draft-ietf-dmm-pmipv6-dlif-00.xml

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<rfc category="std" docName="draft-ietf-dmm-pmipv6-dlif-00">
  <front>
    <title abbrev="PMIPv6 DMM and DLIF">Proxy Mobile IPv6 extensions for Distributed Mobility Management</title>

    <!-- AUTHORS -->

    <author fullname="Carlos J. Bernardos" initials="CJ." surname="Bernardos">
      <organization abbrev="UC3M">Universidad Carlos III de
      Madrid</organization>
      <address>
        <postal>
          <street>Av. Universidad, 30</street>
          <city>Leganes, Madrid</city>
          <code>28911</code>
          <country>Spain</country>
        </postal>
        <phone>+34 91624 6236</phone>
        <email>cjbc@it.uc3m.es</email>
        <uri>http://www.it.uc3m.es/cjbc/</uri>
      </address>
    </author>

    <author fullname="Antonio de la Oliva" initials="A." surname="de la Oliva">
      <organization abbrev="UC3M">Universidad Carlos III de
      Madrid</organization>
      <address>
        <postal>
          <street>Av. Universidad, 30</street>
          <city>Leganes, Madrid</city>
          <code>28911</code>
          <country>Spain</country>
        </postal>
        <phone>+34 91624 8803</phone>
        <email>aoliva@it.uc3m.es</email>
        <uri>http://www.it.uc3m.es/aoliva/</uri>
      </address>
    </author>

    <author fullname="Fabio Giust" initials="F." surname="Giust">
     <organization abbrev="NEC">NEC Laboratories Europe</organization>
      <address>
        <postal>
          <street>NEC Europe Ltd.</street>
          <street>Kurfuersten-Anlage 36</street>
          <city>Heidelberg</city>
          <code>D-69115</code>
          <country>Germany</country>
        </postal>
        <phone>+49 6221 4342216</phone>
        <email>fabio.giust@neclab.eu</email>
      </address>
    </author>    

    <author fullname="Juan Carlos Zuniga"
            initials="JC."
            surname="Zuniga">
      <organization abbrev="SIGFOX">
        SIGFOX
      </organization>
      <address>
        <postal>
          <street>425 rue Jean Rostand</street>
          <city>Labege</city>
          <code> 31670</code>
          <country>France</country>
        </postal>
        <email>j.c.zuniga@ieee.org</email>
        <uri>http://www.sigfox.com/</uri>
      </address>
    </author>

    <author fullname="Alain Mourad"
            initials="A."
            surname="Mourad">
      <organization abbrev="InterDigital">
        InterDigital Europe
      </organization>
      <address>
        <email>Alain.Mourad@InterDigital.com</email>
        <uri>http://www.InterDigital.com/</uri>
      </address>
    </author>

    <date month="April" year="2018" />

    <area>Internet</area>

    <workgroup>DMM Working Group</workgroup>

    <abstract>

      <t>
Distributed Mobility Management solutions allow for setting up networks so that
traffic is distributed in an optimal way and does not rely on centralized
deployed anchors to provide IP mobility support.
      </t>

      <t>
There are many different approaches to address Distributed Mobility Management,
as for example extending network-based mobility protocols (like Proxy Mobile
IPv6), or client-based mobility protocols (as Mobile IPv6), among others. This
document follows the former approach, and proposes a solution based on Proxy
Mobile IPv6 in which mobility sessions are anchored at the last IP hop router
(called mobility anchor and access router). The mobility anchor and access
router is an enhanced access router which is also able to operate as local
mobility anchor or mobility access gateway, on a per prefix basis. The document
focuses on the required extensions to effectively support simultaneously
anchoring several flows at different distributed gateways.
      </t>

      <t>
This document introduces the concept of distributed logical interface, which is
a software construct that allows to easily hide the change of anchor from the
mobile node.
      </t>

    </abstract>

    <note title="Requirements Language">

      <t>
      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 <xref
      target="RFC2119">RFC 2119</xref>.
      </t> 

    </note>

  </front>

  <middle>
    <section anchor="sec:introduction" title="Introduction">

      <t>
The Distributed Mobility Management (DMM) paradigm aims at minimizing the
impact of currently standardized mobility management solutions, which are
centralized (at least to a considerable extent).
      </t>

      <t>
Current IP mobility solutions, standardized with the names of Mobile IPv6 <xref
target="RFC6275"></xref>, or Proxy Mobile IPv6 <xref target="RFC5213"></xref>,
just to cite the two most relevant examples, offer mobility support at the cost
of handling operations at a cardinal point, the mobility anchor, and burdening
it with data forwarding and control mechanisms for a great amount of users. As
stated in <xref target="RFC7333"></xref>, centralized mobility solutions are
prone to several problems and limitations: longer (sub-optimal) routing paths,
scalability problems, signaling overhead (and most likely a longer associated
handover latency), more complex network deployment, higher vulnerability due to
the existence of a potential single point of failure, and lack of granularity on
the mobility management service (i.e., mobility is offered on a per-node basis,
not being possible to define finer granularity policies, as for example
per-application).
      </t>

      <t>
The purpose of Distributed Mobility Management is to overcome the limitations of
the traditional centralized mobility management <xref target="RFC7333" /> <xref
target="RFC7429" />; the main concept behind DMM solutions is indeed
bringing the mobility anchor closer to the MN. Following this idea, in our
proposal, the central anchor is moved to the edge of the network, being deployed
in the default gateway of the mobile node. That is, the first elements that
provide IP connectivity to a set of MNs are also the mobility managers for those
MNs. In the following, we will call these entities Mobility Anchor and Access
Routers (MAARs).
      </t>

      <t>
This document focuses on network-based DMM, hence the starting point is making
PMIPv6 working in a distributed manner <xref target="RFC7429"></xref>. Mobility
is handled by the network without the MNs involvement, but, differently from
PMIPv6, when the MN moves from one access network to another, it also changes
anchor router, hence requiring signaling between the anchors to retrieve the
MN's previous location(s). Also, a key-aspect of network-based DMM, is that a
prefix pool belongs exclusively to each MAAR, in the sense that those prefixes
are assigned by the MAAR to the MNs attached to it, and they are routable at
that MAAR.
      </t>

      <t>
We consider partially distributed schemes, where the data plane only is
distributed among access routers similar to MAGs, whereas the control plane is
kept centralized towards a cardinal node used as information store, but relieved
from any route management and MN's data forwarding task.
      </t>

    </section>

    <section anchor="sec:terminology" title="Terminology">

      <t>
The following terms used in this document are defined in the Proxy Mobile IPv6
specification <xref target="RFC5213" />:

        <list style="empty">
          <t>Local Mobility Anchor (LMA)</t>

          <t>Mobile Access Gateway (MAG)</t>

          <t>Mobile Node (MN)</t>

          <t>Binding Cache Entry (BCE)</t>

          <t>Proxy Care-of Address (P-CoA)</t>

          <t>Proxy Binding Update (PBU)</t>

          <t>Proxy Binding Acknowledgement (PBA)</t>
        </list>
      </t>

      <t>
The following terms used in this document are defined in the DMM Deployment
Models and Architectural Considerations document <xref
target="I-D.ietf-dmm-deployment-models" />:

