Unique Local IPv6 Unicast Addresses (original) (raw)

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PROPOSED STANDARD

Network Working Group R. Hinden Request for Comments: 4193 Nokia Category: Standards Track B. Haberman JHU-APL October 2005

              Unique Local IPv6 Unicast Addresses

Status of This Memo

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

Copyright Notice

Copyright (C) The Internet Society (2005).

Abstract

This document defines an IPv6 unicast address format that is globally unique and is intended for local communications, usually inside of a site. These addresses are not expected to be routable on the global Internet.

Table of Contents

1. Introduction ....................................................2 2. Acknowledgements ................................................3 3. Local IPv6 Unicast Addresses ....................................3 3.1. Format .....................................................3 3.1.1. Background ..........................................4 3.2. Global ID ..................................................4 3.2.1. Locally Assigned Global IDs .........................5 3.2.2. Sample Code for Pseudo-Random Global ID Algorithm ...5 3.2.3. Analysis of the Uniqueness of Global IDs ............6 3.3. Scope Definition ...........................................6 4. Operational Guidelines ..........................................7 4.1. Routing ....................................................7 4.2. Renumbering and Site Merging ...............................7 4.3. Site Border Router and Firewall Packet Filtering ...........8 4.4. DNS Issues .................................................8 4.5. Application and Higher Level Protocol Issues ...............9 4.6. Use of Local IPv6 Addresses for Local Communication ........9 4.7. Use of Local IPv6 Addresses with VPNs .....................10

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RFC 4193 Unique Local IPv6 Unicast Addresses October 2005

5. Global Routing Considerations ..................................11 5.1. From the Standpoint of the Internet .......................11 5.2. From the Standpoint of a Site .............................11 6. Advantages and Disadvantages ...................................12 6.1. Advantages ................................................12 6.2. Disadvantages .............................................13 7. Security Considerations ........................................13 8. IANA Considerations ............................................13 9. References .....................................................13 9.1. Normative References ......................................13 9.2. Informative References ....................................14

1. Introduction

This document defines an IPv6 unicast address format that is globally unique and is intended for local communications [[IPV6](#ref-IPV6 ""Internet Protocol, Version 6 (IPv6) Specification"")]. These addresses are called Unique Local IPv6 Unicast Addresses and are abbreviated in this document as Local IPv6 addresses. They are not expected to be routable on the global Internet. They are routable inside of a more limited area such as a site. They may also be routed between a limited set of sites.

Local IPv6 unicast addresses have the following characteristics:

  - Globally unique prefix (with high probability of uniqueness).

  - Well-known prefix to allow for easy filtering at site
    boundaries.

  - Allow sites to be combined or privately interconnected without
    creating any address conflicts or requiring renumbering of
    interfaces that use these prefixes.

  - Internet Service Provider independent and can be used for
    communications inside of a site without having any permanent or
    intermittent Internet connectivity.

  - If accidentally leaked outside of a site via routing or DNS,
    there is no conflict with any other addresses.

  - In practice, applications may treat these addresses like global
    scoped addresses.

This document defines the format of Local IPv6 addresses, how to allocate them, and usage considerations including routing, site border routers, DNS, application support, VPN usage, and guidelines for how to use for local communication inside a site.

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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 [[RFC2119](./rfc2119 ""Key words for use in RFCs to Indicate Requirement Levels"")].

2. Acknowledgements

The underlying idea of creating Local IPv6 addresses described in this document has been proposed a number of times by a variety of people. The authors of this document do not claim exclusive credit. Credit goes to Brian Carpenter, Christian Huitema, Aidan Williams, Andrew White, Charlie Perkins, and many others. The authors would also like to thank Brian Carpenter, Charlie Perkins, Harald Alvestrand, Keith Moore, Margaret Wasserman, Shannon Behrens, Alan Beard, Hans Kruse, Geoff Huston, Pekka Savola, Christian Huitema, Tim Chown, Steve Bellovin, Alex Zinin, Tony Hain, Bill Fenner, Sam Hartman, and Elwyn Davies for their comments and suggestions on this document.

3. Local IPv6 Unicast Addresses

3.1. Format

The Local IPv6 addresses are created using a pseudo-randomly allocated global ID. They have the following format:

  | 7 bits |1|  40 bits   |  16 bits  |          64 bits           |
  +--------+-+------------+-----------+----------------------------+
  | Prefix |L| Global ID  | Subnet ID |        Interface ID        |
  +--------+-+------------+-----------+----------------------------+

Where:

  Prefix            FC00::/7 prefix to identify Local IPv6 unicast
                    addresses.

