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PROPOSED STANDARD
Internet Engineering Task Force (IETF)                 P. Pillay-Esnault
Request for Comments: 6565                                 Cisco Systems
Category: Standards Track                                       P. Moyer
ISSN: 2070-1721                                            Pollere, Inc.
                                                                J. Doyle
                                               Jeff Doyle and Associates
                                                              E. Ertekin
                                                             M. Lundberg
                                                     Booz Allen Hamilton
                                                               June 2012


  OSPFv3 as a Provider Edge to Customer Edge (PE-CE) Routing Protocol

Abstract

   Many Service Providers (SPs) offer Virtual Private Network (VPN)
   services to their customers using a technique in which Customer Edge
   (CE) routers are routing peers of Provider Edge (PE) routers.  The
   Border Gateway Protocol (BGP) is used to distribute the customer's
   routes across the provider's IP backbone network, and Multiprotocol
   Label Switching (MPLS) is used to tunnel customer packets across the
   provider's backbone.  Support currently exists for both IPv4 and IPv6
   VPNs; however, only Open Shortest Path First version 2 (OSPFv2) as
   PE-CE protocol is specified.  This document extends those
   specifications to support OSPF version 3 (OSPFv3) as a PE-CE routing
   protocol.  The OSPFv3 PE-CE functionality is identical to that of
   OSPFv2 except for the differences described in this document.

Status of This Memo

   This is an Internet Standards Track document.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Further information on
   Internet Standards is available in Section 2 of RFC 5741.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   http://www.rfc-editor.org/info/rfc6565.









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Copyright Notice

   Copyright (c) 2012 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (http://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
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   include Simplified BSD License text as described in Section 4.e of
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.

   This document may contain material from IETF Documents or IETF
   Contributions published or made publicly available before November
   10, 2008.  The person(s) controlling the copyright in some of this
   material may not have granted the IETF Trust the right to allow
   modifications of such material outside the IETF Standards Process.
   Without obtaining an adequate license from the person(s) controlling
   the copyright in such materials, this document may not be modified
   outside the IETF Standards Process, and derivative works of it may
   not be created outside the IETF Standards Process, except to format
   it for publication as an RFC or to translate it into languages other
   than English.

























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Table of Contents

   1. Introduction ....................................................4
   2. Specification of Requirements ...................................4
   3. Requirements ....................................................4
      3.1. OSPFv3 Specificities .......................................5
   4. BGP/OSPFv3 Interaction Procedures for PE Routers ................5
      4.1. VRFs and OSPFv3 Instances ..................................5
           4.1.1. Independent OSPFv3 Instances in PEs .................6
           4.1.2. OSPFv3 Domain Identifier ............................6
      4.2. OSPFv3 Areas ...............................................7
      4.3. VRFs and Routes ............................................7
           4.3.1. OSPFv3 Routes on PEs ................................8
           4.3.2. VPN-IPv6 Routes Received from MP-BGP ................9
      4.4. BGP Extended Communities Attribute ........................12
      4.5. Loop Prevention Techniques ................................14
           4.5.1. OSPFv3 Down Bit ....................................15
           4.5.2. Other Possible Loops ...............................15
   5. OSPFv3 Sham Links ..............................................15
      5.1. Creating a Sham Link ......................................16
      5.2. OSPF Protocol on Sham Link ................................16
      5.3. OSPF Packet Forwarding on Sham Link .......................17
   6. Multiple Address Family Support ................................17
   7. Security Considerations ........................................18
   8. IANA Considerations ............................................18
   9. Acknowledgments ................................................18
   10. References ....................................................18
      10.1. Normative References .....................................18
      10.2. Informative References ...................................19






















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1.  Introduction

   [RFC4364] offers Service Providers (SPs) a method for providing Layer
   3 Virtual Private Network (VPN) services to subtending customer
   networks.  Using the procedures defined in [RFC4364], Provider Edge
   (PE) routers separate customer VPN routing information into Virtual
   Routing and Forwarding (VRF) tables.  The Border Gateway Protocol
   (BGP) is used to disseminate customer network VPN routes between PE
   VRFs configured in the same VPN.

   The initial BGP/MPLS IP VPN specification enabled PE routers to learn
   routes within customer sites through static routing, or through a
   dynamic routing protocol instantiated on the PE-CE link.
   Specifically, [RFC4364] (and its predecessor, [RFC2547]) included
   support for dynamic routing protocols such as BGP, RIP, and OSPFv2.
   The OSPFv2 as the Provider/Customer Edge Protocol specification
   [RFC4577] further updates the operation of OSPFv2 as the PE-CE
   routing protocol by detailing additional extensions to enable intra-
   domain routing connectivity between OSPFv2-based customer sites.

