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INTERNET-DRAFT                                          Laurent Toutain
NGTRANS Tools Working Group                             Hossam Afifi
December 18,1998                                        ENST Bretagne
expires in 6 month

      Dynamic Tunneling: A new method for the IPv4-IPv6 Transition
                    <draft-ietf-ngtrans-dti-00.txt>

Status of this Memo

   This document is an Internet-Draft.  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.

   To view the entire list of current Internet-Drafts, please check the
   1id-abstracts.txt listing contained in the Internet-Drafts Shadow
   Directories on ftp.is.co.za (Africa), ftp.nordu.net (Europe),
   munnari.oz.au (Pacific Rim), ds.internic.net (US East Coast), or
   ftp.isi.edu (US West Coast).

Abstract

   We propose to use an IPv6 tunneling mechanism and encapsulate IPv4
   packets into IPv6 packets. This eases the transition and routers do
   not need to support IPv6 and IPv4 routing tables. The IN_ADDR.arpa
   domain is used to find IPv4 to IPv6 correspondence in a way that does
   not prevent the asymmetrical routing and multi-homing.

   The model also simplifies IPv4 address management since the address
   has no more a localization function but only an identification
   function.

1. Introduction

   The co-existence of IPv6 with IPv4 will be a temporary phase before a
   progressive transition to the IPv6 protocol even if no limit has been
   set for the transition period. The first phase in the transition was
   to install new IPv6 subnetworks connected by tunneling justified by
   the relatively small number of IPv6 networks compared to the global
   internet.

   The goal of this work is to propose a simple and flexible



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   interconnection mechanism where IPv6 and IPv4 networks can be
   separated, but where IPv6 and IPv4 applications can transparently
   exchange information. This gives the opportunity to use IPv6 in
   combination with other protocols for a more flexible routing.

   The next section   introduces native IPv6 networks and hosts and
   places the study in its context. First we describe the model we
   choose to study. We analyze current transitions propositions. In a
   second part we describe the proposal. We cover the cases where
   connections are initiated from the IPv6 and from IPv4 sides
   respectively.


2. Transition Model

   In our view a general model describing the transition period is
   depicted in figure 1. We consider a domain running mostly IPv6 but
   where some IPv4 equipments or applications still remain used. This
   domain is connected to an IPv6-only provider. Somewhere on the
   network a third party provider is able to link the IPv4 and IPv6
   domains. We solve the case where IPv6 equipment must talk with
   equipment in IPv4-only domains and vice versa. We suppose that no
   change can be made to the IPv4-only equipment and applications. The
   transition mechanism must be as transparent as possible to keep the
   advantages of the IPv6 autoconfigation.

        +------+    +-----+    +-----+    +-----+    +-----+
        | DNS  |....| DNS |....| DNS |....| DNS |....| DNS |
        |  v6  |    |     |    |     |    |     |    |  v4 |
        +------+    +-----+    +-----+    +-----+    ------+

        +---------------+    +-----------+    +------------+
        |               |....|dti-tunnel |....|            |
        |               |    |provider y |    |            |
        |               |    +-----------+    |            |
        |               |                     |            |
        |     IPv6      |                     | ipv4-only  |
        |     network   |    +-----------+    | network    |
        |               |....|dti-tunnel |....|            |
        |               |    |provider x |    |            |
        +---------------+    +-----------+    +------------+


   A DNS is running on each domain. Queries to the DNS are done in the
   respective native protocol (we suppose that they are interconnected
   but the way of interconnection is beyond the scope of this draft).

2.1 The double stack



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   [RFC 1933] defines a transition mechanism based on a double stack. A
   host will either send packets in IPv4 or IPv6 depending on the
   protocol used by the destination. The IPv4 mapped addresses allow
   applications compiled with IPv6 system calls to talk with IPv4 only
   applications.

   This method is currently used in the early phase of the transition.
   The main drawbacks are the following. An IPv4 address must be
   allocated to each equipment. If we map this onto our transition model
   previously described, it means that the IPv6 domain is included in
   the IPv4 world. Routers must be configured for the two protocols and
   IPv4 applications must be slightly modified and recompiled to be
   adapted to the IPv6 API.

