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L3VPN WG                                              Hamid Ould-Brahim
draft-ietf-l3vpn-bgpvpn-auto-08.txt                     Nortel Networks
INFORMATIONAL
Expiration Date: March 2007
                                                          Eric C. Rosen
                                                          Cisco Systems

                                                          Yakov Rekhter
                                                       Juniper Networks

                                                              (Editors)

                                                         September 2006


              Using BGP as an Auto-Discovery Mechanism for
                         VR-based Layer-3 VPNs



Status of this Memo


   By submitting this Internet-Draft, each author represents
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Abstract

   In any provider-based VPN scheme, the Provider Edge (PE) devices
   attached to a common VPN must exchange certain information as a
   prerequisite to establish VPN-specific connectivity. The main
   purpose of an auto-discovery mechanism is to enable a PE to
   dynamically discover the set of remote PEs having VPN members in

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   common. The auto-discovery mechanism proceeds by having a PE
   advertises to other PEs, at a minimum, its own IP address and the
   list of VPN members configured on that PE. Once that information is
   received the remote PEs will then identify the list of VPN sites
   members of the same VPN, and use the information
   carried within the discovery mechanism to establish VPN
   connectivity. This draft defines a BGP based auto-discovery
   mechanism for Virtual Router-based layer-3 VPNs. This mechanism is
   based on the approach used by BGP/MPLS-IP-VPN for distributing VPN
   routing information within the service provider(s).

Changes from 07 version (DELETE THIS WHEN IT BECOMES RFC)

  - Updated the IANA section to reflect the review from IANA
  - Nits from Harald's feedback.

1. Introduction


   In any provider-based VPN scheme, the Provider Edge (PE) devices
   attached to a common VPN must exchange certain information as a
   prerequisite to establish VPN-specific connectivity. An auto-
   discovery mechanism allows a PE to dynamically discover the set of
   remote PEs having VPN members in common. The auto-discovery
   mechanism proceeds by having a PE advertises to other PEs, at a
   minimum, its own IP address and the list of VPN sites configured
   on that PE. Once that information is received the remote PEs will
   then identify the list of VPN sites member of the same VPN with the
   advertising PE, and use the information carried within the discovery
   mechanism to establish VPN connectivity.

   The purpose of this draft is to define a BGP based auto-discovery
   mechanism for VR-based VPNs [VPN-VR] solution. This mechanism is
   based on the approach used by [BGP/MPLS-IP-VPN] for distributing VPN
   routing information within the service provider(s).


   Virtual router (VR) addresses must be exchanged, along with the
   information needed to enable the PEs to determine which VRs are in
   the same VPN ("membership"), and which of those VRs are to have VPN
   connectivity ("topology"). Once the VRs are reachable through the
   tunnels, routes ("reachability") are then exchanged by running
   existing routing protocols per VPN basis.

   The BGP-4 multiprotocol extensions are used to carry various
   information about VR-based VPNs. VPN-specific information associated
   with the NLRI is encoded either as attributes of the NLRI, or as
   part of the NLRI itself, or both.



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2. Provider-Provisioned VPN Reference Model

   When using BGP as an auto-discovery mechanism, VR-based l3vpns are
   using a network reference model as illustrated in figure 1.

                     PE                         PE
               +--------------+             +--------------+
   +--------+  | +----------+ |             | +----------+ | +--------+
   |  VPN-A |  | |  VPN-A   | |             | |  VPN-A   | | |  VPN-A |
   |  Sites |--| |Database /| |  BGP route  | | Database/| |-|  sites |
   +--------+  | |Processing| |<----------->| |Processing| | +--------+
               | +----------+ | Distribution| +----------+ |
               |              |             |              |
   +--------+  | +----------+ |             | +----------+ | +--------+
   | VPN-B  |  | |  VPN-B   | |  --------   | |   VPN-B  | | |  VPN-B |
   | Sites  |--| |Database /| |-(Backbones)-| | Database/| |-|  sites |
   +--------+  | |Processing| |  --------   | |Processing| | +--------+
               | +----------+ |             | +----------+ |
               |              |             |              |
   +--------+  | +----------+ |             | +----------+ | +--------+
   | VPN-C  |  | |  VPN-C   | |             | |   VPN-C  | | |  VPN-C |
   | Sites  |--| |Database /| |             | | Database/| |-|  sites |
   +--------+  | |Processing| |             | |Processing| | +--------+
               | +----------+ |             | +----------+ |
               +--------------+             +--------------+


                Figure 1: Network based VPN Reference Model


   It is assumed that the PEs can use BGP to distribute information to
   each other. This may be via direct IBGP peering, via direct EBGP
   peering, via multihop BGP peering, through intermediaries such as
   Route Reflectors, through a chain of intermediate BGP connections,
   etc.


