[Docs] [txt|pdf] [draft-ietf-mpls-l...] [Diff1] [Diff2]

Updated by: 6138 INFORMATIONAL

Network Working Group                                            M. Jork
Request for Comments: 5443                                       GENBAND
Category: Informational                                         A. Atlas
                                                         British Telecom
                                                                 L. Fang
                                                     Cisco Systems, Inc.
                                                              March 2009


                       LDP IGP Synchronization

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   This memo provides information for the Internet community.  It does
   not specify an Internet standard of any kind.  Distribution of this
   memo is unlimited.

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RFC 5443                LDP IGP Synchronization               March 2009


Abstract

   In certain networks, there is dependency on the edge-to-edge Label
   Switched Paths (LSPs) setup by the Label Distribution Protocol (LDP),
   e.g., networks that are used for Multiprotocol Label Switching (MPLS)
   Virtual Private Network (VPN) applications.  For such applications,
   it is not possible to rely on Internet Protocol (IP) forwarding if
   the MPLS LSP is not operating appropriately.  Blackholing of labeled
   traffic can occur in situations where the Interior Gateway Protocol
   (IGP) is operational on a link on which LDP is not.  While the link
   could still be used for IP forwarding, it is not useful for MPLS
   forwarding, for example, MPLS VPN applications or Border Gateway
   Protocol (BGP) route-free cores.  This document describes a mechanism
   to avoid traffic loss due to this condition without introducing any
   protocol changes.

Table of Contents

   1. Introduction ....................................................2
      1.1. Conventions Used in This Document ..........................3
   2. Proposed Solution ...............................................3
   3. Applicability ...................................................4
   4. Interaction with TE Tunnels .....................................5
   5. Security Considerations .........................................5
   6. References ......................................................6
      6.1. Normative References .......................................6
      6.2. Informative References .....................................6
   7. Acknowledgments .................................................6

1.  Introduction

   LDP [RFC5036] establishes MPLS LSPs along the shortest path to a
   destination as determined by IP forwarding.  In a common network
   design, LDP is used to provide Label Switched Paths throughout the
   complete network domain covered by an IGP such as Open Shortest Path
   First (OSPF) [RFC2328] or Intermediate System to Intermediate System
   (IS-IS) [ISO.10589.1992]; i.e., all links in the domain have IGP as
   well as LDP adjacencies.

   A variety of services a network provider may want to deploy over an
   LDP-enabled network depend on the availability of edge-to-edge label
   switched paths.  In a layer 2 (L2) or layer 3 (L3) VPN scenario, for
   example, a given Provider-Edge (PE) router relies on the availability
   of a complete MPLS forwarding path to the other PE routers for the
   VPNs it serves.  This means that all the links along the IP shortest
   path from one PE router to the other need to have operational LDP
   sessions, and the necessary label binding must have been exchanged
   over those sessions.  If only one link along the IP shortest path is



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   not covered by an LDP session, a blackhole exists and services
   depending on MPLS forwarding will fail.  This might be a transient or
   a persistent error condition.  Some of the reasons for this could be:

   - A configuration error.

   - An implementation bug.

   - The link has just come up and has an IGP adjacency but LDP has
     either not yet established an adjacency or session, or has not yet
     distributed all the label bindings.

   The LDP protocol has currently no way to correct the issue.  LDP is
   not a routing protocol; it cannot re-direct traffic to an alternate
   IGP path.

1.1.  Conventions Used in This Document

   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].

2.  Proposed Solution

   The problem described above exists because LDP is tied to
   IP-forwarding decisions but no coupling between the IGP and LDP
   operational state on a given link exists.  If IGP is operational on a
   link but LDP is not, a potential network problem exists.  So the
   solution described by this document is to discourage a link from
   being used for IP forwarding as long as LDP is not fully operational.

   This has some similarity to the mechanism specified in [RFC3137],
   which allows an OSPF router to advertise that it should not be used
   as a transit router.  One difference is that [RFC3137] raises the
   link costs on all (stub) router links, while the mechanism described
   here applies on a per-link basis.

   In detail: when LDP is not "fully operational" (see below) on a given
   link, the IGP will advertise the link with maximum cost to avoid any
   transit traffic over it.  In the case of OSPF, this cost is
   LSInfinity (16-bit value 0xFFFF), as proposed in [RFC3137].  In the
   case of ISIS, the maximum metric value is 2^24-2 (0xFFFFFE).  Indeed,
   if a link is configured with 2^24-1 (the maximum link metric per
   [RFC5305]), then this link is not advertised in the topology.  It is
   important to keep the link in the topology to allow IP traffic to use
   the link as a last resort in case of massive failure.





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   LDP is considered fully operational on a link when an LDP hello
   adjacency exists on it, a suitable associated LDP session (matching
   the LDP Identifier of the hello adjacency) is established to the peer
   at the other end of the link, and all label bindings have been
   exchanged over the session.  At the present time, the latter
   condition cannot generally be verified by a router and some
   estimation may have to be used.  A simple implementation strategy is
   to use a configurable hold-down timer to allow LDP session
   establishment before declaring LDP fully operational.  The default
   timer is not defined in this document due to concerns of the large
   variations of the Label Information Base (LIB) table size and
   equipment capabilities.  In addition, there is a current work in
   progress on LDP End-of-LIB as specified in [End-of-LIB], which
   enables the LDP speaker to signal the completion of its initial
   advertisement following session establishment.  When LDP End-of-LIB
   is implemented, the configurable hold-down timer is no longer needed.
   The neighbor LDP session is considered fully operational when the
   End-of-LIB notification message is received.

