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Network Working Group                                           T. Chown
Internet-Draft                                               M. Thompson
Expires: March 22, 2007                                          A. Ford
                                                               S. Venaas
                                           University of Southampton, UK
                                                      September 18, 2006


         Things to think about when Renumbering an IPv6 network
                draft-chown-v6ops-renumber-thinkabout-05

Status of this Memo

   By submitting this Internet-Draft, each author represents that any
   applicable patent or other IPR claims of which he or she is aware
   have been or will be disclosed, and any of which he or she becomes
   aware will be disclosed, in accordance with Section 6 of BCP 79.

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   This Internet-Draft will expire on March 22, 2007.

Copyright Notice

   Copyright (C) The Internet Society (2006).

Abstract

   This memo presents a summary of scenarios, issues for consideration
   and protocol features for IPv6 network renumbering, i.e. achieving
   the transition from the use of an existing network prefix to a new
   prefix in an IPv6 network.  Its focus lies not in the procedure for
   renumbering, but as a set of "things to think about" when undertaking
   such a renumbering exercise.



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Table of Contents

   1.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  4
     1.1.  Structure of Document  . . . . . . . . . . . . . . . . . .  4
     1.2.  Past IPv4 Renumbering studies in the PIER WG . . . . . . .  4
   2.  Terminology  . . . . . . . . . . . . . . . . . . . . . . . . .  5
   3.  Renumbering Event Triggers . . . . . . . . . . . . . . . . . .  5
     3.1.  Change of uplink prefix  . . . . . . . . . . . . . . . . .  6
       3.1.1.  Migration to new provider  . . . . . . . . . . . . . .  6
       3.1.2.  Dial on Demand . . . . . . . . . . . . . . . . . . . .  6
       3.1.3.  Provider migration and upstream renumbering  . . . . .  7
       3.1.4.  IPv6 transition  . . . . . . . . . . . . . . . . . . .  7
     3.2.  Change of internal topology  . . . . . . . . . . . . . . .  8
     3.3.  Acquisition or merger  . . . . . . . . . . . . . . . . . .  8
     3.4.  Network growth . . . . . . . . . . . . . . . . . . . . . .  8
     3.5.  Network mobility . . . . . . . . . . . . . . . . . . . . .  8
   4.  Renumbering Requirements . . . . . . . . . . . . . . . . . . .  9
     4.1.  Minimal disruption . . . . . . . . . . . . . . . . . . . .  9
     4.2.  Session survivability  . . . . . . . . . . . . . . . . . .  9
       4.2.1.  Short-term session survivability . . . . . . . . . . . 10
       4.2.2.  Medium-term session survivability  . . . . . . . . . . 10
       4.2.3.  Long-term session survivability  . . . . . . . . . . . 10
       4.2.4.  "Sessions" in non-session based transports . . . . . . 11
   5.  IPv6 Protocol Features and their Effects on Renumbering  . . . 11
     5.1.  Multi-addressing . . . . . . . . . . . . . . . . . . . . . 11
     5.2.  Multi-homing techniques  . . . . . . . . . . . . . . . . . 12
       5.2.1.  Relevance of multi-homing to renumbering . . . . . . . 12
       5.2.2.  Current situation with IPv6 multi-homing . . . . . . . 13
     5.3.  Mobile IPv6  . . . . . . . . . . . . . . . . . . . . . . . 13
       5.3.1.  Visited site renumbers when mobile . . . . . . . . . . 14
       5.3.2.  Home site renumbers when mobile  . . . . . . . . . . . 14
       5.3.3.  Home site renumbers when disconnected  . . . . . . . . 14
     5.4.  Multicast  . . . . . . . . . . . . . . . . . . . . . . . . 15
     5.5.  Unique Local Addressing  . . . . . . . . . . . . . . . . . 16
       5.5.1.  ULAs, Multicast and Address Selection  . . . . . . . . 17
       5.5.2.  ULAs with application-layer gateways . . . . . . . . . 18
     5.6.  Anycast addressing . . . . . . . . . . . . . . . . . . . . 18
   6.  Node Configuration Issues  . . . . . . . . . . . . . . . . . . 19
     6.1.  Stateless Address Autoconfiguration  . . . . . . . . . . . 19
       6.1.1.  Router Advertisement Lifetimes . . . . . . . . . . . . 20
       6.1.2.  Stateless Configuration with DHCPv6  . . . . . . . . . 20
       6.1.3.  Tokenised Interface Identifiers  . . . . . . . . . . . 20
     6.2.  Stateful Configuration with DHCPv6 . . . . . . . . . . . . 21
       6.2.1.  Prefix Delegation  . . . . . . . . . . . . . . . . . . 22
       6.2.2.  Source Address Selection Policy distribution . . . . . 22
     6.3.  Router Renumbering . . . . . . . . . . . . . . . . . . . . 22
   7.  Administrative Considerations for Renumbering  . . . . . . . . 23
     7.1.  Router Advertisement Lifetimes . . . . . . . . . . . . . . 23