   While [RFC4364] was defined for IPv4-based networks, [RFC4659]
   extends support to IPv6 VPNs.  It is expected that OSPFv3 will be
   used as the IGP for some IPv6 VPNs just as the OSPFv2 was used for
   IPv4 VPNs.  The advantages of using OSPFv3 as a PE-CE protocol are
   the same as for the IPv4 VPN deployment.

   This document defines the mechanisms required to enable the operation
   of OSPFv3 as the PE-CE routing protocol.  In doing so, it reuses, and
   extends where necessary, methods defined in [RFC4659] and [RFC4577].
   This document also includes the specifications for maintaining intra-
   domain routing connectivity between OSPFv3-based customer sites
   across an SP backbone.

   We presuppose familiarity with the contents of [RFC4364], [RFC4659],
   [RFC4577], [RFC4576], [RFC5340], and [RFC2328].

2.  Specification of Requirements

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in [RFC2119].

3.  Requirements

   The benefits and considerations associated with deploying OSPFv3 as
   the PE-CE routing protocol are similar to those described in
   [RFC4577].  The requirements described in Section 3 of [RFC4577]
   remain semantically identical for the deployment of OSPFv3.



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   [RFC5340] describes the modifications required to OSPF to support
   IPv6.  In that specification, many of the fundamental mechanisms
   associated with OSPFv2 remain unchanged for OSPFv3.  Consequently,
   the operation of OSPFv3 as the PE-CE routing protocol is very similar
   to OSPFv2 as the PE-CE protocol.

3.1.  OSPFv3 Specificities

   Section 2 of [RFC5340] describes the differences between OSPFv3 and
   OSPFv2.  Several of these changes will require modifications to the
   architecture described in [RFC4577].  These differences and their
   corresponding impact to [RFC4577] are described below:

      New LSA types:

      For an IPv6 VPN architecture where customers interface with
      providers through OSPFv3, traditional BGP/OSPF interactions
      specify that VPN-IPv6 reachability information redistributed into
      OSPFv3 will be expressed as AS-External OSPFv3 LSAs.  Instead, it
      may be desirable to view these LSAs as inter-area-prefix LSAs.
      The OSPF Route Type Extended Communities attribute defined in
      [RFC4577] is extended to include OSPFv3 route types.  These new
      encodings are defined in Section 4.4.

      Multiple instances over a link:

      OSPFv3 operates on a per-link basis as opposed to OSPFv2, which
      operates on a per-IP-subnet basis.  The support of multiple OSPFv3
      protocol instances on a link changes the architecture described in
      [RFC4577]. [RFC4577] specifies that each interface belongs to no
      more than one OSPF instance.  For OSPFv3, multiple instances can
      be established over a single interface and associated with the
      same VRF.

      In addition to establishing multiple OSPFv3 instances over a
      single PE-CE link, multiple OSPFv3 instances can also be
      established across a sham link.  This enables multiple OSPFv3
      instances associated with a VRF to independently establish intra-
      area connectivity to other OSPFv3 instances attached to a remote
      PE VRF.  Support for multiple OSPFv3 instances across the sham
      link is described in Section 5.

4.  BGP/OSPFv3 Interaction Procedures for PE Routers

4.1.  VRFs and OSPFv3 Instances

   The relationship between VRFs, interfaces, and OSPFv3 instances on a
   PE router is described in the following section.



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   As defined in [RFC4364], a PE router can be configured with one or
   more VRFs.  Each VRF configured on the PE corresponds to a customer
   VPN and retains the destinations that are reachable within that VPN.
   Each VRF may be associated with one or more interfaces, which allows
   multiple sites to participate in the same VPN.  If OSPFv3 is
   instantiated on an interface associated with a VRF, the VRF will be
   populated with OSPFv3 routing information.

   As OSPFv3 supports multiple instances on a single interface, it is
   therefore possible that multiple customer sites can connect to the
   same interface of a PE router (e.g., through a Layer 2 switch) using
   distinct OSPFv3 instances.  A PE interface can be associated with
   only one VRF, and all OSPFv3 instances running on the same interface
   MUST be associated with the same VRF.  Configurations where a PE
   interface is associated with multiple VRFs are out of scope for this
   document.

