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Versions: (draft-ashw-mpls-te-feed) 00 01 02 03 04 05 06

   MPLS Working Group                                 Peter Ashwood-Smith
   Internet Draft                                     Bilel Jamoussi
   Expiration Date: November 2003                     Don Fedyk
   Standards Track                                    Darek Skalecki
                                                      Nortel Networks

                                                      June 2003

      Improving Topology Data Base Accuracy with Label Switched Path
        Feedback in Constraint Based Label Distribution Protocol

                     draft-ietf-mpls-te-feed-06.txt



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

   One key component of traffic engineering is a concept known as
   constraint based routing. In constraint based routing a topology
   database is maintained on all participating nodes. This database
   contains a complete list of all the links in the network that
   participate in traffic engineering and for each of these links a set
   of constraints, which those links can meet. Bandwidth, for example,
   is one essential constraint. Since the bandwidth available changes
   as new LSPs are established and terminated the topology database
   will develop inconsistencies with respect to the real network. It is
   not possible to increase the flooding rates arbitrarily to keep the
   database discrepancies from growing. A new mechanism is proposed
   whereby a source node can learn about the successes or failures of
   its path selections by receiving feedback from the paths it is

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   attempting. This information is most valuable in failure scenarios
   but is beneficial during other path setup functions as well. This
   fed back information can be incorporated into subsequent route
   computations, which greatly improves the accuracy of the overall
   routing solution by significantly reducing the database
   discrepancies.


Table of Contents

   1.0 Introduction and Description . . . . . . . . . . . . . . . 2
   2.0 Adding feedback TLVs to CR-LDP . . . . . . . . . . . . . . 6
      2.1 Bandwidth directionality considerations.  . . . . . . . 6
   3.0 Link Feedback TLV. . . . . . . . . . . . . . . . . . . . . 7
      3.1 Link feedback TLV Description . . . . . . . . . . . . . 7
      3.2 Local Interface IP Address Subtypes . . . . . . . . . . 8
      3.3 Remote Interface IP Address Subtypes . . . . . . . . .. 8
      3.4 Unreserved Bandwidth Sub Type. . . . . . . . . . .  . . 8
   4.0 Detailed Procedures. . . . . . . . . . . . . . . . . . . . 9
   5.0 IGP Considerations . . . . . . . . . . . . . . . . . . . .10
   6.0 Future Considerations  . . . . . . . . . . . . . . . . . .11
   7.0 RSVP-TE Considerations . . . . . . . . . . . . . . . . . .11
   8.0 Intellectual Property Considerations . . . . . . . . . . .11
   9.0 Security Considerations. . . . . . . . . . . . . . . . . .11
   10.0 IANA Considerations . . . . . . . . . . . . . . . . . . .11
   11.0 Acknowledgements . . . . . . . . . . .. . . . . . . . . .11
   12.0 Normative References. . . . . . . . . . . . . . . . . . .12
   13.0 Informative References. . . . . . . . . . . . . . . . . .12
   14.0 Authors Addresses . . . . . . . . . . . . . . . . . . . .12



1.0 Introduction and Description

   Because the network is a distributed system, it is necessary to have
   a mechanism to advertise information about links to all nodes in the
   network [IS-IS], [OSPF].  A node can then build a topology map of
   the network.  This information is required to be as up-to-date as
   possible for accurate traffic engineered paths.  Information about
   link or node failures must be rapidly propagated through the network
   so that recovery can be initiated. Other information about links
   that may be useful for reasons of quality of service includes
   parameters such as available bandwidth, and delay. The information
   in this topology database is often out of date with respect to the
   real network. Available bandwidth is the most critical of these
   attributes and it can drift substantially with respect to reality
   due to the low frequency of link state updates that can be sustained
   in a very large topology. The deviation in the topology database
   available bandwidth is referred to as being optimistic if the
   database shows more available bandwidth than there really is, or

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   pessimistic if the topology database shows less bandwidth than there
   really is. This distinction is important to enable an efficient
   algorithm to deal with optimistic databases without resorting to
   shorter flooding intervals.

