RFC4007-IPv6 Scoped Address Architecture

Network Working Group S. Deering

Request for Comments: 4007 Cisco Systems

Category: Standards Track B. Haberman

Johns Hopkins Univ

T. Jinmei

Toshiba

E. Nordmark

Sun Microsystems

B. Zill

Microsoft

March 2005

IPv6 Scoped Address Architecture

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.

Abstract

This document specifies the architectural characteristics, eXPected

behavior, textual representation, and usage of IPv6 addresses of

different scopes. According to a decision in the IPv6 working group,

this document intentionally avoids the syntax and usage of unicast

site-local addresses.

Table of Contents

1. IntrodUCtion . . . . . . . . . . . . . . . . . . . . . . . . 2

2. Definitions . . . . . . . . . . . . . . . . . . . . . . . . 3

3. Basic Terminology . . . . . . . . . . . . . . . . . . . . . 3

4. Address Scope . . . . . . . . . . . . . . . . . . . . . . . 3

5. Scope Zones . . . . . . . . . . . . . . . . . . . . . . . . 4

6. Zone Indices . . . . . . . . . . . . . . . . . . . . . . . . 6

7. Sending Packets . . . . . . . . . . . . . . . . . . . . . . 11

8. Receiving Packets . . . . . . . . . . . . . . . . . . . . . 11

9. Forwarding . . . . . . . . . . . . . . . . . . . . . . . . . 11

10. Routing . . . . . . . . . . . . . . . . . . . . . . . . . . 13

11. Textual Representation . . . . . . . . . . . . . . . . . . . 15

11.1. Non-Global Addresses . . . . . . . . . . . . . . . . 15

11.2. The Part. . . . . . . . . . . . . . . . . . 15

11.3. Examples. . . . . . . . . . . . . . . . . . . . . . . 17

11.4. Usage Examples. . . . . . . . . . . . . . . . . . . . 17

11.5. Related API . . . . . . . . . . . . . . . . . . . . . 18

11.6. Omitting Zone Indices . . . . . . . . . . . . . . . . 18

11.7. Combinations of Delimiter Characters. . . . . . . . . 18

12. Security Considerations . . . . . . . . . . . . . . . . . . 19

13. Contributors . . . . . . . . . . . . . . . . . . . . . . . . 20

14. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 20

15. References . . . . . . . . . . . . . . . . . . . . . . . . . 20

15.1. Normative References . . . . . . . . . . . . . . . . . 20

15.2. Informative References . . . . . . . . . . . . . . . . 21

Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 22

Full Copyright Statement . . . . . . . . . . . . . . . . . . . . 24

1. Introduction

Internet Protocol version 6 includes support for addresses of

different "scope"; that is, both global and non-global (e.g., link-

local) addresses. Although non-global addressing has been introduced

operationally in the IPv4 Internet, both in the use of private

address space ("net 10", etc.) and with administratively scoped

multicast addresses, the design of IPv6 formally incorporates the

notion of address scope into its base architecture. This document

specifies the architectural characteristics, expected behavior,

textual representation, and usage of IPv6 addresses of different

scopes.

Though the current address architecture specification [1] defines

unicast site-local addresses, the IPv6 working group decided to

deprecate the syntax and the usage [5] and is now investigating other

forms of local IPv6 addressing. The usage of any new forms of

local addresses will be documented elsewhere in the future. Thus,

this document intentionally focuses on link-local and multicast

scopes only.

2. Definitions

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 [2].

3. Basic Terminology

The terms link, interface, node, host, and router are defined in [3].

The definitions of unicast address scopes (link-local and global) and

multicast address scopes (interface-local, link-local, etc.) are

contained in [1].

4. Address Scope

Every IPv6 address other than the unspecified address has a specific

scope; that is, a topological span within which the address may be

used as a unique identifier for an interface or set of interfaces.

The scope of an address is encoded as part of the address, as

specified in [1].

For unicast addresses, this document discusses two defined scopes:

o Link-local scope, for uniquely identifying interfaces within

(i.e., attached to) a single link only.

o Global scope, for uniquely identifying interfaces anywhere in the

Internet.

