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NGTRANS Working Group                                       F. Templin
INTERNET-DRAFT                                                   Nokia
                                                            T. Gleeson
                                                    Cisco Systems K.K.
                                                             M. Talwar
                                                             D. Thaler
                                                 Microsoft Corporation

Expires 31 April 2003                                  31 October 2002

        Intra-Site Automatic Tunnel Addressing Protocol (ISATAP)

                    draft-ietf-ngtrans-isatap-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

   This document specifies the Intra-Site Automatic Tunnel Addressing
   Protocol (ISATAP) that connects IPv6 hosts and routers (nodes) within
   IPv4 sites. ISATAP is a transition mechanism that enables incremental
   deployment of IPv6 by treating the site's IPv4 infrastructure as a
   Non-Broadcast Multiple Access (NBMA) link layer for IPv6. ISATAP
   mechanisms use an IPv6 interface identifier format that embeds an
   IPv4 address - this enables automatic IPv6-in-IPv4 tunneling within a
   site, whether the site uses globally assigned or private IPv4
   addresses.  The new interface identifier format can be used with both
   local and global unicast IPv6 prefixes - this enables IPv6 routing
   both locally and globally. ISATAP mechanisms introduce no impact on



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   routing table size and require no special IPv4 services (e.g., IPv4
   multicast).


1.  Introduction

   This document presents a simple approach that enables incremental
   deployment of IPv6 within IPv4-based sites in a manner that is com-
   patible with inter-domain transition mechanisms, e.g., [6TO4]. We
   refer to this approach as the Intra-Site Automatic Tunnel Addressing
   Protocol, or ISATAP (pronounced: "ice-a-tap"). ISATAP allows dual-
   stack nodes that do not share a common link with an IPv6 router to
   automatically tunnel packets to the IPv6 next-hop address through
   IPv4, i.e., the site's IPv4 infrastructure is treated as an NBMA link
   layer.

   This document specifies details for the transmission of IPv6 packets
   over ISATAP links (i.e., automatic IPv6-in-IPv4 tunneling), including
   a new EUI-64 [EUI64] based interface identifier [ADDR][AGGR] format
   that embeds an IPv4 address. This format supports configuration of
   global, site-local and link-local addresses as specified in [AUTO] as
   well as simple link-layer address mapping. Simple validity checks for
   received packets are given. Also specified in this document is the
   operation of IPv6 Neighbor Discovery for ISATAP, as permitted for
   NBMA links by [DISC]. The document finally presents deployment and
   security considerations for ISATAP.


2.  Applicability Statement

   ISATAP provides the following features:

     - treats site's IPv4 infrastructure as an NBMA link layer using
       automatic IPv6-in-IPv4 tunneling (i.e., no configured tunnel state)

     - enables incremental deployment of IPv6 hosts within IPv4 sites with
       no aggregation scaling issues at border gateways

     - requires no special IPv4 services within the site (e.g., multicast)

     - supports both stateless address autoconfiguration and manual
       configuration

     - supports networks that use non-globally unique IPv4 addresses (e.g.,
       when private address allocations [PRIVATE] are used), but does not
       allow the virtual ISATAP link to span a Network Address
       Translator [NAT]




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     - compatible with other NGTRANS mechanisms (e.g., [6TO4])


3.  Terminology

   The terminology of [IPv6] applies to this document. The following
   additional terms are defined:

   link:
     same definition as [AUTO][DISC].

   underlying link:
     a link layer that supports IPv4 (for ISATAP), and MAY also support
     IPv6 natively.

   ISATAP link:
     one or more underlying links used for IPv4 tunneling. The IPv4
     network layer addresses of the underlying links are used as
     link-layer addresses on the ISATAP link.

   ISATAP interface:
     a node's attachment to an ISATAP link.

   ISATAP prefix:
     a prefix used to configure an address on the ISATAP interface. This
     prefix is administratively assigned to the ISATAP link and MUST NOT
     be duplicated on native IPv6 links.

   ISATAP address:
     an IPv6 address with an ISATAP prefix and an ISATAP format interface
     identifier constructed as specified in section 4.

   ISATAP router:
     an IPv6 node that has an ISATAP interface over which it forwards
     packets not explicitly addressed to itself.

   ISATAP host:
     any node that has an ISATAP interface and is not an ISATAP router.


