INTERNET DRAFT Jeremy De Clercq Gerard Gastaud Tri T. Nguyen Dirk Ooms Alcatel January, 2001 Expires July, 2001 Connecting IPv6 Domains across IPv4 Clouds with BGP Status of this Memo This document is an Internet-Draft and is in full conformance with all provisions of Section 10 of RFC2026. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet- Drafts. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." The list of current Internet-Drafts can be accessed at http://www.ietf.org/ietf/1id-abstracts.txt The list of Internet-Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. Abstract This document specifies a mechanism for IPv6 islands to communicate with each other over an IPv4 core network without explicit tunnel setup, requiring only one IPv4 address (and a derived IPv4-compatible IPv6 address) per IPv6 island or per set of IPv6 islands connected to the same edge router. The hosts in the IPv6 islands can use native IPv6 addresses. The method uses MP-BGP in the edge routers to exchange IPv6 reachability information between the IPv6 islands. 1. Introduction [TRANS] specifies a method of automatic tunnels by using IPv4- compatible IPv6 addresses. This method is restricted to the case in Ooms Expires July 2001 [Page 1] Internet Draft draft-ietf-ngtrans-bgp-tunnel-00.txt January 2001 which the destination coincides with the endpoint of the tunnel (host-to-host or router-to-host). It has the disadvantage that it requires an IPv4 address per host. This memo specifies a mechanism for IPv6 islands to communicate with each other over an IPv4 core network without explicit tunnel set-up. The mechanism is intended as a transition tool used during the period of co-existence of IPv4 and IPv6. The method relies on BGP in the IPv4 network edge routers to exchange IPv6 reachability information between the IPv6 islands. The provider edge BGP routers are dual-stack and have at least an IPv4 address on the core network side and an IPv6 address at the IPv6 island side. Based on the information distributed by BGP, the data is automatically tunneled over the IPv4 cloud to its destination IPv6 island. This method requires only one IPv4 address (and a derived IPv4-compatible IPv6 address) per IPv6 island or per set of IPv6 islands connected to the same edge router. The hosts in the IPv6 islands can have native IPv6 addresses, this is different from e.g. 6to4 [6TO4], which requires that IPv4- translatable addresses are allocated to the IPv6 hosts. This method can be looked at as a simplified instantiation of the general solution proposed for IPv6 VPNs over a IPv4 backbone [V6VPN]. 2. Terminology The terminology of [IPV6] and [TRANS] applies to this document. We also use some of the terminology of [VPN]. 3. Reference architecture The ISP provides IPv6 services to some of its customers. However, its network core has not been updated to IPv6. The provider has upgraded some routers in some POPs to be dual stack routers. The dual stack routers provide access to IPv6 customers and may provide access to IPv4 customers in addition. The ISP also has access to the global IPv6 Internet. The interface between the Customer Edge (CE) router and the Provider Edge (PE) router is a native IPv6 interface which can be physical or logical. It is assumed that in most cases, a routing protocol IGP or EGP runs between the CE and PE for a customer site to exchange the Ooms Expires July 2001 [Page 2] Internet Draft draft-ietf-ngtrans-bgp-tunnel-00.txt January 2001 site reachability. A customer site may connect to the provider network over more than one interface. It is assumed that all nodes in the IPv6 island have a global IPv6 address. 4. IPv6 Site Prefix Distribution Routing protocols between a CE and a PE are needed to convey site prefixes to the ISP and conversely; for the mechanism described here, there is no specific requirement towards these protocols. Following the IPv6 addressing for global unicast aggregatable address [GUCST], the ISP is likely to have delegated some of its address space to the customer. Routing in an island for destinations outside this island is such that this outbound traffic is sent to one of the island CE (and therefore to the associated PE). The distribution of IPv6 island prefixes to the other IPv6 islands happens via [MP-BGP]. The session between IBGP peers is transported over IPv4 since every peer PE is dual stack and Route Reflectors (if used) are likely to be IPv4 only. The use of IPv4-compatible IPv6 addresses [V6ADDR] as the BGP next hop address allows to circumvent the problem of [MP-BGP] where the next hop has to be of the same family as the NLRI. The IPv4 address in the IPv4-compatible IPv6 address of the PE is the IPv4 address of the PE. The MP-BGP AFI will be IPv6 (value 2), the SAFI will be one of the basic values: unicast, multicast or both (1,2 or 3). When the number of PEs is not too high, it is possible for PEs to peer in a mesh fashion. Otherwise Route Reflectors are used and the PEs are configured with some Route Reflector identity. 