The IPv6 unicast loopback address, ::1, is treated as having link-

local scope within an imaginary link to which a virtual "loopback

interface" is attached.

The unspecified address, ::, is a special case. It does not have any

scope because it must never be assigned to any node according to [1].

Note, however, that an implementation might use an implementation

dependent semantics for the unspecified address and may want to allow

the unspecified address to have specific scopes. For example,

implementations often use the unspecified address to represent "any"

address in APIs. In this case, implementations may regard the

unspecified address with a given particular scope as representing the

notion of "any address in the scope". This document does not

prohibit such a usage, as long as it is limited within the

implementation.

[1] defines IPv6 addresses with embedded IPv4 addresses as being part

of global addresses. Thus, those addresses have global scope, with

regard to the IPv6 scoped address architecture. However, an

implementation may use those addresses as if they had other scopes

for convenience. For instance, [6] assigns link-local scope to IPv4

auto-configured link-local addresses (the addresses from the prefix

169.254.0.0/16 [7]) and converts those addresses into IPv4-mapped

IPv6 addresses in order to perform destination address selection

among IPv4 and IPv6 addresses. This would implicitly mean that the

IPv4-mapped IPv6 addresses equivalent to the IPv4 auto-configuration

link-local addresses have link-local scope. This document does not

preclude such a usage, as long as it is limited within the

implementation.

Anycast addresses [1] are allocated from the unicast address space

and have the same scope properties as unicast addresses. All

statements in this document regarding unicast apply equally to

anycast.

For multicast addresses, there are fourteen possible scopes, ranging

from interface-local to global (including link-local). The

interface-local scope spans a single interface only; a multicast

address of interface-local scope is useful only for loopback delivery

of multicasts within a single node; for example, as a form of inter-

process communication within a computer. Unlike the unicast loopback

address, interface-local multicast addresses may be assigned to any

interface.

There is a size relationship among scopes:

o For unicast scopes, link-local is a smaller scope than global.

o For multicast scopes, scopes with lesser values in the "scop"

subfield of the multicast address (Section 2.7 of [1]) are smaller

than scopes with greater values, with interface-local being the

smallest and global being the largest.

However, two scopes of different size may cover the exact same region

of topology. For example, a (multicast) site may consist of a single

link, in which both link-local and site-local scope effectively cover

the same topological span.

5. Scope Zones

A scope zone, or simply a zone, is a connected region of topology of

a given scope. For example, the set of links connected by routers

within a particular (multicast) site, and the interfaces attached to

those links, comprise a single zone of multicast site-local scope.

Note that a zone is a particular instance of a topological region

(e.g., Alice's site or Bob's site), whereas a scope is the size of a

topological region (e.g., a site or a link).

The zone to which a particular non-global address pertains is not

encoded in the address itself but determined by context, such as the

interface from which it is sent or received. Thus, addresses of a

given (non-global) scope may be re-used in different zones of that

scope. For example, two different physical links may each contain a

node with the link-local address fe80::1.

Zones of the different scopes are instantiated as follows:

o Each interface on a node comprises a single zone of interface-

local scope (for multicast only).

o Each link and the interfaces attached to that link comprise a

single zone of link-local scope (for both unicast and multicast).

o There is a single zone of global scope (for both unicast and

multicast) comprising all the links and interfaces in the

Internet.

o The boundaries of zones of a scope other than interface-local,

link-local, and global must be defined and configured by network

administrators.

Zone boundaries are relatively static features, not changing in

response to short-term changes in topology. Thus, the requirement

that the topology within a zone be "connected" is intended to include

links and interfaces that may only be occasionally connected. For

example, a residential node or network that oBTains Internet Access

by dial-up to an employer's (multicast) site may be treated as part

of the employer's (multicast) site-local zone even when the dial-up

link is disconnected. Similarly, a failure of a router, interface,

or link that causes a zone to become partitioned does not split that

zone into multiple zones. Rather, the different partitions are still

considered to belong to the same zone.