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     7.2.  Border filtering . . . . . . . . . . . . . . . . . . . . . 24
     7.3.  Frequency of renumbering episodes  . . . . . . . . . . . . 24
     7.4.  Delay-related Considerations . . . . . . . . . . . . . . . 25
       7.4.1.  With or without a flag day . . . . . . . . . . . . . . 25
       7.4.2.  Freshness of service data  . . . . . . . . . . . . . . 25
       7.4.3.  Availability of old prefix . . . . . . . . . . . . . . 26
       7.4.4.  Duration of overlap  . . . . . . . . . . . . . . . . . 27
     7.5.  Scalability issues . . . . . . . . . . . . . . . . . . . . 27
       7.5.1.  Packet filters, Firewalls and ACLs . . . . . . . . . . 28
       7.5.2.  Monitoring tools . . . . . . . . . . . . . . . . . . . 30
     7.6.  Considerations with a Dual-Stack Network . . . . . . . . . 30
     7.7.  Equipment administrative ownership . . . . . . . . . . . . 31
   8.  Impact of Topology Design on Renumbering . . . . . . . . . . . 31
     8.1.  Merging networks . . . . . . . . . . . . . . . . . . . . . 31
     8.2.  Fixed length subnets . . . . . . . . . . . . . . . . . . . 32
     8.3.  Use 112-bit prefixes for point-to-point links  . . . . . . 32
     8.4.  Plan for growth where possible . . . . . . . . . . . . . . 33
     8.5.  IPv6 NAT Avoidance . . . . . . . . . . . . . . . . . . . . 33
   9.  Application and service-oriented Issues  . . . . . . . . . . . 34
     9.1.  Shims and sockets  . . . . . . . . . . . . . . . . . . . . 34
     9.2.  Explicitly named IP addresses  . . . . . . . . . . . . . . 35
     9.3.  API dilemma  . . . . . . . . . . . . . . . . . . . . . . . 36
     9.4.  Server Sockets . . . . . . . . . . . . . . . . . . . . . . 37
     9.5.  Sockets surviving invalidity . . . . . . . . . . . . . . . 37
     9.6.  DNS Authority  . . . . . . . . . . . . . . . . . . . . . . 38
   10. Summary  . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
     10.1. IETF Call to Arms  . . . . . . . . . . . . . . . . . . . . 38
   11. IANA Considerations  . . . . . . . . . . . . . . . . . . . . . 39
   12. Security Considerations  . . . . . . . . . . . . . . . . . . . 39
   13. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 39
   14. References . . . . . . . . . . . . . . . . . . . . . . . . . . 40
     14.1. Normative References . . . . . . . . . . . . . . . . . . . 40
     14.2. Informative References . . . . . . . . . . . . . . . . . . 40
   Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 43
   Intellectual Property and Copyright Statements . . . . . . . . . . 44
















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1.  Introduction

   This memo presents a summary of scenarios, issues for consideration
   and protocol features for IPv6 network renumbering, i.e. achieving
   the transition from the use of an existing network prefix to a new
   prefix in an IPv6 network.  This document does not relate the
   procedures for IPv6 renumbering; for such a procedure the reader is
   referred to [1].  The authors plan to use this document, together
   with ongoing operational experience, to refine [1] where necessary,
   to promote that guide from Informational to BCP.  The focus is on
   renumbering site networks, though many of the principles apply to
   renumbering other (ISP) networks.

1.1.  Structure of Document

   This document is split into a number of sections that discuss various
   aspects of network renumbering that should be considered when
   undertaking such an event.  This document begins with a discussion of
   the various reasons behind renumbering events, and the requirements
   to ensure the event goes smoothly.  The following sections then
   discuss a selection of factors that can both help and hinder the
   renumbering procedure, and as such should be taken into account when
   planning the event.  Finally, this document summarises issues with
   applications and services, and attempts to identify places where IP
   addresses may be hard-coded and thus require reconfiguration during a
   renumbering event.

1.2.  Past IPv4 Renumbering studies in the PIER WG

   A number of years ago (1996-1997), the Procedures for Internet/
   Enterprise Renumbering (PIER) WG spent time considering the issues
   for IPv4 renumbering.  The WG produced three RFC documents.  In
   RFC1916 [2], a "call to arms" for input on renumbering techniques was
   made.  RFC2071 [3] documents why IPv4 renumbering is required.
   Interestingly, many, but not all, of the drivers have changed with
   respect to IPv6.  In RFC2072 [4], a Router Renumbering Guide, some
   operational procedures are given, much as they are in Baker [1] for
   IPv6.

   Reflection on RFC2071 is interesting, witness the quote: "It is also
   envisioned that Network Address Translation (NAT) devices will be
   developed to assist in the IPv4 to IPv6 transition, or perhaps
   supplant the need to renumber the majority of interior networks
   altogether, but that is beyond the scope of this document."  That
   need however is still very strong, particularly given the lack of
   Provider Independent (PI) address space in IPv6 (in IPv4, PI address
   space exists mainly for historical, pre-CIDR reasons).




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   RFC2072 is more interesting in the context of this document.  Some is
   certainly relevant, though much is not, due to the inherent changes
   in IPv6.  For example, there is no CIDR and address aggregation is
   given as mandate.  Also, IPv6 subnets are in effect fixed length
   (/64), so local administrators do not need to resize subnets to
   maximise efficient use of address space as they do in IPv4.

   One core message from RFC2072 that holds true today is that of
   section 4 where the observation is made that renumbering networks
   whilst remaining the same hierarchy of subnets (i.e. the cardinality
   of the set of prefixes to renumber remains constant) is the 'easiest'
   scenario to renumber; when each "old" prefix can be mapped to a
   single "new" prefix.

   A distinction of this work is that, where the PIER working group
   consider the transition from IPv4 to IPv6 addressing as a renumbering
   scenario, we strictly consider only the renumbering from IPv6
   prefixes to other IPv6 prefixes and leave transition to well
   documented techniques such as those from the PIER working group.


2.  Terminology

   The following terminology is used in this document (to be expanded in
   future revisions):

   o  Site: An organisationally distinct network, ranging from SOHO
      through to enterprise.

   o  Flag day: A planned service outage.

   o  Node: A device on the network that is being renumbered, or that is
      involved in communication with the network being renumbered.


3.  Renumbering Event Triggers

   This section details typical actions that result in the need for a
   renumbering event, and thus define the scenarios for renumbering.

   In many instances, in particular those where no "flag day" is
   involved, the process of renumbering will inevitably lead to a
   scenario where hosts are multi-addressed or multi-homed as one phase
   of the renumbering procedure.  The relationship between renumbering
   and multi-homing is discussed later in this document.

   In other instances, e.g. a change in the IPv4 address offered by a
   provider to a site using 6to4 [9], the change offers no overlap in



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   external connectivity or addressing, and thus there is no multi-
   homing overlap.

   Triggers may be provider-initiated or customer-initiated.

   Triggers and scenarios for IPv4 renumbering are discussed in RFC2071,
   but many of these are no longer relevant, and in IPv6 some new
   triggers exist, e.g. those related to network mobility or IPv6
   transition tools.

