Keywords: [--------|p], address, dynamic, allocation, client, protocol







Network Working Group                                         R. Kermode
Request for Comments: 2907                                      Motorola
Category: Standards Track                                 September 2000


              MADCAP Multicast Scope Nesting State Option

Status of this Memo

   This document specifies an Internet standards track protocol for the
   Internet community, and requests discussion and suggestions for
   improvements.  Please refer to the current edition of the "Internet
   Official Protocol Standards" (STD 1) for the standardization state
   and status of this protocol.  Distribution of this memo is unlimited.

Copyright Notice

   Copyright (C) The Internet Society (2000).  All Rights Reserved.

Abstract

   This document defines a new option to the Multicast Address Dynamic
   Client Allocation Protocol (MADCAP) to support nested scoping. The
   new option's purpose is to allow clients to learn which scopes nest
   inside each other, and hence it may be used for expanding scope
   searches or hierarchical multicast transport.

Table of Contents

   1.  Introduction. . . . . . . . . . . . . . . . . . . . .    2
        1.1 Time-To-Live (TTL) Scoping Split Horizon Effect.    2
        1.2 Eliminating the Split Horizon Effect with
            Administrative Scoping . . . . . . . . . . . . .    3
        1.3 Terminology. . . . . . . . . . . . . . . . . . .    4
   2.  Multicast Nested Scoping State. . . . . . . . . . . .    5
   3.  Multicast Scope Nesting State Option. . . . . . . . .    5
        3.1 Multicast Scope List Option  . . . . . . . . . .    5
        3.2 Representing the Multicast Scope Nesting State .    6
        3.3 Multicast Scope Nesting State Option Usage . . .    7
   4.  Managing Dynamic Nested Scopes. . . . . . . . . . . .    8
        4.1 MADCAP Server processing of MZAP messages. . . .    9
        4.2 Updating State for Dynamic Nested Scopes due to
                Timer Expiration . . . . . . . . . . . . . .    9
   5.  Multicast Scope Nesting State Option Format . . . . .    9
   6.  Constants . . . . . . . . . . . . . . . . . . . . . .   10
   7.  Security Considerations . . . . . . . . . . . . . . .   11
   8.  IANA Considerations . . . . . . . . . . . . . . . . .   11
   9.  Acknowledgements. . . . . . . . . . . . . . . . . . .   11



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RFC 2907      MADCAP Multicast Scope Nesting State Option September 2000


   10. References. . . . . . . . . . . . . . . . . . . . . .   11
   11. Author's Address. . . . . . . . . . . . . . . . . . .   12
   12. Full Copyright Statement. . . . . . . . . . . . . . .   13

1. Introduction

   The Multicast Address Dynamic Client Allocation Protocol (MADCAP)
   [RFC2730] affords client applications the ability to request
   multicast address allocation services from multicast address
   allocation servers.  As part of the Multicast Address Allocation
   Architecture [RFC2908], MADCAP gives clients the ability to reserve,
   request, and extend leases on multicast addresses.

   A new MADCAP option, the "Multicast Scope Nesting State" option is
   proposed to allow clients to learn not only which scopes exist via
   the existing "Multicast Scope List" option, but how these scopes nest
   inside each other. This new option will also afford clients the
   ability to make better scope selections for a given session and also
   to construct hierarchies of administratively scoped zones. These
   hierarchies may then be used to perform expanding scope searches
   instead of the expanding ring or increasing-TTL searches. Expanding
   scope searches do not suffer from the Split-Horizon Effect present in
   expanding ring searches, and therefore both simplify protocol design
   and provide better localization.

1.1 Time-To-Live (TTL) Scoping Split Horizon Effect

   Multicast searching and localized recovery transport techniques that
   rely on TTL scoping are known to suffer when deployed in a wide scale
   manner. The failing lies in the split horizon effect shown below in
   Figure 1. Here a requestor and responder must each use a TTL that is
   sufficiently large that they will reach the other. When they are
   separated by many hops the TTL becomes large and the number of
   receivers within the multicast tree that only receive either the
   request or the response can become very large.
