        <list style="empty">
          <t>Home Control-Plane Anchor (H-CPA)</t>

          <t>Home Data Plane Anchor (Home-DPA)</t>

          <t>Access Control Plane Node (Access-CPN)</t>

          <t>Access Data Plane Node (Access-DPN)</t>
        </list>
      </t>

      <t>
The following terms are defined and used in this document:
        <list style="hanging">

          <t hangText="MAAR (Mobility Anchor and Access Router).">
First hop router where the mobile nodes attach to. It also plays the role of
mobility manager for the IPv6 prefixes it anchors, running the functionalities
of PMIP's MAG and LMA. Depending on the prefix, it plays the role of Access-DPN,
Home-DPA and Access-CPN.
          </t>

          <t hangText="CMD (Central Mobility Database).">
Node that stores the BCEs allocated for the MNs in the mobility domain. It plays
the role of Home-CPA.
          </t>

          <t hangText="P-MAAR (Previous MAAR).">
MAAR which was previously visited by the MN and is still involved in an active
flow using an IPv6 prefix it has advertised to the MN (i.e., MAAR where that
IPv6 prefix is anchored). There might be multiple P-MAARs for an MN's mobility
session. It plays the role of Home-DPA.
          </t>

          <t hangText="S-MAAR (Serving MAAR).">
MAAR which the MN is currently attached to. Depending on the prefix, it plays
the role of Access-DPN, Home-DPA and Access-CPN.
          </t>

          <t hangText="DLIF (Distributed Logical Interface).">
It is a logical interface at the IP stack of the MAAR. For each active prefix
used by the mobile node, the serving MAAR has a DLIF configured (associated to
the anchoring MAAR). In this way, a serving MAAR exposes itself towards each MN
as multiple routers, one per active anchoring MAAR.
          </t>

        </list>
      </t>

    </section>

    <section anchor="sec:pmipv6_based" title="PMIPv6 DMM extenstions">

      <t>
The solution consists in de-coupling the entities that participates in the data
and the control planes: the data plane becomes distributed and managed by the
MAARs near the edge of the network, while the control plane, besides on the
MAARs, relies on a central entity called Central Mobility Database (CMD). In the
proposed architecture, the hierarchy present in PMIPv6 between LMA and MAG is
preserved, but with the following substantial variations:

        <list style="symbols">

          <t>
The LMA is relieved from the data forwarding role, only the Binding Cache and
its management operations are maintained. Hence the LMA is renamed into Central
Mobility Database (CMD), which is therefore a Home-CPA. Also, the CMD is able to
send and parse both PBU and PBA messages.
          </t>

          <t>
The MAG is enriched with the LMA functionalities, hence the name Mobility Anchor
and Access Router (MAAR). It maintains a local Binding Cache for the MNs that
are attached to it and it is able to send and parse PBU and PBA messages.
          </t>

          <t>
The binding cache will have to be extended to include information regarding
previous MAARs where the mobile node was anchored and still retains active data
sessions, see <xref target="sec:appx2"></xref> for further details.
          </t>

          <t>
Each MAAR has a unique set of global prefixes (which are configurable), that can
be allocated by the MAAR to the MNs, but must be exclusive to that MAAR, i.e. no
other MAAR can allocate the same prefixes.
          </t>

        </list>

      </t>

      <t>
The MAARs leverage on the Central Mobility Database (CMD) to access and update
information related to the MNs, stored as mobility sessions; hence, a
centralized node maintains a global view on the status of the network. The CMD
is queried whenever a MN is detected to join/leave the mobility domain. It might
be a fresh attachment, a detachment or a handover, but as MAARs are not aware of
past information related to a mobility session, they contact the CMD to retrieve
the data of interest and eventually take the appropriate action. The procedure
adopted for the query and the messages exchange sequence might vary to optimize
the update latency and/or the signaling overhead. Here is presented one method
for the initial registration, and three different approaches to update the
mobility sessions using PBUs and PBAs. Each approach assigns a different role to
the CMD:

        <list style="symbols">

          <t>The CMD is a PBU/PBA relay;</t>

          <t>The CMD is only a MAAR locator;</t>

          <t>The CMD is a PBU/PBA proxy.</t>

        </list>

      </t>

      <t>
This solution can be categorized under Model-1: Split Home Anchor Mode in <xref
target="I-D.ietf-dmm-deployment-models" />. As another note, the solution
described in this document allows performing per-prefix anchoring decisions, to
support e.g., some flows to be anchored at a central Home-DPA (like a
traditional LMA) or to enable an application to switch to the locally anchored
prefix to gain route optimization, as indicated in <xref
target="I-D.ietf-dmm-ondemand-mobility" />.
      </t>


      <section anchor="subsec:init" title="Initial registration">

        <t>
Upon the MN's attachment to a MAAR, say MAAR1, if the MN is authorized for the
service, an IPv6 global prefix belonging to the MAAR's prefix pool is reserved
for it (Pref1) into a temporal Binding Cache Entry (BCE) allocated locally. The
prefix is sent in a <xref target="RFC5213" /> PBU with the MN's Identifier
(MN-ID) to the CMD, which, since the session is new, stores a permanent BCE
containing as main fields the MN-ID, the MN's prefix and MAAR1's address as
Proxy-CoA. The CMD replies to MAAR1 with a PBA including the usual options
defined in PMIP/RFC5213, meaning that the MN's registration is fresh and no past
status is available. MAAR1 definitely stores the temporal BCE previously
allocated and unicasts a Router Advertisement (RA) to the MN including the
prefix reserved before, that can be used by the MN to configure an IPv6 address
(e.g., with stateless auto-configuration). The address is routable at the MAAR,
in the sense that it is on the path of packets addressed to the MN. Moreover,
the MAAR acts as plain router for those packets, as no encapsulation nor special
handling takes place. <xref target="fig:DMM_1" /> illustrates this scenario.
        </t>

        <figure anchor="fig:DMM_1" title="First attachment to the network">
          <artwork><![CDATA[
  +-----+      +---+                +--+
  |MAAR1|      |CMD|                |CN|
  +-----+      +---+                +*-+
     |           |                   *
    MN           |                   *     +---+
  attach.        |               *****    _|CMD|_
detection        |         flow1 *       / +-+-+ \
     |           |               *      /    |    \
 local BCE       |               *     /     |     \
 allocation      |               *    /      |      \
     |--- PBU -->|           +---*-+-'    +--+--+    `+-----+
     |          BCE          |   * |      |     |     |     |
     |        creation       |MAAR1+------+MAAR2+-----+MAAR3|
     |<-- PBA ---|           |   * |      |     |     |     |
 local BCE       |           +---*-+      +-----+     +-----+
 finalized       |               *
     |           |         Pref1 *
     |           |              +*-+
     |           |              |MN|
     |           |              +--+
                                                            
  Operations sequence                  Packets flow
]]></artwork>
        </figure>
      </section>

      <section anchor="subsec:relay" title="The CMD as PBU/PBA relay">

        <t>
When the MN moves from its current access and associates to MAAR2 (now the
S-MAAR), MAAR2 reserves another IPv6 prefix (Pref2), it stores a temporal BCE,
and it sends a plain PBU to the CMD for registration. Upon PBU reception and BC
lookup, the CMD retrieves an already existing entry for the MN, binding the
MN-ID to its former location; thus, the CMD forwards the PBU to the MAAR
indicated as Proxy CoA (MAAR1), including a new mobility option to communicate
the S-MAAR's global address to MAAR1, defined as Serving MAAR Option in <xref
target="subsec:smaaropt" />. The CMD updates the P-CoA field in the BCE related
to the MN with the S-MAAR's address.
        </t>