2.2 The SIIT proposal

   This proposal is similar to Network Address Translation (explained
   later), used in IPv4 networks to exchange a private IPv4 address to a
   public IPv4 address. It is difficult with the SIIT proposal to deal
   with applications sending addresses (such as FTP or RTP flows). In
   that case, some Application Level Gateways acting as proxy will be
   required. The proposal focuses on separate IPv6 and IPv4 domains. If
   in the IPv6 domain some equipment wants to talk with an IPv4 domain,
   it will use an automatic IPv4 address allocation of the double stack.
   In that case, routers will have to administrate IPv4 and IPv6 routing
   tables.

   Like NAT (described hereafter), this is a one way translation. It
   means that outside IPv6 domains, IPv4 applications cannot initiate
   communications with IPv6 hosts. The context for header translation in
   the SIIT box can be established only when an exiting IPv6 packet
   leaves the domain.

2.3 The NATPT Proposal

   Unlike SIIT [SIIT], NAT-PT is designed to provide transparently end-
   to-end  solutions. A pool of IPv4 addresses is used to be assigned to
   IPv6 hosts dynamically in response to any request for packets leaving
   one of the boundaries. These assigned addresses in turn are used to
   transparently replace the original addresses used by IPv6 end nodes
   and vice versa. This proposal allows translation in both ways since
   the context inside the transition box is this time established by the
   DNS.

   NATPT does not solve the problem of applications sending IP addresses
   in the payload. DNS and NATPT must be combined to allow the
   establishment of the context. This is generally not the case if the
   translation is not directly made by the IPv6 domain. The DNS request



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   may follow another path that does not go through the third party
   provider assuring the transition.

2.4 The AIIH Proposal

   The AIIH proposal aims at using a combination of DHCPv6 and the DNS
   to establish a transition between IPv6 and v4 in both directions.
   This proposal is complementary to the NAT -PT and SIIT since it
   focuses on topology where IPv4 and IPv6 are in the same domains.

    For an IPv6 host to participate in the AIIH mechanism, it MUST have
   a dual IP layer, supporting both an IPv4 and IPv6 stack. When an IPv6
   host wants to talk with an IPv4 one, the DNS will not answer with an
   IPv6 record but with an IPv4 one. The IPv6 will request a temporary
   IPv4 address. Mechanisms such as DHCP are currently available to do
   such assignment. The opposite case, where an IPv4 host wants to talk
   with a IPv6 host is more difficult to solve since no protocol is
   currently available to do a automatic assignation.

   In our view, there are two main drawbacks in this proposal. The
   router must be configured both for IPv4 and IPv6 protocol and the
   assignment of IPv4 addresses is difficult since the network topology
   must be taken into account.

3. The Dynamic Tunneling Interface

   In the IPv6 case networks are largely spread, we propose to reverse
   the tunneling and encapsulate IPv4 packet into IPv6 packets. This
   would ease the transition since routers need only to be configured
   with IPv6 routing tables. The case of dynamic attribution of IPv4
   addresses will also be simplified since the address has no longer a
   localization function but only an identification function. The system
   has just to maintain uniqueness of the address allocation.

   We think this method can be used either in domains where IPv4
   applications cannot be recompiled, but where the system stack can be
   changed to take benefit from an IPv6 network or with IPv4 only legacy
   equipment. We will explain later scenarios where an IPv4 only domain
   wants to join an IPv6 equipment.

3.1 IPv6 to IPv4

   We start describing the general procedure for an IPv6 host to
   communicate with an IPv4 only application. From our assumptions we
   suppose that the IPv6 equipment MUST support a dual stack.


   When an equipment wants to join an IPv4 host, it may directly use an



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   IPv4 address or resolve a domain name from the DNS and obtain the
   correspondent IPv4 destination address.

   We propose to intercept the packet in a new interface that we call
   dti for dynamic tunneling interface. It may be intercepted by the
   host through the IPv4 routing table lookup or through dynamic network
   libraries hookups but this is implementation dependent. We try hence
   to offer transparently the dti functionalities with no changes in the
   applications. The main difference with AIIH is that IPv4 packets will
   not be directly sent over the network but first filtered by the dti.

   The dti interface systematically encapsulates the IPv4 packet into an
   IPv6 packet. It needs to find the destination IPv6 address and also
   needs to obtain for itself an IPv4 address. We propose to use the DNS
   to make this resolution. The procedure is explained later. Once a
   result is obtained, it should be cached after the first resolution.
   There are many possible results for this IPv6 resolution.

   - The destination has an IPv6 address.