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RFC 2907      MADCAP Multicast Scope Nesting State Option September 2000


                      .......   *******
                   ...       ***       ***        A Only hears S
                 ..        **   ..        **      B hears S and R
                .         *       .         *     C Only hears R
               .         *         .         *
               .         S<------->R         *    . TTL Boundary for S
               .         *         .         *    * TTL Boundary for R
                .    A    *   B   .   C     *
                 ..        **   ..        **
                   ...       ***       ***
                      .......   *******

            Figure 1 : Split Horizon Problem from TTL scoping

1.2 Eliminating the Split Horizon Effect with Administrative Scoping

   Ideally, a mechanism that either eliminates or minimizes the size of
   the A and C regions in Figure 1. as shown in Figure 2. is needed to
   solve this problem. One mechanism that affords this ability is
   administrative scoping [RFC2365], in which routers prevent the
   passing of packets within a certain range of multicast addresses.
   Routers that have this feature can be configured to provide a
   perimeter around a region of the network. This perimeter is said to
   encompass an administratively scoped zone inside of which traffic
   sent to that particular range of multicast addresses can neither
   leave nor enter. Routers can construct and manage administratively
   scoped zones using the MZAP [RFC2776] protocol.

                    ........................
                  .                          .
                 .        many hops           .
                 .S<------------------------>R.
                 .                            .
                  .                          .
                    ........................

          Figure 2 : Eliminating the Split Horizon Effect

   MZAP also includes the ability to determine whether or not
   administratively scoped regions nest inside one another. This allows
   hierarchies such as that shown in Figure 1. to be constructed.










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RFC 2907      MADCAP Multicast Scope Nesting State Option September 2000


        . . . . .  . . . . . . . . . . . . .
       .            scope a                 .     Scope Boundaries
      .                                      .     . = scope  a
     .  _______________      ________________ .    - = scopes b,c
     . /    scope b    \    /  scope c       \ .   # = scopes d,e,f, & g
     .|                 |  |                  |.
     .|  #####    ##### |  |  #####    #####  |.
     .| #scope#  #scope#|  | #scope#  #scope# |.
      .\ # d  #  # e   #|  | # f   #  #  g # /.
       .\ ####    #####/    \ #####    #### /.
        .\____________/      \_____________/.
         . . . . . . . . . . . . . . . . .

          Figure 3 : Admin Scope Zone Nesting Hierarchy example

   A generic expanding scope search algorithm [KERM] that exploits the
   existence of a hierarchy of administratively scoped zones is:

   1) Starting with the smallest known scope for the session, a
      requestor in that session issues a request and waits for a reply.

   2) If a node within that scope hears a request at a certain scope
      that it can satisfy it sends a response at that same scope,
      possibly after some random delay to reduce duplicate responses.

   3) Nodes that receive a response to a particular request while
      waiting to send a response to that request, suppress their own
      response.

   4) If a requestor issues a request to a scope, and does not hear a
      response after a specified amount of time, it retransmits its
      request at the same scope a small number of additional times.
      Should these retries fail to elicit a response, the requestor
      increases the scope to the next largest scope and tries again.

   5) Requestors increase the scope of the request according to step 4
      until either a response is received, or the largest legal scope
      for the session is reached. Should attempts to elicit a response
      at the largest possible scope for the session fail to yield a
      response, the requestor may conclude that the request cannot be
      met.

1.3. Terminology

   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 RFC 2119 [RFC2119].




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RFC 2907      MADCAP Multicast Scope Nesting State Option September 2000


   Throughout the rest of this document, the words "server" or "MADCAP
   server" refer to a host providing multicast address allocation
   services via MADCAP. The words "client" or "MADCAP client" refer to a
   host requesting multicast address allocation services via MADCAP.

2. Multicast Nested Scoping State

   Two scopes, X and Y, can be related in one of four possible ways.

    1) X nests inside Y,
    2) Y nests inside X,
    3) X and Y do not nest (the overlap case), and
    4) X and Y nest inside each other.

   The fourth case SHOULD be interpreted as meaning that X and Y have
   exactly the same border. This does not mean that X and Y are the same
   scope since X and Y may correspond to different ranges of the
   multicast address space.

   This state MUST be stored in the MADCAP servers which MUST allow the
   state to be updated as network conditions change. Each MADCAP server
   SHOULD therefore define two pieces of state that describe whether
   "scope X nests in scope Y" and vice versa. For the remainder of this
   document the nesting relationship shall be denoted as the "/" where
   X/Y defines the relation "X nests inside Y". This relation shall be
   understood to take one of the values "true", or "false".  Nesting
   relationship state that is indeterminate is considered to be "false".

3 Multicast Scope Nesting State Option

   The "Multicast Scope Nesting State" option is proposed to augment the
   "Multicast Scope List" option within the MADCAP protocol by providing
   additional information to applications about how scopes nest. The
   proposed option is OPTIONAL, that is MADCAP servers MAY implement
   this new option, however they are not required to.