        <t>
Upon PBU reception, MAAR1 can install a tunnel on its side towards MAAR2 and the
related routes for Pref1. Then MAAR1 replies to the CMD with a PBA (including
the option mentioned before) to ensure that the new location has successfully
changed, containing the prefix anchored at MAAR1 in the Home Network Prefix
option. The CMD, after receiving the PBA, updates the BCE populating an instance
of the P-MAAR list. The P-MAAR list is an additional field on the BCE that
contains an element for each P-MAAR involved in the MN's mobility session. The
list element contains the P-MAAR's global address and the prefix it has
delegated (see <xref target="sec:appx2"></xref> for further details). Also, the
CMD send a PBA to the new S-MAAR, containing the previous Proxy-CoA and the
prefix anchored to it embedded into a new mobility option called Previous MAAR
Option (defined in <xref target="subsec:pmaaropt"></xref>), so that, upon PBA
arrival, a bi-directional tunnel can be established between the two MAARs and
new routes are set appropriately to recover the IP flow(s) carrying Pref1.
        </t>

        <t>
Now packets destined to Pref1 are first received by MAAR1, encapsulated into the
tunnel and forwarded to MAAR2, which finally delivers them to their destination.
In uplink, when the MN transmits packets using Pref1 as source address, they are
sent to MAAR2, as it is MN's new default gateway, then tunneled to MAAR1 which
routes them towards the next hop to destination. Conversely, packets carrying
Pref2 are routed by MAAR2 without any special packet handling both for uplink
and downlink. The procedure is depicted in <xref target="fig:DMM2" />.
</t>

        <figure anchor="fig:DMM2"
                title="Scenario after a handover, CMD as relay">
          <artwork><![CDATA[
+-----+      +---+      +-----+           +--+            +--+
|MAAR1|      |CMD|      |MAAR2|           |CN|            |CN|
+-----+      +---+      +-----+           +*-+            +*-+
   |           |           |               *               *
   |           |          MN               *     +---+     *
   |           |        attach.        *****    _|CMD|_    *
   |           |          det.   flow1 *       / +-+-+ \   *flow2
   |           |<-- PBU ---|           *      /    |    \  *
   |          BCE          |           *     /     | *******
   |        check+         |           *    /      | *    \
   |        update         |       +---*-+-?    +--+-*+    `+-----+
   |<-- PBU*---|           |       |   * |      |    *|     |     |
route          |           |       |MAAR1|______|MAAR2+-----+MAAR3|
update         |           |       |   **(______)**  *|     |     |
   |--- PBA*-->|           |       +-----+      +-*--*+     +-----+
   |         BCE           |                      *  *
   |        update         |                Pref1 *  *Pref2
   |           |--- PBA*-->|                     +*--*+
   |           |         route         ---move-->|*MN*|
   |           |         update                  +----+

      Operations sequence                  Data Packets flow
PBU/PBA Messages with * contain
        a new mobility option
]]></artwork>
        </figure>

        <t>
For next MN's movements the process is repeated except for the number of P-MAARs
involved, that rises accordingly to the number of prefixes that the MN wishes to
maintain. Indeed, once the CMD receives the first PBU from the new S-MAAR, it
forwards copies of the PBU to all the P-MAARs indicated in the BCE as current
P-CoA (i.e., the MAAR prior to handover) and in the P-MAARs list. They reply
with a PBA to the CMD, which aggregates them into a single one to notify the
S-MAAR, that finally can establish the tunnels with the P-MAARs.
        </t>

        <t>
It should be noted that this design separates the mobility management at the
prefix granularity, and it can be tuned in order to erase old mobility sessions
when not required, while the MN is reachable through the latest prefix acquired.
Moreover, the latency associated to the mobility update is bound to the PBA sent
by the furthest P-MAAR, in terms of RTT, that takes the longest time to reach
the CMD. The drawback can be mitigated introducing a timeout at the CMD, by
which, after its expiration, all the PBAs so far collected are transmitted, and
the remaining are sent later upon their arrival.
        </t>

      </section>

      <section anchor="subsec:locator" title="The CMD as MAAR locator">

        <t>
The handover latency experienced in the approach shown before can be reduced if
the P-MAARs are allowed to signal directly their information to the new S-MAAR.
This procedure reflect what was described in <xref target="subsec:relay" /> up
to the moment the P-MAAR receives the PBU with the P-MAAR option. At that point
a P-MAAR is aware of the new MN's location (because of the S-MAAR's address in
the S-MAAR option), and, besides sending a PBA to the CMD, it also sends a PBA
to the S-MAAR including the prefix it is anchoring. This latter PBA does not
need to include new options, as the prefix is embedded in the HNP option and the
P-MAAR's address OS taken from the message's source address. The CMD is relieved
from forwarding the PBA to the S-MAAR, as the latter receives a copy directly
from the P-MAAR with the necessary information to build the tunnels and set the
appropriate routes. In <xref target="fig:DMM3" /> is illustrated the new
messages sequence, while the data forwarding is unaltered.
        </t>

        <figure anchor="fig:DMM3"
                title="Scenario after a handover, CMD as locator">
          <artwork><![CDATA[
+-----+      +---+      +-----+           +--+            +--+
|MAAR1|      |CMD|      |MAAR2|           |CN|            |CN|
+-----+      +---+      +-----+           +*-+            +*-+
   |           |           |               *               *
   |           |          MN               *     +---+     *
   |           |        attach.        *****    _|CMD|_    *
   |           |          det.   flow1 *       / +-+-+ \   *flow2
   |           |<-- PBU ---|           *      /    |    \  *
   |          BCE          |           *     /     | *******
   |        check+         |           *    /      | *    \
   |        update         |       +---*-+-?    +--+-*+    `+-----+
   |<-- PBU*---|           |       |   * |      |    *|     |     |
route          |           |       |MAAR1|______|MAAR2+-----+MAAR3|
update         |           |       |   **(______)**  *|     |     |
   |--------- PBA -------->|       +-----+      +-*--*+     +-----+
   |--- PBA*-->|         route                    *  *
   |          BCE        update             Pref1 *  *Pref2
   |         update        |                     +*--*+
   |           |           |           ---move-->|*MN*|
   |           |           |                     +----+
                                                                    
       Operations sequence                  Data Packets flow
PBU/PBA Messages with * contain
        a new mobility option
]]></artwork>
        </figure>
      </section>

      <section anchor="subsec:proxy" title="The CMD as MAAR proxy">

        <t>
A further enhancement of previous solutions can be achieved when the CMD sends
the PBA to the new S-MAAR before notifying the P-MAARs of the location change.
Indeed, when the CMD receives the PBU for the new registration, it is already in
possess of all the information that the new S-MAAR requires to set up the
tunnels and the routes. Thus the PBA is sent to the S-MAAR immediately after a
PBU is received, including also in this case the P-MAAR option. In parallel, a
PBU is sent by the CMD to the P-MAARs containing the S-MAAR option, to notify
them about the new MN's location, so they receive the information to establish
the tunnels and routes on their side. When P-MAARs complete the update, they
send a PBA to the CMD to indicate that the operation is concluded and the
information are updated in all network nodes. This procedure is obtained from
the first one re-arranging the order of the messages, but the parameters
communicated are the same. This scheme is depicted in <xref
target="fig:DMM4"></xref>, where, again, the data forwarding is kept untouched.
        </t>

