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draft-ietf-osinsap-allocation-00.txt
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Network Working Group Richard Colella (NIST)
INTERNET DRAFT Ross Callon (Wellfleet)
Obsoletes RFC 1237 Ella Gardner (Mitre)
<draft-ietf-osinsap-allocation-00.txt> Yakov Rekhter (IBM)
October 1993
Guidelines for OSI NSAP Allocation in the Internet
Status of This Memo
This memo represents a proposed update to RFC 1237. RFC 1237 specifies
an IAB standards track protocol for the Internet community, and
requests discussion and suggestions for improvements. Please refer to
the current edition of the ``IAB Official Protocol Standards'' for the
standardization state and status of this protocol. Distribution of
this memo is unlimited. Changes since RFC 1237 are described in
section 1.
This document is an Internet Draft. Internet Drafts are working
documents of the Internet Engineering Task Force (IETF), its Areas,
and its Working Groups. Note that other groups may also distribute
working documents as Internet Drafts.
Internet Drafts are draft documents valid for a maximum of six
months. Internet Drafts may be updated, replaced, or obsoleted by
other documents at any time. It is not appropriate to use Internet
Drafts as reference material or to cite them other than as a "working
draft" or "work in progress."
Abstract
CLNP is currently being deployed in the Internet. This is useful
to support OSI and DECnet(tm) traffic. In addition, CLNP has been
proposed as a possible IPng candidate, to provide a long-term
solution to IP address exhaustion. Required as part of the CLNP
infrastructure are guidelines for network service access point (NSAP)
address assignment. This paper provides guidelines for allocating NSAP
addresses in the Internet.
The guidelines provided in this paper have been the basis for initial
deployment of CLNP in the Internet, and have proven very valuable both
as an aid to scaling of CLNP routing, and for address administration.
Contents
1 Introduction
2 Scope
3 Background
3.1 OSI Routing Standards . . . . . . . . . . . .
3.2 Overview of IS-IS (ISO/IEC 10589) . . . . . . . .
3.3 Overview of IDRP (ISO/IEC 10747) . . . . . . . .
3.3.1 Scaling Mechanisms in IDRP . . . . . . . .
3.4 Requirements of IS-IS and IDRP on NSAPs . . . . . .
4 NSAP and Routing
4.1 Routing Table Abstraction . . . . . . . . . . .
4.2 NSAP Administration and Efficiency . . . . . . . .
5 NSAP Administration and Routing in the Internet
5.1 Administration at the Area . . . . . . . . . .
5.2 Administration at the Leaf Routing Domain . . . . .
5.3 Administration at the Transit Routing Domain . . . .
5.3.1 Direct Service Providers . . . . . . . .
5.3.2 Indirect Providers (Backbones) . . . . . . .
5.4 Multi-homed Routing Domains . . . . . . . . . .
5.5 Private Links . . . . . . . . . . . . . . .
5.6 Zero-Homed Routing Domains . . . . . . . . . .
5.7 Address Transition Issues . . . . . . . . . .
6 Recommendations
6.1 Recommendations Specific to U.S. Parts of the Internet .
6.2 Recommendations Specific to European Parts of the Internet
6.2.1 General NSAP Structure . . . . . . . . . .
6.2.2 Structure of the Country Domain Part . . . . .
6.2.3 Structure of the Country Domain Specific Part . .
6.3 Recommendations Specific to Other Parts of the Internet .
6.4 Recommendations for Multi-Homed Routing Domains . . .
6.5 Recommendations for RDI and RDCI Assignment . . . . .
7 Security Considerations
8 Authors' Addresses
9 Acknowledgments
A Administration of NSAPs
A.1 GOSIP Version 2 NSAPs . . . . . . . . . . . .
A.1.1 Application for Administrative Authority Identifiers
A.1.2 Guidelines for NSAP Assignment . . . . . . .
A.2 Data Country Code NSAPs . . . . . . . . . . .
A.2.1 Application for Numeric Organization Name . . .
A.3 Summary of Administrative Requirements . . . . . .
References . . . . . . . . . . . . . . . . . .
Internet Draft Guidelines for OSI NSAP Allocation Oct 1993
1 Introduction
The Internet is moving towards a multi-protocol environment that
includes CLNP. To support CLNP in the Internet, an OSI lower layers
infrastructure is required. This infrastructure comprises the
connectionless network protocol (CLNP) [9] and supporting routing
protocols. Also required as part of this infrastructure are guidelines
for network service access point (NSAP) address assignment. This paper
provides guidelines for allocating NSAP addresses in the Internet
(the terms NSAP and NSAP address are used interchangeably throughout
this paper in referring to NSAP addresses).
The guidelines presented in this document are quite similar to the
guidelines that are proposed in the Internet for IP address allocation
with CIDR (RFC1519 [19]). The major difference between the two is the
size of the addresses (4 octets for CIDR vs 20 octets for CLNP). The
larger NSAP addresses allows considerably greater flexibility and
scalability.
The remainder of this paper is organized into five major sections and
an appendix. Section 2 defines the boundaries of the problem addressed
in this paper and Section 3 provides background information on OSI
routing and the implications for NSAP addresses.
Section 4 addresses the specific relationship between NSAP addresses
and routing, especially with regard to hierarchical routing and data
abstraction. This is followed in Section 5 with an application of
these concepts to the Internet environment. Section 6 provides
recommended guidelines for NSAP address allocation in the Internet.
This includes recommendations for the U.S. and European parts of the
Internet, as well as more general recommendations for any part of
the Internet.
Appendix A contains a compendium of useful information concerning
NSAP structure and allocation authorities. The GOSIP Version 2 NSAP
structure is discussed in detail and the structure for U.S.-based DCC
(Data Country Code) NSAPs is described. Contact information for the
registration authorities for GOSIP and DCC-based NSAPs in the U.S.,
the General Services Administration (GSA) and the American National
Standards Institute (ANSI), respectively, is provided.
This document obsoletes RFC 1237. The changes from RFC1237 are minor,
and primarily editorial in nature. The descriptions of OSI routing
standards contained in section 3 have been updated to reflect the
current status of the relevant standards, and a description of the
OSI Interdomain Routing Protocol (IDRP) has been added.
Recommendations specific to the European part of the Internet have
been added in section 6, along with recommendations for Routing Domain
Identifiers and Routing Domain Confederation Identifiers needed for
operation of IDRP.
2 Scope
Control over the collection of hosts and the transmission and
switching facilities that compose the networking resources of the
global Internet is not homogeneous, but is distributed among multiple
administrative authorities. Resources under control of a single
administration form a domain. For the rest of this paper, "domain"
and "routing domain" will be used interchangeably. Domains that
share their resources with other domains are called network service
providers (or just providers). Domains that utilize other domains`
resources are called network service subscribers (or simply
subscribers). A given domain may act as a provider and a subscriber
simultaneously.
There are two aspects of interest when discussing OSI NSAP allocation
within the Internet. The first is the set of administrative require-
ments for obtaining and allocating NSAP addresses; the second is the
technical aspect of such assignments, having largely to do with
routing, both within a routing domain (intra-domain routing) and
between routing domains (inter-domain routing). This paper focuses on
the technical issues.
The technical issues in NSAP allocation are mainly related to routing.
This paper assumes that CLNP will be widely deployed in the Internet,
and that the routing of CLNP traffic will normally be based on the OSI
ES-IS (end-system to intermediate system) routing protocol [10], intra-
domain IS-IS protocol [14], and inter-domain IDRP protocol [16]. It is
expected that in the future the OSI routing architecture will be
enhanced to include support for multicast, resource reservation, and
other advanced services. The requirements for addressing for these
future services is outside of the scope of this document.
The guidelines provided in this paper have been the basis for initial
deployment of CLNP in the Internet, and have proven very valuable both
as an aid to scaling of CLNP routing, and to address administration.
In the current Internet many routing domains (such as corporate and
campus networks) attach to transit networks (such as NSFNET regionals)
in only one or a small number of carefully controlled access points.
The former act as subscribers, while the latter act as providers.
Addressing solutions which require substantial changes or constraints
on the current topology are not considered.
The guidelines in this paper are oriented primarily toward the large-
scale division of NSAP address allocation in the Internet. Topics
covered include:
* Arrangement of parts of the NSAP for efficient operation of the
IS-IS routing protocol;
* Benefits of some topological information in NSAPs to reduce
routing protocol overhead, and specifically the overhead
on inter-domain routing (IDRP);
* The anticipated need for additional levels of hierarchy in
Internet addressing to support network growth and use of the
Routing Domain Confederation mechanism of IDRP to provide
support for additional levels of hierarchy;
* The recommended mapping between Internet topological entities
(i.e., service providers and service subscribers) and OSI
addressing and routing components, such as areas, domains
and confederations;
* The recommended division of NSAP address assignment authority
among service providers and service subscribers;
* Background information on administrative procedures for registra-
tion of administrative authorities immediately below the national
level (GOSIP administrative authorities and ANSI organization
identifiers); and,
* Choice of the high-order portion of the NSAP in leaf routing
domains that are connected to more than one regional or backbone.
It is noted that there are other aspects of NSAP allocation, both
technical and administrative, that are not covered in this paper.
Topics not covered or mentioned only superficially include:
* Identification of specific administrative domains in the Internet;
* Policy or mechanisms for making registered information known to
third parties (such as the entity to which a specific NSAP or a
portion of the NSAP address space has been allocated);
* How a routing domain (especially a site) should organize its
internal topology of areas or allocate portions of its NSAP
address space; the relationship between topology and addresses is
discussed, but the method of deciding on a particular topology or
internal addressing plan is not; and,
* Procedures for assigning the System Identifier (ID) portion of the
NSAP. A method for assignment of System IDs is presented in [18].
3 Background
Some background information is provided in this section that is
helpful in understanding the issues involved in NSAP allocation. A
brief discussion of OSI routing is provided, followed by a review
of the intra-domain and inter-domain protocols in sufficient detail
to understand the issues involved in NSAP allocation. Finally, the
specific constraints that the routing protocols place on NSAPs are
listed.
3.1 OSI Routing Standards
OSI partitions the routing problem into three parts:
* routing exchanges between hosts (end systems, ESs) and routers
(intermediate systems, ISs) (ES-IS);
* routing exchanges between routers in the same routing domain
(intra-domain IS-IS); and,
* routing among routing domains (inter-domain IS-IS).
ES-IS (international standard ISO 9542) advanced to international
standard (IS) status within ISO in 1987. Intra-domain IS-IS advanced
to IS status within ISO in 1992. Inter-Domain Routing Protocol (IDRP)
advanced to IS status within ISO in October 1993. CLNP, ES-IS, and
IS-IS are all widely available in vendor products, and have been
deployed in the Internet for several years. IDRP is currently being
implemented in vendor products.
This paper examines the technical implications of NSAP assignment
under the assumption that ES-IS, intra-domain IS-IS, and IDRP routing
are deployed to support CLNP.
3.2 Overview of IS-IS (ISO/IEC 10589)
The IS-IS intra-domain routing protocol, ISO/IEC 10589, provides
routing for OSI environments. In particular, IS-IS is designed to
work in conjunction with CLNP, ES-IS, and IDRP. This section briefly
describes the manner in which IS-IS operates.
In IS-IS, the internetwork is partitioned into routing domains.
A routing domain is a collection of ESs and ISs that operate common
routing protocols and are under the control of a single administration.
Typically, a routing domain may consist of a corporate network, a
university campus network, a regional network, or a similar contiguous
network under control of a single administrative organization. The
boundaries of routing domains are defined by network management by
setting some links to be exterior, or inter-domain, links. If a link
is marked as exterior, no intra-domain IS-IS routing messages are sent
on that link.