3.1.  Change of uplink prefix

   One of the most common causes for renumbering will be a change in the
   site's upstream provider.  As per RFC3177 [10], the typical
   allocation for an IPv6 site is a /48 size prefix taken from the
   globally aggregated address space of the site's provider.  With IPv6,
   sites are highly unlikely to be able to obtain provider independent
   (PI) address space, as have in some cases been obtained in the past
   with IPv4.  Rather, sites use provider assigned (PA) addressing.  As
   a result, if a site changes provider, it must also change its IPv6 PA
   prefix.

3.1.1.  Migration to new provider

   In the simplest case, the customer is triggering the renumbering by
   choosing to change the site's upstream provider to a new ISP and thus
   a new PA IPv6 prefix range.  This may simply be in the form of
   selecting a new commercial provider, although there are several other
   possible scenarios, such as changing from a dial-up to a broadband
   connection, or moving from a community wireless connection to a fixed
   broadband connection.

   A similar scenario exists when a customer migrates to a different
   service from the same provider.  For example, if a customer changes
   from a dialup to a broadband connection, they will likely be
   connecting to a different part of the provider's topology, and
   therefore receive a different address allocation.

3.1.2.  Dial on Demand

   A site may connect intermittently to its upstream provider.  In such
   cases the prefix allocated by the provider may change with each
   connection, as it often does in the case of single IPv4 address
   allocations to SOHO customers today.  Thus the site may receive a
   prefix still in its provider PA range, but the prefix may vary with
   each connection, causing a renumbering event.

   Dynamically assigned IP addresses are common today with dial-up and



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   ISDN Internet connections, and to a lesser extent some broadband
   products, particularly cable modems.  Usually with dynamically
   assigned IP addresses on broadband products, the address is only
   likely to change when the customer reconnects, which could be very
   infrequently.

   This case can be mitigated by encouraging ISPs to offer static IPv6
   prefixes to customers.  Where /48 prefixes are provided, a large ISP
   may be forced to require significantly more than the "default" /32
   allocation from an RIR to an ISP to be able to service its present
   and future customer base.  With always-on more common in new
   deployments, provider re-allocation should be less common; however
   the practice of reallocating IPv4 addresses in SOHO broadband
   networks is not uncommon in current broadband ISPs.

3.1.3.  Provider migration and upstream renumbering

   A site's upstream provider may need to renumber, due for example to a
   change in its network topology or the need to migrate to a different
   or additional prefix from its Regional Internet Registry (RIR).  This
   will in turn trigger the renumbering of the end site.

   Such renumbering events would be expected to be rare, but it should
   be noted that RIR-assigned IPv6 address space is not owned by an ISP.

3.1.4.  IPv6 transition

   During transition to IPv6, there are several scenarios where a site
   may have to renumber.  For example, if the site uses 6to4 for access
   and its IPv4 address is dynamically assigned, an IPv6 renumbering
   event will be triggered when the site's IPv4 address changes.

   Another likely renumbering event would be the change of transition
   mechanism, such as from 6to4 to a static IPv6-in-IPv4 tunnel, or from
   any one of those mechanisms to a native IPv6 link.  When changing
   from 6to4 (2002::/16) addresses to native global aggregatable unicast
   addresses, renumbering would be unavoidable.  When migrating from a
   tunnelled to a native connection, renumbering may not be necessary if
   the same prefix can be routed natively, however this would be
   provider-dependent.

   In addition, there are likely to be many cases of network renumbering
   occurring when the old 6bone prefix (3FFE::/16) is phased out as per
   RFC3701 [11], and networks still using it will have to renumber.

   Finally, there is at least one transition mechanism, ISATAP [12],
   that uses specially crafted host EUI-64 format addresses.  Should a
   site migrate from ISATAP to use either conventional EUI-64 addressing



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   (via stateless address autoconfiguration or perhaps DHCPv6), then
   renumbering would be required at least in the host part of addresses.

   It is also worth noting that nodes that use IPv6 Privacy Extensions
   [13] will in effect renumber the host part of their address on a
   frequent basis, in the case of one popular implementation on a daily
   basis if the node remains on-link on the same network.

3.2.  Change of internal topology

   A site may need to renumber all or part of its internal network due
   to a change of topology, such as creating more or less specific
   subnets, or acquiring a larger IPv6 address allocation.  Motivations
   for splitting a link into separate subnets may be to meet security
   demands on a particular link (policy for link-based access control
   rules), or for link load management by shuffling popular services to
   more appropriate locations in the local topology.  Link-merging may
   be due to department restructuring within the hosting organisation,
   for example.

3.3.  Acquisition or merger

   Two networks may need to merge to one due to the acquisition or
   merger of two organisations or companies.  Such a reorganisation may
   require one or more parts of the new network to renumber to the
   primary PA IPv6 prefix.

3.4.  Network growth

   A site that is allocated a /48 prefix may grow to a size where it
   needs to use a larger prefix for internal networking.  Sites in the
   early stages of IPv6 deployment may only request a /48, even if they
   are likely to outgrow such a prefix in time.  In such a case site-
   wide renumbering may be required to utilise the new prefix if
   organisational restructuring also happens due to the growth.

3.5.  Network mobility

   This covers various cases of network mobility, where a static or
   nomadic network may obtain different uplink connectivity over time,
   and thus be assigned different IPv6 PA prefixes as the topology
   changes.  One example is the "traditional" NEMO network [14], another
   may be a community wireless network where different sets of nodes
   gain uplink connectivity - typically to the same provider - at
   different times.






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4.  Renumbering Requirements

   In this section we enumerate potential specific goals or requirements
   for sites or users undergoing an IPv6 renumbering event.

4.1.  Minimal disruption

   The renumbering event should cause minimal disruption to the routine
   operation of the network being renumbered, and the users of that
   network.

   Disruption is a difficult term to quantify in a generic way, but it
   can be expressed by factors such as:

   o  Application sessions being terminated

   o  Security controls (e.g.  ACLs) blocking access to legitimate
      resources

   o  Unreachability of nodes or networks

   o  Name resolution, directory and configuration services providing
      invalid (out-of-date) address data

   o  Limitation of network management visibility

   These disruptive elements will be covered in situ as we discuss
   protocol features and other renumbering considerations later in this
   memo.

