Secure Autoconfiguration and Routing in an IPv6-Based Ad Hoc Network

1. Secure Autoconfiguration and Routing in anIPv6-Based Ad Hoc Network Jehn-Ruey Jiang Hsuan-Chuang University

2. Outline IPv6 Overview Ad Hoc Networks IP Autoconfiguration CGA S-DSR Conclusion

3. Outline IPv6 Overview Ad Hoc Networks IP Autoconfiguration CGA S-DSR Conclusion

4. Internet History • 1969:ARPANET (using Network Control Protocol, NCP) • 1974: TCP/IP (by Vinton Cerf and Bob Kahn) • 1981: IPv4 (RFC 791) • 1984: NSFNet (using Transmission Control Protocol/Internet Protocol, TCP/IP) • 1990: ARPANET retired • 1991: WWW (World Wide Web) (by Tim Berners-Lee) • 1993: NCSA Mosaic (by Mark Andreesen) → Netscape Navigator • 1990s: Internet • 2000s: internet

5. IPv6 History • 1992: IPng (Next Generation IP) began in IETF (Internet Engineering Task Force)working groups • 1994: IPv6, announced by IESG(Internet Engineering Steering Group) (RFC 1752) (IPv5 is for a stream protocol) • 1998: IP Version 6 Addressing Architecture [July] (RFC2373) • 1998: Internet Protocol, Version 6 (IPv6) Specification [December] (RFC2460)

6. IPv6 Features • Expanded address space128 bits ( 3.4*1038 IP Addresses) • Auto-configurationStateless (Prefix + EUI-64), Stateful (DHCPv6),Addressing Lifetime (Age for renumbering) • Quality of Service 20-bit Flow Label enables identification of traffic flows for real-time Voice and Video stream • Integrated Security SupportIPSec(AH Header+ESP Header) • MobilityNo Foreign Agent, Free of Triangle routing, Plug&Play (Care-of Address)

7. IPv6 Vision IPv6  Anything, Anytime, Anywhere Connection to Internet Source: NDHU

8. Outline IPv6 Overview Ad Hoc Networks IP Autoconfiguration CGA S-DSR Conclusion

9. Ad hoc Networks • Ad hoc: formed, arranged, or done (often temporarily) for a particular purpose only • Ad Hoc Network (MANET):A collection of wireless mobile hosts forming a temporary network without the aid of established infrastructure or centralized administration

10. Infrastructure vs Ad-hoc Modes infrastructure network AP AP wired network AP Multi-hop ad hoc network ad-hoc network ad-hoc network

11. Applications of MANETs • Battlefields • Disaster rescue • Spontaneous meetings • Outdoor activities

12. MANET Routing Protocols • Table Driven (Proactive) DSDV, FSR • On Demand (Reactive)AODV, TORA, ABR, SSA • HybridZRP

13. Secure Routing Protocols • SAODV • SRP • SAR • CSER • SEAD • Ariadene • BSAR

14. Outline IPv6 Overview Ad Hoc Networks IP Autoconfiguration CGA S-DSR Conclusion

15. Stateful vs. Stateless • Stateful DHCPv6 • StatelessDAD (Duplicate Address Detection)

16. DAD (1/3) • A function of NDP (Neighbor Discovery Protocol) • Two types of messages • NS (Neighbor Solicitation) • NA (Neighbor Advertisement)

17. Ethernet Header: Dest. MAC is 33-33-FF-22-22-22 IPv6Header: Source Address is :: Destination address is FF02::1:FF:FE22:2222 NS Header: Target Address is FE80::2AA:FF:FE22:2222 DAD (2/3) Tentative IP: FE80::2AA:FF:FE22:2222 Host A (multicast) Neighbor Solicitation IP : FE80::2AA:FF:FE22:2222 Host B

18. Ethernet Header: Dest. MAC is 33-33-00-00-00-01 IPv6Header: Source Address is FE80::2AA:FF:FE22:2222 Destination address is FF02::1 NA Header: Target Address is FE80::2AA:FF:FE22:2222 DAD (3/3) Tentative IP: FE80::2AA:FF:FE22:2222 Host A Neighbor Solicitation (multicast) Host B IP : FE80::2AA:FF:FE22:2222

19. Outline IPv6 Overview Ad Hoc Networks IP Autoconfiguration CGA S-DSR Conclusion

20. What is a CGA • Cryptographically Generated Address • Also known as SUCV(Statistically Unique and Cryptographically Verifiable) address • It associates a host's address with its public key in order for other hosts to verify the ownership of the address