  L                 Set to 1 if the prefix is locally assigned.
                    Set to 0 may be defined in the future.  See
                    [Section 3.2](#section-3.2) for additional information.

  Global ID         40-bit global identifier used to create a
                    globally unique prefix.  See [Section 3.2](#section-3.2) for
                    additional information.

  Subnet ID         16-bit Subnet ID is an identifier of a subnet
                    within the site.

  Interface ID      64-bit Interface ID as defined in [[ADDARCH](#ref-ADDARCH ""Internet Protocol Version 6 (IPv6) Addressing Architecture"")].

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3.1.1. Background

There were a range of choices available when choosing the size of the prefix and Global ID field length. There is a direct tradeoff between having a Global ID field large enough to support foreseeable future growth and not using too much of the IPv6 address space needlessly. A reasonable way of evaluating a specific field length is to compare it to a projected 2050 world population of 9.3 billion [[POPUL](#ref-POPUL ""World Population Data Sheet of the Population Reference Bureau 2002"")] and the number of resulting /48 prefixes per person. A range of prefix choices is shown in the following table:

Prefix  Global ID     Number of          Prefixes    % of IPv6
        Length        /48 Prefixes       per Person  Address Space

/11       37           137,438,953,472     15         0.049%
/10       38           274,877,906,944     30         0.098%
/9        39           549,755,813,888     59         0.195%
/8        40         1,099,511,627,776    118         0.391%
/7        41         2,199,023,255,552    236         0.781%
/6        42         4,398,046,511,104    473         1.563%

A very high utilization ratio of these allocations can be assumed because the Global ID field does not require internal structure, and there is no reason to be able to aggregate the prefixes.

The authors believe that a /7 prefix resulting in a 41-bit Global ID space (including the L bit) is a good choice. It provides for a large number of assignments (i.e., 2.2 trillion) and at the same time uses less than .8% of the total IPv6 address space. It is unlikely that this space will be exhausted. If more than this were to be needed, then additional IPv6 address space could be allocated for this purpose.

3.2. Global ID

The allocation of Global IDs is pseudo-random [[RANDOM](#ref-RANDOM ""Randomness Requirements for Security"")]. They MUST NOT be assigned sequentially or with well-known numbers. This is to ensure that there is not any relationship between allocations and to help clarify that these prefixes are not intended to be routed globally. Specifically, these prefixes are not designed to aggregate.

This document defines a specific local method to allocate Global IDs, indicated by setting the L bit to 1. Another method, indicated by clearing the L bit, may be defined later. Apart from the allocation method, all Local IPv6 addresses behave and are treated identically.

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The local assignments are self-generated and do not need any central coordination or assignment, but have an extremely high probability of being unique.

3.2.1. Locally Assigned Global IDs

Locally assigned Global IDs MUST be generated with a pseudo-random algorithm consistent with [[RANDOM](#ref-RANDOM ""Randomness Requirements for Security"")]. Section 3.2.2 describes a suggested algorithm. It is important that all sites generating Global IDs use a functionally similar algorithm to ensure there is a high probability of uniqueness.

The use of a pseudo-random algorithm to generate Global IDs in the locally assigned prefix gives an assurance that any network numbered using such a prefix is highly unlikely to have that address space clash with any other network that has another locally assigned prefix allocated to it. This is a particularly useful property when considering a number of scenarios including networks that merge, overlapping VPN address space, or hosts mobile between such networks.

3.2.2. Sample Code for Pseudo-Random Global ID Algorithm

The algorithm described below is intended to be used for locally assigned Global IDs. In each case the resulting global ID will be used in the appropriate prefix as defined in Section 3.2.

 1) Obtain the current time of day in 64-bit NTP format [[NTP](#ref-NTP ""Network Time Protocol (Version 3) Specification, Implementation and Analysis"")].

 2) Obtain an EUI-64 identifier from the system running this
    algorithm.  If an EUI-64 does not exist, one can be created from
    a 48-bit MAC address as specified in [[ADDARCH](#ref-ADDARCH ""Internet Protocol Version 6 (IPv6) Addressing Architecture"")].  If an EUI-64
    cannot be obtained or created, a suitably unique identifier,
    local to the node, should be used (e.g., system serial number).

