IPv6 Assignment and Allocation Policy Document

Dear colleagues,

The RIPE NCC is pleased to make available the latest draft "IPv6 
Assignment and Allocation Policy Document" for your information. This 
document http://www.ripe.net/lir/registries/ipv6.html is the result of 
a collaborative effort of all the Regional Internet Registries (APNIC, 
ARIN, and RIPE NCC) and aims to provide a responsible, globally 
consistent framework for the management of IPv6 address space. This new 
version takes into consideration suggestions and comments made by the 
RIPE community on the ipv6-wg mailing list and at the last RIPE 
meeting, as well as comments made by other communities (such as the 
ARIN and APNIC members, the IETF and the IAB).

IPv6 address space is a public resource and, therefore, its management 
involves developing policies which achieve the best possible balance of 
the needs of all members of the Internet community. The RIPE NCC 
encourages you, as a member of the Internet community, to read this 
document and consider its implications. We invite you to make any 
comments you feel would be constructive to the development of a further 
draft.

In order to ensure global consensus, the discussion of this draft will 
take place on the 6bone mailing list. This way the comments are all 
collected in one place, and interested parties from all 
regions/communities can participate. To join this list, please refer to 
http://www.6bone.net/6bone_email.html. If you would prefer to make 
private comments about this document, please contact Paula Caslav 
<paula at ripe.net>.

Kind regards,

Paula Caslav
RIPE NCC

IPv6 ASSIGNMENT AND ALLOCATION POLICY DOCUMENT (5th draft 16 April 1999)

[* Important note: Throughout this draft, several sections require
numerical values to be specified, pending further discussion and comment
from the Internet community. In such cases the variable "X*" has been 
used
in place of the numerical value. Where relevant the variable is 
accompanied
by a suggested value range, such as "range=3-6".]

TABLE OF CONTENTS

Abstract

1. Scope

2. IPv6 Address Space and the Internet Registry System

2.1 The Internet Registry System Hierarchy

2.2 Goals of the Internet Registry System

3. IPv6 Technical Framework

3.1 IPv6 Addressing Hierarchy

3.2 Initial IPv6 Addressing Hierarchy

4. Addressing Policies

4.1 IPv6 Addresses Not to be Considered Property

4.2 Allocations

4.3 Assignments

4.4 Reclamation Methods/Conditions

5. Organizations Operating in More than One Region

6. DNS and Reverse Address Mapping

7. Glossary

8. List of References

ABSTRACT

This document describes the registry system for distributing globally
unique unicast IPv6 address space. IPv6 address space is distributed in 
a
hierarchical manner (as is IPv4 address space), managed by the IANA and
further delegated by the Regional Internet Registries (Regional IRs) as
described in RFC 1881. In the case of IPv6, the Regional IRs allocate
Top-Level Aggregation Identifiers (TLAs) to organizations, which, as TLA
Registries, in turn allocate or assign address space to other Internet
Service Providers (ISPs) and end users. ISPs then serve as Next Level
Aggregation (NLA) Registries for their customers.

This document describes the responsibilities, policies, and procedures
associated with IPv6 address space management, to be followed by all
organizations within the allocation hierarchy. The intention of this
document is to provide a framework for clear understanding and 
consistent
application of those responsibilities, policies, and procedures 
throughout
all layers of the hierarchy.

1. SCOPE

This document first describes the global Internet Registry system for 
the
distribution of IPv6 address space (as defined in RFC 2374) and the
management of that address space. It then describes the policies and
guidelines governing the distribution of IPv6 address space. The 
policies
set forth in this document should be considered binding on all
organizations that receive allocations or assignments of IPv6 address 
space
either directly or indirectly from a Regional IR.

This document describes the primary operational policies and guidelines 
in
use by all Regional IRs. Regional IRs may implement supplementary 
policies
and guidelines to meet the specific needs of the Internet communities
within their regions.