Zones have the following additional properties:

o Zone boundaries cut through nodes, not links. (Note that the

global zone has no boundary, and the boundary of an interface-

local zone encloses just a single interface.)

o Zones of the same scope cannot overlap; i.e., they can have no

links or interfaces in common.

o A zone of a given scope (less than global) falls completely within

zones of larger scope. That is, a smaller scope zone cannot

include more topology than would any larger scope zone with which

it shares any links or interfaces.

o Each zone is required to be "convex" from a routing perspective;

i.e., packets sent from one interface to any other in the same

zone are never routed outside the zone. Note, however, that if a

zone contains a tunneled link (e.g., an IPv6-over-IPv6 tunnel link

[8]), a lower layer network of the tunnel can be located outside

the zone without breaking the convexity property.

Each interface belongs to exactly one zone of each possible scope.

Note that this means that an interface belongs to a scope zone

regardless of what kind of unicast address the interface has or of

which multicast groups the node joins on the interface.

6. Zone Indices

Because the same non-global address may be in use in more than one

zone of the same scope (e.g., the use of link-local address fe80::1

in two separate physical links) and a node may have interfaces

attached to different zones of the same scope (e.g., a router

normally has multiple interfaces attached to different links), a node

requires an internal means to identify to which zone a non-global

address belongs. This is accomplished by assigning, within the node,

a distinct "zone index" to each zone of the same scope to which that

node is attached, and by allowing all internal uses of an address to

be qualified by a zone index.

The assignment of zone indices is illustrated in the example in the

figure below:

---------------------------------------------------------------

a node

/--link1--\ /--------link2--------\ /--link3--\ /--link4--\

/--intf1--\ /--intf2--\ /--intf3--\ /--intf4--\ /--intf5--\

---------------------------------------------------------------

(imaginary ================= a point- a

loopback an Ethernet to-point tunnel

link) link

Figure 1: Zone Indices Example

This example node has five interfaces:

A loopback interface to the imaginary loopback link (a phantom

link that goes nowhere).

Two interfaces to the same Ethernet link.

An interface to a point-to-point link.

A tunnel interface (e.g., the abstract endpoint of an IPv6-over-

IPv6 tunnel [8], presumably established over either the Ethernet

or the point-to-point link).

It is thus attached to five interface-local zones, identified by the

interface indices 1 through 5.

Because the two Ethernet interfaces are attached to the same link,

the node is only attached to four link-local zones, identified by

link indices 1 through 4. Also note that even if the tunnel

interface is established over the Ethernet, the tunnel link gets its

own link index, which is different from the index of the Ethernet

link zone.

Each zone index of a particular scope should contain enough

information to indicate the scope, so that all indices of all scopes

are unique within the node and zone indices themselves can be used

for a dedicated purpose. Usage of the index to identify an entry in

the Management Information Base (MIB) is an example of the dedicated

purpose. The actual representation to encode the scope is

implementation dependent and is out of scope of this document.

Within this document, indices are simply represented in a format such

as "link index 2" for readability.

The zone indices are strictly local to the node. For example, the

node on the other end of the point-to-point link may well use

entirely different interface and link index values for that link.

An implementation should also support the concept of a "default" zone

for each scope. And, when supported, the index value zero at each

scope SHOULD be reserved to mean "use the default zone". Unlike

other zone indices, the default index does not contain any scope, and

the scope is determined by the address that the default index

accompanies. An implementation may additionally define a separate

default zone for each scope. Those default indices can also be used

as the zone qualifier for an address for which the node is attached

to only one zone; e.g., when using global addresses.

At present, there is no way for a node to automatically determine

which of its interfaces belong to the same zones; e.g., the same link

or the same multicast scope zone larger than interface. In the

future, protocols may be developed to determine that information. In

the absence of such protocols, an implementation must provide a means

for manual assignment and/or reassignment of zone indices.

Furthermore, to avoid performing manual configuration in most cases,

an implementation should, by default, initially assign zone indices

only as follows:

o A unique interface index for each interface.

o A unique link index for each interface.

Then manual configuration would only be necessary for the less common

cases of nodes with multiple interfaces to a single link or of those

with interfaces to zones of different (multicast-only) scopes.

Thus, the default zone index assignments for the example node from

Figure 1 would be as illustrated in Figure 2, below. Manual

configuration would then be required to, for example, assign the same

link index to the two Ethernet interfaces, as shown in Figure 1.