   This is typically sufficient to deal with the link when it is being
   brought up.  LDP protocol extensions to indicate the complete
   transmission of all currently available label bindings after a
   session has come up are conceivable, but not addressed in this
   document.

   The mechanism described in this document does not entail any protocol
   changes and is a local implementation issue.

   The problem space and solution specified in this document have also
   been discussed in an IEEE Communications Magazine paper
   [LDP-Fail-Rec].

3.  Applicability

   In general, the proposed procedure is applicable in networks where
   the availability of LDP-signaled MPLS LSPs and avoidance of
   blackholes for MPLS traffic are more important than always choosing
   an optimal path for IP-forwarded traffic.  Note however that non-
   optimal IP forwarding only occurs for a short time after a link comes
   up or when there is a genuine problem on a link.  In the latter case,
   an implementation should issue network management alerts to report
   the error condition and enable the operator to address it.

   Example network scenarios that benefit from the mechanism described
   here are MPLS VPNs and BGP-free core network designs where traffic
   can only be forwarded through the core when LDP forwarding state is
   available throughout.




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RFC 5443                LDP IGP Synchronization               March 2009


   The usefulness of this mechanism also depends on the availability of
   alternate paths with sufficient bandwidth in the network should one
   link be assigned to the maximum cost due to the unavailability of LDP
   service over it.

   On broadcast links with more than one IGP/LDP peer, the cost-out
   procedure can only be applied to the link as a whole and not to an
   individual peer.  So a policy decision has to be made whether the
   unavailability of LDP service to one peer should result in the
   traffic being diverted away from all the peers on the link.

4.  Interaction with TE Tunnels

   In some networks, LDP is used in conjunction with RSVP-TE, which sets
   up traffic-engineered tunnels.  The path computation for the TE
   tunnels is based on the TE link cost that is flooded by the IGP in
   addition to the regular IP link cost.  The mechanism described in
   this document should only be applied to the IP link cost to prevent
   unnecessary TE tunnel reroutes.

   In order to establish LDP LSPs across a TE tunnel, a targeted LDP
   session between the tunnel endpoints needs to exist.  This presents a
   problem very similar to the case of a regular LDP session over a link
   (the case discussed so far): when the TE tunnel is used for IP
   forwarding, the targeted LDP session needs to be operational to avoid
   LDP connectivity problems.  Again, raising the IP cost of the tunnel
   while there is no operational LDP session will solve the problem.
   When there is no IGP adjacency over the tunnel and the tunnel is not
   advertised as a link into the IGP, this becomes a local issue of the
   tunnel headend router.

5.  Security Considerations

   A Denial-of-Service (DoS) attack that brings down LDP service on a
   link or prevents it from becoming operational on a link could be one
   possible cause of LDP-related traffic blackholing.  This document
   does not address how to prevent LDP session failure.  The mechanism
   described here prevents the use of the link where LDP is not
   operational while IGP is.  Assigning the IGP cost to maximum on such
   a link should not introduce new security threats.  The operation is
   internal to the router to allow LDP and IGP to communicate and react.
   Making many LDP links unavailable, however, is a security threat that
   can cause dropped traffic due to limited available network capacity.
   This may be triggered by operational error or implementation error.
   These errors are considered general security issues and implementors
   should follow the current best security practice [MPLS-GMPLS-Sec].





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6.  References

6.1.  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.

   [RFC5036]        Andersson, L., Ed., Minei, I., Ed., and B. Thomas,
                    Ed., "LDP Specification", RFC 5036, October 2007.

6.2.  Informative References

   [End-of-LIB]     Asati, R., LDP End-of-LIB, Work in Progress, January
                    2009.

   [ISO.10589.1992] International Organization for Standardization,
                    "Intermediate system to intermediate system intra-
                    domain-routing routine information exchange protocol
                    for use in conjunction with the protocol for
                    providing the connectionless-mode Network Service
                    (ISO 8473)", ISO Standard 10589, 1992.

   [LDP-Fail-Rec]   Fang, L., Atlas, A., Chiussi, F., Kompella, K., and
                    G. Swallow, "LDP Failure Detection and Recovery",
                    IEEE Communications Magazine, Vol.42, No.10, October
                    2004.

   [MPLS-GMPLS-Sec] Fang. L., Ed., "Security Framework for MPLS and
                    GMPLS Networks", Work in Progress, November 2008.

   [RFC3137]        Retana, A., Nguyen, L., White, R., Zinin, A., and D.
                    McPherson, "OSPF Stub Router Advertisement", RFC
                    3137, June 2001.

   [RFC5305]        Li, T. and H. Smit, "IS-IS Extensions for Traffic
                    Engineering", RFC 5305, October 2008.

7.  Acknowledgments

   The authors would like to thank Bruno Decraene for his in-depth
   discussion and comments, Dave Ward for his helpful review and input,
   and Loa Andersson, Ross Callon, Amanda Baber, Francis Dupont, Donald
   Eastlake, Russ Housley, Pasi Eronen, Dan Romascanu, Bin Mo, Lan
   Zheng, Bob Thomas, and Dave Ojemann for their reviews and comments.




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Authors' Addresses

   Markus Jork
   GENBAND
   3 Federal St.
   Billerica, MA 01821
   USA

   EMail: Markus.Jork@genband.com


   Alia Atlas
   British Telecom

   EMail: alia.atlas@bt.com


   Luyuan Fang
   Cisco Systems, Inc.
   300 Beaver Brook Road
   Boxborough, MA 01719
   USA

   EMail: lufang@cisco.com
   Phone: 1 (978) 936-1633


























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