These policies and guidelines are subject to change based upon the
development of operational experience and technological innovations, 
which
together emerge as Internet best practice.

The structure of this document is as follows:

Section 2, "IPv6 Address Space and the Internet Registry System", 
describes
the hierarchical structure of responsible organizations within the 
Internet
Registry system and the explicit goals that determine the framework of
policies for allocation and assignment of IPv6 address space.

Section 3, "IPv6 Technical Framework", explains the IPv6 addressing 
format
and describes the differences between TLA, NLA, and SLA blocks.

Section 4, "Addressing Policies", describes the requirements for 
applying
for a TLA allocation and the policies that apply to such allocations. It
discusses how TLA registries can allocate space to other ISPs (NLA 
blocks)
and assign address space to end-users (SLAs).

Section 5, "Organizations Operating in More than One Region", describes 
the
requirements for organizations operating in more than one IR region
requesting address space.

Section 6, "DNS and Reverse Address Mapping", describes the role of the
Regional IRs in providing reverse delegation and explains how the 
Regional
IRs can manage subsidiary reverse delegation of allocated/assigned 
address
space.

Section 7, "Glossary", provides a listing of terms used in this document
along with their definitions.

Section 8, "List of References", provides a list of documents 
referenced in
this document.

2 IPv6 ADDRESS SPACE AND THE INTERNET REGISTRY SYSTEM

IPv6 unicast addresses are aggregatable with contiguous bit-wise masks 
used
to define routable prefixes, using a method similar to that used for 
IPv4
addresses under CIDR. With IPv6, scarcity of address space is assumed 
to no
longer exist for the end-user. However, inefficient assignments of 
address
space and rapid expansion of routing tables remain as serious potential
impediments to the scalability of the Internet. The Internet Registry
system exists to ensure that IPv6 address space is managed in a globally
consistent, fair, and responsible manner that minimizes wastage, and
maximizes aggregation within the routing structure.

2.1 The Internet Registry System Hierarchy

The hierarchical Internet Registry system exists to enable the goals
described in this document to be met. In the case of IPv6, this 
hierarchy
consists of the following levels, as seen from the top down: IANA, 
Regional
Internet Registries, TLA, NLA Registries, and end-sites.

2.1.1 IANA

The Internet Assigned Numbers Authority (IANA) has authority over all IP
number spaces used in the Internet, including IPv6 address space. IANA
allocates parts of the IPv6 address space to Regional Internet 
Registries
(Regional IRs) according to their established needs.

2.1.2 Regional Internet Registries

Regional IRs operate in large geographical regions such as continents.
Currently, three Regional IRs exist: ARIN serving North and South 
America,
the Caribbean, and sub-Saharan Africa; RIPE NCC serving Europe, the 
Middle
East, and parts of Africa; and APNIC serving the Asia Pacific region. 
These
Regional IRs also serve areas beyond their core service areas to ensure
that all parts of the globe are covered. Additional Regional IRs may be
established in the future, although their number will remain relatively
low. Service areas will be of continental dimensions.

Regional IRs are established under the authority of the IANA. This 
requires
consensus within the Internet community and among the ISPs of the
respective region.

2.1.3 TLA Registries

TLA Registries are established under the authority of the appropriate
Regional IR to enable "custodianship" of a TLA or sub-TLA block of IPv6
addresses. TLA Registries perform roles and bear responsibilities which 
are
analogous and consistent with those of the Regional IR within their
designated network services and infrastructures.

2.1.4 NLA Registries

[to be written]

2.1.5 End-sites

[to be written]

2.2 Goals of the Internet Registry System

The goals described in this section have been formulated by the Internet
community with specific reference to IPv6 address space. They reflect 
the
mutual interest of all members of that community in ensuring that the
Internet is able to function and grow to the maximum extent possible. 
It is
the responsibility of every IR to ensure that all assignments and
allocations of IPv6 address space are consistent with these goals.