        <figure anchor="fig:DMM4"
                title="Scenario after a handover, CMD as proxy">
          <artwork><![CDATA[
+-----+      +---+      +-----+           +--+            +--+
|MAAR1|      |CMD|      |MAAR2|           |CN|            |CN|
+-----+      +---+      +-----+           +*-+            +*-+
   |           |           |               *               *
   |           |          MN               *     +---+     *
   |           |        attach.        *****    _|CMD|_    *
   |           |          det.   flow1 *       / +-+-+ \   *flow2
   |           |<-- PBU ---|           *      /    |    \  *
   |          BCE          |           *     /     | *******
   |        check+         |           *    /      | *    \
   |        update         |       +---*-+-?    +--+-*+    `+-----+
   |<-- PBU*---x--- PBA*-->|       |   * |      |    *|     |     |
route          |         route     |MAAR1|______|MAAR2+-----+MAAR3|
update         |         update    |   **(______)**  *|     |     |
   |--- PBA*-->|           |       +-----+      +-*--*+     +-----+
   |          BCE          |                      *  *
   |         update        |                Pref1 *  *Pref2
   |           |           |                     +*--*+
   |           |           |           ---move-->|*MN*|
   |           |           |                     +----+
                                                                  
       Operations sequence                 Data Packets flow
PBU/PBA Messages with * contain
        a new mobility option
]]></artwork>
        </figure>
      </section>

      <section anchor="subsec:dereg" title="De-registration">
        <t>
The de-registration mechanism devised for PMIPv6 is no longer valid in the
Partial DMM architecture. This is motivated by the fact that each MAAR handles
an independent mobility session (i.e., a single or a set of prefixes) for a
given MN, whereas the aggregated session is stored at the CMD. Indeed, when a
previous MAAR initiates a de-registration procedure, because the MN is no longer
present on the MAAR's access link, it removes the routing state for that (those)
prefix(es), that would be deleted by the CMD as well, hence defeating any prefix
continuity attempt. The simplest approach to overcome this limitation is to deny
an old MAAR to de-register a prefix, that is, allowing only a serving MAAR to
de-register the whole MN session. This can be achieved by first removing any
layer-2 detachment event, so that de-registration is triggered only when the
session lifetime expires, hence providing a guard interval for the MN to connect
to a new MAAR. Then, a change in the MAAR operations is required, and at this
stage two possible solutions can be deployed:

          <list style="symbols">
            <t>
A previous MAAR stops the BCE timer upon receiving a PBU from the CMD containing
a "Serving MAAR" option. In this way only the Serving MAAR is allowed to
de-register the mobility session, arguing that the MN left definitely the
domain.
            </t>

            <t>
Previous MAARs can, upon BCE expiry, send de-registration messages to the CMD,
which, instead of acknowledging the message with a 0 lifetime, send back a PBA
with a non-zero lifetime, hence re-newing the session, if the MN is still
connected to the domain.
            </t>

          </list>

The evaluation of these methods is left for future work.

        </t>

      </section>

      <section anchor="sec:dlif_concept" title="The Distributed Logical
Interface (DLIF) concept">

        <t>
One of the main challenges of a network-based DMM solution is how to allow a
mobile node to simultaneously send/receive traffic which is anchored at
different MAARs, and how to influence on the preference of the mobile selecting
the source IPv6 address for a new communication, without requiring special
support on the mobile node stack. This document defines the Distributed Logical
Interface (DLIF), which is a software construct that allows to easily hide the
change of anchor from the mobile node.
        </t>

      <figure anchor="fig:exposing_multiple_routers"
              title="DLIF: exposing multiple routers (one per active anchoring MAAR)">
        <artwork><![CDATA[
  +---------------------------------------------------+
 (                      Operator's                     )
 (                         core                        )
  +---------------------------------------------------+
            |                               |
    +---------------+     tunnel    +---------------+
    |   IP  stack   |===============|   IP  stack   |
    +---------------+               +-------+-------+
    |    mn1mar1    |--+ (DLIFs) +--|mn1mar1|mn1mar2|--+
    +---------------+  |         |  +-------+-------+  |
    | phy interface |  |         |  | phy interface |  |
    +---------------+  |         |  +---------------+  |
          MAAR1       (o)       (o)       MAAR2       (o)
                                   x                 x
                                     x             x
                        prefA::/64     x         x   prefB::/64
                      (AdvPrefLft=0)     x     x
                                           (o)
                                            |
                                         +-----+
                             prefA::MN1  | MN1 |  prefB::MN1
                            (deprecated) +-----+ 
]]></artwork>
      </figure>

        <t>
The basic idea of the DLIF concept is the following. Each serving MAAR exposes
itself towards a given MN as multiple routers, one per active anchoring MAAR
associated to the MN. Let's consider the example shown in <xref
target="fig:exposing_multiple_routers" />, MN1 initially attaches to MAAR1,
configuring an IPv6 address (prefA::MN1) from a prefix locally anchored at MAAR1
(prefA::/64). At this stage, MAAR1 plays both the role of anchoring and serving
MAAR, and also it behaves as a plain IPv6 access router. MAAR1 creates a distributed
logical interface to communicate (point-to-point link) with MN1, exposing itself
as a (logical) router with a specific MAC (e.g., 00:11:22:33:01:01) and IPv6
addresses (e.g., prefA::MAAR1/64 and fe80:211:22ff:fe33:101/64) using the DLIF
mn1mar1. As explained below, these addresses represent the "logical" identity of
MAAR1 towards MN1, and will "follow" the mobile node while roaming within the
domain (note that the place where all this information is maintained and updated
is out-of-scope of this draft; potential examples are to keep it on the HSS or
the user's profile).
        </t>

        <t>
If MN1 moves and attaches to a different MAAR of the domain (MAAR2 in the
example of <xref target="fig:exposing_multiple_routers" />), this MAAR will
create a new logical interface (mn1mar2) to expose itself towards MN1, providing
it with a locally anchored prefix (prefB::/64). In this case, since the MN1 has
another active IPv6 address anchored at a MAAR1, MAAR2 also needs to create an
additional logical interface configured to exactly resemble the one used by
MAAR1 to communicate with MN1. In this example, there is only one active
anchoring MAAR (in addition to MAAR2, which is the serving one): MAAR1, so only
the logical interface mn1mar1 is created, but the same process would be repeated
in case there were more active anchoring MAARs involved. In order to maintain
the prefix anchored at MAAR1 reachable, a tunnel between MAAR1 and MAAR2 is
established and the routing is modified accordingly. The PBU/PBA signaling is
used to set-up the bi-directional tunnel between MAAR1 and MAAR2, and it might
also be used to convey to MAAR2 the information about the prefix(es) anchored at
MAAR1 and about the addresses of the associated DLIF (i.e., mn1mar1).
        </t>