---------------------------------------------------------------

a node

/--link1--\ /--link2--\ /--link3--\ /--link4--\ /--link5--\

/--intf1--\ /--intf2--\ /--intf3--\ /--intf4--\ /--intf5--\

---------------------------------------------------------------

(imaginary ================= a point- a

loopback an Ethernet to-point tunnel

link) link

Figure 2: Example of Default Zone Indices

As well as initially assigning zone indices, as specified above, an

implementation should automatically select a default zone for each

scope for which there is more than one choice, to be used whenever an

address is specified without a zone index (or with a zone index of

zero). For instance, in the example shown in Figure 2, the

implementation might automatically select intf2 and link2 as the

default zones for each of those two scopes. (One possible selection

algorithm is to choose the first zone that includes an interface

other than the loopback interface as the default for each scope.) A

means must also be provided to assign the default zone for a scope

manually, overriding any automatic assignment.

The unicast loopback address, ::1, may not be assigned to any

interface other than the loopback interface. Therefore, it is

recommended that, whenever ::1 is specified without a zone index or

with the default zone index, it be interpreted as belonging to the

loopback link-local zone, regardless of which link-local zone has

been selected as the default. If this is done, then for nodes with

only a single non-loopback interface (e.g., a single Ethernet

interface), the common case, link-local addresses need not be

qualified with a zone index. The unqualified address ::1 would

always refer to the link-local zone containing the loopback

interface. All other unqualified link-local addresses would refer to

the link-local zone containing the non-loopback interface (as long as

the default link-local zone was set to be the zone containing the

non-loopback interface).

Because of the requirement that a zone of a given scope fall

completely within zones of larger scope (see Section 5, above), two

interfaces assigned to different zones of scope S must also be

assigned to different zones of all scopes smaller than S. Thus, the

manual assignment of distinct zone indices for one scope may require

the automatic assignment of distinct zone indices for smaller scopes.

For example, suppose that distinct multicast site-local indices 1 and

2 are manually assigned in Figure 1 and that site 1 contains links 1,

2, and 3, but site 2 only contains link 4. This configuration would

cause the automatic creation of corresponding admin-local (i.e.,

multicast "scop" value 4) indices 1 and 2, because admin-local scope

is smaller than site-local scope.

With the above considerations, the complete set of zone indices for

our example node from Figure 1, with the additional configurations

here, is shown in Figure 3, below.

---------------------------------------------------------------

a node

/--------------------site1--------------------\ /--site2--\

/-------------------admin1--------------------\ /-admin2--\

/--link1--\ /--------link2--------\ /--link3--\ /--link4--\

/--intf1--\ /--intf2--\ /--intf3--\ /--intf4--\ /--intf5--\

---------------------------------------------------------------

(imaginary ================= a point- a

loopback an Ethernet to-point tunnel

link) link

Figure 3: Complete Zone Indices Example

Although the above examples show the zones being assigned index

values sequentially for each scope, starting at one, the zone index

values are arbitrary. An implementation may label a zone with any

value it chooses, as long as the index value of each zone of all

scopes is unique within the node. Zero SHOULD be reserved to

represent the default zone. Implementations choosing to follow the

recommended basic API [10] will want to restrict their index values

to those that can be represented by the sin6_scope_id field of the

sockaddr_in6 structure.

7. Sending Packets

When an upper-layer protocol sends a packet to a non-global

destination address, it must have a means of identifying the intended

zone to the IPv6 layer for cases in which the node is attached to

more than one zone of the destination address's scope.

Although identification of an outgoing interface is sufficient to

identify an intended zone (because each interface is attached to no

more than one zone of each scope), in many cases that is more

specific than desired. For example, when sending to a link-local

unicast address from a node that has more than one interface to the

intended link (an unusual configuration), the upper layer protocol

may not care which of those interfaces is used for the transmission.

Rather, it would prefer to leave that choice to the routing function

in the IP layer. Thus, the upper-layer requires the ability to

specify a zone index, when sending to a non-global, non-loopback

destination address.

8. Receiving Packets

When an upper-layer protocol receives a packet containing a non-

global source or destination address, the zone to which that address

pertains can be determined from the arrival interface, because the

arrival interface can be attached to only one zone of the same scope

as that of the address under consideration. However, it is

recommended that the IP layer convey to the upper layer the correct

zone indices for the arriving source and destination addresses, in

addition to the arrival interface identifier.