4.1.1.  Independent OSPFv3 Instances in PEs

   Similar to [RFC4577], the PE must associate at least one OSPFv3
   instance for each OSPFv3 domain to which it attaches, and each
   instance of OSPFv3 MUST be associated with a single VRF.

   The support of multiple PE-CE OSPFv3 instances per PE interface does
   not change the paradigm that an OSPF instance can be associated with
   only a single VRF.  Furthermore, for each instance instantiated on
   the interface, the PE establishes adjacencies with corresponding CEs
   associated with the instance.  Note that although multiple instances
   may populate a common VRF, they do not leak routes to one another,
   unless configured to do so.

4.1.2.  OSPFv3 Domain Identifier

   The OSPFv3 Domain ID describes the administrative domain of the OSPF
   instance that originated the route.  It has an AS-wide significance
   and is one of the parameters used to determine whether a VPN-IPv6
   route should be translated as an Inter-area-prefix LSA or External
   LSA.  Each OSPFv3 instance MUST have a primary Domain ID that is
   transported along with the VPN-IPv6 route in a BGP attribute over the
   VPN backbone.  Each OSPFv3 instance may have a set of secondary
   Domain IDs that applies to other OSPFv3 instances within its
   administrative domain.

   The primary Domain ID may either be configured or be set to a value
   of NULL.  The secondary Domain IDs are only allowed if a non-NULL
   primary Domain ID is configured.  The Domain ID MUST be configured on
   a per-OSPFv3 instance basis.




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   The Domain ID is used to determine whether an incoming VPN-IPv6 route
   belongs to the same domain as the receiving OSPFv3 instance.  An
   incoming VPN-IPv6 route is said to belong to the same domain if a
   non-NULL incoming Domain ID matches either the local primary or one
   of the secondary Domain IDs.  If the local Domain ID and incoming
   Domain ID are NULL, it is considered a match.

4.2.  OSPFv3 Areas

   Sections 4.1.4 and 4.2.3 of [RFC4577] describe the characteristics of
   a PE router within an OSPFv2 domain.  The mechanisms and expected
   behavior described in [RFC4577] are applicable to an OSPFv3 domain.

4.3.  VRFs and Routes

   From the perspective of the CE, the PE appears as any other OSPFv3
   neighbor.  There is no requirement for the CE to support any
   mechanisms of IPv6 BGP/MPLS VPNs or for the CE to have any awareness
   of the VPNs, thereby enabling any OSPFv3 implementation to be used on
   a CE.

   Because the export and import policies might cause different routes
   to be installed in different VRFs of the same OSPFv3 domain, the VPN
   backbone cannot be considered as a single router from the perspective
   of the domain's CEs.  Rather, each CE should view its connected PE as
   a separate router.

   The PE uses OSPFv3 to distribute routes to CEs, and MP-BGP [RFC4760]
   to distribute VPN-IPv6 routes to other (remote) PE routers as defined
   in [RFC4659].  An IPv6 prefix installed in the VRF by OSPFv3 is
   changed to a VPN-IPv6 prefix by the addition of an 8-octet Route
   Distinguisher (RD) as discussed in Section 2 of [RFC4659].  This VPN-
   IPv6 route can then be redistributed into MP-BGP according to an
   export policy that adds a Route Target (RT) Extended Communities
   attribute to the Network Layer Reachability Information (NLRI)
   [RFC4360].

   Domain IDs are used to distinguish between OSPFv3 instances.  When an
   OSPFv3 distributed route is redistributed into MP-BGP, the Domain ID,
   OSPFv3 Router ID, Area, OSPFv3 Route Type, and Options fields
   (External Route Type) are also carried in Extended Community
   Attributes of the MP-BGP route.

   A PE receiving a VPN-IPv6 NLRI from MP-BGP uses an import policy to
   determine, based on the RT, whether the route is eligible to be
   installed in one of its local VRFs.  The BGP decision process selects





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   which of the eligible routes are to be installed in the associated
   VRF, and the selected set of VPN-IPv6 routes are converted into IPv6
   routes by removing the RD before installation.

   An IPv6 route learned from MP-BGP and installed in a VRF might or
   might not be redistributed into OSPFv3, depending on the local
   configuration.  For example, the PE might be configured to advertise
   only a default route to CEs of a particular OSPFv3 instance.
   Further, if the route is to be redistributed into multiple OSPFv3
   instances, the route might be advertised using different LSA types in
   different instances.