   - It has only an IPv4 address.

   In the first case, the dti returns an IPv6 destination address. It is
   possible to establish an end-to-end tunnel and there is no need to
   obtain a global IPv4 address. If the dti has not yet a local address
   it will configure the IPv4 stack and use the address in the
   encapsulation. The local IPv4 address should be de-allocated after a
   certain idle time.

   In case of an IPv4-only destination equipment, we propose to
   implement tunneling boxes inside the network that we call dti-
   tunnels. These boxes should be as close as possible to IPv4 resources
   to reduce routing of native IPv4 packets. They can also be located on
   a third party provider network if no possible internetworking between
   IPv6 and IPv4 can be achieved in the local domain. The dti must
   obtain a dti-tunnel IPv6 address. This may be statically configured
   in each dual stack host. It could be obtained as mentioned in AIIH
   proposal by means of a RR record in the destination domain name (we
   propose to add in the DNS a new entry for NGTRANS-TUNNELING) or via
   more advanced methods like NHRP.

   The dti sends a DHCP(v4) query to the dti-tunnel encapsulated in
   IPv6. The dti-tunnel assigns an IPv4 address to the dti. In the
   general case, the assignment can be static through an IPv4 pool of
   addresses in the dti-tunnel. The dti-tunnel can act as forwarder and
   obtain dynamically an IPv4 address through a conventional DHCP(v4)
   procedure.




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   The dti is now able to send the packets to the dti-tunnel that
   decapsulates the IPv6 header and sends them to the destination
   through IPv4 network. The procedure is hence quite similar to NAT but
   does not need any address translation at boundaries.

3.2 DNS Resolution in the dti

   The dti queries the DNS when a packet is received from an IPv4
   application to the dual stack. A query to the IN_ADDR.arpa domain is
   sent to obtain the original destination domain name. This is the main
   contribution in the dti tunneling model. Once this is achieved a
   second query is sent to the DNS for the resolution of an AAAA type
   address. If an answer is obtained a direct tunnel can be established.
   Otherwise, the dti may, as it is mentioned in the AIIH proposal look
   for a RR record with the AAAA type to be used as the dti-tunnel. The
   dti proceeds as explained before.

   During the name resolution the dti should check whether the
   destination is located on the local intranet or not. If it is in the
   same domain as the origin then the dti should use a local dti-tunnel.
   We illustrate the DNS procedure by an example: the dti receives a
   packet to be sent over IPv4 to the destination 192.44.77.131. It will
   make a query to the DNS asking for qtype=ptr. The query itself will
   look like:

   131.77.44.192.in-addr.arpa.

   and the answer :

   131.77.44.192.in-addr.arpa    name = abc.xyz.com.

   This entry describing the host abc will give more information on its
   addresses and tell whether there is an IPv6 address for the host. The
   final answer if there is an IPv6 address will be:

   abc                             IN      A       192.44.77.131
                                   IN      AAAA
   3ffe:0305:1002:0001:0a00:2bff:fe1c:b0df

4. IPv4 to IPv6

   We present the second part of the dti model where an IPv4 only
   equipment needs to reach an IPv6 only one.

   If the IPv4 host has already an IPv4 global address to the
   destination it will send the packet through the normal routing
   procedures. Once the packet arrives to any dti-tunnel equipment the
   same DNS resolution as in the dti case (section 3.2) should be done.



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   We try to find an IPv6 address for the IPv4 destination by consulting
   the IN_ADDR.arpa domain and once it is obtained we encapsulate the
   packet in IPv6 and send it to the destination.

   If the IPv4 only host sends a DNS query to resolve the destination
   domain name into an IPv4 address the query may succeed and nothing
   more is needed from the dti model. The packet will be sent using IPv4
   and will arrive to the dti-tunnel as previously described. If however
   the resolver fails to locate an IPv4 address for the requested domain
   name we use the dti model to execute an additional procedure instead
   of returning the name-error to the IPv4 application. The dti will
   make a second query for the same domain name asking this time for an
   IPv6 address resolution. If there is no IPv6 available then the
   resolver will return a name error.

   If however an IPv6 address is found for the requested domain name the
   resolver library should trigger a special dti procedure for the
   tunneling. This is explained in the next paragraph.