9. Forwarding

When a router receives a packet addressed to a node other than

itself, it must take the zone of the destination and source addresses

into account as follows:

o The zone of the destination address is determined by the scope of

the address and arrival interface of the packet. The next-hop

interface is chosen by looking up the destination address in a

(conceptual) routing table specific to that zone (see Section 10).

That routing table is restricted to refer to interfaces belonging

to that zone.

o After the next-hop interface is chosen, the zone of the source

address is considered. As with the destination address, the zone

of the source address is determined by the scope of the address

and arrival interface of the packet. If transmitting the packet

on the chosen next-hop interface would cause the packet to leave

the zone of the source address, i.e., cross a zone boundary of the

scope of the source address, then the packet is discarded.

Additionally, if the packet's destination address is a unicast

address, an ICMP Destination Unreachable message [4] with Code 2

("beyond scope of source address") is sent to the source of the

original packet. Note that Code 2 is currently left as unassigned

in [4], but the IANA will re-assign the value for the new purpose,

and [4] will be revised with this change.

Note that even if unicast site-local addresses are deprecated, the

above procedure still applies to link-local addresses. Thus, if a

router receives a packet with a link-local destination address that

is not one of the router's own link-local addresses on the arrival

link, the router is expected to try to forward the packet to the

destination on that link (subject to successful determination of the

destination's link-layer address via the Neighbor Discovery protocol

[9]). The forwarded packet may be transmitted back through the

arrival interface, or through any other interface attached to the

same link.

A node that receives a packet addressed to itself and containing a

Routing Header with more than zero Segments Left (Section 4.4 of [3])

first checks the scope of the next address in the Routing Header. If

the scope of the next address is smaller than the scope of the

original destination address, the node MUST discard the packet.

Otherwise, it swaps the original destination address with the next

address in the Routing Header. Then the above forwarding rules apply

as follows:

o The zone of the new destination address is determined by the scope

of the next address and the arrival interface of the packet. The

next-hop interface is chosen as per the first bullet of the rules

above.

o After the next-hop interface is chosen, the zone of the source

address is considered as per the second bullet of the rules above.

This check about the scope of the next address ensures that when a

packet arrives at its final destination, if that destination is

link-local, then the receiving node can know that the packet

originated on-link. This will help the receiving node send a

"response" packet with the final destination of the received packet

as the source address without breaking its source zone.

Note that it is possible, though generally inadvisable, to use a

Routing Header to convey a non-global address across its associated

zone boundary in the previously used next address field. For

example, consider a case in which a link-border node (e.g., a router)

receives a packet with the destination being a link-local address,

and the source address a global address. If the packet contains a

Routing Header where the next address is a global address, the next-

hop interface to the global address may belong to a different link

than that of the original destination. This is allowed because the

scope of the next address is not smaller than the scope of the

original destination.

10. Routing

Note that as unicast site-local addresses are deprecated, and link-

local addresses do not need routing, the discussion in this section

only applies to multicast scoped routing.

When a routing protocol determines that it is operating on a zone

boundary, it MUST protect inter-zone integrity and maintain intra-

zone connectivity.

To maintain connectivity, the routing protocol must be able to create

forwarding information for the global groups and for all the scoped

groups for each of its attached zones. The most straightforward way

of doing this is to create (conceptual) forwarding tables for each

specific zone.

To protect inter-zone integrity, routers must be selective in the

group information shared with neighboring routers. Routers routinely

exchange routing information with neighboring routers. When a router

is transmitting this routing information, it must not include any

information about zones other than the zones assigned to the

interface used to transmit the information.