5. Tunneling The use of an IPv4-compatible IPv6 address [V6ADDR] as the BGP next hop address allows a PE that has to forward a packet to automatically determine the IPv4 endpoint of the tunnel by looking at the BGP routing info. If this transition method is used to connect to the public IPv6 Internet, normal IPv4 tunnels [TUNNEL] do the job (no need for more secure LSPs or IPsec tunnels). When there are many peers, the number of tunnels could be a concern. However, there is no state required beyond the BGP state. Ooms Expires July 2001 [Page 3] Internet Draft draft-ietf-ngtrans-bgp-tunnel-00.txt January 2001 Considerations on 'common tunneling techniques' and 'automatic tunneling techniques' in [TRANS] are valid for the mechanism described in this document. 6. PE requirements The dual stack PE has to run MP-BGP. The address of the peer-PEs or the Route Reflector need to be configured. The PE must perform IPv4 encapsulation on packets whose next hop is an IPv4-compatible IPv6 address. A PE must be able to do IPv4 decapsulation. 7. Comparison to MPLS/BGP VPNs The described mechanism is a simplified instantiation of the solution for MPLS/BGP VPNs [VPN, V6VPN]. The method in this draft aims at enabling connections to the public IPv6 Internet, which could be viewed as one large 'public' VPN. Since there is only one VPN connecting hosts with globally unique addresses that do not need island-to-island security, things are much simplified: - Since the IPv6 addresses are globally unique, there is no need for a Route Distinguisher (RD). - No need for VPN Routing and Forwarding (VRF) tables, the route info is in the normal routing table and when the BGP next-hop is a IPv4- compatible IPv6 address the data is tunneled in IPv4 to this BGP next-hop. - No need for a Route Target. - No need for the VPN SAFIs. - No need to carry labels in MP-BGP. The method in this draft could be extended to using LSPs in stead of IP tunnels, but this wouldn't change anything to the MP-BGP behavior (there will never be a 'bottom' label). 8. Security considerations This proposal can use the security features of BGP and any policy defined in the ISP domain. References Ooms Expires July 2001 [Page 4] Internet Draft draft-ietf-ngtrans-bgp-tunnel-00.txt January 2001 [6TO4] B. Carpenter, K. Moore, "Connection of IPv6 domains via IPv4 Clouds without Explicit Tunnels"", draft-ietf-ngtrans-6to4- 05.txt, May 2000. [GUCST] Deering, S., R. Hinden, and M. O'dell, "An IPv6 Aggregatable Global Unicast Address Format" , RFC2374. [IPV6] Deering, S., and R. Hinden, "Internet Protocol, Version 6 (IPv6) Specification", RFC2460. [MP-BGP]T. Bates, R. Chandra, D. Katz, Y. Rekhter, "Multiprotocol Exten- sions for BGP-4", RFC2858. [VPN] Rosen E., Rekhter Y., Brannon S., Chase C., De Clercq J., Hitchin P., Marshall , Srinivasan V., "BGP/MPLS VPNs", draft- rosen-rfc2547bis-02.txt (work in progress). [TRANS] R. Gilligan & E. Nordmark, "Transition Mechanisms for IPv6 Hosts and Routers", RFC2893. [TUNNEL]W. Simpson, "IP in IP Tunneling", RFC1853. [V6ADDR]Deering, S., and R. Hinden, "IP Version 6 Addressing Architec- ture", draft-ietf-ipngwg-addr-arch-v3-02.txt. [V6VPN] Nguyen T., Gastaud G., Ooms D.,"BGP-MPLS VPN extension for IPv6 VPN over an IPv4 infrastructure", draft-nguyen-bgp-ipv6-vpn- 00.txt, October 2000 Authors' Addresses Tri T. Nguyen Alcatel Level 20 Noth Point Tower, 100 Miller Street, North Sydney NSW 2060, Australia E-mail: tri.t.nguyen@alcatel.com Dirk Ooms Alcatel Fr. Wellesplein 1, 2018 Antwerp, Belgium E-mail: dirk.ooms@alcatel.be Gerard Gastaud Alcatel 10 rue Latecoere, BP 57, 78141 Velizy Cedex, France E-mail: gerard.gastaud@alcatel.fr Ooms Expires July 2001 [Page 5] Internet Draft draft-ietf-ngtrans-bgp-tunnel-00.txt January 2001 Jeremy De Clercq Alcatel Fr. Wellesplein 1, 2018 Antwerp, Belgium E-mail: jeremy.de_clercq@alcatel.be Ooms Expires July 2001 [Page 6]