IS-IS routing makes use of two-level hierarchical routing. A routing
domain is subdivided into areas (also known as level 1 subdomains).
Level 1 routers know the topology in their area, including all
routers and hosts. However, level 1 routers do not know the identity
of routers or destinations outside of their area. Level 1 routers
forward all traffic for destinations outside of their area to a level
2 router within their area.
Similarly, level 2 routers know the level 2 topology and know which
addresses are reachable via each level 2 router. The set of all level
2 routers in a routing domain are known as the level 2 subdomain,
which can be thought of as a backbone for interconnecting the areas.
Level 2 routers do not need to know the topology within any level 1
area, except to the extent that a level 2 router may also be a level
1 router within a single area. Only level 2 routers can exchange data
packets or routing information directly with routers located outside
of their routing domain.
NSAP addresses provide a flexible, variable length addressing format,
which allows for multi-level hierarchical address assignment. These
addresses provide the flexibility needed to solve two critical
problems simultaneously: (i) How to administer a worldwide address
space; and (ii) How to assign addresses in a manner which makes
routing scale well in a worldwide Internet.
As illustrated in Figure 1, ISO addresses are subdivided into the
Initial Domain Part (IDP) and the Domain Specific Part (DSP). The IDP
is the part which is standardized by ISO, and specifies the format and
authority responsible for assigning the rest of the address. The DSP
is assigned by whatever addressing authority is specified by the IDP
(see Appendix A for more discussion on the top level NSAP addressing
authorities). It is expected that the authority specified by the IDP
may further sub-divide the DSP, and may assign sub-authorities
responsible for parts of the DSP.
For routing purposes, ISO addresses are subdivided by IS-IS into
the area address, the system identifier (ID), and the NSAP selector
(SEL). The area address identifies both the routing domain and the
area within the routing domain. Generally, the area address
corresponds to the IDP plus a high-order part of the DSP (HO-DSP).
<----IDP---> <----------------------DSP---------------------------->
<-----------HO-DSP------------>
+-----+-----+-------------------------------+--------------+-------+
| AFI | IDI |Contents assigned by authority identified in IDI field|
+-----+-----+-------------------------------+--------------+-------+
<----------------Area Address--------------> <-----ID-----> <-SEL->
IDP Initial Domain Part
AFI Authority and Format Identifier
IDI Initial Domain Identifier
DSP Domain Specific Part
HO-DSP High-order DSP
ID System Identifier
SEL NSAP Selector
Figure 1: OSI Hierarchical Address Structure.
The ID field may be from one to eight octets in length, but must have
a single known length in any particular routing domain. Each router is
configured to know what length is used in its domain. The SEL field is
always one octet in length. Each router is therefore able to identify
the ID and SEL fields as a known number of trailing octets of the NSAP
address. The area address can be identified as the remainder of the
address (after truncation of the ID and SEL fields). It is therefore
not necessary for the area address to have any particular length --
the length of the area address could vary between different area
addresses in a given routing domain.
Usually, all nodes in an area have the same area address. However,
sometimes an area might have multiple addresses. Motivations for
allowing this are several:
* It might be desirable to change the address of an area. The most
graceful way of changing an area address from A to B is to first
allow it to have both addresses A and B, and then after all nodes
in the area have been modified to recognize both addresses, one
by one the nodes can be modified to forget address A.
* It might be desirable to merge areas A and B into one area. The
method for accomplishing this is to, one by one, add knowledge of
address B into the A partition, and similarly add knowledge of
address A into the B partition.
* It might be desirable to partition an area C into two areas, A
and B (where A might equal C, in which case this example becomes
one of removing a portion of an area). This would be accomplished
by first introducing knowledge of address A into the appropriate
nodes (those destined to become area A), and knowledge of address
B into the appropriate nodes, and then one by one removing
knowledge of address C.
Since the addressing explicitly identifies the area, it is very easy
for level 1 routers to identify packets going to destinations outside
of their area, which need to be forwarded to level 2 routers. Thus, in
IS-IS routers perform as follows:
* Level 1 intermediate systems route within an area based on the
ID portion of the ISO address. Level 1 routers recognize, based
on the destination address in a packet, whether the destination
is within the area. If so, they route towards the destination.
If not, they route to the nearest level 2 router.
* Level 2 intermediate systems route based on address prefixes,
preferring the longest matching prefix, and preferring internal
routes over external routes. They route towards areas, without
regard to the internal structure of an area; or towards level 2
routers on the routing domain boundary that have advertised
external address prefixes into the level 2 subdomain. A level 2
router may also be operating as a level 1 router in one area.
A level 1 router will have the area portion of its address manually
configured. It will refuse to become a neighbor with a router whose
area addresses do not overlap its own area addresses. However, if a
level 1 router has area addresses A, B, and C, and a neighbor has
area addresses B and D, then the level 1 IS will accept the other IS
as a level 1 neighbor.
A level 2 router will accept another level 2 router as a neighbor,
regardless of area address. However, if the area addresses do not
overlap, the link would be considered by both routers to be level 2
only, and only level 2 routing packets would flow on the link. External
links (i.e., to other routing domains) must be between level 2 routers
in different routing domains.
IS-IS provides an optional partition repair function. If a level 1
area becomes partitioned, this function, if implemented, allows the
partition to be repaired via use of level 2 routes.
IS-IS requires that the set of level 2 routers be connected. Should
the level 2 backbone become partitioned, there is no provision for use
of level 1 links to repair a level 2 partition.
Occasionally a single level 2 router may lose connectivity to the
level 2 backbone. In this case the level 2 router will indicate in its
level 1 routing packets that it is not "attached", thereby allowing
level 1 routers in the area to route traffic for outside of the area
to a different level 2 router. Level 1 routers therefore route traffic
to destinations outside of their area only to level 2 routers which
indicate in their level 1 routing packets that they are "attached".
A host may autoconfigure the area portion of its address by extracting
the area portion of a neighboring router's address. If this is the
case, then a host will always accept a router as a neighbor. Since the
standard does not specify that the host *must* autoconfigure its area
address, a host may be pre-configured with an area address.
Special treatment is necessary for broadcast subnetworks, such as
LANs. This solves two sets of issues: (i) In the absence of
special treatment, each router on the subnetwork would announce a
link to every other router on the subnetwork, resulting in
O(n-squared) links reported; (ii) Again, in the absence of special
treatment, each router on the LAN would report the same identical
list of end systems on the LAN, resulting in substantial
duplication.
These problems are avoided by use of a "pseudonode", which represents
the LAN. Each router on the LAN reports that it has a link to the
pseudonode (rather than reporting a link to every other router on the
LAN). One of the routers on the LAN is elected "designated router".
The designated router then sends out a Link State Packet (LSP) on
behalf of the pseudonode, reporting links to all of the routers on
the LAN. This reduces the potential n-squared links to n links. In
addition, only the pseudonode LSP includes the list of end systems on
the LAN, thereby eliminating the potential duplication.
The IS-IS provides for optional Quality of Service (QOS) routing,
based on throughput (the default metric), delay, expense, or
residual error probability.
IS-IS has a provision for authentication information to be
carried in all IS-IS PDUs. Currently the only form of
authentication which is defined is a simple password. A password
may be associated with each link, each area, and with the level 2
subdomain. A router not in possession of the appropriate
password(s) is prohibited from participating in the corresponding
function (i.e., may not initialize a link, be a member of the
area, or a member of the level 2 subdomain, respectively).
Procedures are provided to allow graceful migration of passwords
without disrupting operation of the routing protocol. The
authentication functions are extensible so that a stronger,
cryptographically-based security scheme may be added in an
upwardly compatible fashion at a future date.
3.3 Overview of IDRP (ISO/IEC 10747)
The Inter-Domain Routing Protocol (IDRP, ISO/IEC 10747), developed
in ISO, provides routing for OSI environments. In particular, IDRP
is designed to work in conjuction with CLNP, ES-IS, and IS-IS. This
section briefly describes the manner in which IDRP operates.
Consistent with the OSI Routing Framework [13], in IDRP the
internetwork is partitioned into routing domains. IDRP places no
restrictions on the inter-domain topology. A router that participates
in IDRP is called a Boundary Intermediate System (BIS). Domains
that participate in IDRP are not allowed to overlap - a BIS may
belong to only one domain.
A pair of BISs are called external neighbors if these BISs belong
to different domains but share a common subnetwork (i.e., a BIS can
reach its external neighbor in a single network layer hop). Two
domains are said to be adjacent if they have BISs that are external
neighbors of each other. A pair of BISs are called internal
neighbors if these BISs belong to the same domain. In contrast with
external neighbors, internal neighbors don't have to share a common
subnetwork -- IDRP assumes that a BIS should be able to exchange
Network Protocol Date Units (NPDUs) with any of its internal
neighbors by relying solely on intra-domain routing procedures.
IDRP governs the exchange of routing information between a
pair of neighbors, either external or internal. IDRP is
self-contained with respect to the exchange of information between
external neighbors. Exchange of information between internal
neighbors relies on additional support provided by intra-domain
routing (unless internal neighbors share a common subnetwork).
To facilitate routing information aggregation/abstraction, IDRP
allows grouping of a set of connected domains into a Routing Domain
Confederation (RDC). A given domain may belong to more than one RDC.
There are no restrictions on how many RDCs a given domain may
simultaneously belong to, and no preconditions on how RDCs should
be formed -- RDCs may be either nested, or disjoint, or may overlap.
One RDC is nested within another RDC if all members (RDs) of the
former are also members of the latter, but not vice versa. Two RDCs
overlap if they have members in common and also each has members that
are not in the other. Two RDCs are disjoint if they have no members
in common.
Each domain participating in IDRP is assigned a unique Routing
Domain Identifier (RDI). Syntactically an RDI is represented as an
OSI network layer address. Each RDC is assigned a unique Routing
Domain Confederation Identifier (RDCI). RDCIs are assigned out of
the address space allocated for RDIs -- RDCIs and RDIs are
syntactically indistinguishable. Procedures for assigning and
managing RDIs and RDCIs are outside the scope of the protocol.
However, since RDIs are syntactically nothing more than network
layer addresses, and RDCIs are syntactically nothing more than
RDIs, it is expected that RDI and RDCI assignment and management
would be part of the network layer assignment and management
procedures. Recommendations for RDI and RDCI assignment are
provided in section 6.5.
IDRP requires a BIS to be preconfigured with the RDI of the domain
to which the BIS belongs. If a BIS belongs to a domain that is a
member of one or more RDCs, then the BIS has to be preconfigured with
RDCIs of all the RDCs the domain is in, and the information about
relations between the RDCs - nested or overlapped.
IDRP doesn't assume or require any particular internal structure
for the addresses. The protocol provides correct routing as long
as the following guidelines are met:
- End systems and intermediate systems may use any NSAP address
or Network Entity Title (NET -- i.e., an NSAP address without
the selector) that has been assigned under ISO 8348 [11]
guidelines;
- An NSAP prefix carried in the Network Layer Reachability
Information (NLRI) field for a route originated by a BIS in a given
routing domain should be associated with only that routing domain;
that is, no system identified by the prefix should reside in a
different routing domain; ambiguous routing may result if several
routing domains originate routes whose NLRI field contain identical
NSAP address prefixes, since this would imply that the same
system(s) is simultaneously located in several routing domains;
- Several different NSAP prefixes may be associated with a single
routing domain which contains a mix of systems which use NSAP
addresses assigned by several different addressing authorities.