* *

* =========== Organization X *

* *

+-*-----------------+ *

* intf1 intf2 *

* *

* intf3 --- *

* *

***********************************

Router

********************** **********************

* *

Org. Y --- intf4 * * intf5 --- Org. Z

* *

********************** **********************

+---------------------+

Figure 4: Multi-Organization Multicast Router

As an example, the router in Figure 4 must exchange routing

information on five interfaces. The information exchanged is as

follows (for simplicity, multicast scopes smaller or larger than the

organization scope except global are not considered here):

o Interface 1

* All global groups

* All organization groups learned from Interfaces 1, 2, and 3

o Interface 2

* All global groups

* All organization groups learned from Interfaces 1, 2, and 3

o Interface 3

* All global groups

* All organization groups learned from Interfaces 1, 2, and 3

o Interface 4

* All global groups

* All organization groups learned from Interface 4

o Interface 5

* All global groups

* All organization groups learned from Interface 5

By imposing route exchange rules, zone integrity is maintained by

keeping all zone-specific routing information contained within the

zone.

11. Textual Representation

As already mentioned, to specify an IPv6 non-global address without

ambiguity, an intended scope zone should be specified as well. As a

common notation to specify the scope zone, an implementation SHOULD

support the following format:

where

is a literal IPv6 address,

is a string identifying the zone of the address, and

`%' is a delimiter character to distinguish between and

The following subsections describe detailed definitions, concrete

examples, and additional notes of the format.

11.1. Non-Global Addresses

The format applies to all kinds of unicast and multicast addresses of

non-global scope except the unspecified address, which does not have

a scope. The format is meaningless and should not be used for global

addresses. The loopback address belongs to the trivial link; i.e.,

the link attached to the loopback interface. Thus the format should

not be used for the loopback address, either. This document does not

specify the usage of the format when the is the unspecified

address, as the address does not have a scope. This document,

however, does not prohibit an implementation from using the format

for those special addresses for implementation dependent purposes.

11.2. The Part

In the textual representation, the part should be able to

identify a particular zone of the address's scope. Although a zone

index is expected to contain enough information to determine the

scope and to be unique among all scopes as described in Section 6,

the part of this format does not have to contain the scope.

This is because the part should specify the appropriate

scope. This also means that the part does not have to be

unique among all scopes.

With this loosened property, an implementation can use a convenient

representation as . For example, to represent link index 2,

the implementation can simply use "2" as , which would be

more readable than other representations that contain the "link"

scope.

When an implementation interprets the format, it should construct the

"full" zone index, which contains the scope, from the part

and the scope specified by the part. (Remember that a zone

index itself should contain the scope, as specified in Section 6.)

An implementation SHOULD support at least numerical indices that are

non-negative decimal integers as . The default zone index,

which should typically be 0 (see Section 6), is included in the

integers. When is the default, the delimiter characters

"%" and can be omitted. Similarly, if a textual

representation of an IPv6 address is given without a zone index, it

should be interpreted as %, where

is the default zone index of the scope that has.

An implementation MAY support other kinds of non-null strings as

. However, the strings must not conflict with the delimiter

character. The precise format and semantics of additional strings is

implementation dependent.

One possible candidate for these strings would be interface names, as

interfaces uniquely disambiguate any scopes. In particular,

interface names can be used as "default identifiers" for interfaces

and links, because by default there is a one-to-one mapping between

interfaces and each of those scopes as described in Section 6.

An implementation could also use interface names as for

scopes larger than links, but there might be some confusion in this

use. For example, when more than one interface belongs to the same

(multicast) site, a user would be confused about which interface

should be used. Also, a mapping function from an address to a name

would encounter the same kind of problem when it prints an address

with an interface name as a zone index. This document does not

specify how these cases should be treated and leaves it

implementation dependent.

It cannot be assumed that indices are common across all nodes in a

zone (see Section 6). Hence, the format MUST be used only within a

node and MUST NOT be sent on the wire unless every node that

interprets the format agrees on the semantics.

11.3. Examples

The following addresses

fe80::1234 (on the 1st link of the node)

ff02::5678 (on the 5th link of the node)

ff08::9abc (on the 10th organization of the node)

would be represented as follows:

fe80::1234%1

ff02::5678%5

ff08::9abc

(Here we assume a natural translation from a zone index to the

part, where the Nth zone of any scope is translated into

"N".)

If we use interface names as , those addresses could also be

represented as follows:

fe80::1234%ne0

ff02::5678%pvc1.3

ff08::9abc%interface10

where the interface "ne0" belongs to the 1st link, "pvc1.3" belongs

to the 5th link, and "interface10" belongs to the 10th organization.