4.  Transmission of IPv6 Packets on ISATAP Links

   ISATAP links transmit IPv6 packets via automatic tunneling using the
   site's IPv4 infrastructure as an NBMA link layer. Automatic tunneling
   for ISATAP uses the same encapsulation, hop limit, IPv4 header con-
   struction, and decapsualtion specifications in [MECH, 3], i.e., IPv6
   packets are automatically encapsulated in IPv4 using 'ip-protocol-41'
   as the payload type number. The specifications in [MECH, 3.2, 3.4] do



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   not apply for ISATAP; instead:

    - The default link MTU SHOULD be set to the minimum IPv6 MTU of
      1280 bytes [IPV6], unless specific configuration information
      is available. The Don't Fragment bit SHOULD NOT be set in the
      encapsulating IPv4 header.

    - IPv4 ICMP errors and ARP failures may be processed as
      link error notifications, as allowed by [DISC]

   Specific considerations for ISATAP links are given below:


4.1.  ISATAP Interface Identifier Construction

   IPv6 unicast addresses [ADDR][AGGR] include a 64-bit interface iden-
   tifier field in "modified EUI-64 format", based on the IEEE EUI-64
   [EUI64] specification. (Modified EUI-64 format inverts the sense of
   the 'u/l' bit from its specification in [EUI64], i.e., 'u/l' = 0
   indicates local-use.) ISATAP interface identifiers are constructed by
   prepending the 32-bit string '00-00-5E-FE' with an IPv4 address (see
   the following section for examples). Appendix B includes text
   explaining the rationale for this construction rule.


4.2.  Stateless Autoconfiguration and Link-Local Addresses

   ISATAP addresses are unicast addresses [ADDR,2.5] that use ISATAP
   format interface identifiers as follows:

    |           64 bits            |     32 bits   |    32 bits     |
    +------------------------------+---------------+----------------+
    | link-local, site-local or    |   0000:5EFE   |  IPv4 Address  |
    |    global unicast prefix     |               | of ISATAP link |
    +------------------------------+---------------+----------------+

   Link-local, site-local, and global ISATAP addresses can be created
   exactly as specified in [ADDR], (e.g., by auto-configuration [AUTO]
   or manual configuration). For example, the IPv6 address:

     3FFE:1A05:510:1111:0:5EFE:8CAD:8108

   has a prefix of '3FFE:1A05:510:1111::/64' and an ISATAP format inter-
   face identifier with embedded IPv4 address: '140.173.129.8'.  The
   address is alternately written as:

     3FFE:1A05:510:1111:0:5EFE:140.173.129.8




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   The link-local and site-local variants (respectively) are:

     FE80::0:5EFE:140.173.129.8
     FEC0::1111:0:5EFE:140.173.129.8


4.3.  ISATAP Link/Interface Configuration

   A node configures an ISATAP link over one or more underlying IPv4
   links, i.e., the ISATAP link MAY be configured over one or more link-
   layer (IPv4) addresses. Each link-layer address 'V4ADDR_LINK' is used
   to configure a link-local address 'FE80::0:5EFE:V4ADDR_LINK' on an
   ISATAP interface. ISATAP interfaces MAY be assigned one per link-
   layer address, or as a single interface for multiple link-layer
   addresses.

   In the former case, the address of each ISATAP interface SHOULD be
   added to the Potential Routers List (see section 5.2.1). In the lat-
   ter case, the interface will accept ISATAP packets addressed to any
   of the IPv4 link-layer addresses, but will choose one as its primary
   address, used for sourcing packets. Only this address need be repre-
   sented in the Potential Routers List.


4.4.  Sending Rules and Address Mapping

   The IPv6 next-hop address for packets sent on an ISATAP link MUST be
   an ISATAP address. Packets that do not satisfy this constraint MUST
   be discarded and an ICMP destination unreachable indication with code
   3 (Address Unreachable) [ICMPv6] MUST be returned. No other sending
   rules are necessary.

   The procedure for mapping unicast addresses into link-layer addresses
   is to simply treat the last four octets of the ISATAP address as an
   IPv4 address (in network byte order). No multicast address mappings
   are specified.