      <figure anchor="fig:dlif_concept"
              title="Distributed Logical Interface concept">
        <artwork><![CDATA[
+------------------------------------------+ +----------------------+
|                  MAAR1                   | |         MAAR2        |
|+----------------------------------------+| |+--------------------+|
||+------------------++------------------+|| ||+------------------+||
|||+-------++-------+||+-------++-------+||| |||+-------++-------+|||
||||mn3mar1||mn3mar2||||mn2mar1||mn2mar2|||| ||||mn1mar1||mn1mar2||||
|||| LMAC1 || LMAC2 |||| LMAC3 || LMAC4 |||| |||| LMAC5 || LMAC6 ||||
|||+-------++-------+||+-------++-------+||| |||+-------++-------+|||
|||    LIFs of MN3   ||    LIFs of MN2   ||| |||   LIFs of MN1    |||
||+------------------++------------------+|| ||+------------------+||
||              HMAC1   (phy if MAAR1)    || ||HMAC2 (phy if MAAR2)||
|+----------------------------------------+| |+--------------------+|
+------------------------------------------+ +----------------------+
                    x        x                            x
                   x          x                          x
                 (o)          (o)                      (o)
                  |            |                        |
               +--+--+      +--+--+                  +--+--+
               | MN3 |      | MN2 |                  | MN1 |
               +-----+      +-----+                  +-----+
]]></artwork>
      </figure>

        <t>
<xref target="fig:dlif_concept" /> shows the logical interface concept in more
detail. The figure shows two MAARs and three MNs. MAAR1 is currently serving MN2
and MN3, while MAAR2 is serving MN1. MN1, MN2 and MN3 have two active anchoring
MAARs: MAAR1 and MAAR2. Note that a serving MAAR always plays the role of
anchoring MAAR for the attached (served) MNs. Each MAAR has one single physical
wireless interface.
        </t>

        <t>
As introduced before, each MN always "sees" multiple logical routers -- one per
active anchoring MAAR -- independently of to which serving MAAR the MN is
currently attached. From the point of view of the MN, these MAARs are portrayed
as different routers, although the MN is physically attached to one single
interface . The way this is achieved is by the serving MAAR configuring
different logical interfaces. If we focus on MN1, it is currently attached to
MAAR2 (i.e., MAAR2 is its serving MAAR) and, therefore, it has configured an
IPv6 address from MAAR2's pool (e.g., prefB::/64). MAAR2 has set-up a logical
interface (mn1dgw2) on top of its wireless physical interface (phy if MAAR2)
which is used to serve MN1. This interface has a logical MAC address (LMAC6),
different from the hardware MAC address (HMAC2) of the physical interface of
MAAR2. Over the mn1dgw2 interface, MAAR2 advertises its locally anchored prefix
prefB::/64. Before attaching to MAAR2, MN1 visited MAAR1, configuring also an
address locally anchored at this MAAR, which is still being used by the MN1 in
active communications. MN1 keeps "seeing" an interface connecting to MAAR1, as
if it were directly connected to the two MAARs. This is achieved by the serving
MAAR (MAAR1) configuring an additional distributed logical interface: mn1dgw1,
which behaves exactly as the logical interface configured by the actual MAAR1
when MN1 was attached to it. This means that both the MAC and IPv6 addresses
configured on this logical interface remain the same regardless of the physical
MAAR which is serving the MN. The information required by a serving MAAR to
properly configure this logical interfaces can be obtained in different ways: as
part of the information conveyed in the PBA, from an external database (e.g.,
the HSS) or by other means. As shown in the figure, each MAAR may have several
logical interfaces associated to each attached MN, having always at least one
(since a serving MAAR is also an anchoring MAAR for the attached MN).
        </t>

        <t>
In order to enforce the use of the prefix locally anchored at the serving MAAR,
the router advertisements sent over those logical interfaces playing the role of
anchoring MAARs (different from the serving one) include a zero prefix lifetime.
The goal is to deprecate the prefixes delegated by these MAARs (which will be no
longer serving the MN). Note that on-going communications keep on using those
addresses, even if they are deprecated, so this only affects to new sessions.
        </t>

        <t>
The distributed logical interface concept also enables the following use case.
Suppose that access to a local IP network is provided by a given MAAR (e.g.,
MAAR1 in the example shown in <xref target="fig:exposing_multiple_routers" />)
and that the resources available at that network cannot be reached from outside
the local network (e.g., cannot be accessed by an MN attached to MAAR2). This is
similar to the LIPA scenario currently being consider by 3GPP. The goal is to
allow an MN to be able to roam while still being able to have connectivity to
this local IP network. The solution adopted to support this case makes use of
RFC 4191 <xref target="RFC4191" /> more specific routes when the MN moves to a
MAAR different from the one providing access to the local IP network (MAAR1 in
the example). These routes are advertised through the distributed logical
interface representing the MAAR providing access to the local network (MAAR1 in
this example). In this way, if MN1 moves from MAAR1 to MAAR2, any active session
that MN1 may have with a node of the local network connected to MAAR1 will
survive, being the traffic forwarded via the tunnel between MAAR1 and MAAR2.
Also, any potential future connection attempt towards the local network will be
supported, even though MN1 is no longer attached to MAAR1.
        </t>

      </section>






      <section anchor="subsec:messages" title="Message Format">


        <t>
This section defines extensions to the Proxy Mobile IPv6 <xref target="RFC5213"
/> protocol messages.
        </t>

        <section anchor="sec:pbu_format" title="Proxy Binding Update">

          <t>
A new flag (D) is included in the Proxy Binding Update to indicate that the
Proxy Binding Update is coming from a Mobility Anchor and Access Router and not
from a mobile access gateway. The rest of the Proxy Binding Update format
remains the same as defined in <xref target="RFC5213" />.
          </t>

<figure>
        <artwork><![CDATA[
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
                                +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
                                |            Sequence #         |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|A|H|L|K|M|R|P|D| Reserved      |            Lifetime           |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
.                                                               .
.                        Mobility options                       .
.                                                               .

|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
]]></artwork>
</figure>

          <t>
MAAR Flag (D)

            <list>

              <t>
The D Flag is set to indicate to the receiver of the message that the Proxy
Binding Update is from a MAAR.
              </t>

            </list>

          </t>

          <t>
Mobility Options

            <list>

              <t>
Variable-length field of such length that the complete Mobility Header is an
integer multiple of 8 octets long. This field contains zero or more TLV-encoded
mobility options. The encoding and format of defined options are described in
Section 6.2 of <xref target="RFC6275" />. The MAAR MUST ignore and skip any
options that it does not understand.
              </t>

            </list>

          </t>

        </section>

        <section anchor="sec:pba_format" title="Proxy Binding Acknowledgment">

          <t>
A new flag (D) is included in the Proxy Binding Acknowledgment to indicate that
the sender supports operating as a distributed gateway. The rest of the Proxy
Binding Acknowledgment format remains the same as defined in <xref
target="RFC5213" />.
          </t>

<figure>
        <artwork><![CDATA[
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
                                +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
                                |   Status      |K|R|P|D| Reser |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|         Sequence #            |           Lifetime            |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
.                                                               .
.                        Mobility options                       .
.                                                               .
|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
]]></artwork>
</figure>

          <t>
MAAR (D)

            <list>

              <t>
The D is set to indicate that the sender of the message supports operating as a
distributed gateway.
              </t>

            </list>

          </t>

          <t>
Mobility Options

            <list>

              <t>
Variable-length field of such length that the complete Mobility Header is an
integer multiple of 8 octets long. This field contains zero or more TLV-encoded
mobility options. The encoding and format of defined options are described in
Section 6.2 of <xref target="RFC6275" />. The MAAR MUST ignore and skip any
options that it does not understand.
              </t>

            </list>

          </t>

        </section>

        <section anchor="sec:anchored_prefix_format"
                 title="Anchored Prefix Option">