 3) Concatenate the time of day with the system-specific identifier
    in order to create a key.

 4) Compute an SHA-1 digest on the key as specified in [[FIPS](#ref-FIPS ""Federal Information Processing Standards Publication""), [SHA1](#ref-SHA1 ""US Secure Hash Algorithm 1 (SHA1)"")];
    the resulting value is 160 bits.

 5) Use the least significant 40 bits as the Global ID.

 6) Concatenate FC00::/7, the L bit set to 1, and the 40-bit Global
    ID to create a Local IPv6 address prefix.

This algorithm will result in a Global ID that is reasonably unique and can be used to create a locally assigned Local IPv6 address prefix.

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3.2.3. Analysis of the Uniqueness of Global IDs

The selection of a pseudo random Global ID is similar to the selection of an SSRC identifier in RTP/RTCP defined in Section 8.1 of [[RTP](#ref-RTP ""RTP: A Transport Protocol for Real-Time Applications"")]. This analysis is adapted from that document.

Since Global IDs are chosen randomly (and independently), it is possible that separate networks have chosen the same Global ID. For any given network, with one or more random Global IDs, that has inter-connections to other such networks, having a total of N such IDs, the probability that two or more of these IDs will collide can be approximated using the formula:

  P = 1 - exp(-N**2 / 2**(L+1))

where P is the probability of collision, N is the number of interconnected Global IDs, and L is the length of the Global ID.

The following table shows the probability of a collision for a range of connections using a 40-bit Global ID field.

  Connections      Probability of Collision

      2                1.81*10^-12
     10                4.54*10^-11
    100                4.54*10^-09
   1000                4.54*10^-07
  10000                4.54*10^-05

Based on this analysis, the uniqueness of locally generated Global IDs is adequate for sites planning a small to moderate amount of inter-site communication using locally generated Global IDs.

3.3. Scope Definition

By default, the scope of these addresses is global. That is, they are not limited by ambiguity like the site-local addresses defined in [[ADDARCH](#ref-ADDARCH ""Internet Protocol Version 6 (IPv6) Addressing Architecture"")]. Rather, these prefixes are globally unique, and as such, their applicability is greater than site-local addresses. Their limitation is in the routability of the prefixes, which is limited to a site and any explicit routing agreements with other sites to propagate them (also see Section 4.1). Also, unlike site-locals, a site may have more than one of these prefixes and use them at the same time.

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4. Operational Guidelines

The guidelines in this section do not require any change to the normal routing and forwarding functionality in an IPv6 host or router. These are configuration and operational usage guidelines.

4.1. Routing

Local IPv6 addresses are designed to be routed inside of a site in the same manner as other types of unicast addresses. They can be carried in any IPv6 routing protocol without any change.

It is expected that they would share the same Subnet IDs with provider-based global unicast addresses, if they were being used concurrently [[GLOBAL](#ref-GLOBAL ""IPv6 Global Unicast Address Format"")].

The default behavior of exterior routing protocol sessions between administrative routing regions must be to ignore receipt of and not advertise prefixes in the FC00::/7 block. A network operator may specifically configure prefixes longer than FC00::/7 for inter-site communication.

If BGP is being used at the site border with an ISP, the default BGP configuration must filter out any Local IPv6 address prefixes, both incoming and outgoing. It must be set both to keep any Local IPv6 address prefixes from being advertised outside of the site as well as to keep these prefixes from being learned from another site. The exception to this is if there are specific /48 or longer routes created for one or more Local IPv6 prefixes.

For link-state IGPs, it is suggested that a site utilizing IPv6 local address prefixes be contained within one IGP domain or area. By containing an IPv6 local address prefix to a single link-state area or domain, the distribution of prefixes can be controlled.

4.2. Renumbering and Site Merging

The use of Local IPv6 addresses in a site results in making communication that uses these addresses independent of renumbering a site's provider-based global addresses.

When merging multiple sites, the addresses created with these prefixes are unlikely to need to be renumbered because all of the addresses have a high probability of being unique. Routes for each specific prefix would have to be configured to allow routing to work correctly between the formerly separate sites.

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4.3. Site Border Router and Firewall Packet Filtering

While no serious harm will be done if packets with these addresses are sent outside of a site via a default route, it is recommended that routers be configured by default to keep any packets with Local IPv6 addresses from leaking outside of the site and to keep any site prefixes from being advertised outside of their site.