IDRP assumes that the above guidelines have been satisfied, but
it contains no means to verify that this is so. Therefore, such
verification is assumed to be the responsibility of the administrators
of routing domains.
IDRP provides mandatory support for data integrity and optional support
for data origin authentication for all of its messages. Each message
carries a 16-octet digital signature that is computed by applying the
MD-4 algorithm (RFC1320) to the context of the message itself. This
signature provides support for data integrity. To support data origin
authentication a BIS, when computing a digital signature of a message,
may prepend and append additional information to the message. This
information is not passed as part of the message but is known to the
receiver.
3.3.1 Scaling Mechanisms in IDRP
The ability to group domains in RDCs provides a simple, yet powerful
mechanism for routing information aggregation and abstraction. It
allows reduction of topological information by replacing a sequence
of RDIs carried by the RD_PATH attribute with a single RDCI. It also
allows reduction of the amount of information related to transit
policies, since the policies can be expressed in terms of aggregates
(RDCs), rather than individual components (RDs). It also allows
simplification of route selection policies, since these policies can
be expressed in terms of aggregates (RDCs) rather than individual
components (RDs).
Aggregation and abstraction of Network Layer Reachability Information
(NLRI) is supported by the "route aggregation" mechanism of IDRP.
This mechanism is complementary to the Routing Domain Confederations
mechanism. Both mechanisms are intended to provide scalable routing
via information reduction/abstraction. However, the two mechanisms are
used for different purposes: route aggregation for aggregation and
abstraction of routes (i.e., Network Layer Reachability Information),
Routing Domain Confederations for aggregation and abstraction of
topology and/or policy information. To provide maximum benefits, both
mechanisms can be used together. This implies that address assignment
that will facilitate route aggregation does not conflict with the
ability to form RDCs, and vice versa; formation of RDCs should be done
in a manner consistent with the address assignment needed for route
aggregation.
3.4 Requirements of IS-IS and IDRP on NSAPs
The preferred NSAP format for IS-IS is shown in Figure 1. A number
of points should be noted from IS-IS:
* The IDP is as specified in ISO 8348, the OSI network layer service
specification [11];
* The high-order portion of the DSP (HO-DSP) is that portion of the
DSP whose assignment, structure, and meaning are not constrained
by IS-IS;
* The area address (i.e., the concatenation of the IDP and the
HO-DSP) must be globally unique. If the area address of an NSAP
matches one of the area addresses of a router, it is in the
router's area and is routed to by level 1 routing;
* Level 2 routing acts on address prefixes, using the longest
address prefix that matches the destination address;
* Level 1 routing acts on the ID field. The ID field must be unique
within an area for ESs and level 1 ISs, and unique within the
routing domain for level 2 ISs. The ID field is assumed to be
flat. The method presented in RFC 1526 [18] may optionally be used
to assure globally unique IDs;
* The one-octet NSAP Selector, SEL, determines the entity to receive
the CLNP packet within the system identified by the rest of the
NSAP (i.e., a transport entity) and is always the last octet of
the NSAP; and,
* A system shall be able to generate and forward data packets
containing addresses in any of the formats specified by ISO
8348. However, within a routing domain that conforms to IS-IS,
the lower-order octets of the NSAP should be structured as the ID
and SEL fields shown in Figure 1 to take full advantage of IS-IS
routing. End systems with addresses which do not conform may
require additional manual configuration and be subject to
inferior routing performance.
For purposes of efficient operation of the IS-IS routing protocol,
several observations may be made. First, although the IS-IS protocol
specifies an algorithm for routing within a single routing domain, the
routing algorithm must efficiently route both: (i) Packets whose final
destination is in the domain (these must, of course, be routed to the
correct destination end system in the domain); and (ii) Packets whose
final destination is outside of the domain (these must be routed to an
appropriate ``border'' router, from which they will exit the domain).
For those destinations which are in the domain, level 2 routing treats
the entire area address (i.e., all of the NSAP address except the ID
and SEL fields) as if it were a flat field. Thus, the efficiency of
level 2 routing to destinations within the domain is affected only by
the number of areas in the domain, and the number of area addresses
assigned to each area.
For those destinations which are outside of the domain, level 2
routing routes according to address prefixes. In this case, there
is considerable potential advantage (in terms of reducing the amount
of routing information that is required) if the number of address
prefixes required to describe any particular set of external
destinations can be minimized. Efficient routing with IDRP similarly
also requires minimization of the number of address prefixes needed
to describe specific destinations. In other words, addresses need to
be assigned with topological significance. This requirement is
described in more detail in the following sections.
4 NSAPs and Routing
4.1 Routing Data Abstraction
When determining an administrative policy for NSAP assignment, it
is important to understand the technical consequences. The objective
behind the use of hierarchical routing is to achieve some level
of routing data abstraction, or summarization, to reduce the
processing time, memory requirements, and transmission bandwidth
consumed in support of routing. This implies that address
assignment must serve the needs of routing, in order for routing to
scale to very large networks.
While the notion of routing data abstraction may be applied to
various types of routing information, this and the following
sections primarily emphasize one particular type, namely reachability
information. Reachability information describes the set of reachable
destinations.
Abstraction of reachability information dictates that NSAPs be assigned
according to topological routing structures. However, administrative
assignment falls along organizational or political boundaries. These
may not be congruent to topological boundaries, and therefore the
requirements of the two may collide. A balance between these two needs
is necessary.
Routing data abstraction occurs at the boundary between hierarchically
arranged topological routing structures. An element lower in the
hierarchy reports summary routing information to its parent(s). Within
the current OSI routing framework [13] and routing protocols, the
lowest boundary at which this can occur is the boundary between an
area and the level 2 subdomain within a IS-IS routing domain. Data
abstraction is designed into IS-IS at this boundary, since level 1
ISs are constrained to reporting only area addresses.
Level 2 routing is based upon address prefixes. Level 2 routers (ISs)
distribute, throughout the level 2 subdomain, the area addresses of
the level 1 areas to which they are attached (and any manually
configured reachable address prefixes). Level 2 routers compute next-
hop forwarding information to all advertised address prefixes. Level 2
routing is determined by the longest advertised address prefix that
matches the destination address.
At routing domain boundaries, address prefix information is exchanged
with other routing domains via IDRP. If area addresses within a
routing domain are all drawn from distinct NSAP assignment authorities
(allowing no abstraction), then the boundary prefix information
consists of an enumerated list of all area addresses.
Alternatively, should the routing domain ``own'' an address prefix
and assign area addresses based upon it, boundary routing information
can be summarized into the single prefix. This can allow substantial
data reduction and, therefore, will allow much better scaling (as
compared to the uncoordinated area addresses discussed in the previous
paragraph).
If routing domains are interconnected in a more-or-less random (non-
hierarchical) scheme, it is quite likely that no further abstraction
of routing data can occur. Since routing domains would have no defined
hierarchical relationship, administrators would not be able to assign
area addresses out of some common prefix for the purpose of data
abstraction. The result would be flat inter-domain routing; all
routing domains would need explicit knowledge of all other routing
domains that they route to. This can work well in small- and medium-
sized internets, up to a size somewhat larger than the current IP
Internet. However, this does not scale to very large internets. For
example, we expect growth in the future to an international Internet
which has tens or hundreds of thousands of routing domains in the U.S.
alone. Even larger numbers of routing domains are possible when each
home, or each small company, becomes its own routing domain. This
requires a greater degree of data abstraction beyond that which can be
achieved at the ``routing domain'' level.
In the Internet, however, it should be possible to exploit the
existing hierarchical routing structure interconnections, as discussed
in Section 5. Thus, there is the opportunity for a group of routing
domains each to be assigned an address prefix from a shorter prefix
assigned to another routing domain whose function is to interconnect
the group of routing domains. Each member of the group of routing
domains now ``owns'' its (somewhat longer) prefix, from which it
assigns its area addresses.
The most straightforward case of this occurs when there is a set
of routing domains which are all attached only to a single service
provider domain (e.g. regional network), and which use that provider
for all external (inter-domain) traffic. A small address prefix may
be assigned to the provider, which then assigns slightly longer
prefixes (based on the provider's prefix) to each of the routing
domains that it interconnects. This allows the provider, when
informing other routing domains of the addresses that it can reach,
to abbreviate the reachability information for a large number of
routing domains as a single prefix. This approach therefore can
allow a great deal of hierarchical abbreviation of routing
information, and thereby can greatly improve the scalability of
inter-domain routing.
Clearly, this approach is recursive and can be carried through several
iterations. Routing domains at any ``level'' in the hierarchy may
use their prefix as the basis for subsequent suballocations, assuming
that the NSAP addresses remain within the overall length and structure
constraints. The flexibility of NSAP addresses facilitates this form
of hierarchical address assignment and routing. As one example of how
NSAPs may be used, the GOSIP Version 2 NSAP structure is discussed
later in this section.
At this point, we observe that the number of nodes at each lower
level of a hierarchy tends to grow exponentially. Thus the greatest
gains in data abstraction occur at the leaves and the gains drop
significantly at each higher level. Therefore, the law of diminishing
returns suggests that at some point data abstraction ceases to
produce significant benefits. Determination of the point at which data
abstraction ceases to be of benefit requires a careful consideration
of the number of routing domains that are expected to occur at each
level of the hierarchy (over a given period of time), compared to the
number of routing domains and address prefixes that can conveniently
and efficiently be handled via dynamic inter-domain routing protocols.
As the Internet grows, further levels of hierarchy may become
necessary. Again, this requires considerable flexibility in the
addressing scheme, such as is provided by NSAP addresses.
4.2 NSAP Administration and Efficiency
There is a balance that must be sought between the requirements
on NSAPs for efficient routing and the need for decentralized NSAP
administration. The NSAP structure from Version 2 of GOSIP (Figure 2)
offers one example of how these two needs might be met. The AFI,
IDI, DSP Format Identifier (DFI), and Administrative Authority (AA)
fields provide for administrative decentralization. The AFI/IDI pair
of values 47/0005 identify the U.S. Government as the authority
responsible for defining the DSP structure and allocating values
within it (see Appendix A for more information on NSAP structure).
[Note: We are using U.S. GOSIP version 2 addresses only as an
example. It is not necessary that NSAPs be allocated from the
GOSIP Version 2 authority under 47/0005. The ANSI format under the
Data Country Code for the U.S. (DCC=840) and formats assigned to
other countries and ISO members or liaison organizations are also
being used, and work equally well. For parts of the Internet
outside of the U.S. there may in some cases be strong reasons to
prefer a country- or area-specific format rather than the U.S.
GOSIP format. However, GOSIP addresses are used in most cases in
the examples in this paper because:
* The DSP format has been defined and allows hierarchical
allocation; and,
* An operational registration authority for suballocation of
AA values under the GOSIP address space has already been
established at GSA.]
GOSIP Version 2 defines the DSP structure as shown (under DFI=80h) and
provides for the allocation of AA values to administrations. Thus, the
fields from the AFI to the AA, inclusive, represent a unique address
prefix assigned to an administration.
_______________
!<--__IDP_-->_!___________________________________
!AFI_!__IDI___!___________<--_DSP_-->____________!
!_47_!__0005__!DFI_!AA_!Rsvd_!_RD_!Area_!ID_!Sel_!
octets !_1__!___2____!_1__!_3_!__2__!_2__!_2___!_6_!_1__!
IDP Initial Domain Part
AFI Authority and Format Identifier
IDI Initial Domain Identifier
DSP Domain Specific Part
DFI DSP Format Identifier
AA Administrative Authority
Rsvd Reserved
RD Routing Domain Identifier
Area Area Identifier
ID System Identifier
SEL NSAP Selector
Figure 2: GOSIP Version 2 NSAP structure.