4.2.  Session survivability

   The concept of session survivability is catered for by [1] in that
   new sessions adopt either old or new prefix based on the state of the
   renumbering process, as discussed in Section 5.1.  However, other
   approaches to renumbering networks may be appropriate in certain
   deployments, such as where "flag days" are unavoidable, such as where
   two live prefixes are being "swapped".  In these cases, further
   consideration for existing sessions (their longevity, frequency,
   independence across interactions, etc.) is required.

   Some protocols are specifically geared to aid session survivability,
   e.g. the Stream Control Transmission Protocol (SCTP) [15], and may
   prove valuable in mission-critical renumbering scenarios, in
   particular the extension that enables the dynamic addition and
   removal of IP addresses from an SCTP endpoint association [16].

   Sessions may be administratively maintained, such as NFS mounts for



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   user filestore, or they may be user-driven, e.g. long-running ssh
   sessions.

   In general, it is important to consider how TCP and the applications
   above it handle the connection failures that may result from a change
   in address.

   There are different classes of session duration, as described in the
   following sections.

4.2.1.  Short-term session survivability

   A typical short-term session would involve a request-response
   protocol, such as HTTP, where a new network connection is initiated
   per transaction, or at worst for a small transaction set.  In such
   cases the migration to a new network prefix is transparent: the
   client can use the new prefix in new transactions without
   consequence.  Some applications, however, may be skewed by such a
   shift in connection source for the same entity 'user', for example
   applications that use recent connection history as a cue to identity
   (e.g.  POP-before-SMTP as used by many dial-on-demand ISP customers
   <http://popbsmtp.sourceforge.net/>), or for applications that care
   about connection statistics (the same user web-browsing "session" may
   be split into two where a renumbering event occurs in-between client
   transactions).

4.2.2.  Medium-term session survivability

   A medium-term session is typified by an application or service that
   may persist for perhaps a period of a few minutes up to a period of a
   day or so.  This might involve a TCP-based application that is left
   running during a working day, such as an interactive shell (SSH) or a
   large file download.

4.2.3.  Long-term session survivability

   Long term sessions may typically run for several days, if not weeks
   or months.  These might typically include TCP-based NFS mounts, or
   long-running TCP applications.  Sessions in this context may also
   include those applications that, once started, do not re-resolve
   names and so repeatedly open new connections or send new datagrams to
   the same (as bound at time of initialisation) address throughout
   their execution lifetime.  Even if at API-level applications do
   attempt to re-resolve the symbol to which they desire to connect, the
   behaviour of the resolvers is unclear as to whether mappings are
   refreshed from the naming service, and as such even if the
   renumbering site does update its DNS (or NIS, LDAP database etc.),
   the local result may indeed be cached without any indication passed



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   back up to the application as to how 'old' said binding information
   is.

4.2.4.  "Sessions" in non-session based transports

   UDP transport protocols, such as UDP-based NFS mounts, maintain the
   status of a 'session' by keeping state at one or both ends of the
   communication, but without a persistent open socket connection at the
   network layer.  If, due to node renumbering, one endpoint changes
   address then that state becomes invalid and the 'session'
   interrupted.

   Note that some stack implementations do not correctly flag an error
   to applications that attempt to send packets with an invalidated
   source address, see section Section 9.5

   IP addresses are also seen carried in higher-layer protocols, e.g.
   application sessions, such as with FTP.  Any application that makes
   use of layer-3 address data as a unique end-point identifying token
   may be disrupted by the address of the node changing to which that
   token relates.  This may not be an issue in cases where the token is
   treated as abstract (i.e. literally just a token), however where
   locator semantics are inferred, subsequent attempts to 'resolve' the
   token to an address endpoint for communication, for example, will
   fail.


5.  IPv6 Protocol Features and their Effects on Renumbering

   IPv6 includes a number of notable features that can help or hinder -
   and sometimes both - renumbering episodes.  This section discusses
   these features and their associated effects for consideration when
   undertaking network renumbering, both in terms of how they can be
   used to ease the process, as well as potential pitfalls that should
   be considered.

5.1.  Multi-addressing

   As per RFC3513 [17], IPv6 hosts may be multi-addressed.  This means
   that multiple unicast addresses can be assigned and active on the
   same interface.  These addresses can have different reachabilities
   ('scopes' such as link-local or global), different statuses including
   'preferred' and 'deprecated', and may be ephemeral in nature (such as
   care-of addresses when attached to a foreign network [18] or IPv6
   Privacy addresses [13]).  RFC3484 address selection semantics [5]
   determine which of the "MxN" address pairs to use for communication
   in the general case.




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   During a renumbering episode, the addition of an extra address for an
   endpoint increases the number of possible source-destination address
   pairs for communications between nodes to use.  The address selection
   mechanisms specified by RFC3484 are currently at varying stages of
   implementation in operating systems.

   RFC3484 also specifies policy hooks to allow administrative override
   of the default address selection behaviour, for example to
   specifically prefer a source prefix for use with a set of particular
   destinations.  It is thought that this policy-based address selection
   may be of benefit in renumbering events, or used in the development
   of bespoke renumbering tools.

   Multi-addressing also creates various issues with border filtering,
   discussed in detail in Section 7.2.

5.2.  Multi-homing techniques

   A multi-homed site is a site which has multiple upstream providers.
   A site may be multi-homed for various reasons, however the most
   common are to provide redundancy in case of failure, to increase
   bandwidth, and to provide more varied, optimal routes for certain
   destinations.

   In renumbering, multi-homing will either be a temporary state, during
   the transition, or be a permanent feature of the network
   configuration, which may be being altered during the renumbering.

5.2.1.  Relevance of multi-homing to renumbering

   As discussed in section 2, and in particular section 2.5, of [1],
   during the 'without a flag day' renumbering procedure there will be a
   period where both the old and the new prefixes are stable and valid
   for the network.  During such a period, the network may be multi-
   homed, and as such many of the issues relating to multi-homing in
   IPv6 are also relevant, albeit in a small capacity, to the
   renumbering procedure.  A stable multi-homed situation must therefore
   be a requirement for renumbering without a 'flag day'.