Site border routers and firewalls should be configured to not forward any packets with Local IPv6 source or destination addresses outside of the site, unless they have been explicitly configured with routing information about specific /48 or longer Local IPv6 prefixes. This will ensure that packets with Local IPv6 destination addresses will not be forwarded outside of the site via a default route. The default behavior of these devices should be to install a "reject" route for these prefixes. Site border routers should respond with the appropriate ICMPv6 Destination Unreachable message to inform the source that the packet was not forwarded. [[ICMPV6](#ref-ICMPV6 ""Internet Control Message Protocol (ICMPv6) for the Internet Protocol Version 6 (IPv6) Specification"")]. This feedback is important to avoid transport protocol timeouts.

Routers that maintain peering arrangements between Autonomous Systems throughout the Internet should obey the recommendations for site border routers, unless configured otherwise.

4.4. DNS Issues

At the present time, AAAA and PTR records for locally assigned local IPv6 addresses are not recommended to be installed in the global DNS.

For background on this recommendation, one of the concerns about adding AAAA and PTR records to the global DNS for locally assigned Local IPv6 addresses stems from the lack of complete assurance that the prefixes are unique. There is a small possibility that the same locally assigned IPv6 Local addresses will be used by two different organizations both claiming to be authoritative with different contents. In this scenario, it is likely there will be a connection attempt to the closest host with the corresponding locally assigned IPv6 Local address. This may result in connection timeouts, connection failures indicated by ICMP Destination Unreachable messages, or successful connections to the wrong host. Due to this concern, adding AAAA records for these addresses to the global DNS is thought to be unwise.

Reverse (address-to-name) queries for locally assigned IPv6 Local addresses MUST NOT be sent to name servers for the global DNS, due to the load that such queries would create for the authoritative name servers for the ip6.arpa zone. This form of query load is not specific to locally assigned Local IPv6 addresses; any current form

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of local addressing creates additional load of this kind, due to reverse queries leaking out of the site. However, since allowing such queries to escape from the site serves no useful purpose, there is no good reason to make the existing load problems worse.

The recommended way to avoid sending such queries to nameservers for the global DNS is for recursive name server implementations to act as if they were authoritative for an empty d.f.ip6.arpa zone and return RCODE 3 for any such query. Implementations that choose this strategy should allow it to be overridden, but returning an RCODE 3 response for such queries should be the default, both because this will reduce the query load problem and also because, if the site administrator has not set up the reverse tree corresponding to the locally assigned IPv6 Local addresses in use, returning RCODE 3 is in fact the correct answer.

4.5. Application and Higher Level Protocol Issues

Application and other higher level protocols can treat Local IPv6 addresses in the same manner as other types of global unicast addresses. No special handling is required. This type of address may not be reachable, but that is no different from other types of IPv6 global unicast address. Applications need to be able to handle multiple addresses that may or may not be reachable at any point in time. In most cases, this complexity should be hidden in APIs.

From a host's perspective, the difference between Local IPv6 and other types of global unicast addresses shows up as different reachability and could be handled by default in that way. In some cases, it is better for nodes and applications to treat them differently from global unicast addresses. A starting point might be to give them preference over global unicast, but fall back to global unicast if a particular destination is found to be unreachable. Much of this behavior can be controlled by how they are allocated to nodes and put into the DNS. However, it is useful if a host can have both types of addresses and use them appropriately.

Note that the address selection mechanisms of [[ADDSEL](#ref-ADDSEL ""Default Address Selection for Internet Protocol version 6 (IPv6)"")], and in particular the policy override mechanism replacing default address selection, are expected to be used on a site where Local IPv6 addresses are configured.

4.6. Use of Local IPv6 Addresses for Local Communication

Local IPv6 addresses, like global scope unicast addresses, are only assigned to nodes if their use has been enabled (via IPv6 address autoconfiguration [[ADDAUTO](#ref-ADDAUTO ""IPv6 Stateless Address Autoconfiguration"")], DHCPv6 [[DHCP6](#ref-DHCP6 ""Dynamic Host Configuration Protocol for IPv6 (DHCPv6)"")], or manually). They are

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not created automatically in the way that IPv6 link-local addresses are and will not appear or be used unless they are purposely configured.

In order for hosts to autoconfigure Local IPv6 addresses, routers have to be configured to advertise Local IPv6 /64 prefixes in router advertisements, or a DHCPv6 server must have been configured to assign them. In order for a node to learn the Local IPv6 address of another node, the Local IPv6 address must have been installed in a naming system (e.g., DNS, proprietary naming system, etc.) For these reasons, controlling their usage in a site is straightforward.