American National Standard X3.216-1992 [1] specifies the structure of
the DSP for NSAP addresses that use an Authority and Format Identifier
(AFI) value of (decimal) 39, which identifies the "ISO-DCC" (data
country code) format, in which the value of the Initial Domain
Identifier (IDI) is (decimal) 840, which identifies the U.S. National
Body (ANSI). This DSP structure is identical to the structure that
is specified by GOSIP Version 2. The AA field is called "org" for
organization identifier in the ANSI standard, and the ID field is
called "system". The ANSI format, therefore, differs from the GOSIP
format illustrated above only in that the AFI and IDI specify the
"ISO-DCC" format rather than the "ISO 6523-ICD" format used by
GOSIP, and the "AA" field is administered by an ANSI registration
authority rather than by the GSA. Organization identifiers may be
obtained from ANSI. The technical considerations applicable to NSAP
administration are independent of whether a GOSIP Version 2 or an
ANSI value is used for the NSAP assignment.
Similarly, although other countries may make use of slightly different
NSAP formats, the principles of NSAP assignment and use are the same.
The NSAP formats recommended by RARE WG4 for use in Europe are
discussed in section 6.2.
In the low-order part of the GOSIP Version 2 NSAP format, two
fields are defined in addition to those required by IS-IS. These
fields, RD and Area, are defined to allow allocation of NSAPs along
topological boundaries in support of increased data abstraction.
Administrations assign RD identifiers underneath their unique address
prefix (the reserved field is left to accommodate future growth and
to provide additional flexibility for inter-domain routing). Routing
domains allocate Area identifiers from their unique prefix. The result
is:
* AFI+IDI+DFI+AA = administration prefix,
* administration prefix(+Rsvd)+RD = routing domain prefix, and,
* routing domain prefix+Area = area address.
This provides for summarization of all area addresses within a routing
domain into one prefix. If the AA identifier is accorded topological
significance (in addition to administrative significance), an
additional level of data abstraction can be obtained, as is discussed
in the next section.
5 NSAP Administration and Routing in the Internet
Basic Internet routing components are service providers (e.g.,
backbones, regional networks), and service subscribers (e.g., sites
or campuses). These components are arranged hierarchically for the
most part. A natural mapping from these components to OSI routing
components is that providers and subscribers act as routing domains.
Alternatively, a subscriber (e.g., a site) may choose to operate as a
part of a domain (as an area) formed by a service provider. However,
in such a case the area is part of the provider's routing domain and
the discussion in Section 5.1 applies. We assume that some, if not
most, sites will prefer to operate as part of their provider's
routing domain. Such sites can exchange routing information with
their provider via interior routing protocol route leaking or via an
exterior routing protocol. For the purposes of this discussion, the
choice is not significant. The site is still allocated a prefix from
the provider's address space, and the provider will advertise its own
prefix into inter-domain routing.
Given such a mapping, where should address administration and alloca-
tion be performed to satisfy both administrative decentralization and
data abstraction? Three possibilities are considered:
1. at the area,
2. at the leaf routing domain, and,
3. at the transit routing domain (TRD).
Leaf routing domains correspond to sites, where the primary purpose is
to provide intra-domain routing services. Transit routing domains are
deployed to carry transit (i.e., inter-domain) traffic; backbones and
regionals are TRDs.
The greatest burden in transmitting and operating on routing informa-
tion is at the top of the routing hierarchy, where routing information
tends to accumulate. In the Internet, for example, regionals must man-
age the set of network numbers for all networks reachable through the
regional. Traffic destined for other networks is generally routed to
the backbone. The backbones, however, must be cognizant of the network
numbers for all attached regionals and their associated networks.
In general, higher levels of the routing hierarchy will benefit the
most from the abstraction of routing information at a lower level of
the routing hierarchy. There is relatively little direct benefit to the
administration that performs the abstraction, since it must maintain
routing information individually on each attached topological routing
structure.
For example, suppose that a given site is trying to decide whether
to obtain an NSAP address prefix based on an AA value from GSA
(implying that the first four octets of the address would be those
assigned out of the GOSIP space), or based on an RD value from its
regional (implying that the first seven octets of the address are
those assigned to that regional). If considering only their own
self-interest, the site itself, and the attached regional, have
little reason to choose one approach or the other. The site must use
one prefix or another; the source of the prefix has little effect
on routing efficiency within the site. The regional must maintain
information about each attached site in order to route, regardless of
any commonality in the prefixes of the sites.
However, there is a difference when the regional distributes routing
information to backbones and other regionals. In the first case, the
regional cannot aggregate the site's address into its own prefix;
the address must be explicitly listed in routing exchanges, resulting
in an additional burden to backbones and other regionals which must
exchange and maintain this information.
In the second case, each other regional and backbone sees a single
address prefix for the regional, which encompasses the new site. This
avoids the exchange of additional routing information to identify the
new site's address prefix. Thus, the advantages primarily benefit
other regionals and backbones which maintain routing information about
this site and regional.
One might apply a supplier/consumer model to this problem: the higher
level (e.g., a backbone) is a supplier of routing services, while
the lower level (e.g., an attached regional) is the consumer of these
services. The price charged for services is based upon the cost of
providing them. The overhead of managing a large table of addresses
for routing to an attached topological entity contributes to this
cost.
The Internet, however, is not a market economy. Rather, efficient
operation is based on cooperation. The guidelines discussed below
describe reasonable ways of managing the OSI address space that
benefit the entire community.
5.1 Administration at the Area
If areas take their area addresses from a myriad of unrelated NSAP
allocation authorities, there will be effectively no data abstraction
beyond what is built into IS-IS. For example, assume that within a
routing domain three areas take their area addresses, respectively,
out of:
* the GOSIP Version 2 authority assigned to the Department of
Commerce, with an AA of nnn:
AFI=47, IDI=0005, DFI=80h, AA=nnn, ... ;
* the GOSIP Version 2 authority assigned to the Department of the
Interior, with an AA of mmm:
AFI=47, IDI=0005, DFI=80h, AA=mmm, ... ; and,
* the ANSI authority under the U.S. Data Country Code (DCC) (Section
A.2) for organization XYZ with ORG identifier = xxx:
AFI=39, IDI=840, DFI=dd, ORG=xxx, ....
As described in Section 3.3, from the point of view of any particular
routing domain, there is no harm in having the different areas in
the routing domain use addresses obtained from a wide variety of
administrations. For routing within the domain, the area addresses are
treated as a flat field.
However, this does have a negative effect on inter-domain routing,
particularly on those other domains which need to maintain routes to
this domain. There is no common prefix that can be used to represent
these NSAPs and therefore no summarization can take place at the
routing domain boundary. When addresses are advertised by this routing
domain to other routing domains, an enumerated list must be used
consisting of the three area addresses.
This situation is roughly analogous to the dissemination of routing
information in the TCP/IP Internet prior to the introduction of CIDR.
Areas correspond roughly to networks and area addresses to network
numbers. The result of allowing areas within a routing domain to take
their NSAPs from unrelated authorities is flat routing at the area
address level. The number of address prefixes that leaf routing domains
would advertise is on the order of the number of attached areas; the
number of prefixes a regional routing domain would advertise is
approximately the number of areas attached to the client leaf routing
domains; and for a backbone this would be summed across all attached
regionals. As the Internet grows this will quickly become intractable.
A greater degree of hierarchical information reduction is necessary to
allow continued growth in the Internet.
5.2 Administration at the Leaf Routing Domain
As mentioned previously, the greatest degree of data abstraction comes
at the lowest levels of the hierarchy. Providing each leaf routing
domain (that is, site) with a unique prefix results in the biggest
single increase in abstraction, with each leaf domain assigning area
addresses from its prefix. From outside the leaf routing domain, the
set of all addresses reachable in the domain can then be represented
by a single prefix.
As an example, assume a government agency has been assigned the AA
value of zzz under ICD=0005. The agency then assigns a routing domain
identifier to a routing domain under its administrative authority
identifier, rrr. The resulting prefix for the routing domain is:
AFI=47, IDI=0005, DFI=80h, AA=zzz, Rsvd=0, RD=rrr.
All areas within this routing domain would have area addresses
comprising this prefix followed by an Area identifier. The prefix
represents the summary of reachable addresses within the routing
domain.
There is a close relationship between areas and routing domains
implicit in the fact that they operate a common routing protocol and
are under the control of a single administration. The routing domain
administration subdivides the domain into areas and structures a level
2 subdomain (i.e., a level 2 backbone) which provides connectivity
among the areas. The routing domain represents the only path between
an area and the rest of the internetwork. It is reasonable that
this relationship also extend to include a common NSAP addressing
authority. Thus, the areas within the leaf RD should take their NSAPs
from the prefix assigned to the leaf RD.
5.3 Administration at the Transit Routing Domain
Two kinds of transit routing domains (TRDs) are considered, direct
providers and indirect providers. Most of the subscribers of a
direct provider are domains that act solely as service subscribers
(they carry no transit traffic). Most of the subscribers of an
indirect provider are domains that, themselves, act as service
providers. In present terminology a backbone is an indirect
provider, while a TRD is a direct provider. Each case is discussed
separately below.
5.3.1 Direct Service Providers
It is interesting to consider whether direct service providers'
routing domains should be the common authority for assigning NSAPs
from a unique prefix to the leaf routing domains that they serve.
In the long term the number of routing domains in the Internet will
grow to the point that it will be infeasible to route on the basis of
a flat field of routing domains. It will therefore be essential to
provide a greater degree of information abstraction.
Direct providers may assign prefixes to leaf domains, based on a
single (shorter length) address prefix assigned to the provider. For
example, given the GOSIP Version 2 address structure, an AA value
may be assigned to each direct provider, and routing domain values
may be assigned by the provider to each attached leaf routing domain.
A similar hierarchical address assignment based on a prefix assigned
to each provider may be used for other NSAP formats. This results in
direct providers advertising to backbones a small fraction of the
number of address prefixes that would be necessary if they enumerated
the individual prefixes of the leaf routing domains. This represents
a significant savings given the expected scale of global
internetworking.
Are leaf routing domains willing to accept prefixes derived from
the direct providers? In the supplier/consumer model, the direct
provider is offering connectivity as the service, priced according
to its costs of operation. This includes the ``price'' of obtaining
service from one or more indirect providers (e.g. backbones). In
general, indirect providers will want to handle as few address
prefixes as possible to keep costs low. In the Internet environment,
which does not operate as a typical marketplace, leaf routing domains
must be sensitive to the resource constraints of the providers (both
direct and indirect). The efficiencies gained in routing clearly
warrant the adoption of NSAP administration by the direct providers.
The mechanics of this scenario are straightforward. Each direct
provider is assigned a unique prefix, from which it allocates
slightly longer routing domain prefixes for its attached leaf
routing domains. For GOSIP NSAPs, this means that a direct provider
would be assigned an AA identifier. Attached leaf routing domains
would be assigned RD identifiers under the regional's unique prefix.
For example, assume that NIST is a leaf routing domain whose sole
inter-domain link is via SURANet. If SURANet is assigned an AA
identifier kkk, NIST could be assigned an RD of jjj, resulting in
a unique prefix for SURANet of:
AFI=47, IDI=0005, DFI=80h, AA=kkk
and a unique prefix for NIST of
AFI=47, IDI=0005, DFI=80h, AA=kkk, (Rsvd=0), RD=jjj.
A similar scheme can be established using NSAPs allocated under
DCC=840. In this case, a regional applies for an ORG identifier from
ANSI, which serves the same purpose as the AA identifier in GOSIP.