   One of the major problems for a constraint based routing system is
   dealing with changing constraints. Obviously, since bandwidth is one
   of the essential constraints, dealing with the rapid changes in
   reserved bandwidth poses some interesting challenges. In smaller
   networks, one can resort to higher frequency flooding but this
   obviously does not scale. The feedback mechanism is particularly
   useful in the case of link or node failures where the rapid change
   and notification of resource change is crucial to the restoration
   time. Feedback is work conserving in this case since the
   availability of feedback information minimizes the extra burden of
   dealing with out of date topology and resource information.

   The basic approach is to add to the signaling protocol the ability
   to piggyback actual link bandwidth availability information at every
   link that the signaling traverses. This is done as part of the
   reverse messaging on success or failure (mapping, release, withdraw
   or notification). What this means is that every time signaling
   messages flow backwards toward a source to tell it of the success,
   failure or termination of a request, that message contains a
   detailed slice of bandwidth availability information for the exact
   path that the message has followed. This slice of reservation
   information, which is very up to date, is received by the source
   node and attached to the source node's topology database prior to
   making any further source route computations. The result is that the
   source node's topology database will tend to stay synchronized with
   the slices of the network through which it is establishing paths.
   This is nothing more than learning from successes and failures and
   represents an intelligent alternative to either waiting for floods
   or introducing non-determinism (guessing) into the source
   algorithms. It is important to note that the fed-back data is never
   re-flooded. It simply overrides flooded information for the purpose
   of route computation until a superceding flood or fed-back value
   arrives. As such, it is not actually inserted into a topology
   database, most likely it simply is linked to that database as an
   override used only by source route computations. Also the inclusion
   of feedback information is optional. At a minimum the blocked or
   failed link is required but if processing resources are scarce the
   additional feedback at other hops is optional.

   Operating a constraint based routing system without such feedback is
   inefficient at best since a source node will continue to give out
   incorrect route over and over again until it gets an IGP update.
   This could be minutes away and as a result the worst case blocking
   time for a new route is the minimum repeatable flooding interval
   (often several minutes in big networks). Alternatives to feedback
   mechanisms involve adding some non-determinism (randomness) to the

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   routing algorithm in the hopes that it will stumble onto a path that
   works. These sorts of approaches are seen in ATM dynamic routing
   systems, which do not have these forms of feedback.

   In order to get a good understanding of how the feedback works,
   imagine a network with precisely one path (with sufficient
   unreserved bandwidth) available from the source to the destination.
   Further, imagine that the topology database at the source is
   significantly out of date with respect to the real network in that
   the source topology database sees sufficient bandwidth available on
   many different routes to the destination. This is termed being
   optimistic with respect to the network since the source thinks that
   more bandwidth is available than there really is.

   When such an optimistic source selects its first path it will likely
   contain links that do not in reality have sufficient unreserved
   bandwidth. Therefore, the path is only established up to the link
   that does not have sufficient bandwidth. A notification message is
   formatted that contains the actual unreserved bandwidth for this
   blocking link which flows back toward the source, collapsing the
   partially created path as it goes. In addition, at every link that
   this notification traverses, the current unreserved bandwidth
   information for each corresponding link is appended to the vector of
   unreserved bandwidth along the path. In this manner, an accurate
   view of the slice through the network traversed is constructed.
   Eventually this message arrives back at the source node, where the
   vector is taken and used to temporarily override the topology
   database for route computations. This node has just learned from its
   mistake and is now slightly less optimistic with respect to the real
   network conditions.

   Path selection can be attempted again but this time the node will
   not make the same mistake it made the previous time. The link in
   question, at which rejection occurred the first time, will not even
   be eligible this time around, so a source route computation is
   guaranteed to produce a different path (or none). The same procedure
   may be repeated as many times as is necessary, each time learning
   from its mistakes, until eventually no paths remain in the source
   topology to the destination, or a path is found that works. This
   tendency to converge either to a solution or determine that there is
   no solution is an important property of a routing system (it
   actually behaves a lot like a depth first search). This property is
   not present with flooding mechanisms alone since the source node
   must randomly hunt, or continually make the same mistakes, or abort
   until the next flood arrives.