21. Public Key and a CGA

22. Outline IPv6 Overview Ad Hoc Networks IP Autoconfiguration CGA S-DSR Conclusion

23. S-DSR Overview (1/2) • Secure Dynamic Source Routing Protocol • It incorates • DSR protocol • CGA • Address autoconfiguration • DNS autoregistration and discovery

24. S-DSR Overview (2/2) • It allows the network to be bootstrapped without manual administration • It can resist a variety of attacks, including • black hole attack • replay attack • message forging attack • message tampering attack • DNS impersonation attack

25. S-DSR Assumption • There is a publicly known one-way, collision-resistant hashing function H, and there exists an IPv6 DNS server in the MANET. The DNS server has a public-private key pair, which is known by all mobile nodes prior to entering the MANET. • For a mobile which intends to own a permanent domain name, an entry (domain name, IP address) should have been placed at the DNS server before the network is formed. In this case, impersonate such hosts would be impossible. • For a mobile node which dose not intend to own a permanent domain name, its (domain name, IP address) entry can be registered with the DNS server on-line after the network is formed. We adopt the first-come-first-serve policy for registration of new domain names.

26. S-DSR Messages (1/2) 8 types of messages:

27. S-DSR Messages (2/2) Definitions of symbols:

28. S-DSR DAD (1/4) • On receiving AREQ(SIP,seq,DN,ch,RR), each intermediate node appends its address into the route record RR and rebroadcasts the message. • When a node R receives an AREQ with SIP equal to its own IP address, it unicasts an address reply message AREP(SIP,seq,RR, [SIP,seq,ch]RSK, RPK,Rrn) to S along the reverse route derived from RR.

29. S-DSR DAD (2/4) • The AREP message should also be delivered to the DNS server through unicast • When a DNS server N receives the AREQ message and finds that the domain name in the DN field has already been registered by another host of address different from SIP, it will also unicast a DREP message (SIP, seq,RR, [SIP,seq,ch]NSK) to S.

30. S-DSR DAD (3/4) • When the node S with a pending address request receives the AREP message, it authenticates the integrity of the message as follows: • It verifies if SIP matches with H(RPK,Rrn). • It decrypts [SIP,seq,ch]RSK by RPK and verifies if the decrypted result matches with [SIP,seq,ch]. • If both checks pass, the AREP message is considered valid.

31. S-DSR DAD (4/4)

32. S-DSR Routing (1/5) • On receiving (SIP,DIP,seq,SRR,[SIP,DIP,seq] SSK,SPK,Snd), each intermediate node I appends [SIP,seq]ISK,IIP,IPK,Irn into the secure route record SRR and rebroadcasts the message.

33. S-DSR Routing (2/5) • On receiving RREQ (SIP,DIP,seq,SRR,[SIP,DIP,seq] SSK,SPK,Snd), it authenticates the message as follows: • It verifies if SIP matches with H(SPk, Srn). • It decrypts [SIP,DIP,seq]SSK by SPK and verifies if the decrypted result matches with [SIP,DIP,seq] indicated in the message.

34. S-DSR Routing (3/5) • It verifies every IP address appearing in SRR. For an IP address IIP, whose corresponding information is [SIP,seq]ISK, IIP, IPK,Irn, the verification is done by checking if IIP matches with H(IPK,Irn), and if [SIP,seq]ISK can be decrypted by IPk to be [SIP,seq]. • It verifies if seq is greater than the sequence number of any RREQ message sent by S.

35. S-DSR Routing (4/5) • If all the verifications are passed, the RREQ message is considered valid. • The destination node D then unicasts a RREP Message (SIP,DIP,seq,RR,SR(D-S), [SIP,seq,SR(D-S)]DSK,DPK,Drn) to S along source route SR(D-S), which is derived form SRR.

36. S-DSR Routing (5/5)

37. Outline IPv6 Overview Ad Hoc Networks IP Autoconfiguration CGA S-DSR Conclusion

38. Conclusion (1/2) • S-DSR can resist • Black hole attack • Route request (RREQ) message reply attack • Forged route request (RREQ) message attack • Forged address reply (AREP) message attack • Forged route error (RERR) message attack • Tampered control message attacks • DNS server impersonation attack

39. Conclusion (2/2) • Future work:To extend S-DSR to be a credit-based protocol with the help of CGAs, in which each node keeps a record for each IP address to differentiate between favorable nodes and unfavorable nodes.

40. Q&A