5.3.2 Indirect Providers (Backbones)
There does not appear to be a strong case for direct service
providers to take their address spaces from the NSAP space of an
indirect provider (e.g. backbone). The benefit in routing data
abstraction is relatively small. The number of direct providers
today is in the tens and an order of magnitude increase would not
cause an undue burden on the backbones. Also, it may be expected that
as time goes by there will be increased direct interconnection of the
direct providers, leaf routing domains directly attached to the
backbones, and international links directly attached to the providers.
Under these circumstances, the distinction between direct and indirect
providers may become blurred.
An additional factor that discourages allocation of NSAPs from a
backbone prefix is that the backbones and their attached providers are
perceived as being independent. Providers may take their long-haul
service from one or more backbones, or may switch backbones should
a more cost-effective service be provided elsewhere (essentially,
backbones can be thought of the same way as long-distance telephone
carriers). Having NSAPs derived from the backbone is inconsistent with
the nature of the relationship.
5.4 Multi-homed Routing Domains
The discussions in Section 5.3 suggest methods for allocating NSAP
addresses based on service provider connectivity. This allows a
great deal of information reduction to be achieved for those routing
domains which are attached to a single provider. In particular, such
routing domains may select their NSAP addresses from a space allocated
to them by their direct service provider. This allows the provider,
when announcing the addresses that it can reach to other providers, to
use a single address prefix to describe a large number of NSAP
addresses corresponding to multiple routing domains.
However, there are additional considerations for routing domains
which are attached to multiple providers. Such ``multi-homed''
routing domains may, for example, consist of single-site campuses and
companies which are attached to multiple backbones, large
organizations which are attached to different providers at different
locations in the same country, or multi-national organizations which
are attached to providers in a variety of countries worldwide. There
are a number of possible ways to deal with these multi-homed routing
domains.
One possible solution is to assign addresses to each multi-homed
organization independently from the providers to which it is attached.
This allows each multi-homed organization to base its NSAP assignments
on a single prefix, and to thereby summarize the set of all NSAPs
reachable within that organization via a single prefix. The
disadvantage of this approach is that since the NSAP address for that
organization has no relationship to the addresses of any particular
provider, the providers to which this organization is attached will
need to advertise the prefix for this organization to other providers.
Other providers (potentially worldwide) will need to maintain an
explicit entry for that organization in their routing tables. If other
providers do not maintain a separate route for this organization, then
packets destined to this organization will be lost.
For example, suppose that a very large U.S.-wide company ``Mega
Big International Incorporated'' (MBII) has a fully interconnected
internal network and is assigned a single AA value under the U.S.
GOSIP Version 2 address space. It is likely that outside of the U.S.,
a single entry may be maintained in routing tables for all U.S. GOSIP
addresses. However, within the U.S., every backbone and regional
will need to maintain a separate address entry for MBII. If MBII
is in fact an international corporation, then it may be necessary
for every provider worldwide to maintain a separate entry for MBII
(including providers to which MBII is not attached). Clearly this
may be acceptable if there are a small number of such multi-homed
routing domains, but would place an unacceptable load on routers
within providers if all organizations were to choose such address
assignments. This solution may not scale to internets where there are
many hundreds of thousands of multi-homed organizations.
A second possible approach would be for multi-homed organizations to
be assigned a separate NSAP space for each connection to a provider,
and to assign a single address prefix to each area within its routing
domain(s) based on the closest interconnection point. For example, if
MBII had connections to two providers in the U.S. (one east coast, and
one west coast), as well as three connections to national providers
in Europe, and one in the far east, then MBII may make use of six
different address prefixes. Each area within MBII would be assigned a
single address prefix based on the nearest connection.
For purposes of external routing of traffic from outside MBII to a
destination inside of MBII, this approach works similarly to treating
MBII as six separate organizations. For purposes of internal routing,
or for routing traffic from inside of MBII to a destination outside of
MBII, this approach works the same as the first solution.
If we assume that incoming traffic (coming from outside of MBII, with
a destination within MBII) is always to enter via the nearest point
to the destination, then each provider which has a connection to MBII
needs to announce to other providers the ability to reach only those
parts of MBII whose address is taken from its own address space. This
implies that no additional routing information needs to be exchanged
between providers, resulting in a smaller load on the inter-domain
routing tables maintained by providers when compared to the first
solution. This solution therefore scales better to extremely large
internets containing very large numbers of multi-homed organizations.
One problem with the second solution is that backup routes to multi-
homed organizations are not automatically maintained. With the first
solution, each provider, in announcing the ability to reach MBII,
specifies that it is able to reach all of the NSAPs within MBII. With
the second solution, each provider announces that it can reach all of
the NSAPs based on its own address prefix, which only includes some
of the NSAPs within MBII. If the connection between MBII and one
particular provider were severed, then the NSAPs within MBII with
addresses based on that provider would become unreachable via inter-
domain routing. The impact of this problem can be reduced somewhat by
maintenance of additional information within routing tables, but this
reduces the scaling advantage of the second approach.
The second solution also requires that when external connectivity
changes, internal addresses also change.
Also note that this and the previous approach will tend to cause
packets to take different routes. With the first approach, packets
from outside of MBII destined for within MBII will tend to enter via
the point which is closest to the source (which will therefore tend to
maximize the load on the networks internal to MBII). With the second
solution, packets from outside destined for within MBII will tend to
enter via the point which is closest to the destination (which will
tend to minimize the load on the networks within MBII, and maximize
the load on the providers).
These solutions also have different effects on policies. For example,
suppose that country ``X'' has a law that traffic from a source
within country X to a destination within country X must at all
times stay entirely within the country. With the first solution, it
is not possible to determine from the destination address whether
or not the destination is within the country. With the second
solution, a separate address may be assigned to those NSAPs which are
within country X, thereby allowing routing policies to be followed.
Similarly, suppose that ``Little Small Company'' (LSC) has a policy
that its packets may never be sent to a destination that is within
MBII. With either solution, the routers within LSC may be configured
to discard any traffic that has a destination within MBII's address
space. However, with the first solution this requires one entry;
with the second it requires many entries and may be impossible as a
practical matter.
There are other possible solutions as well. A third approach is to
assign each multi-homed organization a single address prefix, based
on one of its connections to a provider. Other providers to which the
multi-homed organization are attached maintain a routing table entry
for the organization, but are extremely selective in terms of which
indirect providers are told of this route. This approach will produce
a single ``default'' routing entry which all providers will know how
to reach the organization (since presumably all providers will maintain
routes to each other), while providing more direct routing in those
cases where providers agree to maintain additional routing information.
There is at least one situation in which this third approach is
particularly appropriate. Suppose that a special interest group of
organizations have deployed their own backbone. For example, lets
suppose that the U.S. National Widget Manufacturers and Researchers
have set up a U.S.-wide backbone, which is used by corporations
who manufacture widgets, and certain universities which are known
for their widget research efforts. We can expect that the various
organizations which are in the widget group will run their internal
networks as separate routing domains, and most of them will also
be attached to other providers (since most of the organizations
involved in widget manufacture and research will also be involved
in other activities). We can therefore expect that many or most of the
organizations in the widget group are dual-homed, with one attachment
for widget-associated communications and the other attachment for
other types of communications. Let's also assume that the total number
of organizations involved in the widget group is small enough that
it is reasonable to maintain a routing table containing one entry
per organization, but that they are distributed throughout a larger
internet with many millions of (mostly not widget-associated) routing
domains.
With the third approach, each multi-homed organization in the widget
group would make use of an address assignment based on its other
attachment(s) to providers (the attachments not associated with the
widget group). The widget backbone would need to maintain routes to
the routing domains associated with the various member organizations.
Similarly, all members of the widget group would need to maintain a
table of routes to the other members via the widget backbone. However,
since the widget backbone does not inform other general worldwide
providers of what addresses it can reach (since the backbone is not
intended for use by other outside organizations), the relatively large
set of routing prefixes needs to be maintained only in a limited number
of places. The addresses assigned to the various organizations which
are members of the widget group would provide a ``default route'' via
each members other attachments to providers, while allowing
communications within the widget group to use the preferred path.
A fourth solution involves assignment of a particular address prefix
for routing domains which are attached to two or more specific
cooperative public service providers. For example, suppose that there
are two regionals ``SouthNorthNet'' and ``NorthSouthNet'' which have a
very large number of customers in common (i.e., there are a large number
of routing domains which are attached to both). Rather than getting
two address prefixes (such as two AA values assigned under the GOSIP
address space) these organizations could obtain three prefixes. Those
routing domains which are attached to NorthSouthNet but not attached
to SouthNorthNet obtain an address assignment based on one of the
prefixes. Those routing domains which are attached to SouthNorthNet
but not to NorthSouthNet would obtain an address based on the second
prefix. Finally, those routing domains which are multi-homed to both
of these networks would obtain an address based on the third prefix.
Each of these two providers would then advertise two prefixes to other
providers, one prefix for leaf routing domains attached to it only,
and one prefix for leaf routing domains attached to both.
This fourth solution could become important when use of public data
networks becomes more common. In particular, it is likely that at some
point in the future a substantial percentage of all routing domains
will be attached to public data networks. In this case, nearly all
government-sponsored networks (such as some current NSFNET regionals)
may have a set of customers which overlaps substantially with the
public networks.
There are therefore a number of possible solutions to the problem
of assigning NSAP addresses to multi-homed routing domains. Each
of these solutions has very different advantages and disadvantages.
Each solution places a different real (i.e., financial) cost on the
multi-homed organizations, and on the providers (including those to
which the multi-homed organizations are not attached).
In addition, most of the solutions described also highlight the
need for each provider to develop policy on whether and under what
conditions to accept customers with addresses that are not based on
its own address prefix, and how such non-local addresses will be
treated. For example, a somewhat conservative policy might be that
an attached leaf RD may use any NSAP address prefix, but that
addresses which are not based on the providers own prefix might not
be advertised to other providers. In a less conservative policy, a
provider might accept customers using such non-local prefixes and
agree to exchange them in routing information with a defined set of
other providers (this set could be an a priori group of providers that
have something in common such as geographical location, or the result
of an agreement specific to the requesting leaf RD). Various policies
involve real costs to providers, which may be reflected in those
policies.
5.5 Private Links
The discussion up to this point concentrates on the relationship
between NSAP addresses and routing between various routing domains
over transit routing domains, where each transit routing domain
interconnects a large number of routing domains and offers a more-or-
less public service.
However, there may also exist a large number of private point-to-point
links which interconnect two private routing domains. In many cases
such private point-to-point links may be limited to forwarding packets
directly between the two private routing domains.
For example, let's suppose that the XYZ corporation does a lot of
business with MBII. In this case, XYZ and MBII may contract with a
carrier to provide a private link between the two corporations, where
this link may only be used for packets whose source is within one of
the two corporations, and whose destination is within the other of the
two corporations. Finally, suppose that the point-to-point link is
connected between a single router (router X) within XYZ corporation
and a single router (router M) within MBII. It is therefore necessary
to configure router X to know which addresses can be reached over
this link (specifically, all addresses reachable in MBII). Similarly,
it is necessary to configure router M to know which addresses can be
reached over this link (specifically, all addresses reachable in XYZ
Corporation).
The important observation to be made here is that such private
links may be ignored for the purpose of NSAP allocation, and do not
pose a problem for routing. This is because the routing information
associated with private links is not propagated throughout the
internet, and therefore does not need to be collapsed into a
provider's prefix.
In our example, lets suppose that the XYZ corporation has a single
connection to an NSFNET regional, and has therefore received an
address allocation from the space administered by that regional.
