is to create rule groups that, in aggregate, enable the fastest possible searching of each packet against the rules in the rule set.
- the optimal partitioning should be the grouping of maximal subsets of spatially disjoint rules.
- consolidating the disjoint groups into a single larger group containing rules that are ordered using other criteria (such as hit probabilities or hardware cache friendliness) and employing linear or interpolated search algorithms may improve performance.
- a critical concept is the flexibility to organize the rules within the rule set in different ways that enable the use of the most efficient and applicable search algorithm that is available that accounts for the hardware capabilities, which is the motivation behind the term "adaptive" in Adaptive Packet Filtering.
- Rule sets may be partitioned, sorted and consolidated in-place.
- each disjoint group should generally contain the maximal subsets of disjoint rules in order to reduce the number of disjoint groups in the rule set.
- the transform and comparison functions may be different for each rule group.
- the algorithms may account for the hit probabilities of each rule and the aggregate hit probabilities of each group.
- the search performed within any given rule group may employ the fastest available search algorithm applicable to that group even if it may be different from the specified search algorithm hint.
- a sub-linear binary search within a disjoint rule group may account for hit probabilities at each pivot so that each recursion could maximize the probability of a rule match.
- a constant-time search within a disjoint rule group is possible by defining a hashing function as the transform function such that the hash values for all rules within a group are unique within that group.
- R2 from 2.3.4.5 to 4.5.6.7 allow
- R3 from 3.4.5.6 to 5.6.7.8 allow
- R4 from *.*.*.* to 3.4.5.6 allow
- R5 from *.*.*.* to *.*.*.* deny
- SV can contain 2 groups of disjoint and dependent rules:
- G2 (R4, R5), dependent, linear or
- Rl from 1.2. 3.4 to 3.4. 5.6 deny
- R2 from 2.3. 4.5 to 4.5. 6.7 allow
- R3 from 1.2. 3.4 to 4.5. 6.7 deny
- R4 from 1.*. * _ * to * -k * * allow
- R5 from 3.4. 5.6 to 5.6. 7.8 deny
- R6 from 2. *. to * * * * _ * deny
- R7 from * . * . to 3.4. 5.6 allow
- R9 from to * . * . deny
- S2' contains 4 groups of "spatially disjoint" rules:
- S2' can contain 2 groups of disjoint and dependent rules:
- Gl (Rl, R2, R3, R5) , disjoint, sub-linear
- Each of these tuples have underlying scalar integer/bit vector
- transform function is a transform to scalar key which concatenates the digits of each of the tuples into a large integer
- transform function is a transform to scalar key which concatenates the bits of each of the tuples into a large integer/bit
- transform function is an identity function (i.e. transformation function that does not do anything), then defining a multi-dimensional comparison function for sorting purposes.
- identity function i.e. transformation function that does not do anything
- comparison function that is radix-based for each tuple, which would essentially result in a rule set that is radix sorted by each tuple.
- the transform function must convert the rule into a sortable key, which does not necessarily have to be a scalar key (i.e. it can be a multi-dimensional key that uses a multi-dimensional comparison function for sorting).
- Rule representation is the way a rule and a rule set are conceptually represented in software.
- the most common representation of a rule is as an N-tuple object or structure that simply holds all the tuples together:
- the most common representation of a rule set is an array or linked list that hold the rules in a fixed order, and allows for iteration forwards and backwards in the array or list.
- OPTWALL A Hierarchical Traffic-Ware Firewall
- T3 R2, R4, R8
- T1 (0-3), 12 (4-5) and T3 (6-8) are stored outside of the rule and rule set data structures.
- a linear algorithm is one whose computational time increases linearly as the size of the set is increased. The best example of this is when looking up a word in a dictionary. If the dictionary is unsorted, then the order of the words would be arbitrary. Therefore, when looking up the word "zebra," one could start from the beginning and search until the end to find it. If the dictionary contains 1 ,000 entries, you would need to examine all 1,000 words in the worst case.
- a sub-linear algorithm is one whose computational time increases sub-linearly as the size of the set is increased.
- the dictionary were sorted alphabetically, then one could still use a linear search by starting from the beginning and searching until the end to find "zebra.”
- Another example of a sub-linear algorithm is hashing.
- the computer could have an array containing all the words in the dictionary where each word's position in the array is the hash value of the word (subject to collisions). In the above example, the array's 52nd position would have the word "zebra," so it would take only 1 comparison to determine a match without collision.
- This hash technique can be selectively used in APF. 5) Explanation of disjoint rules.
- a rule R1 is "disjoint" from another rule R2 if their positions in the rule set S can be exchanged without altering the overall security policy.
- An example of this is rule set S containing:
- Rl from 1.*.*.* to 2.3.4.5 deny
- R2 from 1.2.3.4 to 1.2.3.4 allow has the same security policy as rule set S' containing:
- R2 from 1.2.3.4 to 1.2.3.4 allow
- a rule R1 is "spatially disjoint" from another rule R2 if they are “disjoint” and their corresponding tuples do not unevenly overlap (must be exactly equal, or do not overlap at all).
- R1 and R2 are disjoint but not spatially disjoint because the first tuple of R1 (1.*.*.*) and R2 (1.2.3.4) are not equal but do overlap, i.e. the value of 1.2.3.4 would match the first tuple of both R1 and R2.
- An example of spatially disjoint rules are:
- R3 from 1.2.3.4 to 3.4.5.6 deny
- R4 from 2.3.4.5 to 3.4.5.6 allow
- the first tuple of R1 ( .2.3.4) and the first tuple of R2 (2.3.4.5) do not overlap
- the second tuple of R1 (3.4.5.6) and R2 (3.4.5.6) are equal
- the » third tuple of R1 (deny) and R2 (allow) do not overlap.
- spatially disjoint rules are dependent upon the definition of a transform function T, so it may be possible to define T such that rules need not be “spatially disjoint” so long as rules are "disjoint.”
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EP10819667.6A EP2471218B1 (en) | 2009-08-28 | 2010-10-28 | Method, system, and computer readable medium for adaptive packet filtering |
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AU2010297968A AU2010297968B2 (en) | 2009-08-28 | 2010-10-28 | Methods, systems, and computer readable media for adaptive packet filtering |
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US12/871,806 US8495725B2 (en) | 2009-08-28 | 2010-08-30 | Methods, systems, and computer readable media for adaptive packet filtering |
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WO2011038420A3 (en) | 2011-06-16 |
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