   MADCAP servers shall learn this additional nesting information by
   means of static configuration or via some other protocol such as MZAP
   [RFC2776] that manages administrative scopes in a dynamic fashion.

3.1 Multicast Scope List Option

   To understand the "Multicast Scope Nesting State" option one must
   first understand the "Multicast Scope List" option.







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   The Multicast Scope List option in MADCAP is used by MADCAP servers
   to inform MADCAP clients of which zones are visible. Visible scopes
   are enumerated inside the option as successive tuples, where each
   tuple consists of the following information:

      o Scope ID:
          The smallest address for the range of multicast addresses
          covered by this scope.

      o Last Address:
          The largest address for the range of multicast addresses
          covered by this scope.

      o TTL:
          The TTL to be used when sending messages to this scope.

      o Name(s):
          One or more language specific names for the scope.

3.2 Representing the Multicast Scope Nesting State

   Given a Multicast Scope List containing descriptions for n scopes one
   can form n(n-1)/2 pairings. As was shown in section 2 each pairing
   can take on one of four possible states. Thus, for a list of n scopes
   there exists 2 pieces of information for each pairing for a total of
   n(n-1) pieces of information regarding which scopes do and do not
   nest inside each other.

   There are several ways to represent this state using full matrices,
   sparse-matrices, and using lists of variable length lists. In the
   interests of maximal efficiency and flexibility, the Multicast
   Nesting State Option uses a bit-packed matrix approach.  In this
   approach a matrix is constructed using pieces of X/Y state where X is
   the row and Y is the column.  A "1" in the matrix means that the
   relationship "row nests inside column" is true, while a "0" means
   that this relationship is either false or indeterminate.  The
   diagonal of the matrix is removed, since this is the case where X is
   the same as Y, and each row is then zero-padded to the next byte
   boundary to give the final representation.

   An example of how a matrix would be constructed for the following
   scope nestings  S1/S2, S2/S3, S2/S4, S3/S5, S4/S5, S5/S6, and S6/S7.
   Note that a number of additional nesting relationships are implied
   from this set.







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RFC 2907      MADCAP Multicast Scope Nesting State Option September 2000


                         ________________________________
                        /............          \    \    \
                       /.S3 _________._____     \    \    \
                      |.   /+--+    \ .    \    |    |    |
                      |.  | |S1| S2 | . S4 | S5 | S6 | S7 |
                      |.   \+--+    / .    |    |    |    |
                       \.   \______/ .     |    |    |    |
                        \....\.......      /    /    /    /
                         \    \___________/    /    /    /
                          \___________________/    /    /
       \ Y                 \______________________/    /
      X \ 1 2 3 4 5 6 7     \_________________________/
         +-+-+-+-+-+-+-+
      1  |1 1 1 1 1 1 1|      *111111       1111 1100       0xfc
      2  |0 1 1 1 1 1 1|      0*11111       0111 1100       0x7c
      3  |0 0 1 0 1 1 1|      00*0111       0001 1100       0x1c
      4  |0 0 0 1 1 1 1|  =>  000*111   =>  0001 1100   =>  0x1c
      5  |0 0 0 0 1 1 1|      0000*11       0000 1100       0x0c
      6  |0 0 0 0 0 1 1|      00000*1       0000 0100       0x04
      7  |0 0 0 0 0 0 1|      000000*       0000 0000       0x00
         +-+-+-+-+-+-+-+                           ^^
                          * = X/Y where   zero padding
                             X == Y
         Final Representation: 0xfc 0x7c 0x1c 0x1c 0x0c 0x04 0x00

         Figure 4. Scope Nesting Example

3.3 Multicast Scope Nesting State Option Usage

   The "Multicast Scope Nesting State" option is dependent upon the
   "Multicast Scope List" option. This decision was made according to
   the following reasoning.  The Multicast Nest State Option requires
   that the scopes be identified along with their nesting properties.
   Since the information needed to describe a scope is contained in the
   Multicast Scope List option and this information can change, the
   MADCAP messages that contain the Multicast Scope Nesting State option
   must be atomic and therefore must include the "Multicast Scope List
   Option".

   Thus, the "Multicast Scope Nesting State" option MUST only be used in
   messages that carry the "Multicast Scope List" option, specifically:

        ACK (in response to GETINFO)

   Since the Multicast Nest State option is dependent upon the Multicast
   Scope List option, it MUST NOT be included without the Multicast
   Scope List option.