These goals will occasionally be in conflict with the interests of
individual ISPs or end-users. Therefore, IRs evaluating requests for
allocations and assignments must carefully analyze all relevant
considerations and must seek to balance the needs of individual 
applicants
with the needs of the Internet community as a whole. The policies and
guidelines described in this document are intended to help IRs balance
these needs in consistent and equitable ways. Full documentation of, and
transparency within, the decision making process must also be 
maintained in
order to achieve this result.

2.2.1 Uniqueness

Each IPv6 unicast address must be globally unique. This is an absolute
requirement for guaranteeing that every host on the Internet can be
uniquely identified.

2.2.2 Aggregation

IPv6 addresses must be distributed in a hierarchical manner, permitting 
the
aggregation of routing information and limiting the number of routing
entries advertised into the Internet. This is necessary to ensure proper
operation of Internet routing and to maximize the routing system's 
ability
to meet the demands of both likely and unforeseeable future increases in
both size and topological complexity. In IPv6, aggregation of internal 
and
external routes is the primary goal.

This goal is motivated by the problems which arose in IPv4 network
addressing. IPv4 address allocations have not been sufficiently
hierarchical to ensure efficient routing across the Internet. 
Inefficient
use of classful allocations led to an excess of routing entries 
appearing
in the default-free routing table. Furthermore, increased complexity of
network topologies led to IPv4 prefixes being announced many times via
different routes.

Responsible policies and guidelines must limit the number of top level
prefixes that are announced on the Internet so as to ensure that the
problems of IPv4 are not repeated in IPv6. Such policies and guidelines
will always reflect the constraints of current router technology and 
will
be subject to reevaluation as that technology advances. Furthermore, 
such
policies and guidelines will be reviewed according to a model consistent
with that provided in RFC 2374 and RFC 2450. Under this model, a 
threshold
is set significantly below the number of default-free routing table 
entries
considered to be currently supportable. If the number of entries reaches
that threshold, then allocation criteria are to be reviewed (see section
4.4).

2.2.3 Efficient Address Usage

Although IPv6 address resources are abundant, the global Internet 
community
must be careful to avoid repeating the problems that arose in relation 
to
IPv4 addresses. Specifically, even though "conservation" of IPv6 
addresses
is not a significant concern, registries must implement policies and
guidelines that prevent organizations from stockpiling addresses. IPv6
addressing architecture allows considerable flexibility for end-users;
however, all registries must avoid wasteful use of TLA and NLA address
space by ensuring that allocations and assignments are made efficiently 
and
based on demonstrated need.

2.2.4 Registration

Every assignment and allocation of IPv6 Internet address space must be
registered in a publicly accessible database. This is necessary to 
ensure
uniqueness and to provide information for Internet trouble shooting at 
all
levels. It also reflects the expectation of the Internet community that 
all
custodians of public resources, such as public address space, should be
identifiable. As is the case with IPv4 addresses, each of the Regional 
IRs
will maintain a public database where all IPv6 allocations and 
assignments
are entered.



3. IPv6 TECHNICAL FRAMEWORK

3.1 IPv6 Addressing Hierarchy

RFC 2374 specifies that aggregatable addresses are organized into a
topological hierarchy, consisting of a public topology, a site topology,
and interface identifiers. These in turn map to the following:

| 3|  13 | 8 |   24   |   16   |    64 bits                 |
+--+-----+---+--------+--------+----------------------------+
|FP| TLA |RES|   NLA  |  SLA   |   Interface ID             |
|  | ID  |   |   ID   |  ID    |                            |
+--+-----+---+--------+--------+----------------------------+
|-- public topology---|  site  |     Interface              |
|                     |topology|                            |
+---------------------+--------+----------------------------+
|                              |                            |
|-------- network portion----->+<-----host portion----------|
|                             /64                           |
|-----------------------------------------------------------|

The site topology is represented by a /48, giving each site 16 bits to
create their local topology. The host portion is represented by the 
last 64
bits of the address. A /64 is the minimum network prefix that can be
assigned within a site. Additional subnets would require assignment of
additional prefixes of the same size or shorter.