   In addition to feeding back bandwidth on failure, feedback on
   success is recommended. This has important consequences on our
   ability to spread load or to spill over to new links as existing
   links fill. It is true that spilling over to new links does not
   require feedback on success since a node could simply wait for a

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   feedback on failure, but better load spreading can be achieved
   earlier.

   Finally, when a path is torn down the release/withdraw messages also
   contain bandwidth information that can be fed back to override the
   source topology database. This is very important during failure
   scenarios where the links required for rerouting the path share
   common sub-segments with the failed path. Without the feedback, the
   common sub-segments may not indicate sufficient available bandwidth
   until an LSA flood is received which may mean many seconds without a
   connection. With feedback at least the database is up to date with
   respect to available bandwidth up to the point of failure in the
   path. Also since failure involves many paths tearing down and re-
   establishing this is the time that it is most critical to have an
   accurate view.

   When preemption is being employed it is also extremely important
   that the topology database inconsistencies be small. If not, high
   setup priority LSPs may unnecessarily preempt lower holding priority
   LSPs to obtain bandwidth that, had they had a more up to date view
   of unreserved bandwidth, they would have been able to find
   elsewhere. Since preempted LSPs may in turn preempt other LSPs in a
   domino like effect, the results of such database inconsistencies can
   have wide reaching ripple like impacts. These feedback mechanisms
   help reduce these occurrences significantly.

   There are a number of network conditions where feedback shows its
   value. One can think of a constraint-based network as being in one
   of three conditions. The first is called ramp-up, this is when the
   rate of arriving reservations exceeds the rate of departing
   reservations. The second is called steady state, this is when the
   rate of arriving reservations is about the same as the rate of
   departing reservations. Finally, the ramp-down condition is that
   which has a greater rate of departing reservations than arriving
   reservations.

   These three network conditions show distinctly different types of
   error in the topology databases. In particular an optimistic view of
   available bandwidth by a source node is characteristic of the ramp-
   up condition of a network. A pessimistic view of available bandwidth
   by a source node is characteristic of the ramp-down condition of a
   network. If one plots the average error in the topology databases
   with respect to the real network for the three different network
   conditions, one will see the error slowly go positive during ramp
   up, slowly go negative during ramp down, and drift slowly around 0
   for the steady condition. The effect of flooding on this plot is to
   periodically snap the error back to 0 at flooding intervals. The
   effect of the feedback algorithm is to bring an optimistic error
   back to zero without having to wait for the flood interval. On
   average then, the feedback algorithm tends to halve the absolute
   error, keeping it mostly negative or pessimistic. This makes sense

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   since a routing system will never give paths to links that it thinks
   do not have resources and as a result its pessimistic view of the
   world stays that way until it gets a flood.  This relieves the IGP
   updates of the most urgent requirement of flooding when bandwidth is
   consumed. Availability of new bandwidth occurs when paths are
   released or new links become available.  Floods already accompany
   new links. Significant releases of bandwidth can be broadcast at
   relatively low frequencies in the order of several minutes with
   little operational impact.


2.0 Adding feedback TLVs to CR-LDP

   Two new TLVs are optionally added to the CR-LDP mapping,
   notification, and withdraw messages. There may be an arbitrary
   number of these TLV in any order or position in the message. It is
   recommended that they be placed such that they can be read and
   applied to override the topology database by scanning the message
   forwards and walking the topology database from the point where the
   last link feedback TLV left off.

   Each TLV consists of the eight unreserved bandwidth values for each
   holding priority 0 through 7 as IEEE floating-point numbers (the
   units are unidirectional bytes per second). Following this are the
   IP addresses of the two ends of the interface. Two TLVs are
   possible, one for IPV4 and one for IPV6 addressing of the link.

   Note: the feedback TLVs may also optionally be included in query or
   query-reply messages in response to bandwidth update queries from an
   LER. Details of this mechanism are provided in [QUERY].