          <t>
A new Anchored Prefix option is defined for use with the Proxy Binding Update
and Proxy Binding Acknowledgment messages exchanged between distributed
gateways. This option is used for exchanging the mobile node's prefix anchored
at the anchoring MAAR. There can be multiple Anchored Prefix options present in
the message.
          </t>

          <t>
The Anchored Prefix Option has an alignment requirement of 8n+4. Its format is
as follows:
          </t>

<figure>
        <artwork><![CDATA[
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      |   Reserved    | Prefix Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
+                                                               +
|                                                               |
+                        Anchored Prefix                        +
|                                                               |
+                                                               +
|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
]]></artwork>
</figure>

          <t>
Type

            <list>

              <t>
To be assigned by IANA.
              </t>

            </list>

          </t>

          <t>
Length

            <list>

              <t>
8-bit unsigned integer indicating the length of the option in octets, excluding
the type and length fields. This field MUST be set to 18.
              </t>

            </list>

          </t>

          <t>
Reserved

            <list>

              <t>
This field is unused for now. The value MUST be initialized to 0 by the sender
and MUST be ignored by the receiver.
              </t>

            </list>

          </t>

          <t>
Prefix Length

            <list>

              <t>
8-bit unsigned integer indicating the prefix length of the IPv6 prefix contained
in the option.
              </t>

            </list>

          </t>

          <t>
Anchored Prefix

            <list>

              <t>
A sixteen-byte field containing the mobile node's IPv6 Anchored Prefix.
              </t>

            </list>

          </t>

        </section>

        <section anchor="sec:local_prefix_format" title="Local Prefix Option">

          <t>
A new Local Prefix option is defined for use with the Proxy Binding Update and
Proxy Binding Acknowledgment messages exchanged between MAARs. This option is
used for exchanging a prefix of a local network that is only reachable via the
anchoring MAAR. There can be multiple Local Prefix options present in the
message.
          </t>

          <t>
The Local Prefix Option has an alignment requirement of 8n+4. Its format is
as follows:
          </t>

<figure>
        <artwork><![CDATA[
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      |   Reserved    | Prefix Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
+                                                               +
|                                                               |
+                         Local Prefix                          +
|                                                               |
+                                                               +
|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
]]></artwork>
</figure>

          <t>
Type

            <list>

              <t>
To be assigned by IANA.
              </t>

            </list>

          </t>

          <t>
Length

            <list>

              <t>
8-bit unsigned integer indicating the length of the option in octets, excluding
the type and length fields. This field MUST be set to 18.
              </t>

            </list>

          </t>

          <t>
Reserved

            <list>

              <t>
This field is unused for now. The value MUST be initialized to 0 by the sender
and MUST be ignored by the receiver.
              </t>

            </list>

          </t>

          <t>
Prefix Length

            <list>

              <t>
8-bit unsigned integer indicating the prefix length of the IPv6 prefix contained
in the option.
              </t>

            </list>

          </t>

          <t>
Local Prefix

            <list>

              <t>
A sixteen-byte field containing the IPv6 Local Prefix.
              </t>

            </list>

          </t>

        </section>

        <section anchor="subsec:pmaaropt" title="Previous MAAR Option">
          <t>This new option is defined for use with the Proxy Binding
          Acknowledgement messages exchanged by the CMD to a MAAR. This option
          is used to notify the S-MAAR about the previous MAAR's global
          address and the prefix anchored to it. There can be multiple
          Previous MAAR options present in the message. Its format is as
          follows:</t>

          <figure>
            <artwork><![CDATA[
 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    | Prefix Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
+                                                               +
|                                                               |
+                     P-MAAR's address                          +
|                                                               |
+                                                               +
|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
+                                                               +
|                                                               |
+                    Home Network Prefix                        +
|                                                               |
+                                                               +
|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
]]></artwork>
          </figure>

          <t>Type <list>
              <t>To be assigned by IANA.</t>
            </list></t>

          <t>Length <list>
              <t>8-bit unsigned integer indicating the length of the option in
              octets, excluding the type and length fields. This field MUST be
              set to 34.</t>
            </list></t>

          <t>Prefix Length <list>
              <t>8-bit unsigned integer indicating the prefix length of the
              IPv6 prefix contained in the option.</t>
            </list></t>

          <t>Previous MAAR's address <list>
              <t>A sixteen-byte field containing the P-MAAR's IPv6 global
              address.</t>
            </list></t>

          <t>Home Network Prefix <list>
              <t>A sixteen-byte field containing the mobile node's IPv6 Home
              Network Prefix.</t>
            </list></t>
        </section>

        <section anchor="subsec:smaaropt" title="Serving MAAR Option">
          <t>This new option is defined for use with the Proxy Binding Update
          and Proxy Binding Acknowledgement messages exchanged between the CMD
          and a Previous MAAR. This option is used to notify the P-MAAR about
          the current Serving MAAR's global address. Its format is as
          follows:</t>

          <figure>
            <artwork><![CDATA[

 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    |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
+                                                               +
|                                                               |
+                     S-MAAR's address                          +
|                                                               |
+                                                               +
|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
]]></artwork>
          </figure>

          <t>Type <list>
              <t>To be assigned by IANA.</t>
            </list></t>

          <t>Length <list>
              <t>8-bit unsigned integer indicating the length of the option in
              octets, excluding the type and length fields. This field MUST be
              set to 16.</t>
            </list></t>

          <t>Serving MAAR's address <list>
              <t>A sixteen-byte field containing the S-MAAR's IPv6 global
              address.</t>
            </list></t>
        </section>

        <section anchor="sec:dlif_link_local_format"
                 title="DLIF Link-local Address Option">

          <t>
A new DLIF Link-local Address option is defined for use with the Proxy Binding
Update and Proxy Binding Acknowledgment messages exchanged between MAARs. This
option is used for exchanging the link-local address of the DLIF to be
configured on the serving MAAR so it resembles the DLIF configured on the
anchoring MAAR.
          </t>

          <t>
The DLIF Link-local Address option has an alignment requirement of 8n+6. Its
format is as follows:
          </t>

<figure>
        <artwork><![CDATA[
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     |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
+                                                               +
|                                                               |
+                  DLIF Link-local Address                      +
|                                                               |
+                                                               +
|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
]]></artwork>
</figure>

          <t>
Type

            <list>

              <t>
To be assigned by IANA.
              </t>

            </list>

          </t>

          <t>
Length

            <list>

              <t>
8-bit unsigned integer indicating the length of the option in octets, excluding
the type and length fields. This field MUST be set to 16.
              </t>

            </list>

          </t>

          <t>
DLIF Link-local Address

            <list>

              <t>
A sixteen-byte field containing the link-local address of the logical interface.
              </t>

            </list>

          </t>

        </section>

        <section anchor="sec:dlif_link_layer_format"
                 title="DLIF Link-layer Address Option">

          <t>
A new DLIF Link-layer Address option is defined for use with the Proxy Binding
Update and Proxy Binding Acknowledgment messages exchanged between MAARs. This
option is used for exchanging the link-layer address of the DLIF to be
configured on the serving MAAR so it resembles the DLIF configured on the
anchoring MAAR.
          </t>

          <t>
The format of the DLIF Link-layer Address option is shown below. Based on the
size of the address, the option MUST be aligned appropriately, as per mobility
option alignment requirements specified in <xref target="RFC6275" />.
          </t>

<figure>
        <artwork><![CDATA[
     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     |          Reserved             |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
+                    DLIF Link-layer Address                    +
.                              ...                              .
|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
]]></artwork>
</figure>