4.5.  Validity Checks for Received Packets

   Packets received on ISATAP interfaces MUST satisfy at least one
   (i.e., one or both) of the following validity checks:









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     - the network-layer (IPv6) source address has a prefix configured on
       the ISATAP interface and an ISATAP-format interface identifier that
       embeds the link-layer (IPv4) source address, i.e., source is on-link

     - the link-layer (IPv4) source address is an "active" member of
       the Potential Routers List (see section 5.2), i.e., previous
       hop is an on-link ISATAP router actively being used by the node

   Packets that do not satisfy at least one of the above checks are
   silently discarded.


5.  Neighbor Discovery for ISATAP Links

   Section 3.2 of [DISC] ("Supported Link Types") provides the following
   guidelines for non-broadcast multiple access (NBMA) link support:

     "Redirect, Neighbor Unreachability Detection and next-hop determi-
     nation should be implemented as described in this document. Address
     resolution and the mechanism for delivering Router Solicitations
     and Advertisements on NBMA links is not specified in this docu-
     ment."

   ISATAP links SHOULD implement Redirect, Neighbor Unreachability
   Detection, and next-hop determination exactly as specified in [DISC].
   Address resolution and the mechanisms for delivering Router Solicita-
   tions and Advertisements for ISATAP links are not specified by
   [DISC]; instead, they are specified in this document. (Note that
   these mechanisms MAY potentially apply to other types of NBMA links
   in the future.)


5.1.  Address Resolution

   Protocol addresses (IPv6) in ISATAP are resolved to link-layer
   addresses (IPv4) by a static computation, i.e., the last four octets
   are treated as an IPv4 address.

   ISATAP nodes SHOULD perform Neighbor Unreachability Detection (NUD)
   as specified in [DISC, 7.3], and MUST send solicited neighbor adver-
   tisements as specified in [DISC, 7.2.4].

   The link-layer address option used in [DISC] is not needed. Link-
   layer address options SHOULD NOT be sent in any Neighbor Discovery
   packets, and MUST be silently ignored in any received Neighbor Dis-
   covery packets.





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5.2.  Router and Prefix Discovery

   Since the site's IPv4 infrastructure is treated as an NBMA link
   layer, unsolicited Router Advertisements do not provide sufficient
   means for router discovery on ISATAP links. Thus, alternate mecha-
   nisms are required and specified below:


5.2.1.  Conceptual Data Structures

   ISATAP nodes use the conceptual data structures Prefix List and
   Default Router List exactly as specified in [DISC,5.1]. ISATAP links
   add a new conceptual data structure "Potential Router List" and the
   following new configuration variable:

     ResolveInterval    Time between name service resolutions.
                        Default and suggested minimum: 1hr

   A Potential Router List (PRL) is associated with every ISATAP link.
   The PRL provides context for router discovery and a trust basis for
   router validation (see security considerations). Each entry in the
   PRL has an IPv4 address and an associated timer used for polling. The
   IPv4 address represents a router's ISATAP interface (likely to be an
   "advertising interface"), and is used to construct the ISATAP link-
   local address for that interface.

   When a node enables an ISATAP link, it initializes the Potential
   Router List (PRL) for that link. Unless other information is avail-
   able (e.g., manual address configuration, a vendor-specific DHCP
   option, etc.) the following method (similar to the [SIP, 1.4.2] pro-
   cedure) SHOULD be used:

     1. The site administrator maintains address records for ISATAP
        router interfaces, and makes these available in the site's
        name service. Nodes attempt to find one or more addresses
        for the PRL by querying the name service.

     2. There are no mandatory rules on the selection of domain name
        to be used within a site for this purpose, but administrators
        are encouraged to use the "isatap.domainname" convention
        (e.g., isatap.example.com), as specified in [RFC2219]. Nodes
        can construct this domain name by prepending the label "isatap"
        to their parent domain name, which is established by other
        means. Nodes then query this domain name for address records
        (e.g., DNS 'A' resource records), and initialize the PRL with
        the IPv4 addresses in the replies.

     3. After initialization, nodes periodically repeat the above



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        procedure ResolveInterval to update the PRL with any IPv4
        addresses added/deleted since the previous iteration. When
        DNS is used, nodes MUST follow the procedures in [RFC1035]
        regarding cache invalidation when the DNS time-to-live expires.