IPv4 to IPv6 tunneling

   The resolver must have a pre-configured dti-tunnel IPv4 address for
   its domain. It should send a query to this equipment asking to assign
   an IPv4 address to the IPv6 destination. The dti-tunnel obtains an
   IPv4 address from a local pool or using DHCPv4. It remotely
   configures the IPv4 destination stack and updates the in_addr.arpa
   domain name with a pointer entry to the IPv6 host. Since the
   destination may be multi-homed, it is also necessary to update the
   destination DNS database with the new IPv4 address. We present
   hereafter a solution to avoid the need to update the destination
   domain name. Note also that all these procedure will use time to live
   fields that will protect the system from any malicious attack trying
   to consume all IPv4 available addresses in a site. The following
   example traces the steps in the IPv4/IPv6 direction.

   The resolver intercepts a query to lmn.xyz.com asking for an IPv4
   address (A type query). The query fails and the resolver asks again
   for an IPv6 address. This time the query succeeds and an IPv6 address
   is returned. The resolver sends a special query to its pre-configured
   dti-tunnel asking for the assignment of an IPv4 address to the
   lmn.xyz.com destination. The dti-tunnel makes a DHCPv4 query and
   obtains the required address (192.108.119.33 for example). It should
   use a special procedure to configure (lmn.xyz.com) with the new
   address and update its own DNS:

   33.119.108.192.in-addr.arpa    name = lmn.xyz.com.

   In case the dti-tunnel uses an additional DHCP(v4) feature that



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   enables to remotely configure the destination dual stack with the
   newly assigned IPv4 address, it returns the IPv4 address to the
   resolver and stops. If however a different procedure is used to
   configure the remote destination host with the IPv4 address another
   DNS update in the destination domain will also be needed:

   lmn                     IN      A 192.119.108.33
                                   AAAA
   3ffe:0305:1002:0001:0a00:2bff:fe1c:b099

   Any dti-tunnel that will receive the packet will be able to find the
   IPv6 address and establish the tunnel by consulting the destination
   domain name. Again if the use of a DHCPv4 server driven procedure is
   adopted then when a different dti-tunnel receives an IPv4 assignment
   request for the IPv6 host it will try to configure remotely the
   destination stack through DHCPv4. If an address is already assigned
   for that host then the DHCPv4 configuration will fail and the current
   IPv4 destination address will be returned in the error message (see
   section 5). The dti-tunnel will return the address to the resolver
   and the communication will start.

   The usage of a new server driven DHCPv4 request will improve the
   security environment since the dti-tunnel will not need to update the
   destination domain name.

4.1 Path MTU

   When packets are sent to the dti-tunnel the header length may change
   the link MTU. This can be either detected by the PMTU detection or if
   necessary by means of the IPv6 fragmentation extension.

5. Required Additional Features

   The dti model will require some additional protocol features. Note
   that most of them are also required in the AIIH proposal.

   In the reverse direction (from IPv4 to IPv6) two new procedures are
   required. The dti resolver needs to send a query to the dti-tunnel
   asking for the assignment of an IPv4 address. The dti-tunnel has to
   remotely configure the destination IPv4 stack with a new address.
   This whole procedure could be done by the DHCPv4 protocol if an
   additional feature enables the DHCPv4 server to initiate an IPv4
   assignment procedure without a previous solicitation from the client.

   An additional entry in the DNS for ipv4/ipv6 capability tunnel would
   also be very useful (for all the proposals) in order to find for each
   domain the closest tunneling equipment.




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6. Bibliography

   [AIIH] J. Bound. Assignment of IPv4 Global Addresses to IPv6 Hosts
   (AIIH). <draft-ietf-ngtrans-assgn-ipv4-addrs-00.txt> Expired.

   [SIIT] E. Nordmark,Stateless    IP/ICMP     Translator (SIIT),
   <draft-ietf-ngtrans-siit-02.txt>, Work in progress, November 1998.

   [NAT] G. Tsirtsis, P. Srishuresh. Network Address Translation -
   Protocol Translation (NAT-PT). <draft-ietf-ngtrans-natpt-03.txt>.

7. Authors Addresses

           Laurent Toutain         Hossam
   Afifi                                                      ENST
   Bretagne         2 rue de la chataigneraie         BP 78
           35512 Cesson Sevigne             {toutain,
   afifi}@rennes.enst-bretagne.fr         Tel: (+33) 2 99 12 70 20 -
   Fax: (+33) 2 99 12 70 30
































Toutain & Afifi                                                 [Page 9]


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