Because all interface IDs are required to be in the EUI-64 format (as
specified in RFC 2373 and RFC 2374) the boundary between the network and
host portions is "hard" and ID address space cannot be further 
sub-divided.

Also, in order to facilitate multihoming, the boundary between the 
public
topology and the site topology division at the /48 is also hard. (RFC 
2374
explains this more completely.)

3.2 Initial IPv6 Addressing Hierarchy

A modified version of the addressing hierarchy described in section 3.1
will be used for the initial IPv6 allocations. The first TLA prefix (TLA
0x0001) has been divided into further blocks, called "sub-TLAs", with a
13-bit sub-TLA identifier. Part of the reserved space and the NLA space
have been used for this purpose.

This modified addressing hierarchy has the following format and prefix
boundaries:



Format boundaries

| 3|    13    |    13   | 6 |   13   |   16   |     64 bits        |
+--+----------+---------+---+--------+--------+--------------------+
|FP|   TLA    | sub-TLA |Res|   NLA  |  SLA   |    Interface ID    |
|  |    ID    |         |   |    ID  |   ID   |                    |
+--+----------+---------+---+--------+--------+--------------------+


Prefix boundaries (starting at bit 0)

            number of the   number of the           ID
            left-most       right-most       longest   length
            bit             bit              prefix    (in bits)
            ************    ************     *******   ********
TLA ID       3                  15             /16        13
sub-TLA ID   16                 28             /29        13
Reserved     29                 34
NLA ID       35                 47             /48        13
SLA ID       48                 63             /64        16

For purposes of a "slow start" of a sub-TLA, the first allocation to a 
TLA
Registry will be a /35 block (representing 13 bits of NLA space). The
Regional IR making the allocation will reserve an additional six bits 
for
the sub-TLA registry. When the TLA Registry has fully used the first /35
block, the Regional IR will use the reserved space to make subsequent
allocations (see section 4.2.5).

All router interfaces are required to have at least one link-local 
unicast
address or site-local address. It is recommended that site-local 
addresses
be used for all point-to-point links, loopback addresses, and so forth. 
As
these are not required to be visible outside the site's network, they do
not require public address space. Any global unicast address space 
assigned
must not be used for link-local or site-local purposes as there is 
address
space reserved for these purposes. (Note that "all 1s" and "all 0s" are
valid unless specifically excluded through reservation. See list of
reserved addresses in RFC 2373.)

4. ADDRESSING POLICIES

As described above, Regional IRs make IPv6 allocations to requesting
organizations that qualify for a sub-TLA (TLA Registries). TLA 
Registries
then allocate NLA space to ISPs that are their customers (NLA 
Registries).
NLA Registries in turn assign SLA space to end-users. TLA Registries may
also assign SLA space directly to end-users. TLA Registries and NLA
Registries also use SLA space to address their own networks. This
hierarchical structure of allocations and assignments is designed to
maximize the aggregation of routing information.

4.1 IPv6 Addresses not to be considered property

All allocations and assignments of IPv6 address space are made on the 
basis
that the holder of the address space is not to be considered the 
"owner" of
the address space, and that all such allocations and assignments always
remain subject to the current policies and guidelines described in this
document. Holders of address space may potentially be required, at some
time in the future, to return their address space and renumber their
networks in accordance with the consensus of the Internet community in
ensuring that the goals of aggregation and efficiency continue to be 
met.

4.1.1 Terms of allocations and assignments to be specified

At the time of making any allocation or assignment of IPv6 address 
space,
Registries should specify the terms upon which the address space is to 
be
held and the procedures for reviewing those terms in the future. Such 
terms
and procedures should be consistent with the policies and guidelines
described in this document.