3. Carrying VR-based VPN information in BGP

   The BGP-4 multiprotocol extensions are used to carry various
   information about VPNs. VPN-specific information associated with the
   NLRI is encoded either as attributes of the NLRI, or as part of the
   NLRI itself, or both.  The addressing information in the NLRI field
   is ALWAYS within the VPN address space, and therefore MUST be unique
   within the VPN. The address specified in the BGP next hop attribute,
   on the other hand, is in the service provider addressing space.


   The NLRI is a VPN-IP address or a labeled VPN-IP address. The NLRI
   address prefix is an address of one of the virtual routers
   configured on the PE. That address is used by the VRs to establish
   routing adjacencies and tunnel to each other [VPN-VR].


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4. Interpretation of VPN Information in the VR Model

4.1  Membership Discovery

   The VPN-ID format as defined in [RFC-2685] is used to identify a
   VPN. All virtual routers that are members of a specific VPN share
   the same VPN-ID. A VPN-ID is carried in the NLRI to make addresses
   of VRs globally unique. Making these addresses globally unique is
   necessary if one uses BGP for VRs' auto-discovery.


4.2  Encoding of the VPN-ID in the NLRI

   For the virtual router model, the VPN-ID is carried within the route
   distinguisher (RD) field. In order to hold the 7-bytes VPN-ID, the
   first byte of RD type field is used to indicate the existence of the
   VPN-ID format. A value of 0x80 in the first byte of RD's type field
   indicates that the RD field is carrying the VPN-ID format. In this
   case, the type field range 0x8000-0x80ff will be reserved for the
   virtual router case.


4.3  VPN-ID Extended Community

   A new extended community is used to carry the VPN-ID format. This
   attribute is transitive across the Autonomous system boundary. The
   type field of the VPN-ID extended community is of regular type to be
   assigned by IANA [BGP-COMM]. The remaining 7 bytes hold the VPN-ID
   value field as per [RFC-2685]. The BGP UPDATE message will carry
   information for a single VPN. It is the VPN-ID Extended Community,
   or more precisely route filtering based on the Extended Community
   that allows one VR to find out about other VRs in the same VPN.


4.4  VPN Topology Information

   A new extended community is used to indicate different VPN topology
   values. This attribute is transitive across the Autonomous system
   boundary. The value of the type field for extended type is assigned
   by IANA. The first two bytes of the value field (of the remaining 6
   bytes) are reserved. The actual topology values are carried within
   the remaining four bytes. The following topology values are defined:

         Value    Topology Type

           1          "Hub"
           2          "Spoke"
           3          "Mesh"

   Arbitrary values can also be used to allow specific topologies to be
   constructed.


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   In a hub and spoke topology, spoke VRs (i.e., PE having VRs as
   spokes within the VPN) will advertise their BGP information with VPN
   topology extended community with value of "2". Spoke VRs will only
   be allowed to connect to hub VRs and therefore spoke VR-based PEs
   will just import VPN information from BGP that is set of "1". Hub
   sites can connect to both hub and spoke sites (i.e., Hub VRs can
   import VPN topology of both values "1", "2", or "3". In a mesh
   topology, mesh sites connect to each other, each VR will advertise
   VPN topology information of "3".

   Furthermore, in the presence of both hub and spoke and mesh
   topologies within the same VPN, mesh sites can as well connect to
   hub sites and vice versa.




5. Tunnel Discovery

   Layer-3 VPNs must be implemented through some form of tunneling
   mechanism, where the packet formats and/or the addressing used
   within the VPN can be unrelated to that used to route the tunneled
   packets across the backbone. There are numerous tunneling mechanisms
   that can be used by a network based VPN (e.g., IP/IP [RFC-2003], GRE
   tunnels [RFC-1701], IPSec [RFC-2401], and MPLS tunnels [RFC-3031]).
   Each of these tunnels allows for opaque transport of frames as
   packet payload across the backbone, with forwarding disjoint from
   the address fields of the encapsulated packets. A provider edge
   router may terminate multiple types of tunnels and forward packets
   between these tunnels and other network interfaces in different
   ways. BGP can be used to carry tunnel endpoint addresses between
   edge routers.