          <t>
Type

            <list>

              <t>
To be assigned by IANA.
              </t>

            </list>

          </t>

          <t>
Length

            <list>

              <t>
8-bit unsigned integer indicating the length of the option in octets, excluding
the type and length fields.
              </t>

            </list>

          </t>

          <t>
Reserved

            <list>

              <t>
This field is unused for now. The value MUST be initialized to 0 by the sender
and MUST be ignored by the receiver.
              </t>

            </list>

          </t>

          <t>
DLIF Link-layer Address

            <list>

              <t>
A variable length field containing the link-layer address of the logical
interface to be configured on the serving distributed gateway.
              </t>

              <t>
The content and format of this field (including byte and bit ordering) is as
specified in Section 4.6 of <xref target="RFC4861" /> for carrying link-layer
addresses. On certain access links, where the link-layer address is not used or
cannot be determined, this option cannot be used.
              </t>

            </list>

          </t>

        </section>

      </section>

    </section>

    <!-- end of section "PMIPv6-based" -->


    <section anchor="IANA" title="IANA Considerations">

      <t>
This document defines new mobility options that require IANA actions.
      </t>

      <t>
TBD.
      </t>

    </section>

    <section anchor="Security" title="Security Considerations">

      <t>
The protocol extensions defined in this document share the same security
concerns of Proxy Mobile IPv6 <xref target="RFC5213" />. It is recommended that
the signaling messages, Proxy Binding Update and Proxy Binding Acknowledgment,
exchanged between the MAARs are protected using IPsec using the established
security association between them. This essentially eliminates the threats
related to the impersonation of a MAAR.
      </t>

    </section>

    <section anchor="Acknowledgments" title="Acknowledgments">

      <t>
The authors would like to thank Marco Liebsch for his comments and discussion on
the documents <xref target="I-D.bernardos-dmm-distributed-anchoring" /> and
<xref target="I-D.bernardos-dmm-pmip" /> on which the present document is based.
      </t>

      </section>

  </middle>

  <back>
    <references title="Normative References">

      &rfc2119;
      &rfc6275;
      &rfc5213;
      &rfc4191;
      &rfc4861;

    </references>

    <references title="Informative References">

      &rfc7333;
      &rfc7429;
      &I-D.bernardos-dmm-distributed-anchoring;
      &I-D.bernardos-dmm-pmip;
      &I-D.ietf-dmm-ondemand-mobility;
      &I-D.ietf-dmm-deployment-models;

    </references>

	<section anchor="sec:appx1" title="Comparison with Requirement document">
	<t>
In this section we descrbe how our solution addresses the DMM requirements
listed in <xref target="RFC7333"></xref>.
	</t>

	<section anchor="subsec:req1" title="Distributed mobility management">
	<t>
"IP mobility, network access solutions, and forwarding solutions provided by DMM
MUST enable traffic to avoid traversing a single mobility anchor far from the
optimal route."
	</t>
	<t>
In our solution, a MAAR is responsible to handle the mobility for those IP flows
started when the MN is attached to it. As long as the MN remains connected to
the MAAR's access links, the IP packets of such flows can benefit from the
optimal path. When the MN moves to another MAAR, the path becomes non-optimal
for ongoing flows, as they are anchored to the previous MAAR, but newly started
IP sessions are forwarded by the new MAAR through the optimal path.
	</t>
	</section>
	
	<section anchor="subsec:req2" title="Bypassable network-layer mobility support for each application session">
	<t>
"DMM solutions MUST enable network-layer mobility, but it MUST be possible for
any individual active application session (flow) to not use it. Mobility support
is needed, for example, when a mobile host moves and an application cannot cope
with a change in the IP address. Mobility support is also needed when a mobile
router changes its IP address as it moves together with a host and, in the
presence of ingress filtering, an application in the host is interrupted.
However, mobility support at the network layer is not always needed; a mobile
node can often be stationary, and mobility support can also be provided at other
layers. It is then not always necessary to maintain a stable IP address or
prefix for an active application session."
	</t>
	<t>
Our DMM solution operates at the IP layer, hence upper layers are totally
transparent to the mobility operations. In particular, ongoing IP sessions are
not disrupted after a change of access network. The routability of the old
address is ensured by the IP tunnel with the old MAAR. New IP sessions are
started with the new address. From the application's perspective, those
processes which sockets are bound to a unique IP address do not suffer any
impact. For the other applications, the sockets bound to the old address are
preserved, whereas next sockets use the new address.
	</t>
	</section>
	
	<section anchor="subsec:req3" title="IPv6 deployment">
	<t>	
"DMM solutions SHOULD target IPv6 as the primary deployment environment and
SHOULD NOT be tailored specifically to support IPv4, particularly in situations
where private IPv4 addresses and/or NATs are used."
	</t>
	<t>
The DMM solution we propose targets IPv6 only.
	</t>
	</section>
	
	<section anchor="subsec:req4" title="Existing mobility protocols">
	<t>		
"A DMM solution MUST first consider reusing and extending IETF standard
protocols before specifying new protocols."
	</t>
	<t>
This DMM solution is derived from the operations and messages specified in <xref
target="RFC5213"></xref>.
	</t>
	</section>

	<section anchor="subsec:req5" title="Coexistence with deployed networks/hosts and operability
          across different networks">
	<t>	
"A DMM solution may require loose, tight, or no integration into existing
mobility protocols and host IP stacks. Regardless of the integration level, DMM
implementations MUST be able to coexist with existing network deployments, end
hosts, and routers that may or may not implement existing mobility protocols.
Furthermore, a DMM solution SHOULD work across different networks, possibly
operated as separate administrative domains, when the needed mobility management
signaling, forwarding, and network access are allowed by the trust relationship
between them"
	</t>
	<t>
The partially DMM solution can be extended to provide a fallback mechanism to
operate as legacy Proxy Mobile IPv6. It is necessary to instruct MAARs to always
establish a tunnel with the same MAAR, working as LMA. The fully DMM solution
can be extended as well, but it requires more intervention. The partially DMM
solution can be deployed across different domains with trust agreements if the
CMDs ot the operators are enabled to transfer context from one node to another.
The fully DMM solution works across multiple domains if both solution apply the
same signalling scheme.
	</t>	
	</section>

	<section anchor="subsec:req6" title="Operation and management considerations">
	<t>	
"A DMM solution needs to consider configuring a device, monitoring the current
operational state of a device, and responding to events that impact the device,
possibly by modifying the configuration and storing the data in a format that
can be analyzed later.
	</t>
	<t>
The proposed solution can re-use existing mechanisms defined for the operation
and management of Proxy Mobile IPv6.
	</t>	
	</section>

	<section anchor="subsec:req7" title="Security considerations">
	<t>	
"A DMM solution MUST support any security protocols and mechanisms needed to
secure the network and to make continuous security improvements. In addition,
with security taken into consideration early in the design, a DMM solution MUST
NOT introduce new security risks or amplify existing security risks that cannot
be mitigated by existing security protocols and mechanisms."
	</t>
	<t>
The proposed solution does not specify a security mechanism, given that the same
mechanism for PMIPv6 can be used.
	</t>
	</section>
	
	<section anchor="subsec:req8" title="Multicast">
	<t>	
"DMM SHOULD enable multicast solutions to be developed to avoid network
inefficiency in multicast traffic delivery."
	</t>
	<t>
This solution in its current version does not specify any support for multicast
traffic, which is left for study in future versions.
	</t>