4.2 Allocations

In order to meet the goal of aggregation (section 2.2.2) Regional IRs 
will
only allocate sub-TLA address space to organizations that meet the 
criteria
specified in one or more of the following sections: 4.2.1 "General 
Criteria
for Initial Sub-TLA Allocation" and 4.2.2 "Criteria for sub-TLA 
Allocations
in Transitional 'Bootstrap' Phase".

The criteria for an initial allocation to an organization are different
from the criteria that apply for subsequent allocations. Whereas the
requirements for an initial allocation are based on technical
considerations, requests for additional address space are evaluated 
solely
on the basis of the usage rate of the initial allocation.

The following criteria for sub-TLA allocations reflect the intentions of
the authors of the IPv6 addressing architecture (see RFC 2374, RFC 2373,
and RFC 2950), namely that addressing policies must promote the goal of
aggregation. The basis of these criteria is that it is primarily the
organizations acting as transit providers or exchange points that will 
be
involved in the top-level routing hierarchy and that other Service
Providers should receive NLA address space from these organizations.

4.2.1 General Criteria for Initial Sub-TLA Allocation

Subject to sections 4.2.2, and 4.2.3, Regional IRs will only make an
initial allocation of sub-TLA address space to organizations that meet
criterion (a) AND at least one part of criterion (b), as follows:

a. The requesting organization's IPv6 network must have BGP peering
relationships with the IPv6 networks of at least three other 
organizations
that have a sub-TLA allocated to them.

AND either

b(i). The requesting organization must have reassigned IPv6 addresses
received from its upstream provider or providers to [X*: range=30-50] 
SLA
customer sites with routed networks connected by permanent or
semi-permanent links.

OR

b(ii). The requesting organization must demonstrate a clear intent to
provide IPv6 service within [X*: range=6-12] months after receiving
allocated address space. This must be substantiated by such documents 
as an
engineering plan or deployment plan.



4.2.2 Criteria for sub-TLA Allocations in Transitional "Bootstrap" Phase

By requiring BGP peering relationships with at least three other IPv6
networks, section 4.2.1 creates a problem during the initial period of
transition to IPv6 network addressing, namely that too few organizations
will meet the general criteria during this phase (referred to as the
"bootstrap phase"). The criteria in this section provide an interim
mechanism for eligibility that will only apply during the bootstrap 
phase,
that is until the number of organizations operating IPv6 networks is
considered sufficient for the general criteria to operate. (See section
4.2.2.1 "Duration of Bootstrap Phase".)

Notwithstanding section 4.2.1, during the bootstrap phase, Regional IRs
will make an initial allocation of sub-TLA address space to 
organizations
that meet criterion (a) AND criterion (b) AND either criterion (c) OR
criterion (d).

a. The requesting organization's network must have BGP peering
relationships with at least three other public Autonomous Systems in the
default-free zone.

AND

b. The requesting organization must show that it plans to provide
production IPv6 service within [X*: range=6-12] months after receiving
allocated address space. This must be substantiated by such documents 
as an
engineering plan or a deployment plan.

AND either

c. The requesting organization must be an IPv4 transit provider and must
show that it already has issued IPv4 address space to [X*: range=30-50]
customer sites that can meet the criteria for a /48 IPv6 assignment. In
this case, the organization must have an up-to-date routing policy
registered in one of the databases of the Internet Routing Registry, 
which
the Regional IR may verify by checking the routing table information on 
one
of the public looking glass sites).

OR
d. The requesting organization must demonstrate that it has experience 
with
IPv6 through active use of a pseudo-TLA (pTLA) registered to it for at
least six months prior to requesting a sub-TLA. The regional IRs may
require documentation of acceptable 6Bone routing policies and practice
from the requesting organization.

4.2.2.1 Duration of Bootstrap Phase

The eligibility criteria in this section will only apply until 100
requesting organizations have received allocations of sub-TLA address
space, provided that no more than 60 of these organizations are located 
in
one Regional IR's region. After this threshold has been reached, the
bootstrap phase will be considered to be over and Regional IRs will only
make allocations to organizations that meet the general criteria in 
section
4.2.1.