   The BGP next hop will carry the service provider tunnel endpoint
   address. As an example, if IPSec is used as tunneling mechanism, the
   IPSec tunnel remote address will be discovered through BGP, and the
   actual tunnel establishment is achieved through IPSec signaling
   protocol.

   When MPLS tunneling is used, the label carried in the NLRI field is
   associated with an address of a VR, where the address is carried in
   the NLRI and is encoded as a VPN-IP address.

   The auto-discovery mechanism should convey minimum information for
   the tunnels to be setup. The means of distributing multiplexors must
   be defined either via some sort of tunnel-protocol-specific signaling
   mechanism, or via additional information carried by the
   auto-discovery protocol. That information may or may not be
   used directly within the specific signaling protocol. On one end of
   the spectrum, the combination of IP address (such as BGP next hop and
   IP address carried within the NLRI) and the label and/or VPN-ID
   provides sufficient information for a PE to setup per VPN tunnels or

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   shared tunnels per set of VPNs. On another end of the spectrum
   additional specific tunnel related information can be carried within
   the discovery process if needed.



6. Scalability Considerations

   In this section, we briefly summarize the main characteristics of
   our model with respect to scalability.

   Recall that the Service Provider network consists of (a) PE routers,
   (b) BGP Route Reflectors, (c) P routers (which are neither PE
   routers nor Route Reflectors), and, in the case of multi-provider
   VPNs, (d) ASBRs.

   A PE router, unless it is a Route Reflector should not retain
   VPN-related information unless it has at least one VPN with an
   Import Target identical to one of the VPN-related information Route
   Target attributes.  Inbound filtering should be used to cause such
   information to be discarded.  If a new Import Target is later added
   to one of the PE's VPNs (a "VPN Join" operation), it must then
   acquire the VPN-related information it may previously have
   discarded.

   This can be done using the refresh mechanism described in [BGP-
   RFSH].

   The outbound route filtering mechanism of [BGP-ORF], [BGP-CONS] can
   also be used to advantage to make the filtering more dynamic.

   Similarly, if a particular Import Target is no longer present in
   any of a PE's VPNs (as a result of one or more "VPN Prune"
   operations), the PE may discard all VPN-related information which,
   as a result, no longer have any of the PE's VPN's Import Targets as
   one of their Route Target Attributes.

   Note that VPN Join and Prune operations are non-disruptive, and do
   not require any BGP connections to be brought down, as long as the
   refresh mechanism of [BGP-RFSH] is used.

   As a result of these distribution rules, no one PE ever needs to
   maintain all routes for all VPNs; this is an important scalability
   consideration.

   Route reflectors can be partitioned among VPNs so that each
   partition carries routes for only a subset of the VPNs supported by
   the Service Provider. Thus no single route reflector is required to
   maintain VPN-related information for all VPNs.

   For inter-provider VPNs, if multi-hop EBGP is used, then the ASBRs
   need not maintain and distribute VPN-related information at all.


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   P routers do not maintain any VPN-related information.  In order
   to properly forward VPN traffic, the P routers need only maintain
   routes to the PE routers and the ASBRs.

   As a result, no single component within the Service Provider network
   has to maintain all the VPN-related information for all the VPNs.
   So the total capacity of the network to support increasing numbers
   of VPNs is not limited by the capacity of any individual component.

   An important consideration to remember is that one may have any
   number of INDEPENDENT BGP systems carrying VPN-related information.
   This is unlike the case of the Internet, where the Internet BGP
   system must carry all the Internet routes. Thus one significant
   (but perhaps subtle) distinction between the use of BGP for the
   Internet routing and the use of BGP for distributing VPN-related
   information, as described in this document is that the former is not
   amenable to partition, while the latter is.


7. Security Considerations


   This document describes a BGP-based auto-discovery mechanism which
   enables a PE router that attaches to a particular VPN to discover
   the set of other PE routers that attach to the same VPN.  Each PE
   router that is attached to a given VPN uses BGP to advertise that
   fact. Other PE routers which attach to the same VPN receive these
   BGP advertisements. This allows that set of PE routers to discover
   each other. Note that a PE will not always receive these
   advertisements directly from the remote PEs; the advertisements may
   be received from "intermediate" BGP speakers.