   In such a situation, however, the multi-homed state will not be
   permanent, and will only exist for the duration for which it is
   required, i.e. for the period during the renumbering procedure when
   both prefixes should be valid.

   Renumbering can also occur, however, in a network that is already
   multi-homed, for example with redundant links to multiple providers.
   Such a site may wish to renumber for any of the situations given in
   the earlier section, as well as renumbering because of changes in the



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   number of upstream providers.  If at least one of the upstream links
   remains unchanged during the renumbering, however, then these links
   could be used exclusively for that period, alleviating some of the
   issues with prefix changes.  The stable link(s) could therefore be
   the only prefixes advertised as valid for the 'stable state', with
   the removal of the old prefix and introduction of the new prefix
   being separate events.

   Until the best practice for the multi-homing situation is defined,
   however, its effect on renumbering is not a focus of this document.

5.2.2.  Current situation with IPv6 multi-homing

   Unlike IPv4 multi-homing, where PI address space is relatively easy
   to obtain and thus a site can broadcast its own routing information,
   most IPv6 addresses will be PA addresses and thus the site will have
   no control over routing information.  Multi-homing in IPv6 therefore
   does not necessarily exist in the same way as in IPv4 and the
   multi6 [38] working group was chartered to try to find a solution.

   Most IPv6 multi-homing solutions fall into the categories of either
   being host-centric, where it is the hosts that are multi-addressed,
   and choose which addresses to use, or site-based, where it is the
   site exit routers that decide which connections to use.  The simplest
   solutions are extensions of the current multi-addressing techniques,
   but these suffer from the problem that, at some point, connections
   using the old addresses will be broken.

   The more advanced solutions [19], and in particular the solution
   taken forward into the shim6 [39] working group, examine the
   potential for splitting the 'identity' and 'location' features of IP,
   currently both represented by the IP address, and connecting to a
   host's identity, rather than its address, so that connections can
   continue unhindered across renumbering events.  Such solutions are,
   however, very much in their infancy and as yet do not provide a
   stable solution to this problem.

   Support for the level of multi-homing required during a renumbering
   exercise is, however, mostly provided by multi-addressing
   (Section 5.1), since all that is primarily required is stable use of
   either prefix for a given period.  The core issue remains, however,
   that at some point the connections using the old address will be
   broken when the addresses are removed.  The impact of this can be
   limited as best as possible during the renumbering procedure.

5.3.  Mobile IPv6

   Mobile IPv6 (MIPv6) [18] specifies routing support to permit an IPv6



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   host to continue using its "permanent" home address as it moves
   around the Internet.  Mobile IPv6 supports transparency above the IP
   layer, including maintenance of active TCP connections and UDP port
   bindings.  There are a number of issues to take into account when
   renumbering episodes occur where Mobile IPv6 is deployed:

   Renumbering a network which has mobile IPv6 active is a potentially
   complex issue to think about.  In particular, can changed router
   advertisements correctly reach the mobile nodes, and can they be
   correctly renumbered, like a node on the local network?  In addition,
   an even more complex issue is what happens when the home agent
   renumbers?  Is it possible for the mobile nodes to be informed and
   correctly renumber and continue, or will the link be irretrievably
   broken?

5.3.1.  Visited site renumbers when mobile

   When a node is mobile and attached to a foreign network it, like any
   other node on the link, is subject to prefix renumbering at that
   site.  Detecting a new prefix through the receipt of router
   advertisements, the mobile node can then re-bind with its home agent
   informing it of its care-of address - just as if it had detached from
   the foreign network and migrated elsewhere.  Where the node receives
   forewarning of the renumbering episode, the Mobility specification
   suggests that the node explicitly solicits an update of the prefix
   information on its home network

5.3.2.  Home site renumbers when mobile

   When mobile, a host can still be contacted at its original (home)
   address.  Should the home network renumber whilst the node is away
   but active (i.e. having bound to the home agent and registered a live
   care-of address), then it can be informed of the new global routing
   prefix used at the home site through the Mobile Prefix Solicitation
   and Mobile Prefix Advertisement ICMPv6 messages (sections 6.7 and 6.8
   of RFC3775 [18] respectively).

5.3.3.  Home site renumbers when disconnected

   Finally, if a mobile node is detached (i.e. no binding with the home
   agent exists with the node present on a foreign network) and the home
   network renumbers, the recommended procedure - documented as an
   appendix to the mobility specification and therefore not necessarily
   proven - is to fall back to alternative methods of 'rediscovering'
   its home network, using the DNS to find the new global routing prefix
   for the home network and therefore the Home Agent's subnet anycast
   address, 'guessing' at what the node's new home address would be on
   the basis of a 64 bit prefix and 64 bit interface identifier, and



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   then attempting to perform registration to bind its new location.

5.4.  Multicast

   IPv6 supports an enriched model of multicast compared to IPv4 in that
   there are well-defined scopes for multicast communication that are
   readily expressed in the protocol's addressing architecture.
   Multicast features much more prominently in the core specification,
   for example it is the enabling technology for the Neighbour Discovery
   protocol (a much more efficient approach to layer 2 address discovery
   than compared to ARP with IPv4).

   Where multicast is used to discover the availability of core services
   (e.g. all DHCPv6 servers in a site will join FF05::1:3), the effect
   of renumbering the unicast address of those services will mean that
   the services are still readily discoverable without resorting to a
   (bespoke or otherwise) service location protocol to continue to
   function - particularly if (unicast) ULAs are not deployed locally as
   per Section 5.5.

   One issue related to IPv6 multicast and renumbering is the embedding
   of unicast addresses into multicast addresses specified in RFC3306
   [20] and the embedded-RP (Rendezvous Point) in RFC3956 [21].