If 60 organizations have been allocated sub-TLAs within one region (but
less than 100 have been allocated worldwide) then the bootstrap phase
within that region will be considered to be over. Additional 
applications
from that region must satisfy the general criteria in section 4.2.1, 
while
applications from other regions need only satisfy the bootstrap 
criteria.

When 100 sub-TLA registries are formed worldwide, there will be enough
choices for new prospective sub-TLAs to find others to connect to and 
the
bootstrap phase can end. The regional limitation on bootstrapping is
intended to prevent one region consuming all available bootstrap
opportunities before IPv6 deployment has started in other regions.

4.2.3 Special considerations

4.2.3.1 Exchange Points

It is expected that some exchange points will play a new role in IPv6, 
by
acting as a sub-TLA registry for ISPs that connect to the exchange 
point.
Because there is little information available about such exchange points
and how they will operate, they have not been considered during 
development
of sub-TLA eligibility criteria. As these exchange points are 
established,
the Regional IRs will evaluate whether special criteria are required. 
It is
expected that the Regional IRs will request from the exchange point
information about the nature of the contracts they enter with the ISPs
seeking IPv6 address space.

4.2.3.2 Multihomed Sites

[to be written]

4.2.4 Size for Initial Allocation: "Slow-Start" Mechanism

Regional IRs will adopt a "slow start" mechanism when making initial
allocations of sub-TLA space to eligible organizations. By this 
mechanism,
the initial allocation will allow 13 bits worth of NLA IDs to be used by
the organization unless the requesting organization submits 
documentation
to the Regional IR to justify an exception based on topological grounds.
This initial allocation allows the organization to create a hierarchy
within the allocation depending on their customer type (ISP or end-site)
and the topology of their own network. For example, an organization may
receive 8,192 SLAs (a /48 each). (See section 4.3 for policies relating 
to
assignments.)

The slow-start mechanism for sub-TLA allocations is important to the
development of IPv6 addressing hierarchies for several reasons. One
significant reason is that it allows the Regional IRs to set relatively 
low
entrance criteria for organizations seeking a sub-TLA allocation. This
makes the process fair to all organizations requesting sub-TLA space by
giving everybody the same (relatively small) amount and basing future
allocations on track record. Furthermore, the effect of this process 
will
be to create a range of different prefix lengths which, in the event 
that
routing table growth requires it, will allow the ISP industry to make
rational decisions about which routes to filter.

Another important reason for adopting the slow-start mechanism is to 
allow
Regional IRs to maintain contact with TLA Registries as they develop,
thereby providing a level of support and training that will help ensure
that policies and practices are implemented consistently. Without a slow
start mechanism, TLA Registries receiving large initial allocations may 
not
have formal contact with the Regional IR for several years. The 
slow-start
mechanism helps Regional IRs to meet the goals of registration and
efficiency, by providing a process that enables them to monitor whether 
the
TLA Registries are properly registering assignments in the database and
correctly applying the policies for NLA and SLA assignments contained in
this document.

4.2.5 Criteria for Subsequent Sub-TLA Allocations

Regional IRs will not make subsequent allocations of sub-TLA address 
space
to a TLA Registry unless the TLA Registry has used at least 80 percent 
of
its previously allocated address space. In this context, the address 
space
is considered to be "used" if the TLA Registry has made all of its
allocations and assignments of that address space in accordance with the
policies and guidelines specified in this document.

The size of the subsequent allocation depends on the demonstrated usage
rate of the previous allocation.