Similarly, let's suppose that MBII, as an international corporation
with connections to six different backbones or regionals, has chosen
the second solution from Section 5.4, and therefore has obtained six
different address allocations. In this case, all addresses reachable
in the XYZ Corporation can be described by a single address prefix
(implying that router M only needs to be configured with a single
address prefix to represent the addresses reachable over this point-
to-point link). All addresses reachable in MBII can be described by
six address prefixes (implying that router X needs to be configured
with six address prefixes to represent the addresses reachable over
the point-to-point link).
In some cases, such private point-to-point links may be permitted
to forward traffic for a small number of other routing domains,
such as closely affiliated organizations. This will increase the
configuration requirements slightly. However, provided that the number
of organizations using the link is relatively small, then this still
does not represent a significant problem.
Note that the relationship between routing and NSAP addressing
described in other sections of this paper is concerned with problems
in scaling caused by large, essentially public transit routing domains
which interconnect a large number of routing domains. However, for
the purpose of NSAP allocation, private point-to-point links which
interconnect only a small number of private routing domains do not
pose a problem, and may be ignored. For example, this implies that
a single leaf routing domain which has a single connection to a
``public'' backbone (e.g., the NSFNET), plus a number of private
point-to-point links to other leaf routing domains, can be treated
as if it were single-homed to the backbone for the purpose of NSAP
address allocation.
5.6 Zero-Homed Routing Domains
Currently, a very large number of organizations have internal
communications networks which are not connected to any external
network. Such organizations may, however, have a number of private
point-to-point links that they use for communications with other
organizations. Such organizations do not participate in global
routing, but are satisfied with reachability to those organizations
with which they have established private links. These are referred to
as zero-homed routing domains.
Zero-homed routing domains can be considered as the degenerate case
of routing domains with private links, as discussed in the previous
section, and do not pose a problem for inter-domain routing. As above,
the routing information exchanged across the private links sees very
limited distribution, usually only to the RD at the other end of the
link. Thus, there are no address abstraction requirements beyond those
inherent in the address prefixes exchanged across the private link.
However, it is important that zero-homed routing domains use valid
globally unique NSAP addresses. Suppose that the zero-homed routing
domain is connected through a private link to an RD. Further, this
RD participates in an internet that subscribes to the global OSI
addressing plan (i.e., ISO 8348). This RD must be able to distinguish
between the zero-homed routing domain's NSAPs and any other NSAPs that
it may need to route to. The only way this can be guaranteed is if the
zero-homed routing domain uses globally unique NSAPs.
5.7 Address Transition Issues
Allocation of NSAP addresses based on connectivity to providers is
important to allow scaling of inter-domain routing to an internet
containing millions of routing domains. However, such address
allocation based on topology also implies that a change in topology
may result in a change of address.
This need to allow for change in addresses is a natural, inevitable
consequence of any method for routing data abstraction. The basic
notion of routing data abstraction is that there is some correspondence
between the address and where a system (i.e., a routing domain, area,
or end system) is located. Thus if the system moves, in some cases
the address will have to change. If it were possible to change the
connectivity between routing domains without changing the addresses,
then it would clearly be necessary to keep track of the location of
that routing domain on an individual basis.
Because of the rapid growth and increased commercialization of the
Internet, it is possible that the topology may be relatively volatile.
This implies that planning for address transition is very important.
Fortunately, there are a number of steps which can be taken to help
ease the effort required for address transition. A complete description
of address transition issues is outside of the scope of this paper.
However, a very brief outline of some transition issues is contained in
this section.
Also note that the possible requirement to transition addresses
based on changes in topology imply that it is valuable to anticipate
the future topology changes before finalizing a plan for address
allocation. For example, in the case of a routing domain which is
initially single-homed, but which is expecting to become multi-homed
in the future, it may be advantageous to assign NSAP addresses based
on the anticipated future topology.
In general, it will not be practical to transition the NSAP addresses
assigned to a routing domain in an instantaneous ``change the address
at midnight'' manner. Instead, a gradual transition is required in
which both the old and the new addresses will remain valid for a
limited period of time. During the transition period, both the old and
new addresses are accepted by the end systems in the routing domain,
and both old and new addresses must result in correct routing of
packets to the destination.
Provision for transition has already been built into IS-IS.
As described in Section 3, IS-IS allows multiple addresses to
be assigned to each area specifically for the purpose of easing
transition.
Similarly, there are provisions in OSI for the autoconfiguration of
area addresses. This allows OSI end systems to find out their area
addresses automatically, either by passively observing the ES-IS
IS-Hello packets transmitted by routers, or by actively querying the
routers for their NSAP address. If the ID portion of the address is
assigned in a manner which allows for globally unique IDs [18], then
an end system can reconfigure its entire NSAP address automatically
without the need for manual intervention. However, routers will still
require manual address reconfiguration.
During the transition period, it is important that packets using
the old address be forwarded correctly, even when the topology has
changed. This is facilitated by the use of ``best match'' inter-domain
routing.
For example, suppose that the XYZ Corporation was previously connected
only to the NorthSouthNet NSFNET regional. The XYZ Corporation
therefore went off to the NorthSouthNet administration and got a
routing domain assignment based on the AA value assigned to the
NorthSouthNet regional under the GOSIP address space. However, for
a variety of reasons, the XYZ Corporation decided to terminate its
association with the NorthSouthNet, and instead connect directly to
the NewCommercialNet public data network. Thus the XYZ Corporation
now has a new address assignment under the ANSI address assigned to
the NewCommercialNet. The old address for the XYZ Corporation would
seem to imply that traffic for the XYZ Corporation should be routed to
the NorthSouthNet, which no longer has any direct connection with XYZ
Corporation.
If the old provider (NorthSouthNet) and the new provider
(NewCommercialNet) are adjacent and cooperative, then this transition
is easy to accomplish. In this case, packets routed to the XYZ
Corporation using the old address assignment could be routed to the
NorthSouthNet, which would directly forward them to the
NewCommercialNet, which would in turn forward them to XYZ Corporation.
In this case only NorthSouthNet and NewCommercialNet need be aware of
the fact that the old address refers to a destination which is no
longer directly attached to NorthSouthNet.
If the old provider and the new provider are not adjacent, then the
situation is a bit more complex, but there are still several possible
ways to forward traffic correctly.
If the old provider and the new provider are themselves connected by
other cooperative transit routing domains, then these intermediate
domains may agree to forward traffic for XYZ correctly. For example,
suppose that NorthSouthNet and NewCommercialNet are not directly
connected, but that they are both directly connected to the NSFNET
backbone. In this case, all three of NorthSouthNet, NewCommercialNet,
and the NSFNET backbone would need to maintain a special entry for XYZ
corporation so that traffic to XYZ using the old address allocation
would be forwarded via NewCommercialNet. However, other routing
domains would not need to be aware of the new location for XYZ
Corporation.
Suppose that the old provider and the new provider are separated by a
non-cooperative routing domain, or by a long path of routing domains.
In this case, the old provider could encapsulate traffic to XYZ
Corporation in order to deliver such packets to the correct backbone.
Also, those locations which do a significant amount of business with
XYZ Corporation could have a specific entry in their routing tables
added to ensure optimal routing of packets to XYZ. For example,
suppose that another commercial backbone ``OldCommercialNet'' has a
large number of customers which exchange traffic with XYZ Corporation,
and that this third provider is directly connected to both
NorthSouthNet and NewCommercialNet. In this case OldCommercialNet will
continue to have a single entry in its routing tables for other traffic
destined for NorthSouthNet, but may choose to add one additional (more
specific) entry to ensure that packets sent to XYZ Corporation's old
address are routed correctly.
Whichever method is used to ease address transition, the goal is that
knowledge relating XYZ to its old address that is held throughout the
global internet would eventually be replaced with the new information.
It is reasonable to expect this to take weeks or months and will be
accomplished through the distributed directory system. Discussion of
the directory, along with other address transition techniques such as
automatically informing the source of a changed address, are outside
the scope of this paper.
6 Recommendations
We anticipate that the current exponential growth of the Internet will
continue or accelerate for the foreseeable future. In addition, we
anticipate a continuation of the rapid internationalization of the
Internet. The ability of routing to scale is dependent upon the use
of data abstraction based on hierarchical NSAP addresses. As CLNP use
increases in the Internet, it is therefore essential to assign
NSAP addresses with great care.
It is in the best interests of the internetworking community that the
cost of operations be kept to a minimum where possible. In the case of
NSAP allocation, this again means that routing data abstraction must
be encouraged.
In order for data abstraction to be possible, the assignment of NSAP
addresses must be accomplished in a manner which is consistent with
the actual physical topology of the Internet. For example, in those
cases where organizational and administrative boundaries are not
related to actual network topology, address assignment based on such
organization boundaries is not recommended.
The intra-domain IS-IS routing protocol allows for information
abstraction to be maintained at two levels: systems are grouped
into areas, and areas are interconnected to form a routing domain.
The inter-domain IDRP routing protocol allows for information
abstraction to be maintained at multiple levels by grouping
routing domains into Routing Domain Confederations and using route
aggregation capabilities.
For zero-homed and single-homed routing domains (which are expected
to remain zero-homed or single-homed), we recommend that the NSAP
addresses assigned for OSI use within a single routing domain use
a single address prefix assigned to that domain. Specifically, this
allows the set of all NSAP addresses reachable within a single domain
to be fully described via a single prefix. We recommend that single-
homed routing domains use an address prefix based on its connectivity
to a public service provider. We recommend that zero-homed routing
domains use globally unique addresses.
We anticipate that the total number of routing domains existing on a
worldwide OSI Internet to be great enough that additional levels of
hierarchical data abstraction beyond the routing domain level will be
necessary. To provide the needed data abstraction we recommend to use
Routing Domain Confederations and route aggregation capabilities
of IDRP.
The general technical requirements for NSAP address guidelines
do not vary from country to country. However, details of address
administration may vary between countries. Also, in most cases,
network topology will have a close relationship with national
boundaries. For example, the degree of network connectivity will
often be greater within a single country than between countries.
It is therefore appropriate to make specific recommendations based on
national boundaries, with the understanding that there may be specific
situations where these general recommendations need to be modified.
Moreover, that suggests that national boundaries may be used to group
domains into Routing Domain Confederations.
Each of the country-specific or continent-specific recommendations
presented below are consistent with the technical requirements for
scaling of addressing and routing presented in this RFC.
6.1 Recommendations Specific to U.S. Parts of the Internet
NSAP addresses for use within the U.S. portion of the Internet are
expected to be based primarily on two address prefixes: the ICD=0005
format used by The U.S. Government, and the DCC=840 format defined
by ANSI.
We anticipate that, in the U.S., public interconnectivity between
private routing domains will be provided by a diverse set of providers,
including (but not necessarily limited to) regional networks and
commercial Public Data Networks.
These networks are not expected to be interconnected in a strictly
hierarchical manner. For example, the NSFNET regionals may be
directly connected, and all three of these types of networks may
have direct international connections.
However, the total number of such providers is expected to remain (for
the foreseeable future) small enough to allow addressing of this set
of providers via a flat address space. These providers will be used
to interconnect a wide variety of routing domains, each of which may
comprise a single corporation, part of a corporation, a university
campus, a government agency, or other organizational unit.
In addition, some private corporations may be expected to make use
of dedicated private providers for communication within their own
corporations.
We anticipate that the great majority of routing domains will be
attached to only one of the providers. This will permit hierarchical
address abbreviation based on provider. We therefore strongly recommend
that addresses be assigned hierarchically, based on address prefixes
assigned to individual providers.