   If an IPv6 route learned from MP-BGP is to be redistributed into a
   particular OSPFv3 instance, the OSPF Domain Identifier Extended
   Communities attribute of the VPN-IPv6 route is used to determine
   whether the OSPFv3 instance from which the route was learned is the
   same as the OSPFv3 instance into which the route is to be
   redistributed.

4.3.1.  OSPFv3 Routes on PEs

   VRFs may be populated by both OSPFv3 routes from a CE or VPN-IPv6
   routes from other PEs via MP-BGP.  OSPFv3 routes are installed in a
   VRF using the OSPFv3 decision process.  They may be redistributed
   into BGP and disseminated to other PEs participating in the VPN.  At
   these remote PEs, the VPN-IPv6 routes may be imported into a VRF and
   redistributed into the OSPFv3 instance(s) associated with that VRF.

   As specified in [RFC4659], routes imported and exported into a VRF
   are controlled by the Route Target (RT) Extended Communities
   attribute.  OSPFv3 routes that are redistributed into BGP are given
   an RT that corresponds to the VRF.  This RT is examined at remote
   PEs.  In order to import a route, a VRF must have an import RT that
   is identical to the route's RT.  For routes that are eligible to be
   imported into the VRF, the standard BGP decision process is used to
   choose the "best" route(s).

   When a route is advertised from a CE to a PE via OSPFv3 and that
   route is installed in the VRF associated with the CE, the route is
   advertised to other locally attached CEs under normal OSPFv3
   procedures.

   The route is also redistributed into MP-BGP to be advertised to
   remote PEs.  The information necessary for accurate redistribution
   back into OSPFv3 by the remote PEs is carried in the OSPF Route Type,
   OSPF Domain ID, and OSPF Router ID Extended Communities attributes
   (Section 4.4).  The relevant local OSPFv3 information encoded into
   these attributes are as follows:



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      The Area ID of the PE-CE link.

      The Route Type, as determined by the LSA type from which the route
      was learned.

      The Options fields (External metric-type).

      The Domain ID of the OSPFv3 process.  If no Domain ID is
      configured, the NULL identifier is used.

      The PE's Router ID associated with the OSPFv3 instance.

   A Multi-Exit-Discriminator (MED) attribute SHOULD also be set to the
   value of the OSPFv3 metric associated with the route plus 1, when the
   OSPFv3 route is redistributed into the MP-BGP.

4.3.2.  VPN-IPv6 Routes Received from MP-BGP

   When a PE receives a valid VPN-IPv6 route from MP-BGP and has
   identified an association with a local VRF, it must determine:

      Whether a route to the corresponding IPv6 prefix is to be
      installed in the VRF;

      Whether the installed IPv6 route is to be redistributed to one or
      more local OSPFv3 instances; and

      What OSPFv3 LSA type is to be used when advertising the route into
      each OSPFv3 instance.

   An IPv6 route derived from a received VPN-IPv6 route is not installed
   in the associated local VRF if:

      The BGP decision process identifies a better route to the
      destination NLRI; or

      A configured import policy prohibits the installation of the
      route.

   The PE advertises the IPv6 route learned from MP-BGP to attached CEs
   via OSPFv3 if:

      No configured filtering prohibits redistributing the route to
      OSPFv3;

      No configured policy blocks the route in favor of a less-specific
      summary route; and




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      Redistribution of a BGP learned IPv6 route into OSPF is based on
      local policy.

   The subsequent sections discuss the advertisement of routes learned
   from MP-BGP and the rules for determining to which LSA types and to
   which CEs to advertise the routes.

   When the PE sends an LSA to a CE, it sets the DN-bit in the LSA to
   prevent looping.  The DN-bit is discussed in Section 4.5.1.

4.3.2.1.  OSPF Inter-Area Routes

   A PE advertises an IPv6 route using an Inter-Area-Prefix (type
   0x2003) LSA under the following circumstances:

      The OSPFv3 domain from which the IPv6 route was learned is the
      same (as determined by the Domain ID) as the domain of the OSPFv3
      instance into which it is to be redistributed; and

      The IPv6 route was advertised to a remote PE in an Intra-Area-
      Prefix (type 0x2009) OR an Inter-Area-Prefix (type 0x2003) LSA.

   Note that under these rules, the PE represents itself as an Area
   Border Router (ABR) regardless of whether or not the route is being
   advertised into the same area number from which the remote PE learned
   it (that is, whether the VPN-IPv6 route carries the same or different
   area numbers).