5.2.2.  Validation of Router Advertisement Messages

   A node MUST silently discard any received Router Advertisement mes-
   sages that do not satisfy the validity checks in [DISC,6.1.2] as well
   as the following additional validity check for ISATAP:

        - the network-layer (IPv6) source address is derived from
          an IPv4 address in the PRL


5.2.3.  Router Specification

   Advertising ISATAP interfaces of routers behave the same as advertis-
   ing interfaces described in [DISC,6.2]. However, periodic unsolicited
   multicast Router Advertisements are not required, thus the "interval
   timer" associated with advertising interfaces is not used for that
   purpose.

   When an ISATAP router receives a valid Router Solicitation on an
   advertising ISATAP interface, it replies with a unicast Router Adver-
   tisement to the address of the node which sent the Router Solicita-
   tion. The source address of the Router Advertisement is a link-local
   unicast address associated with the interface. This MAY be the same
   as the destination address of the Router Solicitation. ISATAP routers
   MAY engage in the polling process described under Host Specification
   below (e.g. if Router Advertisement consistency verification
   [DISC,6.2.7] is desired), but this is not required.


5.2.4.  Host Specification

   Hosts periodically poll one or more entries in the PRL ("PRL(i)") by
   sending unicast Router Solicitation messages using the IPv4 address
   ("V4ADDR_PRL(i)") and associated timer in the entry. Hosts add the
   following variable to support the polling process:

     MinRouterSolicitInterval
                   Minimum time between sending Router Solicitations
                   to any router. Default and suggested minimum: 15min

   When a PRL(i) is selected for polling, the host sets its associated
   timer to MinRouterSolicitInterval and initiates polling following a
   short delay as for initial solicitations [ND,6.3.7]), and when the



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   associated timer expires.

   Polling consists of sending Router Solicitations to the ISATAP link-
   local address constructed from the entry's IPv4 address, i.e., they
   are sent to 'FE80::0:5EFE:V4ADDR_PRL(i)' instead of 'All-Routers mul-
   ticast'. They are otherwise sent in the same manner described in
   [DISC,6.3.7].

   When the host receives a valid Router Advertisement (i.e., one that
   satisfies the validity checks in sections 4.5 and 5.2.2) it is pro-
   cesses in the same manner described in [DISC,6.3.4]. The host addi-
   tionally resets the timer associated with the V4ADDR_PRL(i) embedded
   in the network-layer source address in the Router Advertisement. The
   timer is reset to either 0.5 * (the minimum value in the router life-
   time or valid lifetime of any on-link prefixes advertised) or Min-
   RouterSolicitInterval; whichever is longer.


6.  ISATAP Deployment Considerations


6.1.  Host And Router Deployment Considerations

   For hosts, if an underlying link supports both IPv4 (over which ISA-
   TAP is implemented) and also supports IPv6 natively, then ISATAP MAY
   be enabled if the native IPv6 layer does not receive Router Adver-
   tisements (i.e., does not have connection with an IPv6 router). After
   a non-link-local address has been configured and a default router
   acquired on the native link, the host SHOULD discontinue the 'Router
   Polling Process' process specified in section 5.2.4 and allow exist-
   ing ISATAP address configurations to expire as specified in
   [DISC,5.3][AUTO,5.5.4]. Any ISATAP addresses added to the DNS for
   this host should also be removed. In this way, ISATAP use will gradu-
   ally diminish as IPv6 routers are widely deployed throughout the
   site.

   Routers MAY configure an interface to simultaneously support both
   native IPv6, and also ISATAP (over IPv4). Routing will operate as
   usual between these two domains. Note that the prefixes used on the
   ISATAP and native IPv6 interfaces will be distinct. The IPv4
   address(es) configured on a router's ISATAP interface(s) SHOULD be
   added (either automatically or manually) to the site's address
   records for ISATAP router interfaces (see section 5.2.1).








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6.2.  Site Administration Considerations

   The following considerations are noted for sites that deploy ISATAP:

     - ISATAP links are administratively defined by a set of router
       interfaces, and set of nodes which have those interface addresses
       in their potential router lists. Thus, ISATAP links are defined by
       administrative (not physical) boundaries.

     - ISATAP hosts and routers can be deployed in an ad-hoc and independent
       fashion. In particular, ISATAP hosts can be deployed with little/no
       advanced knowledge of existing ISATAP routers, and ISATAP routers
       can deployed with no reconfiguration requirements for hosts.