2.1 Bandwidth directionality considerations

   The order of the two addresses in the feedback TLV implies the
   direction in which the bandwidth is available. For example if the
   local address is A and the remote address is B the bandwidth is
   unreserved in the A to B direction.

   It is possible for an implementation to provide both the A to B
   direction and the B to A direction as part of the same feedback
   message. This is done by simply including a TLV with A, B as the
   addresses of the link and a different TLV with B, A as the addresses
   of the link. Should CR-LDP evolve to be able to support bi-
   directional traffic flow and reservations, it is expected that bi-
   directional feedback would also be implemented via this mechanism.







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3.0 Link Feedback TLV


   The Feedback payload consists of one or more nested
   Type/Length/Value (TLV) triplets for extensibility.  The format of
   each TLV is:

   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             |             Length            |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   |                            Value...                           |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

   The Length field defines the length of the value portion in octets
   (thus a TLV with no value portion would have a length of zero).  The
   TLV is padded to four-octet alignment;  padding is not included in
   the length field (so a three octet value would have a length of
   three, but the total size of the TLV would be eight octets).  Nested
   TLVs are also 32-bit aligned.  Unrecognized types are ignored.

3.1 Link feedback TLV Description

   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
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   |U|F|          TBD IANA         |      Length                   |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   |                            Sub TLVs                           |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

   This document introduces essentially one Feedback TLV. There may be
   multiple instances of the Feedback TLV in a CR-LDP message, one for
   each different links along the path. Due to the current format that
   TE extension documents organize TE information the feedback TLV has
   sub TLVs. This allows the information to conform to the current TE
   conventions and allows options for additional future feedback
   elements. The formats are derived from the TE extensions TLVs for
   IS-IS [IS-IS] and OSPF [OSPF].

   U bit
   Unknown TLV bit must be set to 1.  As with all CR-LDP messages, upon
   receipt of an unknown TLV, if U is if U is set (=1), the unknown TLV

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   is silently ignored and the rest of the message is processed as if
   the unknown TLV did not exist.

   F bit
   Forward unknown TLV bit must be set to 1.  This bit applies only
   when the U bit is set and the CR-LDP message containing the unknown
   TLV is to be forwarded.  If F is set (=1), the unknown TLV is
   forwarded with the containing message.

   The following sub TLVs for the Feedback TLV are defined:

   1 - Local interface IP address (IPv4)
   2 - Remote interface IP address (IPv4)
   3 - Local interface IP address (IPv6)
   4 - Remote interface IP address (IPv6)
   5 - Unreserved bandwidth

   This document defines the sub types. The code points are to be
   assigned by IANA.

3.2 Local Interface IP Address Sub Types

   The Local Interface IP Address sub-TLV specifies the IP address(es)
   of the interface corresponding to this link. Normally there will
   only be one address.  If there are multiple
   local addresses on the link, they are all listed in this sub-TLV.

   The Local Interface IPv4 Address sub-TLV is TLV type 1, and is 4N
   octets in length, where N is the number of local addresses.

   The Local Interface IPv6 Address sub-TLV is TLV type 3, and is 16N
   octets in length, where N is the number of local addresses.


3.3 Remote Interface IP Address Sub Types

   The Remote Interface IP Address sub-TLV specifies the IP address(es)
   of the neighbor's interface corresponding to this link.  This and
   the local address are used to discern multiple parallel links
   between systems.

   The Remote Interface IPv4 Address sub-TLV is TLV type 2, and is 4N
   octets in length, where N is the number of neighbor addresses.

   The Remote Interface IPv6 Address sub-TLV is TLV type 4, and is 16N
   octets in length, where N is the number of neighbor addresses.

3.4 Unreserved Bandwidth Sub Type

   The Unreserved Bandwidth sub-TLV specifies the amount of bandwidth


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   not yet reserved at each of the eight priority levels, in IEEE
   floating point format.  The values correspond to the bandwidth that
   can be reserved with a setup priority of 0 through 7, arranged in
   increasing order with priority 0 occurring at the start of the sub-
   TLV, and priority 7 at the end of the sub-TLV. The units are bytes
   per second.