4.3.2.2.  OSPF Intra-Area Route

   A route is advertised as an intra-area route using an Intra-Area-
   Prefix (type 0x2009) LSA only when sham links are used, as described
   in Section 5.  Otherwise, routes are advertised as either inter-area
   (Section 4.3.2.1) or external / Not-So-Stubby Area (NSSA) (Section
   4.3.2.3) routes.

4.3.2.3.  OSPF External Routes and NSSA Routes

   A PE considers an IPv6 route to be external under the following
   circumstances:

      The OSPFv3 domain from which the route was learned is different
      (as determined by the Domain ID) from the domain of the OSPFv3
      instance into which it is redistributed; or







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      The OSPFv3 domain from which the route was learned is the same as
      the domain of the OSPFv3 instance into which it is redistributed,
      AND it was advertised to the remote PE in an AS-External-LSA (type
      0x4005) or an NSSA-LSA (type 0x2007); or

      The route was not learned from an OSPFv3 instance.

   To determine if the learned route is from a different domain, the
   Domain ID associated with the VPN-IPv6 route (in the OSPF Domain ID
   Extended Communities attribute or attributes) is compared with the
   local OSPFv3 Domain ID, if configured.  Compared Domain IDs are
   considered identical if:

   1.  All 8 bytes are identical; or

   2.  Both Domain IDs are NULL (all zeroes).

   Note that if the VPN-IPv6 route does not have a Domain ID in its
   attributes, or if the local OSPFv3 instance does not have a
   configured Domain ID (i.e., in either case), the route is considered
   to have a NULL Domain ID.

   An IPv6 route that is determined to be external might or might not be
   advertised to a connected CE, depending on the type of area to which
   the PE-CE link belongs and whether there is a configured policy
   restricting its advertisement.

   If there are multiple external routes to the same prefix, the
   standard OSPFv3 decision process is used to select the "best" route.

   If the external route is to be advertised and the area type of the
   PE-CE link is NSSA, the PE advertises the route in an NSSA-LSA (type
   0x2007); otherwise, the external route is advertised in an
   AS-External-LSA (type 0x4005).

   The DN-bit of the LSA advertising the external route MUST be set, as
   described in Section 4.5.1.

   If the VPN-IPv6 route indicates a route Type-1 metric, the PE should
   advertise the external route with that metric-type; otherwise, the
   metric-type of the external IPv6 route is set to Type-2 by default.
   Note that, by default, a PE should advertise an external route with a
   Type-2 metric if the IPv6 route's Domain ID is different than the
   local OSPFv3 instance, unless specified otherwise by local policy.







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4.4.  BGP Extended Communities Attributes

   OSPFv3 routes from one site are translated and delivered
   transparently to the remote site as BGP VPN-IPv6 routes.  The
   original OSPFv3 routes carry OSPFv3-specific information that needs
   to be communicated to the remote PE to ensure transparency.  BGP
   Extended Communities are used to carry the needed information to
   enable the receiving side to reconstruct a database just as in the
   OSPFv2 case.

   All OSPFv3 routes added to the VRF routing table on a PE router are
   examined to create a corresponding VPN-IPv6 route in BGP.  Each of
   the OSPFv3 routes MUST have the corresponding BGP Extended
   Communities Attributes that contain and preserve the OSPFv3
   information of the original OSPFv3 route.  The BGP Extended
   Communities attributes defined in [RFC4577] are reused for
   convenience.

   OSPF Domain Identifier Extended Communities Attribute

   Each OSPFv3 Instance within a VRF MUST have a Domain ID.  The Domain
   ID is configured per OSPFv3 Instance.  The OSPFv3 Domain ID is a
   6-byte number, and its default value is 0.  This attribute has a
   2-byte type field, encoded with a value of 0x0005, 0x0105, or 0x0205.

        0                   1                   2                   3
        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |          Type Value           |    Domain Identifier          |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |                     Domain Identifier Cont.                   |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

         The OSPF Domain Identifier Extended Communities Attribute

      OSPFv3 Domain IDs field : 6 bytes

      Each OSPFv3 Instance within a VRF MUST have a Domain ID and its
      default value (if none is configured) is 0.  The Domain ID is
      configured per OSPFv3 Instance.

   OSPF Router ID Extended Communities Attribute

   The OSPFv3 Router ID is a 32-bit number as in OSPFv2.  This attribute
   has a 2-byte type field, encoded with a value of 0x0107.






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        0                   1                   2                   3
        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |          Type Value           |          Router ID            |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |       Router ID Cont.         |          UNUSED               |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

             The OSPF Router ID Extended Communities Attribute

      OSPFv3 Router ID field : 4 bytes

      The OSPFv3 Router ID is a 32-bit number as in OSPFv2.  Setting
      this field is OPTIONAL, and its default value is 0.