To limit the use of Local IPv6 addresses the following guidelines apply:

  - Nodes that are to only be reachable inside of a site:  The local
    DNS should be configured to only include the Local IPv6
    addresses of these nodes.  Nodes with only Local IPv6 addresses
    must not be installed in the global DNS.

  - Nodes that are to be limited to only communicate with other
    nodes in the site:  These nodes should be set to only
    autoconfigure Local IPv6 addresses via [[ADDAUTO](#ref-ADDAUTO ""IPv6 Stateless Address Autoconfiguration"")] or to only
    receive Local IPv6 addresses via [[DHCP6](#ref-DHCP6 ""Dynamic Host Configuration Protocol for IPv6 (DHCPv6)"")].  Note: For the case
    where both global and Local IPv6 prefixes are being advertised
    on a subnet, this will require a switch in the devices to only
    autoconfigure Local IPv6 addresses.

  - Nodes that are to be reachable from inside of the site and from
    outside of the site:  The DNS should be configured to include
    the global addresses of these nodes.  The local DNS may be
    configured to also include the Local IPv6 addresses of these
    nodes.

  - Nodes that can communicate with other nodes inside of the site
    and outside of the site: These nodes should autoconfigure global
    addresses via [[ADDAUTO](#ref-ADDAUTO ""IPv6 Stateless Address Autoconfiguration"")] or receive global address via [[DHCP6](#ref-DHCP6 ""Dynamic Host Configuration Protocol for IPv6 (DHCPv6)"")].
    They may also obtain Local IPv6 addresses via the same
    mechanisms.

4.7. Use of Local IPv6 Addresses with VPNs

Local IPv6 addresses can be used for inter-site Virtual Private Networks (VPN) if appropriate routes are set up. Because the addresses are unique, these VPNs will work reliably and without the need for translation. They have the additional property that they will continue to work if the individual sites are renumbered or merged.

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5. Global Routing Considerations

Section 4.1 provides operational guidelines that forbid default routing of local addresses between sites. Concerns were raised to the IPv6 working group and to the IETF as a whole that sites may attempt to use local addresses as globally routed provider- independent addresses. This section describes why using local addresses as globally-routed provider-independent addresses is unadvisable.

5.1. From the Standpoint of the Internet

There is a mismatch between the structure of IPv6 local addresses and the normal IPv6 wide area routing model. The /48 prefix of an IPv6 local addresses fits nowhere in the normal hierarchy of IPv6 unicast addresses. Normal IPv6 unicast addresses can be routed hierarchically down to physical subnet (link) level and only have to be flat-routed on the physical subnet. IPv6 local addresses would have to be flat-routed even over the wide area Internet.

Thus, packets whose destination address is an IPv6 local address could be routed over the wide area only if the corresponding /48 prefix were carried by the wide area routing protocol in use, such as BGP. This contravenes the operational assumption that long prefixes will be aggregated into many fewer short prefixes, to limit the table size and convergence time of the routing protocol. If a network uses both normal IPv6 addresses [[ADDARCH](#ref-ADDARCH ""Internet Protocol Version 6 (IPv6) Addressing Architecture"")] and IPv6 local addresses, these types of addresses will certainly not aggregate with each other, since they differ from the most significant bit onwards. Neither will IPv6 local addresses aggregate with each other, due to their random bit patterns. This means that there would be a very significant operational penalty for attempting to use IPv6 local address prefixes generically with currently known wide area routing technology.

5.2. From the Standpoint of a Site

There are a number of design factors in IPv6 local addresses that reduce the likelihood that IPv6 local addresses will be used as arbitrary global unicast addresses. These include:

  - The default rules to filter packets and routes make it very
    difficult to use IPv6 local addresses for arbitrary use across
    the Internet.  For a site to use them as general purpose unicast
    addresses, it would have to make sure that the default rules
    were not being used by all other sites and intermediate ISPs
    used for their current and future communication.

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  - They are not mathematically guaranteed to be unique and are not
    registered in public databases.  Collisions, while highly
    unlikely, are possible and a collision can compromise the
    integrity of the communications.  The lack of public
    registration creates operational problems.