   The Unreserved Bandwidth sub-TLV is TLV type 5, and is 32 octets in
   length.



4.0 Detailed Procedures

   On receipt of a withdraw, notification, query-reply, or mapping
   message pertaining to a request made by CR-LDP (as opposed to LDP),
   a feedback TLV of the appropriate format for the interface over
   which the message was received is inserted into the message before
   forwarding it back to the source of the request. The interface's
   local and remote interface address in the appropriate format are
   placed in the TLV.
   The eight bandwidth values are filled in with the outgoing bandwidth
   available on this interface for each of the eight holding priorities
   in bytes per second.

   On receipt of a CR-LDP request message, which cannot be satisfied, a
   notification message is formatted normally. The Feedback TLV with
   the local and remote interface address in the appropriate format and
   the eight bandwidth values are filled in with the outgoing bandwidth
   available on this interface for each of the eight holding priorities
   in bytes per second.

   On receipt of a CR-LDP request message which has been satisfied and
   which results in a mapping being generated. No feedback TLV is added
   since the previous node will insert the proper TLV when it receives
   the reverse flowing mapping.

   When an LDP session goes down either because of a link failure,
   TCP/IP timeout, keep alive timeout, adjacency timeout etc. Other LDP
   sessions in the module must generate either notification, withdraw
   or release messages for LSPs that traversed the LDP in question. In
   the case that the LSP was created by CR-LDP and that a withdraw or
   notification is about to be generated, LDP will insert a feedback
   TLV for the interface which just went down that contains 0's for all
   the bandwidth values and attach to it the proper interface
   addresses. Where LDP FT procedures [RFC3479] are in use, LSPs that
   are protected by FT procedures should not be torn down until after
   session reestablishment has failed.  During LDP re-establishment
   time new connections may be queued and delayed for the re-
   establishment time.  If signaling delay is undesirable feedback may

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   be used to report zero bandwidth. In this case, if LDP is
   successfully re-established a Link LSA should be triggered if
   sufficient amount bandwidth is available.


   When the LDP session that originated a CR-LDP label request receives
   a mapping that contains feedback TLV's it is recommended that these
   bandwidth values supersede the corresponding values in the node's
   topology database for source route computations. Doing so permits
   this node to immediately synchronize its topology with respect to
   the real bandwidth reservations along the path that was just
   established.

   When the LDP session that originated a CR-LDP label request receives
   a notification that contains feedback TLV's it is recommended that
   these bandwidth values supersede the corresponding values in the
   node's topology database for source route computations. Doing so
   permits this node to immediately synchronize its topology with
   respect to the real bandwidth reservations along the path that just
   failed to establish. The source node may then re-compute a path
   knowing that the computation will take into account the failure if
   it was caused by the topology database being in error with respect
   to the real network state.

5.0 IGP considerations

   Implementations MUST NOT permit bandwidth information learned by
   this feedback mechanism to be re-flooded via IS-IS, OSPF or any
   other IGP. The bandwidth information learned via these feedback
   mechanisms is to be used ONLY for source route computations on the
   nodes that are directly on the path that fed back the bandwidth.
   Normally only the source node of the LSP, or perhaps intermediate
   gateway nodes will use this information. It is however permitted for
   intermediate nodes that are forwarding this feedback information to
   store it for their own local source route computations.
   There is a possibility of a race condition between the bandwidth
   information that is received via feedback and that, which is
   received via a normal IGP flood. While there may be a discrepancy
   between the two, both are within a few 100 milliseconds of being
   correct. Solutions to allow us to determine which information is
   most up to date (say by adding a sequence number) do not add any
   significant benefit. Constraint based, source routed systems will
   always have errors in the local topology database with respect to
   the real network. These errors can be reduced through reduced
   flooding intervals, path following feedback and selective flooding
   but realistically the errors cannot be reduced below the second or
   so range. As a result propagation delay order race conditions are
   noise with respect to the average expected errors. An implementation
   SHOULD therefore consider the most recently received update (IGP or
   feedback) as being the most up to date.