   The former is purely a way of assigning addresses that helps with
   multicast address assignment, avoiding different sites from using the
   same multicast addresses.  If a site's unicast prefix changes, then
   one will also need to change the multicast addresses.  By way of
   example, a site renumbering away from prefix 2001:DB8:BEEF::/48"
   might have globally-scoped multicast addresses in use under the
   prefix "FF3E:30:2001:DB8:BEEF::/96".  One may continue using the old
   addresses for a while, but this should be avoided since another site
   may inherit the prefix and they may end up using the same multicast
   addresses.

   The issue with embedded-RP is that, by definition, the RP address is
   embedded.  So if the RP address changes, then the group addresses
   must also be changed.  This may happen not only when a site is
   renumbered, but also if a site is restructured or the RP is moved
   within the site.  The embedded address is used by routers to
   determine the RP address.  Applications must use new group addresses
   once the RP is not available on the old address.

   Another interesting topic is multicast source renumbering.  With
   traditional multicast a source should be able to start streaming from
   a new address, and nodes belonging to the multicast group will
   immediately start receiving.  There might be some application issues
   though.  If sources are identified by the source address only, then



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   this might appear as a new source to the receivers (as they would
   where IPv6 Privacy addresses are used).  Using RTP a receiver may
   determine it's the same source.

   With Source Specific Multicast (SSM), source renumbering is more
   complicated since receivers must specify exactly which sources they
   want to to receive from.  This means that receivers must somehow be
   told to join the new source addresses, and must be able to discover
   those addresses.

5.5.  Unique Local Addressing

   Section 5 of [22] suggests that the use of Local IPv6 addresses in a
   site results in making communication using these addresses
   independent of renumbering a site's provider based global addresses.
   It also points out that a renumbering episode is not triggered when
   merging multiple sites that have deployed centrally assigned unique
   local addresses[23] because the FC00::/7 ULA prefix assures global
   uniqueness.  The use of ULAs internally should ideally mitigate
   against global address renumbering of nodes, particularly as intra-
   site communication can continue unhindered by the change in global
   address prefixes due to provider migration or re-assignment of prefix
   from an upstream.

   ULAs appear to lend themselves particularly well for long-lived
   sessions (from the categorisation Section 4.2.3) whose nature is
   intra-site, for example local filestore mounts over TCP-mounted NFS:
   With clients using ULA source addresses to mount filestore using the
   ULA of an NFS server, both client and server can have their global
   routing prefix renumbered without consequence to ongoing local
   connections.

   When merging two sites that have both deployed FC00::/7 locally-
   assigned ULA prefixes, the chance of collision is inherently small
   given the pseudo-random global-ID determination algorithm of [22].
   Consideration of possible collisions may be prudent however unlikely
   the occurrence may be.

   With reference to section 2 of [1], the adoption of ULA to assist in
   network renumbering can be considered a 'seasoning' of Baker's
   renumbering procedure: where interaction between local nodes and
   their services cannot suffer the inherent issues observed when
   migrating to a new aggregatable global unicast prefix, the use of
   FC00::/7 unique local addresses may offer an appropriately stable and
   reliable solution.  Whilst on the surface, the use of ULAs in
   networks that also have global connectivity appears straightforward
   and of immediate benefit as regards provider migration, they
   currently suffer significant operational issues including address



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   selection, border filtering, name service provision and routing.

   If addresses under a global routing prefix are deployed alongside
   ULAs, then nodes will need to cater for being multi-addressed with
   multiple addresses of the same (global) syntactic scope, e.g. follow
   the principles laid out in RFC3484 [5].  The administrator should
   ideally be able to set local policy such that nodes use ULAs for
   intranet communications and global addresses for global Internet
   communications.  Note in particular that address selection policy
   different from the defaults of RFC3484 are required for sites that
   have deployed ULAs whilst making use of multicast in scopes greater
   than link-scope (i.e.  FFx3 and higher).

5.5.1.  ULAs, Multicast and Address Selection

   For ordinary unicast traffic, the address selection rules of RFC3484
   will function correctly.  Assuming no higher-precedence rules are
   matched, a multi-addressed host will choose its source address
   through finding the address with the longest matching prefix compared
   with the destination address.  This will pick global unicast
   addresses (i.e. within 2000::/3) for communication with other such
   addresses, and pick ULAs for other ULAs.  This correct behaviour is
   dependent on sites running two-face DNS, however, and therefore
   ensuring remote sites do not know of non-routable ULAs.

   The key problem with ULAs and source address selection occurs,
   however, when sending to multicast addresses.  When it falls to the
   longest matching prefix tests, a ULA will always come out as
   preferable to a global unicast address for matching a multicast
   (FF00::/8) address.

   This does not affect link-local multicast, however, as the preference
   for the appropriate scope will choose the unicast link-local address
   before looking at the longest prefix match (see Section 3.1 of
   RFC3484).  For scopes wider than link-local, however, the ULA will by
   default always be chosen.

   Local policy needs to be implemented such that, e.g., global-scope
   multicast addresses have the same `label' as global aggregatable
   unicast addresses in RFC3484 parlance.  Additional rules could also
   be added such that site- and organisational-scope multicast addresses
   prefer ULAs as source addresses, again by defining an appropriate
   label.

   Whilst no standard policy distribution mechanism exists for
   overriding default RFC3484 preference rules, [24] proposes the use of
   a DHCPv6 option in sites where stateful configuration is available.




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5.5.2.  ULAs with application-layer gateways

   The use of ULAs may not necessarily be accompanied by provider-
   assigned (PA) addresses in connected networks.  If addresses under a
   PA global routing prefix are not used, application layer gateway
   deployment will be required for ULA-only nodes internal to the
   network to communicate with external nodes that are not part of the
   same ULA topology.

   Destination nodes that are addressed under FC00::/7 which are not
   part of the same administrative domain from which the ULA allocation
   of the local node is made, nor part of a predetermined routing
   agreement between two organisations utilising different ULAs for
   nodes within their own sites, would be filtered at the site border as
   usual.

   Typical deployments utilising this technique would include those
   networks where an administrative policy decision has been made to
   restrict those services available to the users, or where connectivity
   is sufficeintly intermittent that as few nodes as possible are
   exposed to the issues of ephemeral connectivity.