     - ISATAP nodes periodically send Router Solicitations to all entries
       in the Potential Router List. Worst-case control traffic is on the
       order of (M x N), where 'M' is the number of routers in the Potential
       Router List and 'N' is the total number of nodes on the ISATAP link.
       The MinRouterSolicitInterval ([5.2.4]) bounds control traffic for
       large numbers of nodes even in worst-case scenarios.

     - ISATAP nodes periodically refresh the entries on the PRL, typically
       by polling the DNS. Responsible site administration can reduce the
       control traffic. At a minimum, administrators SHOULD ensure that
       the site's address records for ISATAP router interfaces (see
       section 5.2.1) are well maintained.


7.  IANA considerations

   Appendix B offers one possible specification for managing the IEEE
   OUI assigned to IANA for EUI-64 interface identifier construction.
   This specification is made freely available to IANA for any purpose
   they may find useful.


8.  Security considerations

   Site administrators are advised that, in addition to possible attacks
   against IPv6, security attacks against IPv4 MUST also be considered.
   Many security considerations in [6OVER4,9] apply also to ISATAP.

   Responsible IPv4 site security management is strongly encouraged. In
   particular, border gateways SHOULD implement filtering to detect
   spoofed IPv4 source addresses at a minimum; ip-protocol-41 filtering
   SHOULD also be implemented.

   If IPv4 source address filtering is not correctly implemented, the



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   validity checks in section 4.7 will not be effective in preventing
   IPv6 source address spoofing.

   If filtering for ip-protocol-41 is not correctly implemented, IPv6
   source address spoofing is clearly possible, but this can be elimi-
   nated if both IPv4 source address filtering, and the validity checks
   in section 4.7 are implemented.

   [DISC,6.1.2] implies that nodes trust Router Advertisements they
   receive from on-link routers, as indicated by a value of 255 in the
   IPv6 'hop-limit' field. Since this field is not decremented when ip-
   protocol-41 packets traverse multiple IPv4 hops [MECH,3.3], ISATAP
   links require a different trust model. In particular, ONLY those
   Router Advertisements received from a member of the Potential Routers
   List are trusted; all others are silently discarded (see section
   5.2.2). This trust model is predicated on IPv4 source address filter-
   ing, as described above.

   The ISATAP address format does not support privacy extensions for
   stateless address autoconfiguration [PRIVACY]. However, since the
   ISATAP interface identifier is derived from the node's IPv4 address,
   ISATAP addresses do not have the same level of privacy concerns as
   IPv6 addresses that use an interface identifier derived from the MAC
   address.

Acknowledgements

   Some of the ideas presented in this draft were derived from work at
   SRI with internal funds and contractual support. Government sponsors
   who supported the work include Monica Farah-Stapleton and Russell
   Langan from U.S. Army CECOM ASEO, and Dr. Allen Moshfegh from U.S.
   Office of Naval Research. Within SRI, Dr. Mike Frankel, J. Peter Mar-
   cotullio, Lou Rodriguez, and Dr. Ambatipudi Sastry supported the work
   and helped foster early interest.

   The following peer reviewers are acknowledged for taking the time to
   review a pre-release of this document and provide input: Jim Bound,
   Rich Draves, Cyndi Jung, Ambatipudi Sastry, Aaron Schrader, Ole
   Troan, Vlad Yasevich.

   The authors acknowledge members of the NGTRANS community who have
   made significant contributions to this effort, including Rich Draves,
   Alain Durand, Nathan Lutchansky, Art Shelest, Margaret Wasserman, and
   Brian Zill.

   The authors wish to acknowledge the work of Quang Nguyen [VET] under
   the guidance of Dr. Lixia Zhang that proposed very similar ideas to
   those that appear in this document. This work was first brought to



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   the authors' attention on September 20, 2002.

   Finally, the authors recognize that ideas similar to those in this
   document may have already been presented by others and wish to
   acknowledge any other such contributions.

Normative References

   [ADDR]     Hinden, R., and S. Deering, "IP Version 6 Addressing
              Architecture", RFC 2373, July 1998. (Pending approval
              of "addr-arch-v3").