4.2.5.1 Contiguous allocations

The subsequent allocation will be contiguous with the previously 
allocated
range to allow for aggregation of routing information. When a Regional 
IR
makes an initial allocation to TLA Registry, it will reserve the full
sub-TLA from which this allocation was made. Subsequent allocations to 
that
TLA Registry will be made from the reserved sub-TLA. If no further 
growth
is possible within that sub-TLA range, the Regional IR may allocate a 
full
TLA. (Note, this practice may eventually lead to a situation in which no
empty sub-TLAs are available, but the existing sub-TLAs are not fully
utilised. If this occurs, then the provisions of section 4.4 will 
apply.)

4.2.6 Registering and Verifying Usage

Each TLA Registry is responsible for the usage of the sub-TLA address 
space
it receives and must register all end-site assignments and ISP 
allocations
in the database of the Regional IR in its region. The Regional IR may
verify whether all assignments are registered in the database. In 
addition
to the database entries, the Regional IR may ask for periodic reports
specifying how the addresses are being used.

Registered end-sites must be connected and reachable. To verify this, 
the
relevant Regional IR is entitled to ping /48s within end-sites. 
Filtering
holes should be negotiated by the Regional IR and the organization 
holding
the addresses in question. Therefore, it is suggested that end-sites use
anycast cluster addresses on their border routers to enable this. It is
expected that one /48 SLA block is enough address space per end-site. 
If an
end-site requests an additional SLA, the TLA Registry must send the 
request
to the Regional IR for a second opinion.

4.2.7 Renumbering

It is possible that circumstances could arise whereby sub-TLA address 
space
becomes scarce. This could occur, for example, due to inefficient use of
assigned address space, or to an increase in the number of organizations
holding both TLA and sub-TLA space.

If such circumstances arise, it may be necessary for Regional IRs to
require that

previously allocated address space be renumbered into different ranges.

If a Regional IR requires a TLA Registry to renumber its own network, 
this
will also have an impact on all of its customers' networks. Therefore, 
it
is recommended that TLA Registries and NLA Registries enter contractual
arrangements with their customers at the time of the first allocation or
assignment. Such arrangements should clarify that the address space 
might
have to be returned, requiring all end-sites to be renumbered. If
renumbering is required, then TLA Registries should inform their 
customers
as soon as possible.

Regional IRs requiring a TLA Registry to renumber will allow that 
Registry
at least[X*: 12-24] months to return the sub-TLA space. [Note that the
granted renumbering time may depend on the prefix length returned. The
draft document
<http://search.ietf.org/internet-drafts/draft-ietf-ipngwg-router-renum-0
8.txt>
describes the issues involved in and methods used for renumbering IPv6
networks.]

[Note that site-local addresses are not affected by renumbering the 
global
unicast IPv6 addresses.]

4.2.8 Allocations to NLA Registries

TLA Registries with ISP customers may use their 13 bits of NLA address
space to create an addressing hierarchy for those ISPs. Each of the TLA
Registry's own end-user organizations would receive a /48 (see section
4.3); however, the ISP customers (NLA Registries) could be "allocated"
additional bits in order to aggregate the ISP's customers internally. A
slow-start mechanism will be used for these NLA allocations.

The NLA block is an allocation to the NLA Registry and not an 
assignment.
Therefore, if the NLA Registry does not use it fully within a certain
period of time, [X* time to be specified here?] the TLA Registry may
require it to be returned.

Once an NLA Registry has assigned at least 80 percent of its 
allocation, it
may request an additional block from the TLA Registry. This block can be
any size, depending on the NLA Registry's usage rate for its first 
block. A
TLA Registry receiving a request for subsequent NLA allocations must 
submit
the request to the relevant Regional IR for a second opinion.

Each NLA allocation must be registered in the Regional IR's database. 
All
end-user assignments must also be registered in the Regional IR's 
database.
The same procedures for these end-user assignments apply for the 
end-user
assignments made by the TLA Registry to their customers directly.
Ultimately, the TLA Registry is responsible for management of all 
address
space it allocates and should, therefore, appropriately monitor all
assignments made by the NLA Registries to which it allocates. The 
Regional
IR can at any time ask for additional information about the allocations 
and
assignments being made.