11.4. Usage Examples

Applications that are supposed to be used in end hosts such as

telnet, FTP, and ssh may not explicitly support the notion of address

scope, especially of link-local addresses. However, an expert user

(e.g., a network administrator) sometimes has to give even link-local

addresses to such applications.

Here is a concrete example. Consider a multi-linked router called

"R1" that has at least two point-to-point interfaces (links). Each

of the interfaces is connected to another router, "R2" and "R3",

respectively. Also assume that the point-to-point interfaces have

link-local addresses only.

Now suppose that the routing system on R2 hangs up and has to be

reinvoked. In this situation, we may not be able to use a global

address of R2, because this is routing trouble and we cannot expect

to have enough routes for global reachability to R2.

Hence, we have to login R1 first and then try to login R2 by using

link-local addresses. In this case, we have to give the link-local

address of R2 to, for example, telnet. Here we assume the address is

fe80::2.

Note that we cannot just type

% telnet fe80::2

here, since R1 has more than one link and hence the telnet command

cannot detect which link it should try to use for connecting.

Instead, we should type the link-local address with the link index as

follows:

% telnet fe80::2%3

where "3" after the delimiter character `%' corresponds to the link

index of the point-to-point link.

11.5. Related API

An extension to the recommended basic API defines how the format for

non-global addresses should be treated in library functions that

translate a nodename to an address, or vice versa [11].

11.6. Omitting Zone Indices

The format defined in this document does not intend to invalidate the

original format for non-global addresses; that is, the format without

the zone index portion. As described in Section 6, in some common

cases with the notion of the default zone index, there can be no

ambiguity about scope zones. In such an environment, the

implementation can omit the "%" part. As a result, it can

act as though it did not support the extended format at all.

11.7. Combinations of Delimiter Characters

There are other kinds of delimiter characters defined for IPv6

addresses. In this subsection, we describe how they should be

combined with the format for non-global addresses.

The IPv6 addressing architecture [1] also defines the syntax of IPv6

prefixes. If the address portion of a prefix is non-global and its

scope zone should be disambiguated, the address portion SHOULD be in

the format. For example, a link-local prefix fe80::/64 on the second

link can be represented as follows:

fe80::%2/64

In this combination, it is important to place the zone index portion

before the prefix length when we consider parsing the format by a

name-to-address library function [11]. That is, we can first

separate the address with the zone index from the prefix length, and

just pass the former to the library function.

The preferred format for literal IPv6 addresses in URLs is also

defined [12]. When a user types the preferred format for an IPv6

non-global address whose zone should be explicitly specified, the

user could use the format for the non-global address combined with

the preferred format.

However, the typed URL is often sent on the wire, and it would cause

confusion if an application did not strip the portion

before sending. Note that the applications should not need to care

about which kind of addresses they're using, much less parse or strip

out the portion of the address.

Also, the format for non-global addresses might conflict with the URI

syntax [13], since the syntax defines the delimiter character (`%')

as the escape character. This conflict would require, for example,

that the part for zone 1 with the delimiter be represented

as '%1'. It also means that we could not simply copy a non-escaped

format from other sources as input to the URI parser. Additionally,

if the URI parser does not convert the escaped format before passing

it to a name-to-address library, the conversion will fail. All these

issues would decrease the benefit of the textual representation

described in this section.

Hence, this document does not specify how the format for non-global

addresses should be combined with the preferred format for literal

IPv6 addresses. In any case, it is recommended to use an FQDN

instead of a literal IPv6 address in a URL, whenever an FQDN is

available.

12. Security Considerations

A limited scope address without a zone index has security

implications and cannot be used for some security contexts. For

example, a link-local address cannot be used in a traffic selector of

a security association established by Internet Key Exchange (IKE)

when the IKE messages are carried over global addresses. Also, a

link-local address without a zone index cannot be used in access

control lists.

The routing section of this document specifies a set of guidelines

whereby routers can prevent zone-specific information from leaking

out of each zone. If, for example, multicast site boundary routers

allow site routing information to be forwarded outside of the site,

the integrity of the site could be compromised.

