First Step Towards Automatic Correction of Firewall Policy Faults

1. First Step Towards Automatic Correction of Firewall Policy Faults Fei Chen Alex X. LiuComputer Science and EngineeringMichigan State University JeeHyun Hwang Tao XieComputer ScienceNorth Carolina State University Published in the Proceedings of USENIX Large Installation System Administration Conference (LISA 2010) Best Student Paper Award

2. What do we do here? • Most firewall policies are poorly configured and contain faults. [Wool 2004 & 2010] • A coworker may mess up your firewall rules. • Any modification may introduce firewall faults. • We invent methods for fixing firewall policies automatically. • We first model 5 types of faults. • For each type of faults, we develop an algorithm to fix them. • Given a faulty firewall policy, we propose a systematic method to fix the faults automatically using the 5 algorithms.

3. Roadmap • Background • Firewalls • Firewall policies • Firewall policy faults • Technical challenges • Fault model of firewall policies • Five types of faults • Problem formalization • Our solution • Experimental results

4. Background – Firewalls • A firewall checks all outgoing and incoming packets • The firewall policy decides whether to accept or discard a packet Private Network Outgoing Packets Internet Incoming Packets Firewall

5. Background – Firewall Policies • A firewall policy is usually specified as a sequence of rules • Each rule consists of a predicate and a decision. • A predicate typically includes five fields: source IP, destination IP, source port, destination port, protocol type • Typical decisions are accept and discard. • Conflict Resolution: first-match Firewall Policy Packet

6. Background – Firewall Policy Faults • Most firewall policies are poorly configured and contain faults. [Wool 2004 & 2010] • It is dangerous to have faults in a firewall policy. A policy fault • either allows malicious traffic to sneak into the private network • or blocks legitimate traffic and disrupts normal business processes • A faulty policy evaluates some packets to unexpected decisions. • Such packets are called misclassified packets of a faulty firewall policy • Manually locating and correcting firewall faults are impractical. • A firewall may consist of thousands of rules • Automatically correcting firewall faults is an important problem.

7. Roadmap • Background • Firewalls • Firewall policies • Firewall policy faults • Technical challenges • Fault model of firewall policies • Five types of faults • Problem formalization • Our solution • Experimental results

8. Three Key Technical Challenges • It is difficult to determine the number of policy faults and the type of each fault. • A set of misclassified packets can be caused by different types of faults and different number of faults. • It is difficult to correct a firewall fault. • A firewall policy may consists of a large number of rules. • Each rule has a predicate over multi-dimensional fields. • It is difficult to correct a fault without introducing other faults • Due to the first match, correcting faults in a firewall rule affects the functionally of all the subsequent rules.

9. Roadmap • Background • Firewalls • Firewall policies • Firewall policy faults • Technical challenges • Fault model of firewall policies • Five types of faults • Problem formalization • Our solution • Experimental results

10. Fault Model of Firewall Policies (1/2) • We propose a fault model that includes five types of faults (1) Wrong order: the order of firewall rules is wrong. Correction technique: Order Fixing (2) Missing rules: some rules are missed in the firewall policy. Correction technique: Rule Addition (3) Wrong predicates: the predicates of some rules are wrong. Correction technique: Predicate Fixing r*

11. Fault Model of Firewall Policies (2/2) (4) Wrong decisions: the decisions of some rules are wrong. Correction technique: Decision Fixing (5) Wrong extra rules: some rules are not needed in the policy. Correction technique: Rule Deletion Each operation of these five techniques is called a modification.

12. Roadmap • Background • Firewalls • Firewall policies • Firewall policy faults • Technical challenges • Fault model of firewall policies • Five types of faults • Problem formalization • Our solution • Experimental results

13. Detection of Faulty Firewall Policies • A faulty firewall policy is detected when • administrators find that the policy allows some malicious packets or blocks some legitimate packets. • These packets cannot provide enough information about the faults • The number of these observed packets is typically small • Bruteforce testing every possible packets needs 2104 • How to generate test packets for faulty firewall policies? Faulty Firewall Policy Malicious Packets × Legitimate Packets Administrator

14. Generating Test Packets for Faulty Policies • We employ the automated packet generation techniques in [Hwang et al. 2008] to generate test packets • Administrators identify passed/failed tests automatically or manually According to security requirements for the firewall policy, • If the decision of a packet is correct, administrators classify it as a passedtest. • Otherwise, administrators classify it as a failed test. Faulty Firewall Policy Packet Generation Classify Packets Passed Packets Failed Packets

15. Problem Statement • Input: (1) A faulty firewall policy FW(2) A set of passed tests PT, |PT|≥0 (3) A set of failed tests FT, |FT|>0 • Output:A sequence of modifications <M1, …, Mm>, where Mj (1≤j ≤m) denotes one modifition, satisfies the following two conditions:(1) After applying <M1, …, Mm> to FW, all tests in PT and FT become passed tests.(2) No other sequence that satisfies the first condition has the smaller number of modifications than m. • This is a global optimization problem and hard to solve because • a policy may consist of a large number of rules, and • different combinations of modifications can be made.