5.6.  Anycast addressing

   Syntactically indistinguishable from unicast addresses, 'anycast'
   offers nodes a mean to route traffic toward the topologically nearest
   instance of a service (as represented by an IP address), relying on
   the routing infrastructure to deliver appropriately.  RFC2526 [25]
   defines a set of reserved subnet anycast addresses within the highest
   128 values of the 64 bit IID space.  Of that space, currently only
   three are used, of which one is actively used and is for discovery of
   Mobile IPv6 Home-Agents.  At the current time there are no 'global'
   well-known anycast addresses assigned by IANA.

   In order to participate using anycast, nodes need to be configured as
   routers (to comply with RFC3513 [17]) and exchange routing
   information about the reachability of the specific anycast address.
   This extra level of administration requirement is negligible in the
   context of services as the services themselves would need
   configuration anyway.

   There have been proposals to define globally well-known anycast
   addresses for core services, such as the DNS [26].  Anycast scales
   with regard subnet-anycast in the sense that the global routing
   prefix used to direct packets to an anycast node within a site is no
   different from any other host, and therefore nothing 'special' in the
   global routing architecture is required - only locally within the
   site does the multi-node nature of anycast need to be considered.



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   However, for global well-known anycast addresses to be defined, host-
   specific routes will need to be advertised and distributed throughout
   the entire Internet.  As acknowledged by section 2.6 of [17], this
   presents a severe scaling limit and it is expected that support for
   global anycast sets may be unavailable or very restricted.  A good
   discussion of best current practice for service provision using
   anycast addressing can be found in [27].

   The use of well-known anycast addresses would assist the renumbering
   exercise by removing the requirement to change the addresses in the
   configuration of such services.  The use of anycast DNS would
   alleviate concerns with ensuring node reconfiguration, for example
   when using Stateless DHCPv6 (Section 6.1.2).  While anycasting
   datagram-based services such as DNS pose little problems, anycast
   does not maintain state, and so it would not be guaranteed that
   sequential TCP packets were to go to the same host.  As discussed in
   [28], responses from TCP sessions begun to an anycast address should
   be sent from the unicast address, and future communication should
   continue with this address.  While this means that communication will
   continue with the same unicast address, that address is subject to
   the standard address deprecation and validity.  Note that anycasting
   of this form can be an alternative to site or organisational scope
   multicast service discovery as described in Section 5.4.


6.  Node Configuration Issues

   This section discusses how IPv6 node configuration protocols (both
   stateless and stateful, including DHCPv6, as well as ICMP router
   renumbering messages) can be used to facilitate a renumbering event,
   plus any complications caused by these processes, to which
   consideration should be given.

6.1.  Stateless Address Autoconfiguration

   Many IPv6 networks are likely to be configured using Stateless
   Address AutoConfiguration [6] (SLAAC), and in order to work through
   the multi-staged process as documented by Baker [1], the new prefix
   is introduced via router advertisements, and then the old prefix is
   deprecated, and finally removed.

   Initially the router advertisements will contain only the prefix of
   the old network, then for a time they will contain both the old and
   the new, but with a shorter (zero) lifetime on the old prefix to
   indicate that it is deprecated.  Finally the router advertisements
   will contain only the new prefix.





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6.1.1.  Router Advertisement Lifetimes

   RFC2462 (IPv6 Stateless Autoconfiguration) [6] specifies the
   technique for expiring assigned prefixes and then invalidating them,
   such that a network has opportunity to gracefully withdraw a prefix
   from service whilst not terminally disrupting on-going applications
   that use addresses under it.  Section 5.5.4 of RFC2462 in particular
   details the procedure for deprecation and subsequent invalidation.

   By mandating as a node requirement the ability to phase out addresses
   assigned to an interface, network renumbering is readily facilitated:
   subnet routers update the pre-existing prefix and mark them as
   'deprecated' with a scheduled time for expiration and then advertise
   (when appropriate) the new prefix that should be chosen for all
   outgoing communications.

6.1.2.  Stateless Configuration with DHCPv6

   Sometimes, DHCPv6 will be used alongside SLAAC.  SLAAC will provide
   the address assignment, and DHCPv6 will provide additional host
   configuration options, such as DNS servers.  If any of the DHCPv6
   options are directly related to the IPv6 addresses being renumbered,
   then the configuration must be changed at the appropriate time during
   the renumbering event, even though it itself does not handle the
   address assignments.

   Since the configuration is stateless, the DHCPv6 server will not know
   which clients to contact to inform them to refresh.  Clients of the
   configuration protocol should poll the service to obtain potentially
   updated ancillary data, such as suggested by [29].  It is proposed
   that a new DHCPv6 service option is added to inform clients of an
   upper bound for how long they should wait before re-requesting
   service information.

6.1.3.  Tokenised Interface Identifiers

   IPv6 Stateless Address Auto-configuration (SLAAC) enables network
   administrators to deploy devices in a network and have those devices
   automatically generate global addresses without any administrative
   intervention, and without the need for any stateful configuration
   service such as DHCPv6.

   However, certain services - such as HTTP, SMTP and IMAP - may better
   benefit from having 'well known' identifiers that do not depend on
   the physical hardware address of the server's network interface card,
   e.g. <prefix>::53 for name servers.

   Tokenised addresses offer a facility for administrators to specify



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   the bottom 64 bits of an IPv6 address for a node whilst allowing the
   top 64 bits (the network prefix) to be automatically configured from
   router advertisements.

   Currently, only more recent versions of Sun Microsytems' Solaris
   operating system features ioctl-configured support for tokenised
   interface identifiers, although recent work at Southampton has
   demonstrated that the configuration technique can be introduced
   trivially through simple kernel extensions in Linux.

   As regards renumbering, automatically configured tokenised addresses,
   where the network prefix component is learnt through router
   advertisements, ease the renumbering process where administrators
   have elected to use well known interface identifiers.  Rather than
   having to manually reconfigure the nodes with the new addresses, the
   nodes can rely on automatic configuration techniques to pick up the
   new prefix.