Since the use of the textual representation of non-global addresses

is restricted to use within a single node, it does not create a

security vulnerability from outside the node. However, a malicious

node might send a packet that contains a textual IPv6 non-global

address with a zone index, intending to deceive the receiving node

about the zone of the non-global address. Thus, an implementation

should be careful when it receives packets that contain textual non-

global addresses as data.

13. Contributors

This document is a combination of several separate efforts. Atsushi

Onoe took a significant role in one of them and deeply contributed to

the content of Section 11 as a co-author of a separate proposal.

14. Acknowledgements

Many members of the IPv6 working group provided useful comments and

feedback on this document. In particular, Margaret Wasserman and Bob

Hinden led the working group to make a consensus on IPv6 local

addressing. Richard Draves proposed an additional rule to process

Routing header containing scoped addresses. Dave Thaler and Francis

Dupont gave valuable suggestions to define semantics of zone indices

in terms of related API. Pekka Savola reviewed a version of the

document very carefully and made detailed comments about serious

problems. Steve Bellovin, Ted Hardie, Bert Wijnen, and Timothy

Gleeson reviewed and helped improve the document during the

preparation for publication.

15. References

15.1. Normative References

[1] Hinden, R. and S. Deering, "Internet Protocol Version 6 (IPv6)

Addressing Architecture", RFC 3513, April 2003.

[2] Bradner, S., "Key words for use in RFCs to Indicate Requirement

Levels", BCP 14, RFC 2119, March 1997.

[3] Deering, S. and R. Hinden, "Internet Protocol, Version 6 (IPv6)

Specification", RFC 2460, December 1998.

[4] Conta, A. and S. Deering, "Internet Control Message Protocol

(ICMPv6) for the Internet Protocol Version 6 (IPv6)

Specification", RFC 2463, December 1998.

15.2. Informative References

[5] Huitema, C. and B. Carpenter, "Deprecating Site Local

Addresses", RFC 3879, September 2004.

[6] Draves, R., "Default Address Selection for Internet Protocol

version 6 (IPv6)", RFC 3484, February 2003.

[7] Cheshire, S., Aboba, B., and E. Guttman, "Dynamic Configuration

of Link-Local IPv4 Addresses", Work in Progress.

[8] Conta, A. and S. Deering, "Generic Packet Tunneling in IPv6

Specification", RFC 2473, December 1998.

[9] Narten, T., Nordmark, E., and W. Simpson, "Neighbor Discovery

for IP Version 6 (IPv6)", RFC 2461, December 1998.

[10] Gilligan, R., Thomson, S., Bound, J., McCann, J., and W.

Stevens, "Basic Socket Interface Extensions for IPv6", RFC 3493,

February 2003.

[11] Gilligan, R., "Scoped Address Extensions to the IPv6 Basic

Socket API", Work in Progress, July 2002.

[12] Hinden, R., Carpenter, B., and L. Masinter, "Format for Literal

IPv6 Addresses in URL's", RFC 2732, December 1999.

[13] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform

Resource Identifiers (URI): Generic Syntax", RFC 3986, January

2005.

Authors' Addresses

Stephen E. Deering

Cisco Systems, Inc.

170 West Tasman Drive

San Jose, CA 95134-1706

USA

Brian Haberman

Johns Hopkins University Applied Physics Laboratory

11100 Johns Hopkins Road

Laurel, MD 20723-6099

USA

Phone: +1-443-778-1319

EMail: brian@innovationslab.net

Tatuya Jinmei

Corporate Research & Development Center, Toshiba Corporation

1 Komukai Toshiba-cho, Saiwai-ku

Kawasaki-shi, Kanagawa 212-8582

Japan

Phone: +81-44-549-2230

Fax: +81-44-520-1841

EMail: jinmei@isl.rdc.toshiba.co.jp

Erik Nordmark

17 Network Circle

Menlo Park, CA 94025

USA

Phone: +1 650 786 2921

Fax: +1 650 786 5896

EMail: Erik.Nordmark@sun.com

Brian D. Zill

Microsoft Research

One Microsoft Way

Redmond, WA 98052-6399

USA

Phone: +1-425-703-3568

Fax: +1-425-936-7329

EMail: bzill@microsoft.com

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