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RFC 2907      MADCAP Multicast Scope Nesting State Option September 2000


   Clients that need to explicitly learn the nesting relationships
   between scopes should therefore send a GETINFO message to the server
   with the "Multicast Scope List" AND "Multicast Scope Nesting State"
   option codes listed in an Option Request option.

4. Managing Dynamically Nested Scopes

   Scopes can either be manually or automatically configured.  When
   scopes are manually configured the relationships between them will
   also be static, assuming that network does not partition due to
   router failure.  Should the network partition or heal after a
   partition it is highly likely that the nesting relationships will
   change.  Scope nesting relationships will also change as a network is
   brought up or when a change is deliberately made to a router either
   through manual reconfiguration or by some automatic means.

   To ensure that nesting relationships are correctly determined when
   scope boundaries undergo change MADCAP servers MUST include a
   mechanism that allow for:

    a) whether the nesting decision is still under consideration or
       can be considered definitive, and therefore be announced to
       MADCAP clients.

    b) whether one or both scopes for a particular nesting state entry
       have been destroyed, and hence whether the nesting state should
       therefore be discarded.

    c) whether the scope boundaries have changed so that whereas scope
       X did or did not nest inside scope Y, the opposite is now true.

   To realize a) and b) MADCAP servers MUST implement the following two
   timers; NEST_NO_DECISION_TIMER, ZONES_EXIST_TIMER.

   The first timer, NEST_NO_DECISION_TIMER, is used to mark time between
   a MADCAP server's first hearing of a scope and making a decision
   about its relationship to other zones.  Up until the time this timer
   expires MADCAP servers MUST NOT conclude that the scope nests within
   another.

   The NEST_NO_DECISION_TIMER timer will also be used to timeout X/Y =
   "false" state to allow X/Y to be reset to true in the event that the
   boundaries for zone X and zone Y change so that zone X now nests
   inside zone Y.

   The second timer ZONES_EXIST_TIMER will be used to timeout the
   internal state between two scopes in the event that one or both
   scopes are destroyed.



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RFC 2907      MADCAP Multicast Scope Nesting State Option September 2000


4.1 MADCAP Server processing of MZAP messages

   When MZAP is used to discover the nesting relationship between scopes
   MADCAP servers will eavesdrop into the MZAP messages that are
   periodically transmitted by the Zone Border Routers (ZBR) during the
   normal course of administrative scope boundary maintenance.  In this
   way they will be able to learn which scopes exist (via Zone
   Announcement Messages, ZAMs) and which of these scopes do not nest
   (via Not Inside Messages, NIMs). This state must be cached within the
   MADCAP server.

   When a MADCAP server S receives a NIM from a ZBR containing
   information that scope X does not nest in scope Y, it MUST update its
   internal state in the following manner.

      1) S MUST update its internal X/Y state to "false".
      2) S MUST restart NEST_NO_DECISION_TIMER for the newly updated
         X/Y state.

4.2 Updating State for Dynamic Scopes due to timer expiration.

   MADCAP servers will update X/Y nesting state upon the expiration of
   timers in the following manner.

    o If the NEST_NO_DECISION_TIMER expires for a state entry X/Y AND no
      MADCAP messages have been received that indicate scope X does not
      nest inside scope Y, a MADCAP Server, S, MUST conclude that scope
      X nests inside scope Y. As a result S will change X/Y from
      "false" to "true".

      When a state change from "false" to "true" occurs for X/Y, S must
      also start the ZONES_EXIST_TIMER timer for X/Y. The
      ZONES_EXIST_TIMER should only reset when a Zone Announcement
      Message (ZAM) has been received for both zone X and zone Y since
      the last time it was restarted. This ensures that both zone X and
      zone Y are known to still exist.

    o If the ZONES_EXIST_TIMER expires for a state entry X/Y, S
      SHOULD conclude that either zone Y or zone X no longer exists and
      hence that both X/Y and Y/X state should be destroyed.

5. Multicast Scope Nesting State Option Format

           Code        Len     Count  Nest State Matrix
      +-----+-----+-----+-----+-----+-----+-...-+-----+
      |    17     |     p     | m   | N1  |     | Nm  |
      +-----+-----+-----+-----+-----+-----+-...-+-----+




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RFC 2907      MADCAP Multicast Scope Nesting State Option September 2000


   Code: 16 bits
      Option identifier 17.

   Len: 16 bits
      The length of the option in bytes.

   Count: 8 bits
      The number of zones present in the Nest State Matrix. This value
      MUST be identical to the Count field in the preceding Multicast
      State List option. If this is not the case the scope nesting
      state information MUST BE ignored.