6.2.  Stateful Configuration with DHCPv6

   As opposed to stateless autoconfiguration, IPv6 stateful or managed
   configuration can be achieved through the deployment of DHCPv6.
   Section 18.1.8 of [30] details how a node should respond to the
   receipt of stateful configuration data from a DHCPv6 server where the
   lifetime indicated has expired (is zero).  Section 19.4.1 details how
   clients should respond to being instructed by DHCPv6 servers to
   reconfigure (potentially forceful renumbering).  Section 22.6 details
   how prefix validity time is conveyed (c.f. the equivalent data in
   SLAAC's Router Advertisement).

   In order to renumber such a network, the DHCPv6 server should send
   reconfigure messages to inform the clients that the configuration has
   changed, and the clients should re-request configuration details from
   the DHCPv6 server.  This, of course, relies on the clients correctly
   responding to such messages.

   Where DHCPv6 has been employed, careful consideration about the
   configuration of the service is required such that administrators can
   be confident that clients will re-contact the service to refresh
   their configuration data.  As alluded to in sections 22.4 and 22.5 of
   [30], the configurable timers that offer servers the ability to
   control when clients re-contacts the server about its configuration
   can be set such that clients rarely (if ever) connect to validate
   their configuration set.

   The approach described in [29] allows the lifetime of other
   configuration information supplied by DHCPv6 to be ramped down in
   preparation for a planned renumbering event.



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6.2.1.  Prefix Delegation

   Where stateless autoconfiguration enables hosts to request prefixes
   from link-attached routers, prefix delegation enables routers to
   request a prefix for advertising from superior routers, i.e. routers
   closer to the top of the prefix hierarchy - typically topologically
   closer, therefore, to the provider.  Once the router has been
   delegated prefix(es), it can begin advertising it to the connected
   subnet (perhaps even multi-link) with indicators for hosts to use
   stateful (DHCPv6) or stateless address autoconfiguration as per
   RFC2461.

   There have been two principal approaches to prefix delegation
   proposed: HPD (Hierarchical Prefix Delegation for IPv6), which
   proposed the use of bespoke ICMPv6 messages for prefix delegation,
   and IPv6 Prefix Options for Dynamic Host Configuration Protocol [31],
   which defines a DHCPv6 option type.  Of the two approaches, the
   DHCPv6-based approach has received wide support and is on the
   standards track.

6.2.2.  Source Address Selection Policy distribution

   It has been proposed that DHCPv6 could also be used to distribute
   source address selection policy to nodes [24].  The model proposes
   that consumer edge router receives policies (e.g. from multiple ISPs
   in the case of multi-homed networks) and re-distributes them to end
   nodes.  The end nodes then put them into their local policy table,
   which leads to appropriate source address selection.  Where the
   design goal was a distribution mechanism in light of multi-homed
   networks, the adoption of the technique for the multi-prefix states
   of [1] during renumbering appears appropriate.

6.3.  Router Renumbering

   RFC2894 [7] defines a mechanism for renumbering IPv6 routers
   throughout a network using a bespoke ICMP message type for
   manipulating the set of prefixes deployed throughout subnets.
   Through the use of prefix matching and a rudimentary algebra for bit-
   wise manipulation of prefix data bound to router interfaces, the
   mechanism enables administrators to affect every router within a
   scope from a single administration workstation.  One drawback of
   RFC2894 is that it requires an enterprise-wide IPsec infrastructure
   to be deployed to secure the ICMP messages in order to be compliant.

   The approach utilises multicast communication to the all-routers
   address, FF05::2, scoped to the entire 'site' as determined by router
   filter policy to distribute configuration updates to all (compliant)
   routers.  The mechanism also works with more specific addressing



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   modalities, such as link-local multicast (FF02::2) to reach all
   routers on a specific link, or directed unicast to affect a specific
   router instance.  When surveying current implementations very few
   IPv6 implementations bound their interfaces to the Site-wide All-
   Routers multicast address (FF05::2), and fewer still have
   implementations of RFC2894.

   Example use cases cited in RFC2894 are for deploying global routing
   prefixes across a hierarchical network where site-locals already
   exist (presumably updated now to Unique Local Addresses), and for
   renumbering from an existing prefix to another in a similar manner to
   that proposed by Baker (i.e. the deployment of a new prefix alongside
   the existing one, which is deprecated and subsequently expired and
   removed - using the same mechanism described).

   The specification was developed before the shift in recommendation
   away from the Top-, Next- at Site-Level Aggregation Identifier
   address allocation hierarchy of RFC3513, although the techniques
   documented for renumbering the global routing prefix and subnet ID
   components in the updated address allocation recommendations [17] are
   not affected by the architectural change.

   As with other prefix assignment techniques, it is the responsibility
   of the node to correctly deprecate and then expire the use of a
   previously assigned prefix as defined by the IPv6 Neighbour Discovery
   protocol, RFC2461 [8], section 4.6.2 describing the Prefix
   Information option in particular.


7.  Administrative Considerations for Renumbering

   This section is concerned with factors that affect the renumbering
   procedure, from a network administration viewpoint.  In particular,
   this section discusses areas that a network administrator should
   consider before undertaking a renumbering event, to ensure that it
   proceeds smoothly.  This includes considerations of event frequency,
   scalability, and those relating to delays in information propagation.

7.1.  Router Advertisement Lifetimes

   As discussed in Section 6.1.1, IPv6 Stateless Autoconfiguration
   allows the expiration of assigned prefixes.  This process permits
   existing sessions to continue while preferring a new prefix.  It
   should be noted, however, that there are some limitations in the
   specification that have an impact in renumbering.  In particular, it
   is not possible to reduce a prefix's lifetime to below two hours if
   it has previously been available at a longer validity.  This
   therefore emphasises the need to plan renumbering events in advance



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   if at all possible, to reduce the lifetime as required, within these
   limitations.

7.2.  Border filtering

   Multi-addressing (Section 5.1) allows multiple globally reachable
   addresses to be assigned to node interfaces, but one administrative
   caveat that arises is that of site border filtering.  Not only is it
   the norm for sites to filter at their border router traffic that is
   not destined t
PAFTECH AB 2003-2026
2026-04-24 01:12:15