16. Roadmap • Background • Firewalls • Firewall policies • Firewall policy faults • Technical challenges • Fault model of firewall policies • Five types of faults • Problem formalization • Our solution • Experimental results

17. Automatic Correction of Firewall Policy Faults • We propose a greedy algorithm to address this problem. • For each step, we correct one fault in the policy such that |PT| increases. • To determine which technique should be used, we try the five correction techniques and then find the one that maximizes |PT|. Faulty Firewall Policy Rule Addition Order Fixing Predicate Fixing Decision Fixing Rule Deletion No |Failed Tests|=0 ? Yes Passed Packets Failed Packets Fixed Firewall Policy

18. Running Example r1: F1 [1, 5]  F2 [1, 10]  a r2: F1 [1, 6]  F2 [3, 10]  a r3: F1 [6,10]  F2 [1, 3]  d r4: F1 [7,10]  F2 [4, 8]  a r5: F1 [1,10]  F2 [1, 10]  d A faulty firewall policy p1: (3, 2)  a p2: (5, 7)  a p3: (6, 7)  a p4: (7, 2)  d p5: (8,10) d p6: (6, 3)  d p7: (7, 9)  a p8: (8, 5)  d A set of failed tests A set of passed tests

19. Order Fixing (1/2) • Swapping every two rules is computationally expensive. • There are (n-1)(n-2)/2 pairs of rules that can be swapped • We use all-match firewall decision diagrams (all-match FDDs) [Liu et al. 2008] as the core data structure. • Any firewall policy can be converted to an equivalent all-match FDD. r1: F1 [1, 5]  F2 [1, 10]  a r2: F1 [1, 6]  F2 [3, 10]  a r3: F1 [6,10]  F2 [1, 3]  d r4: F1 [7,10]  F2 [4, 8]  a r5: F1 [1,10]  F2 [1, 10]  d F1 [7, 10] [1, 5] [6, 6] F2 F2 F2 [1, 2] [9,10] [1,3] [4,10] [3, 10] [1,2] [3,3] [4,8] 1,5 1,2,5 3,5 2,3,5 2,5 3,5 4,5 5

20. Order Fixing (2/2) • All-match FDD has the following nice property. Swapping two rules is equivalent to swapping the sequence numbers of the two rules in the terminal nodes of all-match FDD • For the running example, this technique can find that swapping r2 and r3 can increase |PT| by 1 • change the failed test (6, 3)  d to a passed test  <r1, r3, r2, r4, r5> <r1, r2, r3, r4, r5> F1 [7, 10] [1, 5] [6, 6] 3,2,5 F2 F2 F2 [1, 2] [9,10] [1,3] [4,10] [3, 10] [1,2] [3,3] [4,8] 1,5 1,2,5 3,5 2,3,5 2,5 3,5 4,5 5

21. Rule Addition • Bruteforce addition for each position is computationally expensive • The number of possible rules that can be added for each position is O(2204). • The basic idea of rule addition is that for each position • Find all possible failed tests that can be corrected by adding a rule • Compute a rule that matches the maximum number of failed tests • For adding a rule between r1, r2, we can compute F1 [6, 8]  F2 [3, 5]  d to correct two failed tests p6: (6, 3)  d and p8: (8, 5)  d . p7: (7, 9)  a p6: (6, 3)  d p8: (8, 5)  d r*: F1 [ , ]  F2 [ , ]  dec p7: (7, 9)  a p6: (6, 3)  d p8: (8, 5)  d r*: F1 [ , ]  F2 [ , ]  dec p6: (6, 3)  d p7: (7, 9)  a p8: (8, 5)  d r*: F1 [ , ]  F2 [ , ]  dec p7: (7, 9)  a p8: (8, 5)  d r*: F1 [ , ]  F2 [ , ]  dec p8: (8, 5)  d r*: F1 [ , ]  F2 [ , ]  dec p7: (7, 9)  a