For the GOSIP address format, this implies that Administrative
Authority (AA) identifiers should be assigned to all providers
(explicitly including the NSFNET backbone, the NSFNET regionals, and
other major government backbones). For those leaf routing domains
which are connected to a single provider, they should be assigned a
Routing Domain (RD) value from the space assigned to that provider.
To provide routing information aggregation/abstraction we recommend
that each provider together with all of its leaf domains form a
Routing Domain Confederation. That, combined with hierarchical address
assignment, would provide significant reduction in the volume of
routing information that needs to be handled by IS01747. Note that
presence of multihomed leaf domains would imply that such
Confederations will overlap, which is explicitly supported by IDRP.
We recommend that all providers explicitly be involved in the task
of address administration for those leaf routing domains which are
single-homed to them. This will offer a valuable service to their
customers, and will also greatly reduce the resources (including
human and network resources) necessary for that provider to take
part in inter-domain routing.
Each provider should develop policy on whether and under what
conditions to accept customers using addresses that are not based on
the provider's own address prefix, and how such non-local addresses
will be treated. Policies should reflect the issue of cost associated
with implementing such policies.
We recommend that a similar hierarchical model be used for NSAP
addresses using the DCC-based address format. The structure for
DCC=840-based NSAPs is provided in Section A.2.
For routing domains which are not attached to any publically-
available provider, no urgent need for hierarchical address
abbreviation exists. We do not, therefore, make any additional
recommendations for such ``isolated'' routing domains, except to
note that there is no technical reason to preclude assignment of
GOSIP AA identifier values or ANSI organization identifiers to such
domains. Where such domains are connected to other domains by private
point-to-point links, and where such links are used solely for routing
between the two domains that they interconnect, no additional
technical problems relating to address abbreviation is caused by such
a link, and no specific additional recommendations are necessary.
6.2 Recommendations Specific to European Parts of the Internet
This section contains additional RARE recommendations for allocating
NSAP addresses within each national domain, administered by a National
Standardization Organization (NSO) and national research network
organizations.
NSAP addresses are expected to be based on the ISO DCC scheme.
Organizations which are not associated with a particular country and
which have reasons not to use a national prefix based on ISO DCC
should follow the recommendations covered in chapters 6.3 and 6.4.
ISO DCC addresses are not associated with any specific subnetwork
type and service provider and are thus independent of the type or
ownership of the underlying technology.
6.2.1 General NSAP structure
The general structure of a Network Address defined in ISO 8348
is further divided into:
+-----------+-----------------------------------------+
| IDP | DSP |
+-----+-----+-----------+-----------------------------+
| AFI | IDI | CDP | CDSP |
+-----+-----+-----+-----+----------------+------+-----+
| AFI | IDI | CFI | CDI | RDAA | ID | SEL |
+-----+-----+-----+-----+----------------+------+-----+
octets | 1 | 2 | 2..4 | 0..13 | 1..8 | 1 |
+-----+-----+-----------+----------------+------+-----+
IDP Initial Domain Part
AFI Authority and Format Identifier, two-decimal-digit,
38 for decimal abstract syntax of the DSP or
39 for binary abstract syntax of the DSP
IDI Initial Domain Identifier, a three-decimal-digit
country code, as defined in ISO 3166
DSP Domain Specific Part
CDP Country Domain Part, 2..4 octets
CFI Country Format Identifier, one digit
CDI Country Domain Identifier, 3 to 7 digits, fills
CDP to an octet boundary
CDSP Country Domain Specific Part
RDAA Routing Domain and Area Address
ID System Identifier (1..8 octet)
SEL NSAP Selector
The total length of an NSAP can vary from 7 to 20 octets.
6.2.2 Structure of the Country Domain Part
The CDP identifies an organization within a country and the CDSP
is then available to that organization for further internal
structuring as it wishes. Non-ambiguity of addresses is ensured
by there being the NSO a single national body that allocates the
CDPs.
The CDP is further divided into CFI and CDI, where the CFI identifies
the format of the CDI. The importance of this is that it enables
several types of CDI to be assigned in parallel, corresponding to
organizations with different requirements and giving different
amounts of the total address space to them, and that it conveniently
enables a substantial amount of address space to be reserved for
future allocation.
The possible structures of the CDP are as follows:
CFI = /0 reserved
CFI = /1 CDI = /aaa very large organizations or
trade associations
CFI = /2 CDI = /aaaaa organizations of intermediate size
CFI = /3 CDI = /aaaaaaa small organizations and single users
CFI = /4../F reserved
Note: this uses the hexadecimal reference publication format
defined in ISO 8348 of a solidus "/" followed by a string of
hexadecimal digits. Each "a" represents a hexadecimal digit.
Organizations are classified into large, medium and small for the
purpose of address allocation, and one CFI is made available for each
category of organization.
This recommendation for CDP leaves space for the U.S. GOSIP Version 2
NSAP model (Appendix A.1) by the reserved CFI /8, nevertheless it is
not recommended for use in the European Internet.
6.2.3 Structure of the Country Domain Specific Part
The CDSP must have a structure (within the decimal digit or binary
octet syntax selected by the AFI value 38 or 39) satisfying both the
routing requirements (IS-IS) and the logical requirements of the
organization identified (CFI + CDI).
6.3 Recommendations Specific to Other Parts of the Internet
For the part of the Internet which is outside of the U.S. and Europe,
it is recommended that the DSP format be structured hierarchically
similarly to that specified within the U.S. and Europe no matter
whether the addresses are based on DCC or ICD format.
Further, in order to allow aggregation of NSAPs at national boundaries
into as few prefixes as possible, we further recommend that NSAPs
allocated to routing domains should be assigned based on each routing
domain's connectivity to a national Internet backbone.
6.4 Recommendations for Multi-Homed Routing Domains
Some routing domains will be attached to multiple providers within
the same country, or to providers within multiple countries. We refer
to these as ``multi-homed'' routing domains. Clearly the strict
hierarchical model discussed above does not neatly handle such routing
domains.
There are several possible ways that these multi-homed routing domains
may be handled. Each of these methods vary with respect to the amount
of information that must be maintained for inter-domain routing
and also with respect to the inter-domain routes. In addition, the
organization that will bear the brunt of this cost varies with the
possible solutions. For example, the solutions vary with respect to:
* resources used within routers within the providers;
* administrative cost on provider personnel; and,
* difficulty of configuration of policy-based inter-domain routing
information within leaf routing domains.
Also, the solution used may affect the actual routes which packets
follow, and may effect the availability of backup routes when the
primary route fails.
For these reasons it is not possible to mandate a single solution for
all situations. Rather, economic considerations will require a variety
of solutions for different routing domains, regionals, and backbones.
6.5 Recommendations for RDI and RDCI assignment
While RDIs and RDCIs need not be related to the set of
addresses within the domains (confederations) they depict,
for the sake of simplicity we recommend that RDIs and RDCIs
be assigned based on the NSAP prefixes assigned to domains and
confederations.
A leaf RD should use the NSAP prefix assigned to it as
its RDI. A multihomed RD should use one of the NSAP prefixes
assigned to it as its RDI. If a service provider forms
a Routing Domain Confederation with some of its subscribers
and the subscribers take their addresses out of the provider,
then the NSAP prefix assigned to the provider should be used as
the RDCI of the confederation. In this case the provider may
use a longer NSAP prefix for its own RDIs. In all other
cases a provider should use the address prefix that it
uses for assigning addresses to systems within the provider
as its RDI.
7 Security Considerations
Security issues are not discussed in this memo (except for the
discussion of IS-IS authentication in section 3.2).
8 Authors' Addresses
Richard P. Colella
National Institute of Standards & Technology
Building 225/Room B217
Gaithersburg, MD 20899
Phone: (301) 975-3627
EMail: colella@nist.gov
Ross Callon
c/o Wellfleet Communications, Inc
2 Federal Street
Billerica, MA 01821
Phone: (508) 436-3936
Email: callon@wellfleet.com
Ella P. Gardner
The MITRE Corporation
7525 Colshire Drive
McLean, VA 22102-3481
Phone: (703) 883-5826
EMail: epg@gateway.mitre.org
Yakov Rekhter
T.J. Watson Research Center, IBM Corporation
P.O. Box 218
Yorktown Heights, NY 10598
Phone: (914) 945-3896
EMail: yakov@watson.ibm.com
9 Acknowledgments
The authors would like to thank the members of the IETF OSI-NSAP
Working Group and of RARE WG4 for the helpful suggestions made during
the writing of this paper. We would also like to thank Radia Perlman
of Novell, and Marcel Wiget of SWITCH for their ideas and help.
RFCxxxx Guidelines for OSI NSAP Allocation in the Internet Oct 1993
A Administration of NSAPs
NSAPs represent the endpoints of communication through the Network
Layer and must be globally unique [4]. ISO 8348 defines the semantics
of the NSAP and the abstract syntaxes in which the semantics of the
Network address can be expressed [11].
The NSAP consists of the initial domain part (IDP) and the domain
specific part (DSP). The initial domain part of the NSAP consists
of an authority and format identifier (AFI) and an initial domain
identifier (IDI). The AFI specifies the format of the IDI, the network
addressing authority responsible for allocating values of the IDI,
and the abstract syntax of the DSP. The IDI specifies the addressing
subdomain from which values of the DSP are allocated and the network
addressing authority responsible for allocating values of the DSP from
that domain. The structure and semantics of the DSP are determined by
the authority identified by the IDI. Figure 3 shows the NSAP address
structure.
_______________
!_____IDP_____!________________________________
!__AFI_!_IDI__!______________DSP______________!
IDP Initial Domain Part
AFI Authority and Format Identifier
IDI Initial Domain Identifier
DSP Domain Specific Part
Figure 3: NSAP address structure.
The global network addressing domain consists of all the NSAP
addresses in the OSI environment. Within that environment, seven
second-level addressing domains and corresponding IDI formats are
described in ISO 8348:
* X.121 for public data networks
* F.69 for telex
* E.163 for the public switched telephone network numbers
* E.164 for ISDN numbers
* ISO Data Country Code (DCC), allocated according to ISO 3166 [6]
* ISO International Code Designator (ICD), allocated according to
ISO 6523 [7]
* Local to accommodate the coexistence of OSI and non-OSI network
addressing schemes.
For OSI networks in the U.S., portions of the ICD subdomain are
available for use through the U.S. Government, and the DCC subdo-
main is available for use through The American National Standards
Institute (ANSI). The British Standards Institute is the registration
authority for the ICD subdomain, and has registered four IDIs for
the U.S. Government: those used for GOSIP, DoD, OSINET, and the OSI
Implementors Workshop. ANSI, as the U.S. ISO Member Body, is the
registration authority for the DCC domain in the United States.
A.1 GOSIP Version 2 NSAPs
GOSIP Version 2 makes available for government use an NSAP addressing
subdomain with a corresponding address format as illustrated in
Figure 2 on page 16. The ``47'' signifies that it is based on the ICD
format and uses a binary syntax for the DSP. The 0005 is an IDI value
which has been assigned to the U.S. Government. Although GOSIP Version
2 NSAPs are intended primarily for U.S. Government use, requests from
non-government and non-U.S. organizations will be considered on a
case-by-case basis.
The format for the DSP under ICD=0005 has been established by the
National Institute of Standards and Technology (NIST), the authority
for the ICD=0005 domain, in GOSIP Version 2 [3] (see Figure 2,
page 16). NIST has delegated the authority to register AA identifiers
for GOSIP Version 2 NSAPs to the General Services Administration
(GSA).
ISO 8348 allows a maximum length of 20 octets for the NSAP address.