  - The addresses are allocated randomly.  If a site had multiple
    prefixes that it wanted to be used globally, the cost of
    advertising them would be very high because they could not be
    aggregated.

  - They have a long prefix (i.e., /48) so a single local address
    prefix doesn't provide enough address space to be used
    exclusively by the largest organizations.

6. Advantages and Disadvantages

6.1. Advantages

This approach has the following advantages:

  - Provides Local IPv6 prefixes that can be used independently of
    any provider-based IPv6 unicast address allocations.  This is
    useful for sites not always connected to the Internet or sites
    that wish to have a distinct prefix that can be used to localize
    traffic inside of the site.

  - Applications can treat these addresses in an identical manner as
    any other type of global IPv6 unicast addresses.

  - Sites can be merged without any renumbering of the Local IPv6
    addresses.

  - Sites can change their provider-based IPv6 unicast address
    without disrupting any communication that uses Local IPv6
    addresses.

  - Well-known prefix that allows for easy filtering at site
    boundary.

  - Can be used for inter-site VPNs.

  - If accidently leaked outside of a site via routing or DNS, there
    is no conflict with any other addresses.

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6.2. Disadvantages

This approach has the following disadvantages:

  - Not possible to route Local IPv6 prefixes on the global Internet
    with current routing technology.  Consequentially, it is
    necessary to have the default behavior of site border routers to
    filter these addresses.

  - There is a very low probability of non-unique locally assigned
    Global IDs being generated by the algorithm in [Section 3.2.3](#section-3.2.3).
    This risk can be ignored for all practical purposes, but it
    leads to a theoretical risk of clashing address prefixes.

7. Security Considerations

Local IPv6 addresses do not provide any inherent security to the nodes that use them. They may be used with filters at site boundaries to keep Local IPv6 traffic inside of the site, but this is no more or less secure than filtering any other type of global IPv6 unicast addresses.

Local IPv6 addresses do allow for address-based security mechanisms, including IPsec, across end to end VPN connections.

8. IANA Considerations

The IANA has assigned the FC00::/7 prefix to "Unique Local Unicast".

9. References

9.1. Normative References

[ADDARCH] Hinden, R. and S. Deering, "Internet Protocol Version 6 (IPv6) Addressing Architecture", RFC 3513, April 2003.

[FIPS] "Federal Information Processing Standards Publication", (FIPS PUB) 180-1, Secure Hash Standard, 17 April 1995.

[GLOBAL] Hinden, R., Deering, S., and E. Nordmark, "IPv6 Global Unicast Address Format", RFC 3587, August 2003.

[ICMPV6] Conta, A. and S. Deering, "Internet Control Message Protocol (ICMPv6) for the Internet Protocol Version 6 (IPv6) Specification", RFC 2463, December 1998.

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[IPV6] Deering, S. and R. Hinden, "Internet Protocol, Version 6 (IPv6) Specification", RFC 2460, December 1998.

[NTP] Mills, D., "Network Time Protocol (Version 3) Specification, Implementation and Analysis", RFC 1305, March 1992.

[RANDOM] Eastlake, D., 3rd, Schiller, J., and S. Crocker, "Randomness Requirements for Security", BCP 106, RFC 4086, June 2005.

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

[SHA1] Eastlake 3rd, D. and P. Jones, "US Secure Hash Algorithm 1 (SHA1)", RFC 3174, September 2001.

9.2. Informative References

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

[ADDSEL] Draves, R., "Default Address Selection for Internet Protocol version 6 (IPv6)", RFC 3484, February 2003.

[DHCP6] Droms, R., Bound, J., Volz, B., Lemon, T., Perkins, C., and M. Carney, "Dynamic Host Configuration Protocol for IPv6 (DHCPv6)", RFC 3315, July 2003.

[POPUL] Population Reference Bureau, "World Population Data Sheet of the Population Reference Bureau 2002", August 2002.

[RTP] Schulzrinne, H., Casner, S., Frederick, R., and V. Jacobson, "RTP: A Transport Protocol for Real-Time Applications", STD 64, RFC 3550, July 2003.

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Authors' Addresses

Robert M. Hinden Nokia 313 Fairchild Drive Mountain View, CA 94043 USA

Phone: +1 650 625-2004 EMail: bob.hinden@nokia.com

Brian Haberman Johns Hopkins University Applied Physics Lab 11100 Johns Hopkins Road Laurel, MD 20723 USA

Phone: +1 443 778 1319 EMail: brian@innovationslab.net

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