   OSPF Route Type Extended Communities Attribute

   The OSPF Route Type Extended Communities Attribute MUST be present.
   It contains a 2-byte type field, encoded with a value of 0x0306.  The
   remaining 6 bytes are divided into 3 fields, an Area Number, a Route
   Type, and an Options field.

        0                   1                   2                   3
        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |          Type Value           |         Area Number           |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |      Area Number Cont.        |  Route Type   |    Options    |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

            The OSPF Route Type Extended Communities Attribute

      Area Number : 4 bytes

      The area number indicates the 32-bit Area ID to which the route
      belongs.

      Route Types : 1 byte













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      To accommodate OSPFv3 LSA types (as registered by [RFC5340]), the
      Route Type field is encoded as follows:

       Route Type  Route Type      LSA Type   Description
         Code
       -----------------------------------------------------------
         3      Inter-area-prefix  0x2003   Inter-Area-Prefix-LSA
         5      External           0x4005   AS-External-LSA
         7      NSSA               0x2007   NSSA-LSA
         1 or 2 Intra-area-prefix  0x2009   Intra-Area-Prefix-LSA

                          Route Type Field Encoding

      Options : 1 byte

      The Options field indicates the options that are associated with
      the OSPFv3 route.

                         8   7   6   5   4   3   2   1
                       +---+---+---+---+---+---+---+---+
                       |   |   |   |   |   |   |   | E |
                       +---+---+---+---+---+---+---+---+

                        The OSPFv3 Route Options Field

      The least significant bit (i.e., bit E) in this field designates
      the external metric-type.  If the bit is clear, the route carries
      a Type-1 external metric; if the bit is set, the route carries a
      Type-2 external metric.

4.5.  Loop Prevention Techniques

   In some topologies, it is possible for routing loops to occur due to
   the nature and manner of route reachability propagation.  One such
   example is the case of a dual-homed CE router connected to two PEs;
   those PE routers would receive reachability information both through
   their CE and their peer PE.  As there is transparent transport of
   OSPFv3 routes over the VPN backbone, it is not possible for the PE
   routers to determine whether they are within a loop.

   The loop scenarios in OSPFv3 topologies are identical to those in the
   OSPFv2 topologies described in Sections 4.2.5.1 and 4.2.5.2 of
   [RFC4577].  Of the two loop prevention mechanisms described in the
   aforementioned sections, only the DN-bit option will be supported in
   the OSPFv3 implementation.






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4.5.1.  OSPFv3 Down Bit

   [RFC4576] describes the usage of the DN-bit for OSPFv2 and is
   applicable for OSPFv3 for Inter-area-prefix LSAs, NSSA LSAs, and
   External LSAs.  Similarly, the DN-bit MUST be set in Inter-area-
   prefix LSAs, NSSA LSAs, and AS-External LSAs, when these are
   originated from a PE to a CE, to prevent those prefixes from being
   re-advertised into BGP.  As in [RFC4577], any LSA with the DN-bit set
   must not be used for route calculations on PE routers.

   The DN-bit MUST be clear in all other LSA types.  The OSPFv3 DN-bit
   format is described in Appendix A.4.1.1 of [RFC5340].

4.5.2.  Other Possible Loops

   The mechanism described in Section 4.5.1 of this document is
   sufficient to prevent looping if the DN-bit information attached to a
   prefix is preserved in the OSPF domain.  As described in Section
   4.2.5.3 of [RFC4577], caution must be exercised if mutual
   redistribution that is performed on a PE causes loss of loop
   prevention information.

5.  OSPFv3 Sham Links

   This section modifies the specification of OSPFv2 sham links (defined
   in Section 4.2.7 of [RFC4577]) to support OSPFv3.  Support for OSPFv3
   sham links is an OPTIONAL feature of this specification.

   A sham link enables a VPN backbone to act as an intra-area link.  It
   is needed when two sites are connected by an intra-area "backdoor"
   link and the inter-area VPN backbone route would be less preferable
   due to OSPF route preference rules.  The figure below shows the
   instantiation of a sham link between two VPN sites.

                             (VPN backbone)
        (site-1)      <-------- sham link -------->      (site-2)
         CE1 -------- PE1 -------- P ---------- PE2 -------- CE2
          |                                                   |
          |___________________________________________________|
               <------------ backdoor link -------------->
                        (OSPF intra-area link)

                                 Sham Link

   Much of the operation of sham links remains semantically identical to
   what was previously specified.  There are, however, several
   differences that need to be defined to ensure the proper operation of
   OSPFv3 sham links.