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6.0 Future considerations

   Constraint based routing systems such as CR-LDP will in the future
   offer other forms of constraint than simply reserved bandwidth.
   Actual utilization levels, current congestion levels, number of
   discrete channels/wavelengths available etc. are all possible
   constraints that change rapidly and which must be taken into
   consideration when computing a route. It is expected that this
   mechanism will be used to feedback these and other new forms of link
   constraining data.

7.0 RSVP-TE consideration

   Nothing precludes the use of such feedback mechanisms with a similar
   TLV structure in the RSVP-TE Resv and other reverse flowing messages
   although repeatedly applying unchanged feedback should be avoided.
   This could be accomplished by a simple rule that only permits
   feedback information on the original RESV, not on subsequent
   refreshes. This document only covers the CR-LDP protocol.

8.0 Intellectual Property Consideration

   The IETF has been notified of intellectual property rights claimed
   in regard to some or all of the specification contained in this
   document.  For more information consult the online list of claimed
   rights.

9.0 Security Considerations

   This document covers an additional data structure, a TLV to an
   existing LDP message. Therefore the security aspects of this are the
   same as a LDP. CR-LDP inherits the same security mechanism described
   in Section 4.0 of [RFC3032] to protect against the introduction of
   spoofed TCP segments into LDP session connection streams.

10.0 IANA Considerations

   The Feedback TLV as well as Types for sub-TLVs in a Feedback TLV are
   to be registered with IANA.

   [RFC3212] defines the CR-LDP TLV name space.  This memo requires
   assignment of one TLV Type from that range.

   Also, sub-Types of a Feedback TLV need to be assigned by IANA. The
   types from 6 to 32767 are by expert review controlled by IANA. The
   types 32768 to 65535 are reserved for private use.


11.0 Acknowledgments

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   The authors would like to thank Keith Dysart for his guidance and
   Jerzy Miernik for helping implement these concepts and bringing them
   to life. The authors' would like to acknowledge Dave Allan for his
   comments and suggestions.

12.0 Normative References

   [RFC3212] Jamoussi, B. et al., "Constraint-Based LSP Setup using
   LDP", RFC 3212, January 2002.

   [RCF3032] Andersson, L. et al., "LDP Specification", RFC 3032,
   January 2001.

   [IS-IS] Li, T., Smit, H., "Extensions to IS-IS for traffic
   engineering", Internet Draft, draft-ietf-isis-traffic-04.txt,
   December 2001.

   [OSPF] Katz,D., Yeung, D., Kompella, K., " Traffic Engineering
   Extensions to OSPF Version 2," draft-katz-yeung-ospf-traffic-08.txt,
   September 2002.

13.0 Informative References


   [QUERY] Ashwood-Smith, P., Paraschiv, A., " Multi Protocol Label
   Switching Label Distribution Protocol Query Message Description
   ", Internet Draft, draft-anto-ldp-query-08.txt, June 2003.

   [RFC3479] Farrel, A et al., " Fault Tolerance for the Label
   Distribution Protocol (LDP)", RFC 3479, February 2003

14.0 Author's Addresses

   Peter Ashwood-Smith               Bilel Jamoussi
   Nortel Networks Corp.             Nortel Networks Corp.
   P.O. Box 3511 Station C,          600 Technology Park Drive
   Ottawa, ON K1Y 4H7                Billerica, MA 01821
   Canada                            USA
   Phone: +1 613-763-4534            phone: +1 978-288-4506
   petera@nortelnetworks.com         jamoussi@nortelnetworks.com

   Darek Skalecki                    Don Fedyk
   Nortel Networks Corp.             Nortel Networks Corp.
   P.O. Box 3511 Station C,          600 Technology Park Drive
   Ottawa, On K1Y 4H7                Billerica, MA 01821
   Canada                            USA
   Phone: +1 613-765-2252            Phone: +1 978-288-3041
   dareks@nortelnetworks.com         dwfedyk@nortelnetworks.com



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