	</section>
    </section>

    <section anchor="sec:appx2" title="Implementation experience">

      <t>
The network-based DMM solution described in section <xref
target="subsec:proxy"></xref> is now available at the Open Distributed Mobility
Management (ODMM) project (http://www.odmm.net/), under the name of Mobility
Anchors Distribution for PMIPv6 (MAD-PMIPv6). The ODMM platform is intended to
foster DMM development and deployment, by serving as a framework to host open
source implementations.
</t>

      <t>
The MAD-PMIPv6 code is developed in ANSI C from the existing UMIP implementation
for PMIP. The most relevant changes with respect to the UMIP original version
are related to how to create the CMD and MAAR's state machines from those of an
LMA and a MAG; for this purpose, part of the LMA code was copied to the MAG, in
order to send PBA messages and parse PBU. Also, the LMA routing functions were
removed completely, and moved to the MAG, because MAARs need to route through
the tunnels in downlink (as an LMA) and in uplink (as a MAG).
      </t>

      <t>
Tunnel management is hence a relevant technical aspect, as multiple tunnels are
established by a single MAAR, which keeps their status directly into the MN's
BCE. Indeed, from the implementation experience it was chosen to create an
ancillary data structure as field within a BCE: the data structure is called
"MAAR list" and stores the previous MAARs' address and the corresponding
prefix(es) assigned for the MN. Only the CMD and the serving MAAR store this
data structure, because the CMD maintains the global MN's mobility session
formed during the MN's roaming within the domain, and the serving MAAR needs to
know which previous MAARs were visited, the prefix(es) they assigned and the
tunnels established with them. Conversely, a previous MAAR only needs to know
which is the current Serving MAAR and establish a single tunnel with it. For
this reason, a MAAR that receives a PBU from the CMD (meaning that the MN
attached to another MAAR), first sets up the routing state for the MN's
prefix(es) it is anchoring, then stop the BCE expiry timer and deletes the MAAR
list (if present) since it is no longer useful.
      </t>

      <t>
In order to have the MN totally unaware of the changes in the access link, all
MAARs implement the Distributed Logical Interface (DLIF) concept. Moreover, it
should be noted that the protocols designed in the document work only at the
network layer to handle the MNs joining or leaving the domain. This should
guarantee a certain independency to a particular access technology. The
implementation reflects this reasoning, but we argue that an interaction with
lower layers produces a more effective attachment and detachment detection,
therefore improving the performance, also regarding de-registration mechanisms.
      </t>

      <t>
It was chosen to implement the "proxy" solution because it produces the shortest
handover latency, but a slight modification on the CMD state machine can produce
the first scenario described ("relay") which guarantees a more consistent
request/ack scheme between the MAARS. By modifying also the MAAR's state machine
it can be implemented the second solution ("locator").
     </t>

     <t>
An early MAD-PMIPv6 implementation was shown during a demo session at the IETF
83rd, in Paris in March 2012. An enhancement version of the prototype has been
presented at the 87th IETF meeting in Berlin, July 2013. The updated demo
included a use case scenario employing a CDN system for video delivery. More,
MAD-PMIPv6 has been extensively used and evaluated within a testbed employing
heterogeneous radio accesses within the framework of the MEDIEVAL EU project.
MAD-PMIPv6 software is currently part of a DMM test-bed comprising 3 MAARs, one
CMD, one MN and a CN. All the machines used in the demos were Linux UBUNTU 10.04
systems with kernel 2.6.32, but the prototype has been tested also under newer
systems. This testbed was also used by the iJOIN EU project.
     </t>

    </section>

    <section anchor="sec:appx3" title="Applicability to the fog environment">

      <t>
Virtualization is invading all domains of the E2E 5G network, including the
access, as a mean to achieve the necessary flexibility in support of the E2E
slicing concept. The ETSI NFV framework is the cornerstone for making
virtualization such a promising technology that can be matured in time for 5G.
Typically, virtualization has been mostly envisaged in the core network, where
sophisticated data centers and clouds provided the right substrate. And mostly,
the framework focused on virtualizing network functions, so called VNFs
(virtualized network functions), which were somewhat limited to functions that
are delay tolerant, typically from the core and aggregation transport.
      </t>

      <t>
As the community has recently been developing the 5G applications and their
technical requirements, it has become clear that certain applications would
require very low latency which is extremely challenging and stressing for the
network to deliver through a pure centralized architecture. The need to provide
networking, computing, and storage capabilities closer to the users has
therefore emerged, leading to what is known today as the concept of intelligent
edge. ETSI has been the first to address this need recently by developing the
framework of mobile edge computing (MEC).
      </t>

      <t>
Such an intelligent edge could not be envisaged without virtualization. Beyond
applications, it raises a clear opportunity for networking functions to execute
at the edge benefiting from inherent low latencies.
      </t>

      <t>
Whilst it is appreciated the particular challenge for the intelligent edge
concept in dealing with mobile users, the edge virtualization substrate has been
largely assumed to be fixed or stationary. Although little developed, the
intelligent edge concept is being extended further to scenarios where for
example the edge computing substrate is on the move, e.g., on-board a car or a
train, or that it is distributed further down the edge, even integrating
resources from different stakeholders, into what is known as the fog. The
challenges and opportunities for such extensions of the intelligent edge remain
an exciting area of future research.
      </t>

      <t>
<xref target="fig:fog" /> shows a diagram representing the fog virtualization
concept. The fog is composed by virtual resources on top of heterogeneous
resources available at the edge and even further in the RAN and end-user
devices. These resources are therefore owned by different stakeholders who
collaboratively form a single hosting environment for the VNFs to run. As an
example, virtual resources provided to the fog might be running on eNBs, APs, at
micro data centers deployed in shopping malls, cars, trains, etc. The fog is
connected to data centers deeper into the network architecture (at the edge ir
the core).
      </t>

      <figure anchor="fig:fog" title="Fog virtualization">
        <artwork><![CDATA[
      +--------------------------------+  +-------------------+
      | -------   --------   --------  |  |      ----------   |
      | |     |   |      |   |      |  |  |    ---------- |   |
      | | @UE |   | @car |   | @eNB |  |  |  ---------- | |   |
      | -------   --------   --------  |  |  |  Data  | | |   |
      |                                |  |  | Center | | -   |
      | -------- Heterogeneous ------- |  |  |  (DC)  |-      |
 phy  | |      |   computing   |     | |  |  ----------       |
infra | |@train|    devices    | @AP | |==|      ----------   |
      | --------    forming    ------- |  |    ---------- |   |
      |             the fog            |  |  ---------- | |   |
      | ---------        ------------  |  |  |  Data  | | |   |
      | |       |        |          |  |  |  | Center | | -   |
      | | @mall |        | @localDC |  |  |  |  (DC)  |-      |
      | ---------        ------------  |  |  ----------       |
      |              FOG               |  |       CLOUD       |
      +--------------------------------+  +-------------------+
      <--------- fog and edge ----------------->
                                  <--- edge & central cloud ---> 
      ]]></artwork>
      </figure>

      <t>
In this context, where the "fog" hosts functions and resources, it is important
to enable their mobility. In future versions of this document we will describe
how to apply the solution described here to the fog environment.
      </t>

    </section>

    <!---->
  </back>
</rfc>