22. Evaluation Setup • We generate faulty firewall policies from 40 real-life policies. • Each faulty policy contains one type of fault, and the number of faults ranges from 1 to 5. • For each faulty policy, we employed the packet generating technique [Hwang et al. 2008] and then classified them into passed and failed tests • We applied our greedy algorithm to produce the fixed policy. • Methodology • Difference ratio over FWreal, FWfaulty, and FWfixed • The average number of modifications Faulty Policy Fixed Policy Real Policy FWreal FWfaulty FWfixed (FWreal , FWfixed ) (FWreal , FWfaulty )

23. Roadmap • Background • Firewalls • Firewall policies • Firewall policy faults • Technical challenges • Fault model of firewall policies • Five types of faults • Problem formalization • Our solution • Experimental results

24. Effectiveness (1/4) • For wrong decision faultsThe percentages of fixed policies that are equivalent to their corresponding real-life policies are 73.5%, 68.8%, 63.7%, 59.3%, and 53.8%, respectively.

25. Effectiveness (2/4) • For wrong order faults The percentages of fixed policies that are equivalent to their corresponding real-life policies are 69.7%, 64.2%, 59.7%, 54.3%, and 48.9%, respectively.

26. Effectiveness (3/4) • For wrong extra rule faultsThe percentages of fixed policies that are equivalent to their corresponding real-life policies are 68.3%, 63.5%, 59.3%, 53.2%, and 47.3%, respectively.

27. Effectiveness (4/4) • In terms the number of modificationsThe number of modifications of our approach is close to the minimum number.

28. Contributions • Propose the first comprehensive fault model for firewall policies • Propose the first systematic approach that can automatically correct all or part of the misclassified packets of a faulty policy. • Conduct extensive experiments on real-life firewall policies to evaluate the effectiveness of our approach.

29. Questions Thank you!

30. Reference • [Wool 2004] A quantitative study of firewall configuration errors. IEEE Computer 37, 6 (2004), pp. 62–67. • [Wool 2010] Trends in Firewall Configuration Errors: Measuring the Holes in Swiss Cheese. IEEE Internet Computing 14, 4 (2010), pp. 58–65 . • [Hwang et al. 2008] Systematic structural testing of firewall policies. In Proceedings of IEEE International Symposium on Reliable Distributed Systems (SRDS) (2008), pp. 105–114. • [Liu et al. 2008] All-match based complete redundancy removal for packet classifiers in TCAMs. In Proceedings of IEEE Conference on Computer Communications (INFOCOM) (2008), pp. 574–582.

31. Limitation of Prior Art • A firewall fault localization scheme was proposed [Marmorstein et al. 2007]. • Find failed tests that violate the security requirement of a firewall policy • Use the failed tests to locate two or three faulty rules in the policy. • Drawbacks • Many types of faults cannot be located. For example, wrong order of firewall rules cannot be located. • Even if a faulty rule is located, it may not be corrected by just changing the faulty rules. For example, if a firewall policy misses one rule, change existing rules cannot correct the fault. • The scheme only were applied to a simple policy with 5 rules, which cannot strongly demonstrate the effectiveness of the scheme.

32. Predicate Fixing • The basic idea of predicate fixing is similar to rule addition. • However, there are two major differences. • For fixing ri’s predicate, compute only a rule with the same decision of ri. • After fixing ri’s predicate, the original rule ri does not exist. • Compute a rule that matches the maximum number of failed test • The new rule r2 with accept decision can be computed asF1 [6, 7]  F2 [7, 9]  a

33. Decision Fixing • The idea of decision fixing is that for each rule ri • Find the passed and failed tests whose first-match rule is ri • The set of the passed tests for ri can be computed as PT(i)-PT(i+1) • The set of the passed tests for ri can be computed as FT(i)-FT(i+1) • The increased number of passed tests by change the decision of ri is |FT(i)-FT(i+1)| - |PT(i)-PT(i+1)| • If change ri’s decision, the passed tests in PT(i)-PT(i+1) become failed tests and the failed tests in FT(i)-FT(i+1) become passed tests. • Changing r4’s decision can change the failed test p8 to a passed test.

34. Rule Deletion • The idea of rule deletion • Use all-match FDD to calculate the increased number of passed packets • Deleting r4 changes p8 to a passed test. • The failed test p8 matches the first path • r4 and r5 have different decisions F1 [7, 10] [1, 5] [6, 6] F2 F2 F2 [1, 2] [9,10] [1,3] [4,10] [3, 10] [1,2] [3,3] [4,8] 1,5 1,2,5 3,5 2,3,5 2,5 3,5 4,5 5