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   One of the primary differences between sham links for OSPFv3 and sham
   links as specified in [RFC4577] is for configurations where multiple
   OSPFv3 instances populate a VRF.  It may be desirable to provide
   separate intra-area links between these instances over the same sham
   link.  To achieve this, multiple OSPFv3 instances may be established
   across the PE-PE sham link to provide intra-area connectivity between
   PE-CE OSPFv3 instances.

   Note that even though multiple OSPFv3 instances may be associated
   with a VRF, a sham link is still thought of as a relation between two
   VRFs.

   Another modification to OSPFv2 sham links is that OSPFv3 sham links
   are now identified by 128-bit endpoint addresses.  Since sham link
   endpoint addresses are now 128 bits, they can no longer default to
   the RouterID, which is a 32-bit number.  Sham link endpoint addresses
   MUST be configured.

   Sham link endpoint addresses MUST be distributed by BGP as routeable
   VPN IPv6 addresses, each with an IPv6 address prefix that is 128 bits
   long.  As specified in Section 4.2.7.1 of [RFC4577], these endpoint
   addresses MUST NOT be advertised by OSPFv3; if there is no BGP route
   to the sham link endpoint address, that address is to appear
   unreachable, so that the sham link appears to be down.

   If there is a BGP route to the remote sham link endpoint address, the
   sham link appears to be up.  Conversely, if there is no BGP route to
   the sham link endpoint address, the sham link appears to be down.

5.1.  Creating a Sham Link

   The procedures for creating an OSPFv3 sham link are identical to
   those specified in Section 4.2.7.2 of [RFC4577].  Note that the
   creation of OSPFv3 sham links requires the configuration of both
   local and remote 128-bit sham link endpoint addresses.  The local
   sham link endpoint address associated with a VRF MAY be used by all
   OSPFv3 instances that are attached to that VRF.  The OSPFv3 PE-PE
   "link" Instance ID in the protocol packet header is used to
   demultiplex multiple OSPFv3 instance protocol packets exchanged over
   the sham link.

5.2.  OSPF Protocol on Sham Link

   Much of the operation of OSPFv3 over a sham link is semantically the
   same as the operation of OSPFv2 over a sham link, as described in
   Section 4.2.7.3 of [RFC4577].  This includes the methodology for
   sending and receiving OSPFv3 packets over sham links, as well as




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   Hello/Router Dead Intervals.  Furthermore, the procedures associated
   with the assignment of sham link metrics adhere to those set forth
   for OSPFv2.  OSPFv3 sham links are treated as on-demand circuits.

   Although the operation of the OSPFv3 protocol over the sham link is
   the same as OSPFv2, multiple OSPFv3 instances may be instantiated
   across this link.  By instantiating multiple instances across the
   sham link, distinct intra-area connections can be established between
   PE-PE OSPFv3 instances associated with the endpoint addresses.

   For example, if two OSPFv3 instances (O1, O2) attach to a VRF V1, and
   on a remote PE, two other OSPFv3 instances (O3, O4) attach to a VRF
   V2, it may be desirable to connect O1 and O3 with an intra-area link,
   and O2 and O4 with an intra-area link.  This can be accomplished by
   instantiating two OSPFv3 instances across the sham link, which
   connects V1 and V2.  O1 and O3 can be mapped to one of the sham link
   OSPFv3 instances; O2 and O4 can be mapped to the other sham link
   OSPFv3 instance.

5.3.  OSPF Packet Forwarding on Sham Link

   The rules associated with route redistribution, stated in Section
   4.2.7.4 of [RFC4577], remain unchanged in this specification.
   Specifically:

      If the next-hop interface for a particular route is a sham link,
      then the PE SHOULD NOT redistribute that route into BGP as a VPN-
      IPv6 route.

      Any other route advertised in an LSA that is transmitted over a
      sham link MUST also be redistributed (by the PE flooding the LSA
      over the sham link) into BGP.

   When redistributing these LSAs into BGP, they are encoded with the
   BGP Extended Communities Attributes, as defined in Section 4.4 of
   this document.

   When forwarding a packet, if the preferred route for that packet has
   the sham link as its next-hop interface, then the packet MUST be
   forwarded according to the corresponding BGP route (as defined in
   [RFC4364] and [RFC4659]).