   It is of critical importance that a particular PE should not be
   "discovered" to be attached to a particular VPN unless that PE
   really is attached to that VPN, and indeed is properly authorized to
   be attached to that VPN.  If any arbitrary node on the Internet
   could start sending these BGP advertisements, and if those
   advertisements were able to reach the PE routers, and if the PE
   routers accepted those advertisements, then anyone could add any
   site to any VPN.  Thus the auto-discovery procedures described here
   presuppose that a particular PE trusts its BGP peers to be who they
   appear to be, and further that it can trusts those peers to be
   properly securing their local attachments.  (That is, a PE must
   trust that its peers are attached to, and are authorized to be
   attached to, the VPNs to which they claim to be attached.).

   If a particular remote PE is a BGP peer of the local PE, then the
   BGP authentication procedures of RFC 2385 can be used to ensure that
   the remote PE is who it claims to be, i.e., that it is a PE that is
   trusted.

   If a particular remote PE is not a BGP peer of the local PE, then
   the information it is advertising is being distributed to the local

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   PE through a chain of BGP speakers.  The local PE must trust that
   its peers only accept information from peers that they trust in
   turn, and this trust relation must be transitive.  BGP does not
   provide a way to determine that any particular piece of received
   information originated from a BGP speaker that was authorized to
   advertise that particular piece of information.  Hence the
   procedures of this document should be used only in environments
   where adequate trust relationships exist among the BGP speakers.

   Some of the VPN schemes which may use the procedures of this
   document can be made robust to failures of these trust
   relationships.  That is, it may be possible to keep the VPNs secure
   even if the auto-discovery procedures are not secure.  For example,
   a VPN based on the VR model can use IPsec tunnels for transmitting
   data and routing control packets between PE routers.  An
   illegitimate PE router which is discovered via BGP will not have the
   shared secret which makes it possible to set up the IPsec tunnel,
   and so will not be able to join the VPN.  Similarly, [IP-GRE]
   describes procedures for using IPsec tunnels to secure VPNs based on
   the [BGP/MPLS-IP-VPN] model.  The details for using IPsec to secure
   a particular sort of VPN depend on that sort of VPN and so are out
   of scope of the current document.


8. IANA Considerations


    IANA has assigned new extended community <TBD> for Topology
    values for VR-based L3VPN solution.

    IANA has assigned new extended community <TBD> for
    carrying VPN-ID format based on RFC2685 format.

    IANA has assigned new SAFI number <TBD> for indicating that
    the NLRI is carrying information for VR for labeled prefixes.

    SAFI number "140" for indicating that the NLRI is carrying
    information for VR for non-labeled prefixes.

9. Use of BGP Capability Advertisement

   A BGP speaker that uses VPN information as described in this
   document with multiprotocol extensions should use the Capability
   Advertisement procedures [RFC-3392] to determine whether the speaker
   could use Multiprotocol Extensions with a particular peer.

10. Acknowledgement

   The authors would like to acknowledge Benson Schliesser, and Thomas
   Narten for the constructive and fruitful comments.

11. Normative References

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   [BGP-COMM] Ramachandra, Tappan, et al., "BGP Extended Communities
      Attribute",  RFC4360.

   [BGP-MP] Bates, Chandra, Katz, and Rekhter, "Multiprotocol
      Extensions for BGP4", February 1998, RFC 2283.

   [RFC-3107] Rekhter Y, Rosen E., "Carrying Label Information in
      BGP4", January 2000, RFC3107.

   [BGP/MPLS-IP-VPN] Rosen E., et al, "BGP/MPLS VPNs", RFC4364.

   [RFC-2685] Fox B., et al, "Virtual Private Networks Identifier",
      RFC 2685, September 1999.

   [RFC-3392] Chandra, R., et al., "Capabilities Advertisement with
      BGP-4", RFC3392, May 2002.

   [VPN-VR] Knight, P., Ould-Brahim H., Gleeson, B., "Network based IP
      VPN Architecture using Virtual Routers", Work in progress.


12. Informative References



   [RFC-1701] Hanks, S., Li, T., Farinacci, D. and P. Traina, "Generic
      Routing Encapsulation (GRE)", RFC 1701, October 1994.

   [RFC-2003] Perkins, C., "IP Encapsulation within IP", RFC 2003,
      October 1996.