The AFI of 47 occupies one octet, and the IDI of 0005 occupies
two octets. The DSP is encoded as binary as indicated by the AFI of
47. One octet is allocated for a DSP Format Identifier, three octets
for an Administrative Authority identifier, two octets for Routing
Domain, two octets for Area, six octets for the System Identifier,
and one octet for the NSAP selector. Note that two octets have been
reserved to accommodate future growth and to provide additional
flexibility for inter-domain routing. The last seven octets of the
GOSIP NSAP format are structured in accordance with IS-IS [14], the
intra-domain IS-IS routing protocol. The DSP Format Identifier (DFI)
identifies the format of the remaining DSP structure and may be used
in the future to identify additional DSP formats; the value 80h in the
DFI identifies the GOSIP Version 2 NSAP structure.
The Administrative Authority identifier names the administrative
authority which is responsible for registration within its domain.
The administrative authority may delegate the responsibility for
registering areas to the routing domains, and the routing domains
may delegate the authority to register System Identifiers to the
areas. The main responsibility of a registration authority at any
level of the addressing hierarchy is to assure that names of entities
are unambiguous, i.e., no two entities have the same name. The
registration authority is also responsible for advertising the names.
A routing domain is a set of end systems and intermediate systems
which operate according to the same routing procedures and is wholly
contained within a single administrative domain. An area uniquely
identifies a subdomain of the routing domain. The system identifier
names a unique system within an area. The value of the system
field may be a physical address (SNPA) or a logical value. Address
resolution between the NSAP and the SNPA may be accomplished by an ES-
IS protocol [10], locally administered tables, or mapping functions.
The NSAP selector field identifies the end user of the network layer
service, i.e., a transport layer entity.
A.1.1 Application for Administrative Authority Identifiers
The steps required for an agency to acquire an NSAP Administrative
Authority identifier under ICD=0005 from GSA will be provided in the
updated GOSIP users' guide for Version 2 [2] and are given below.
Requests from non-government and non-U.S. organizations should
originate from a senior official, such as a vice-president or chief
operating officer.
* Identify all end systems, intermediate systems, subnetworks, and
their topological and administrative relationships.
* Designate one individual (usually the agency head) within an
agency to authorize all registration requests from that agency
(NOTE: All agency requests must pass through this individual).
* Send a letter on agency letterhead and signed by the agency head
to GSA:
Telecommunications Customer Requirements Office
U. S. General Services Administration
Information Resource Management Service
Office of Telecommunications Services
18th and F Streets, N.W.
Washington, DC 20405
Fax +1 202 208-5555
The letter should contain the following information:
- Requestor's Name and Title,
- Organization,
- Postal Address,
- Telephone and Fax Numbers,
- Electronic Mail Address(es), and,
- Reason Needed (one or two paragraphs explaining the intended
use).
* If accepted, GSA will send a return letter to the agency head
indicating the NSAP Administrative Authority identifier as-
signed,effective date of registration, and any other pertinent
information.
* If rejected, GSA will send a letter to the agency head explaining
the reason for rejection.
* Each Authority will administer its own subaddress space in
accordance with the procedures set forth by the GSA in Section
A.1.2.
* The GSA will maintain, publicize, and disseminate the assigned
values of Administrative Authority identifiers unless specifically
requested by an agency not to do so.
A.1.2 Guidelines for NSAP Assignment
Recommendations which should be followed by an administrative
authority in making NSAP assignments are given below.
* The authority should determine the degree of structure of the
DSP under its control. Further delegation of address assignment
authority (resulting in additional levels of hierarchy in the
NSAP) may be desired.
* The authority should make sure that portions of NSAPs that it
specifies are unique, current, and accurate.
* The authority should ensure that procedures exist for dissemi-
nating NSAPs to routing domains and to areas within each routing
domain.
* The systems administrator must determine whether a logical or a
physical address should be used in the System Identifier field
(Figure2, page 16). An example of a physical address is a 48-bit
MAC address; a logical address is merely a number that meets the
uniqueness requirements for the System Identifier field, but
bears no relationship to an address on a physical subnetwork.
We recommend that IDs should be assigned to be globally unique,
as made possible by the method described in [18].
* The network address itself contains information that may be
used to aid routing, but does not contain a source route [12].
Information that enables next-hop determination based on NSAPs
is gathered and maintained by each intermediate system through
routing protocol exchanges.
* GOSIP end systems and intermediate systems in federal agencies
must be capable of routing information correctly to and from any
subdomain defined by ISO 8348.
* An agency may request the assignment of more than one Administra-
tive Authority identifier. The particular use of each should be
specified.
A.2 Data Country Code NSAPs
NSAPs from the Data Country Code (DCC) subdomain will also be common
in the international Internet. ANS X3.216-1992 specifies the DSP
structure under DCC=840 [1]. In the ANS, the DSP structure is
identical to that specified in GOSIP Version 2, with the
Administrative Authority identifier replaced by the numeric form
of the ANSI-registered organization name, as shown in Figure 4.
Referring to Figure 4, when the value of the AFI is 39, the IDI
denotes an ISO DCC and the abstract syntax of the DSP is binary
octets. The value of the IDI for the U.S. is 840, the three-digit
numeric code for the United States under ISO 3166 [6]. The numeric
form of organization name is analogous to the Administrative Authority
identifier in the GOSIP Version 2 NSAP.
______________
!<--_IDP_-- >_!_____________________________________
!AFI_!__IDI__!____________<--_DSP_-->_____________!
!_39_!__840__!DFI_!_ORG_!Rsvd_!RD_!Area_!_ID_!Sel_!
octets !_1__!___2___!_1__!__3__!_2___!_2_!__2__!_6__!_1__!
IDP Initial Domain Part
AFI Authority and Format Identifier
IDI Initial Domain Identifier
DSP Domain Specific Part
DFI DSP Format Identifier
ORG Organization Name (numeric form)
Rsvd Reserved
RD Routing Domain Identifier
Area Area Identifier
ID System Identifier
SEL NSAP Selector
Figure 4: NSAP format for DCC=840 as proposed in ANSI X3S3.3.
A.2.1 Application for Numeric Organization Name
The procedures for registration of numeric organization names in
the U.S. have been defined and are operational. To register a
numeric organization name, the applicant must submit a request for
registration and the $1,000 (U.S.) fee to the registration authority,
the American National Standards Institute (ANSI). ANSI will register a
numeric value, along with the information supplied for registration,
in the registration database. The registration information will be
sent to the applicant within ten working days. The values for numeric
organization names are assigned beginning at 113527.
The application form for registering a numeric organization name may
be obtained from the ANSI Registration Coordinator at the following
address:
Registration Coordinator
American National Standards Institute
11 West 42nd Street
New York, NY 10036
+1 212 642 4976 (tel)
+1 212 398 0023 (fax)
RFC822: mtopping@attmail.com
X.400: G=marisa; S=topping; A=attmail; C=us
Once an organization has registered with ANSI, it becomes a registra-
tion authority itself. In turn, it may delegate registration authority
to routing domains, and these may make further delegations, for in-
stance, from routing domains to areas. Again, the responsibilities of
each Registration Authority are to assure that NSAPs within the domain
are unambiguous and to advertise them as applicable.
A.3 Summary of Administrative Requirements
NSAPs must be globally unique, and an organization may assure this
uniqueness for OSI addresses in two ways. The organization may
apply to GSA for an Administrative Authority identifier. Although
registration of Administrative Authority identifiers by GSA primarily
serves U.S. Government agencies, requests for non-government and
non-U.S. organizations will be considered on a case-by-case basis.
Alternatively, the organization may apply to ANSI for a numeric
organization name. In either case, the organization becomes the
registration authority for its domain and can register NSAPs or
delegate the authority to do so.
In the case of GOSIP Version 2 NSAPs, the complete DSP structure is
given in GOSIP Version 2. For ANSI DCC-based NSAPs, the DSP structure
is specified in ANS X3.216-1992. The DSP structure is identical to
that specified in GOSIP Version 2.
References
[1] ANSI. American National Standard for the Structure and
Semantics of the Domain-Specific Part (DSP) of the OSI Network
Service Access Point (NSAP) Address. American National Standard
X3.216-1992.
[2] Tim Boland. Government Open Systems Interconnection Profile
Users' Guide Version 2 [DRAFT]. NIST Special Publication,
National Institute of Standards and Technology, Computer Systems
Laboratory, Gaithersburg, MD, June 1991.
[3] GOSIP Advanced Requirements Group. Government Open Systems
Interconnection Profile (GOSIP) Version 2. Federal Information
Processing Standard 146-1, U.S. Department of Commerce, National
Institute of Standards and Technology, Gaithersburg, MD, April
1991.
[4] Christine Hemrick. The OSI Network Layer Addressing Scheme, Its
Implications, and Considerations for Implementation. NTIA Report
85-186, U.S. Department of Commerce, National Telecommunications
and Information Administration, 1985.
[5] ISO. Addendum to the Network Service Definition Covering Network
Layer Addressing. RFC 941, Network Working Group, April 1985.
[6] ISO/IEC. Codes for the Representation of Names of Countries.
International Standard 3166, ISO/IEC JTC 1, Switzerland, 1984.
[7] ISO/IEC. Data Interchange - Structures for the Identification
of Organization. International Standard 6523, ISO/IEC JTC 1,
Switzerland, 1984.
[8] ISO/IEC. Information Processing Systems - Open Systems
Interconnection -- Basic Reference Model. International
Standard 7498, ISO/IEC JTC 1, Switzerland, 1984.
[9] ISO/IEC. Protocol for Providing the Connectionless-mode
Network Service. International Standard 8473, ISO/IEC JTC 1,
Switzerland, 1986.
[10] ISO/IEC. End System to Intermediate System Routing Exchange
Protocol for use in Conjunction with the Protocol for the
Provision of the Connectionless-mode Network Service.
International Standard 9542, ISO/IEC JTC 1, Switzerland, 1987.
[11] ISO/IEC. Information Processing Systems -- Data Communications
-- Network Service Definition. International Standard 8348, 1992.
[12] ISO/IEC. Information Processing Systems - OSI Reference Model
- Part3: Naming and Addressing. Draft International Standard
7498-3, ISO/IEC JTC 1, Switzerland, March 1989.
[13] ISO/IEC. Information Technology - Telecommunications and
Information Exchange Between Systems - OSI Routeing Framework.
Technical Report 9575, ISO/IEC JTC 1, Switzerland, 1989.
[14] ISO/IEC. Intermediate System to Intermediate System Intra-Domain
Routeing Exchange Protocol for use in Conjunction with the
Protocol for Providing the Connectionless-Mode Network
Service (ISO 8473). International Standard ISO/IEC 10589, 1992.
[15] K. Loughheed and Y. Rekhter. A Border Gateway Protocol 3
(BGP-3). RFC 1267, Network Working Group, 1991.
[16] ISO/IEC. Protocol for Exchange of Inter-Domain Routeing
Information among Intermediate Systems to support Forwarding
of ISO 8473 PDUs, International Standard 10747, ISO/IEC JTC 1,
Switzerland 1993.
[17] R. Callon, TCP and UDP with Bigger Addresses (TUBA), A Simple
Proposal for Internet Addressing and Routing. RFC 1347, June
1992.
[18] D. Piscitello, Assignment of System Identifiers for TUBA/CLNP
Hosts. RFC 1526, Sept 1993.
[19] V. Fuller, T. Li, J. Yu, K. Varadhan, "Classless Inter-Domain
Routing (CIDR): an Address Assignment and Aggregation Strategy",
RFC 1519, September 1993.
[20] ISO/IEC JTC1/SC6. Addendum to ISO 9542 Covering Address
Administration. N6273, March 1991.