4.3 Assignments

4.3.1 Assignments to End-users

The minimum assignment to end-user organizations that have a need to 
create
subnets in their network is a /48 (80 bits of address space). Within 
this
/48, 16 bits are an SLA block used for subnetting and further 64 bits 
are
used per interface.

TLA Registries must submit all requests they receive for additional
assignments to the relevant Regional IR for evaluation (a "second
opinion"). All such requests must document the full use of the initial 
SLA
and must be accompanied by an engineering plan justifying the need for
additional address space.

Dial-up lines are considered part of an ISP's infrastructure and,
therefore, addresses for such purposes should be assigned from the SLA
block of that ISP. It is expected that longer prefixes be used for
non-permanent, single-user connections.

4.4 Reclamation Methods/Conditions

Allocations are valid only as long as the criteria for allocations 
continue
to be met. Consistent with the goal of aggregation described in section
2.2.2, the criteria for allocations may be reviewed with regard to 
current
routing technology. The current threshold point for reviewing the
allocation criteria is [X*: range=4,000-8,000] default-free entries in 
the global
routing table.

If this threshold is reached and current routing technology then allows
additional route entries, the number of possible TLAs and sub-TLAs may 
be
increased accordingly.

However, if the limit is reached current routing technology then is not
able to support additional routing entries, all allocations made up to 
that
point will be reviewed. TLA Registries with a very low usage rate [X*: 
to
be defined] or that do not meet the new criteria may have their sub-TLA
space revoked. These Registries will be required to renumber their 
networks
and return their previous allocation within a maximum of [X*: 
range=6-12]
months. During the period that routing technology is being investigated,
the Regional IRs will continue allocating address space even if the 
number
of "possible" routes are reached.

5. ORGANIZATIONS OPERATING IN MORE THAN ONE REGION

Organizations requesting sub-TLA space that operate in more than one
region, and that need separate sub-TLA blocks for routing purposes, may
request the address space from more than one of the Regional IRs, 
provided
that the organization's networks meet the criteria for allocation of
sub-TLA address space in each of the relevant regions.



6. DNS AND REVERSE ADDRESS MAPPING

[To be written..]

7. GLOSSARY

Allocation - The provision of IP address space to ISPs that reassign 
their
address space to customers.

Assignment - The provision of IP address space to end-user 
organizations.

End-user - An organization receiving reassignments of IPv6 addresses
exclusively for use in operational networks.

Interface Identifiers - A 64-bit IPv6 unicast address identifier that
identifies an interface on a link.

NLA ID - Next-Level Aggregation Identifier.

NLA Registry - Internet Service Providers receiving IPv6 address
allocations from a TLA Registry.

Public Topology - The collection of providers and exchanges who provide
public Internet transit service.

Regional Internet Registries - Organizations operating in large
geographical regions such as continents which are responsible for fair
distribution of globally unique Internet address space and for 
documenting
address space allocation and assignment.

Site - A location, physical or virtual, with a network backbone 
connecting
various network equipment and systems together. There is no limit to the
physical size or scope of a site.

Site Topology - A local, specific site or organization which does not
provide public transit service to nodes outside the site.

SLA ID - Site-Level Aggregation Identifier.

Slow Start - The efficient means by which addresses are allocated to TLA
Registries and to NLA ISPs. This method involves issuing small address
blocks until the provider can show an immediate requirement for larger
blocks.

TLA ID - Top-Level Aggregation Identifier.

TLA Registry - Organizations receiving TLA/sub-TLA ID from Regional IRs 
to
reassign to customers.

Unicast - An identifier for a single interface. A packet sent to a 
unicast
address is delivered to the interface identified by that address. Note 
that
the definition of an IPv4 host is different from an IPv6 identifier. One
physical host may have many interfaces, and therefore many IPv6
identifiers.

8. LIST OF REFERENCES