   Nest State Matrix:
      The compressed bit-packed representation of the matrix, derived
      in the same manner as shown in Figure 4.  Note for N scopes
      the compressed matrix will be N times ceil((N-1)/8) bytes long,
      where ceil() is the function that rounds up to the nearest integer.
      The scopes corresponding to the rows and columns of this matrix
      list in the same order as they appear in the Multicast Scope
      List Option.

6. Constants

   [NEST_NO_DECISION_TIMER] The time after which a MADCAP server or
        client can assume that a message announcing that two zones
        do not nest should not be received. The length of this timer
        is dependent upon the zone announcement protocol used to
        inform the MADCAP router of which zones currently exist.
        When MZAP [RFC2776] is used this value should be greater than
        the MZAP timeout value NIM-INTERVAL +30%. This corresponds
        to a timeout value of 1800 + 30% = 2340 seconds (39 minutes).

   [ZONES_EXIST_TIMER] The time after which a MADCAP server or client
        should assume that the zone in question does not exist when
        zones are detected dynamically. The length of this timer is
        dependent upon the zone announcement protocol used to inform
        the MADCAP router of which zones currently exist. When MZAP
        [RFC2776] is used this value should be no less than the MZAP
        timeout value NIM-HOLDTIME, which has a default of
        5460 seconds (91 minutes).











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7. Security Considerations

   Since this document proposes an extension to the MADCAP protocol via
   the addition of a new option, the same set of security concerns
   apply.

   In addition to these concerns are those that would arise were the
   information in the Multicast Scope Nesting State option to be
   falsified. In this case the clients would be misinformed as to which
   scopes nest inside one another. In this event, the client would then
   make incorrect decisions regarding the order in which to use the
   scopes. The effect of this would be to use larger scopes than
   necessary, which would effectively flatten any scope hierarchy
   present and  nullify the advantage afforded by the hierarchy's
   presence.

   Thus a malformed or tampered Multicast Scope Nesting option may cause
   protocols that rely upon the existence of a scoping hierarchy to
   scale less well, but it would not prevent them from working.

8. IANA Considerations

   The Multicast Nesting State Option has been assigned MADCAP option
   code 17 by the IANA [RFC2730].

9. Acknowledgments

   The Author would like to acknowledge Mark Handley and Dave Thaler for
   the helpful discussions and feedback which helped shape and refine
   this document.

10. References

   [KERM]    Kermode, R., "Smart Network Caches: Localized Content and
             Application Negotiated Recovery Mechanisms for Multicast
             Media Distribution", Ph.D. Thesis, MIT Media Laboratory,
             June 1998.

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

   [RFC2365] Meyer, D., "Administratively Scoped IP Multicast", BCP 23,
             RFC 2365, July 1998.








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RFC 2907      MADCAP Multicast Scope Nesting State Option September 2000


   [RFC2730] Patel, B.V., Shah, M. and S.R. Hanna, "Multicast Address
             Dynamic Client Allocation Protocol (MADCAP)", RFC 2730,
             December 1999.

   [RFC2776] Handley, M., Thaler, D. and R. Kermode, "Multicast-Scope
             Zone Announcement Protocol (MZAP)", RFC 2776, February
             2000.

   [RFC2908] Handley, M., Thaler, D. and D. Estrin, "The Internet
             Multicast Address Allocation Architecture", RFC 2908,
             September 2000.

11. Author's Address

   Roger Kermode
   Motorola Australian Research Centre
   Locked Bag 5028
   Botany, NSW 1455
   Australia

   EMail: Roger.Kermode@motorola.com






























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12.  Full Copyright Statement

   Copyright (C) The Internet Society (2000).  All Rights Reserved.

   This document and translations of it may be copied and furnished to
   others, and derivative works that comment on or otherwise explain it
   or assist in its implementation may be prepared, copied, published
   and distributed, in whole or in part, without restriction of any
   kind, provided that the above copyright notice and this paragraph are
   included on all such copies and derivative works.  However, this
   document itself may not be modified in any way, such as by removing
   the copyright notice or references to the Internet Society or other
   Internet organizations, except as needed for the purpose of
   developing Internet standards in which case the procedures for
   copyrights defined in the Internet Standards process must be
   followed, or as required to translate it into languages other than
   English.

   The limited permissions granted above are perpetual and will not be
   revoked by the Internet Society or its successors or assigns.

   This document and the information contained herein is provided on an
   "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING
   TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING
   BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION
   HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
   MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.

Acknowledgement

   Funding for the RFC Editor function is currently provided by the
   Internet Society.



















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