6.  Multiple Address Family Support

   The support of multiple address families (AFs) in OSPFv3 is described
   in [RFC5838]. [RFC5838] differentiates between AFs by using reserved
   ranges of Instance IDs for each AF.




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   The architecture described in this document is fully compatible with
   [RFC5838].  The OSPFv3 PE-CE protocol can support multiple address
   families across a VPN backbone.  All AFs redistributed from OSPFv3
   into BGP on a PE MUST contain the BGP Extended Communities Attributes
   as described in Section 4.4.

7.  Security Considerations

   The extensions described in this document are specific to the use of
   OSPFv3 as the PE-CE protocol and do not introduce any new security
   concerns other than those already defined in Section 6 of [RFC4577].

8.  IANA Considerations

   An early version of this document resulted in the allocation of
   OSPFv3 Route Attributes (0x0004) entry in the BGP IPv6 Address
   Specific Extended Community.  This allocation is no longer required.
   IANA has marked the OSPFv3 Route Attributes (0x0004) entry in the BGP
   IPv6 Address Specific Extended Community registry as deprecated.  The
   BGP Extended Communities Attributes in this document have already
   been registered by IANA.

9.  Acknowledgments

   The authors would like to thank Kelvin Upson, Seiko Okano, Matthew
   Everett, Dr. Vineet Mehta, Paul Wells, and Marek Karasek for their
   support of this work.  Thanks to Peter Psenak, Abhay Roy, Acee
   Lindem, Nick Weeds, Robert Hanzl, and Daniel Cohn for their Last Call
   comments.  Special thanks to Stewart Bryant, Stephen Farrel, and Fred
   Baker for their thorough review.

10.  References

10.1.  Normative References

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC2328]  Moy, J., "OSPF Version 2", STD 54, RFC 2328, April 1998.

   [RFC4360]  Sangli, S., Tappan, D., and Y. Rekhter, "BGP Extended
              Communities Attribute", RFC 4360, February 2006.

   [RFC4364]  Rosen, E. and Y. Rekhter, "BGP/MPLS IP Virtual Private
              Networks (VPNs)", RFC 4364, February 2006.






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   [RFC4576]  Rosen, E., Psenak, P., and P. Pillay-Esnault, "Using a
              Link State Advertisement (LSA) Options Bit to Prevent
              Looping in BGP/MPLS IP Virtual Private Networks (VPNs)",
              RFC 4576, June 2006.

   [RFC4577]  Rosen, E., Psenak, P., and P. Pillay-Esnault, "OSPF as the
              Provider/Customer Edge Protocol for BGP/MPLS IP Virtual
              Private Networks (VPNs)", RFC 4577, June 2006.

   [RFC4659]  De Clercq, J., Ooms, D., Carugi, M., and F. Le Faucheur,
              "BGP-MPLS IP Virtual Private Network (VPN) Extension for
              IPv6 VPN", RFC 4659, September 2006.

   [RFC4760]  Bates, T., Chandra, R., Katz, D., and Y. Rekhter,
              "Multiprotocol Extensions for BGP-4", RFC 4760, January
              2007.

   [RFC5340]  Coltun, R., Ferguson, D., Moy, J., and A. Lindem, "OSPF
              for IPv6", RFC 5340, July 2008.

   [RFC5838]  Lindem, A., Ed., Mirtorabi, S., Roy, A., Barnes, M., and
              R. Aggarwal, "Support of Address Families in OSPFv3", RFC
              5838, April 2010.

10.2.  Informative References

   [RFC2547]  Rosen, E. and Y. Rekhter, "BGP/MPLS VPNs", RFC 2547, March
              1999.























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Authors' Addresses

   Padma Pillay-Esnault
   Cisco Systems
   510 McCarty Blvd.
   Milpitas, CA 95035
   USA

   EMail: ppe@cisco.com


   Peter Moyer
   Pollere, Inc.
   325M Sharon Park Drive #214
   Menlo Park, CA 94025
   USA

   EMail: pete@pollere.net


   Jeff Doyle
   Jeff Doyle and Associates
   9878 Teller Ct.
   Westminster, CO 80021
   USA

   EMail: jdoyle@doyleassociates.net


   Emre Ertekin
   Booz Allen Hamilton
   5220 Pacific Concourse Drive
   Los Angeles, CA 90045
   USA

   EMail: ertekin_emre@bah.com


   Michael Lundberg
   Booz Allen Hamilton
   8283 Greensboro Drive
   McLean, VA 22102
   USA

   EMail: lundberg_michael@bah.com






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