   [RFC-2026] Bradner, S., "The Internet Standards Process -- Revision
      3", RFC 2026, October 1996.

   [RFC-2401] Kent S., Atkinson R., "Security Architecture for the
      Internet Protocol", RFC 2401, November 1998.

   [RFC-2119] Bradner, S., "Key words for use in RFCs to Indicate
      Requirement Levels", RFC 2119, March 1997.


   [IP-GRE] Rosen, E., et al., "Use of PE-PE GRE or IP in BGP/MPLS IP
      Virtual Private Networks", draft-ietf-l3vpn-gre-ip-2547-03.txt,
      October 2004, Work in Progress.

   [BGP-RFSH] Chen, A., "Route Refresh Capability for BGP-4", RFC 2918,
      September 2000.

   [BGP-ORF] Chen, E., and Rekhter, Y., "Cooperative Route Filtering
      Capability for BGP-4", draft-ietf-idr-route-filter-11.txt,
      December 2004, Work in Progress.

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   [BGP-CONS] Marques, P., et al., "Constrained VPN route distribution"
     draft-ietf-l3vpn-rt-constrain-01.txt, September 2004, work in
     progress

13. Annex: Auto-Discovery in VR and MPLS-IP-VPN Interworking Scenarios

   Two interwoking scenarios are considered when the network is using
   both virtual routers and BGP/MPLS-IP-VPN. The first scenario is a
   CE-PE relationship between a PE (implementing BGP/MPLS-IP-VPN), and
   a VR appearing as a CE to the PE. The connection between the VR, and
   the PE can be either direct connectivity, or through a tunnel (e.g.,
   IPSec).

   The second scenario is when a PE is implementing both architectures.
   In this particular case, a single BGP session configured on the
   service provider network can be used to advertise either BGP/MPLS-
   IP-VPN VPN information or the virtual router related VPN
   information. From the VR and the BGP/MPLS-IP-VPN point of view there
   is complete separation from data path and addressing schemes.
   However the PE's interfaces are shared between both architectures.

   A PE implementing only BGP/MPLS-IP-VPN will not import routes from a
   BGP UPDATE message containing the VPN-ID extended community. On the
   other hand, a PE implementing the virtual router architecture will
   not import routes from a BGP UPDATE message containing the route
   target extended community attribute.

   The granularity at which the information is either BGP/MPLS-IP-VPN
   related or VR-related is per BGP UPDATE message. Different SAFI
   numbers are used to indicate that the message carried in BGP
   multiprotocol extension attributes is to be handled by the VR or
   BGP/MPLS-IP-VPN architectures.


14. Contributors


   Bryan Gleeson
   Nokia
   313 Fairchild Drive
   Mountain View CA 94043  USA
   bryan.gleeson/at/nokia.com


   Peter Ashwood-Smith
   Nortel Networks
   P.O. Box 3511 Station C,
   Ottawa, ON K1Y 4H7, Canada
   Phone: +1 613 763 4534
   Email: petera@nortelnetworks.com



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                draft-ietf-l3vpn-bgpvpn-auto-08.txt       September 2006

   Luyuan Fang
   AT&T
   200 Laurel Avenue
   Middletown, NJ 07748
   Email: Luyuanfang@att.com
   Phone: +1 (732) 420 1920

  Jeremy De Clercq
  Alcatel
  Francis Wellesplein 1
  B-2018 Antwerpen, Belgium
  Phone: +32 3 240 47 52
  Email: jeremy.de_clercq@alcatel.be

  Riad Hartani
  Caspian Networks
  170 Baytech Drive
  San Jose, CA 95143
  Phone: 408 382 5216
  Email: riad@caspiannetworks.com

  Tissa Senevirathne
  Force10 Networks
  1440 McCarthy Blvd,
  Milpitas, CA 95035.
  Phone: 408-965-5103
  Email: tsenevir@hotmail.com


15. Author' Addresses

   Hamid Ould-Brahim
   Nortel Networks
   P O Box 3511 Station C
   Ottawa, ON K1Y 4H7, Canada
   Email: hbrahim@nortelnetworks.com



   Eric C. Rosen
   Cisco Systems, Inc.
   1414 Massachusetts Avenue
   Boxborough, MA 01719
   E-mail: erosen@cisco.com


   Yakov Rekhter
   Juniper Networks
   1194 N. Mathilda Avenue
   Sunnyvale, CA 94089
   Email: yakov@juniper.net


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