   [AGGR]     Hinden., R, O'Dell, M., and Deering, S., "An IPv6
              Aggregatable Global Unicast Address Format",
              RFC 2374, July 1998.

   [AUTO]     Thomson, S., and T. Narten, "IPv6 Stateless Address
              Autoconfiguration", RFC 2462, December 1998.

   [DISC]     Narten, T., Nordmark, E., and W. Simpson, "Neighbor
              Discovery for IP Version 6 (IPv6)", RFC 2461,
              December 1998.

   [EUI64]    IEEE, "Guidelines for 64-bit Global Identifier (EUI-64)
              Registration Authority",
              http://standards.ieee.org/regauth/oui/tutori-
   als/EUI64.html,
              March 1997.

   [ICMPv6]   Conta, A. and S. Deering, "Internet Control Message
              Protocol (ICMPv6) for the Internet Protocol Version 6
              (IPv6) Specification", RFC 2463, December 1998.

   [IPV4]     Postel, J., "Internet Protocol", RFC 791.

   [IPV6]     Deering, S., and R. Hinden, "Internet Protocol, Version 6
              (IPv6) Specification", RFC 2460.

   [MECH]     Gilligan, R., and E. Nordmark, "Transition Mechanisms for
              IPv6 Hosts and Routers", RFC 2893, August 2000.

   [NAT]      Egevang, K., and P. Francis, "The IP Network Address
              Translator (NAT)", RFC 1631, May 1994.

   [PRIVATE]  Rekhter, Y., Moskowitz, B., Karrenberg, D., de Groot, G.,
              and E. Lear, "Address Allocation for Private Internets",
              RFC 1918, February 1996.




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   [SIP]      Handley, M., Schulzrinne, H., Schooler, E., and
              J. Rosenberg, "SIP: Session Initiation Protocol",
              RFC 2543, March 1999.


Informative References

   [6OVER4]   Carpenter, B. and C. Jung, "Transmission of IPv6 over IPv4
              Domains without Explicit Tunnels", RFC 2529.

   [6TO4]     Carpenter, B., and K. Moore, "Connection of IPv6 Domains
              via IPv4 Clouds", RFC 3056, February 2001.

   [IANA]     Reynolds, J., and J. Postel, "Assigned Numbers", STD 2,
              USC/Information Sciences Institute, October 1994.

   [PRIVACY]  Narten, T., R. Draves, "Privacy Extensions for Stateless
              Address Autoconfiguration in IPv6", RFC 3041,
              January 2001.

   [RFC1035]  Mockapetris, P., "Domain Names - Implementation and
              Specification", RFC 1035, November 1987.

   [RFC2219]  Hamilton, M., and R. Wright, "Use of DNS Aliases for
              Network Services", RFC 2219 (BCP), October 1997.

   [VET]      Nguyen, Quang, "Virtual Ethernet: A New Approach to
              IPv6 Transition", http://irl.cs.ucla.edu/vet/report.ps,
              MS Project Report, Spring 1998.

Authors Addresses

      Fred L. Templin
      Nokia
      313 Fairchild Drive
      Mountain View, CA, USA
      Phone: (650)-625-2331
      Email: ftemplin@iprg.nokia.com

      Tim Gleeson
      Cisco Systems K.K.
      Shinjuku Mitsu Building
      2-1-1 Nishishinjuku, Shinjuku-ku
      Tokyo 163-0409, JAPAN
      email: tgleeson@cisco.com

      Mohit Talwar
      Microsoft Corporation



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      One Microsoft Way
      Redmond, WA  98052-6399
      Phone: +1 425 705 3131
      EMail: mohitt@microsoft.com

      Dave Thaler
      Microsoft Corporation
      One Microsoft Way
      Redmond, WA  98052-6399
      Phone: +1 425 703 8835
      EMail: dthaler@microsoft.com

APPENDIX A: Major Changes

   changes from version 05 to version 06:

     - Addressed operational issues identified in 05 based on
       discussion between co-authors

     - Clarified ambiguous text per comments from Hannu Flinck;
       Jason Goldschmidt

   changes from version 04 to version 05:

     - Moved historical text in section 4.1 to Appendix B in
       response to comments from Pekka Savola

     - Identified operational issues for anticipated deployment
       scenarios

     - Included SRI IPR statement and contact information

     - Included reference to Quang Nguyen work

   changes from version 03 to version 04:

     - Re-wrote section on Potential Router List initialization to
       reference existing precedence in other documents

     - several minor wording changes based on feedback from the
       community

   changes from version 02 to version 03:

     - Added contributing co-authors

     - RSs are now sent to unicast addresses rather than all-routers-multicast




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     - Brought draft into better alignment with other IPv6
       standards-track documents

     - Added applicability statement

   changes from version 01 to version 02:

     - Cleaned up text and tightened up terminology. Changed "IPv6 destination
       address" to "IPv6 next-hop address" under "sending rules". Changed
       definition of ISATAP prefix to include link and site-local. Changed
       language in sections 4 and 5


   changes from version 00 to version 01:

     - Revised draft to require different /64 prefixes for ISATAP
       addresses and native IPv6 addresses. Thus, a node's ISATAP
       interface is assigned a /64 prefix that is distinct from the
       prefixes assigned to any other interfaces attached to the
       node - be they physical or logical interfaces. This approach
       eliminates ISATAP-specific sending rules presented in earlier
       draft versions.

     - Changed sense of 'u/l' bit in the ISATAP address interface
       identifier to indicate "local scope", since ISATAP interface
       identifiers are unique only within the scope of the ISATAP
       prefix. (See section 4.)

   changes from personal draft to version 00:

     - Title change to provide higher-level description of field of
       use addressed by this draft. Removed other extraneous text.

     - Major new section on automatic discovery of off-link IPv6 routers
       when IPv6-IPv4 compatibility addresses are used.

APPENDIX B: Rationale for Interface Identifier Construction Rules

   ISATAP specifies an [EUI64]-format address construction for the Orga-
   nizationally-Unique Identifier (OUI) owned by the Internet Assigned
   Numbers Authority [IANA]. This format (given below) is used to con-
   struct both native [EUI64] addresses for general use and modified
   EUI-64 format interface identifiers for use in IPv6 unicast
   addresses:







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    |0                      2|2      3|3      3|4                      6|
    |0                      3|4      1|2      9|0                      3|
    +------------------------+--------+--------+------------------------+
    |  OUI ("00-00-5E"+u+g)  |  TYPE  |  TSE   |          TSD           |
    +------------------------+--------+--------+------------------------+

   Where the fields are:

      OUI     IANA's OUI: 00-00-5E with 'u' and 'g' bits (3 octets)

      TYPE    Type field; specifies interpretation of (TSE, TSD) (1 octet)

      TSE     Type-Specific Extension (1 octet)

      TSD     Type-Specific Data (3 octets)

   And the following interpretations are specified based on TYPE:

      TYPE         (TSE, TSD) Interpretation
      ----         -------------------------
      0x00-0xFD    RESERVED for future IANA use
      0xFE         (TSE, TSD) together contain an embedded IPv4 address
      0xFF         TSD is interpreted based on TSE as follows:

                   TSE          TSD Interpretation
                   ---          ------------------
                   0x00-0xFD    RESERVED for future IANA use
                   0xFE         TSD contains 24-bit EUI-48 intf id
                   0xFF         RESERVED by IEEE/RAC

   Thus, if TYPE=0xFE, TSE is an extension of TSD. If TYPE=0xFF, TSE is
   an extension of TYPE. Other values for TYPE (hence, other interpreta-
   tions of TSE, TSD) are reserved for future IANA use.

   The above specification is compatible with all aspects of [EUI64],
   including support for encapsulating legacy EUI-48 interface identi-
   fiers (e.g., an IANA EUI-48 format multicast address such as:
   '01-00-5E-01-02-03' is encapsulated as: '01-00-5E-FF-FE-01-02-03').
   But, the specification also provides a special TYPE (0xFE) to indi-
   cate an IPv4 address is embedded. Thus, when the first four octets of
   a [ADDR]-compatible IPv6 interface identifier are: '00-00-5E-FE'
   (note: the 'u/l' bit MUST be 0) the interface identifier is said to
   be in "ISATAP format" and the next four octets embed an IPv4 address
   encoded in network byte order.

INTELLECTUAL PROPERTY

   SRI International has notified the IETF of IPR considerations for



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   some aspects of this specification. For more information consult the
   online list of claimed rights.

















































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