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RFC1768 - Host Group Extensions for CLNP Multicasting

王朝other·作者佚名  2008-05-31
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Network Working Group D. Marlow

Request for Comments: 1768 NSWC-DD

Category: EXPerimental March 1995

Host Group Extensions for CLNP Multicasting

Status of this Memo

This memo defines an Experimental Protocol for the Internet

community. This memo does not specify an Internet standard of any

kind. Discussion and suggestions for improvement are requested.

Distribution of this memo is unlimited.

Abstract

This memo documents work performed in the TUBA (TCP/UDP over Bigger

Addresses) working group of IPng area prior to the July 1994 decision

to utilize SIPP-16 as the basis for IPng. The TUBA group worked on

extending the Internet Protocol suite by the use of ISO 8473 (CLNP)

and its related routing protocols. This memo describes multicast

extensions to CLNP and its related routing protocols for Internet

multicast use. Publication of this memo does not imply acceptance by

any IETF Working Group for the ideas expressed within.

This memo provides a specification for multicast extensions to the

CLNP protocol similar to those provided to IP by RFC1112. These

extensions are intended to provide the mechanisms needed by a host

for multicasting in a CLNP based Internet. This memo covers

addressing extensions to the CLNP addressing strUCture, extensions to

the CLNP protocol and extensions to the ES-IS protocol. An appendix

discusses the differences between IP multicast and the CLNP multicast

approach provided in this memo.

Acknowledgments

The specification provided here was developed by a number of

individuals in the IETF TUBA working group as well as the ANSI X3S3.3

and ISO SC6 WG2 committees. Key contributions were made by Steve

Deering, Joel Halpern, Dave Katz and Dave Oran.

Table of Contents

1. Introduction .......................................... 2

2. Levels of Conformance.................................. 3

3. Group Network Addresses................................ 4

4. Model of a CLNP End System Multicast Implementation.... 8

5. Extensions to the CLNP Protocol........................ 8

6. Extensions to the ES-IS Routeing Protocol ............. 15

7. Security Considerations ............................... 39

Appendix A. Differences with RFC1112 .................... 40

Appendix B. Issues Under Study ........................... 43

References ................................................ 44

Author's Address .......................................... 45

1. Introduction

This memo provides a specification for multicast extensions for CLNP

in order to provide a CLNP based Internet the capabilities provided

for IP by RFC1112 (Host Extensions for IP Multicasting) [RFC1112].

This memo uses an outline similar to that of RFC1112.

Paraphrasing RFC1112, "CLNP multicasting is the transmission of a

CLNP datagram to a "host group", a set of zero or more End Systems

identified by a single group Network address (GNA). A multicast

datagram is delivered to all members of its destination host group

with the same "best-efforts" reliability as regular unicast CLNP

datagrams, i.e., the datagram is not guaranteed to arrive intact at

all members of the destination group or in the same order relative to

other datagrams.

"The membership of a host group is dynamic; that is End Systems may

join and leave groups at any time. There is no restrictions on the

location or number of members in a host group. An End System may be a

member of more than one group at a time. An End System need not be a

member of a group to send datagrams to it.

"A host group may be permanent or transient. A permanent group has an

administratively assigned GNA. It is the address, not the membership

of the group, that is permanent; at any time a permanent group may

have any number of members, even zero.

"Internetwork forwarding of CLNP multicast datagrams is handled by

"multicast capable" Intermediate Systems which may be co-resident

with unicast capable Intermediate Systems.

The multicast extensions to the CLNP addressing structure defines

group Network addresses which identify host groups. The multicast

extensions to CLNP provides a means for identifying a CLNP packet and

provides scope control mechanisms for CLNP multicast packets. The

multicast extensions to the ES-IS protocol provide the mechanisms

needed for a host to exchange control information with multicast

capable routers. These extensions to the ES-IS protocol provide for

a host to "announce" which multicast packets are of interest and for

a multicast capable router to dynamically "map" group Network

addresses to subnetwork addresses.

This memo specifies the extensions required by an End System to make

use of CLNP multicast. In addition the requirements placed upon

multicast capable Intermediate Systems to exchange information with

multicast capable End Systems is specified. No specifications are

provided related to the information exchanges between Intermediate

Systems to support multicast route selection or multicast Protocol

Data Unit (PDU) forwarding. A discussion of multicast route selection

and PDU forwarding has been written by Steve Deering [Deering91].

Note that for these multicast extensions to work there must exist an

uninterrupted path of multicast capable routers between the End

Systems comprising a host group (such paths may utilize tunneling

(i.e., unicast CLNP encapsulated paths between multicast capable CLNP

routers)). In order to support multicast route selection and

forwarding for a CLNP based internet additional specifications are

needed. Specifications of this type could come in the form of new

protocols, extensions to the current CLNP based routing protocols or

use of a technique out of the IETF's Inter-Domain Multicast Routing

(IDMR) group. The IDMR group is currently investigating multicast

protocols for routers which utilize a router's unicast routing

protocols, this approach may extend directly to CLNP routers.

While many of the techniques and assumptions of IP multicasting (as

discussed in RFC1112) are used in CLNP multicasting, there are

number of differences. Appendix A describes the differences between

CLNP multicasting and IP multicasting. This memo describes techniques

brought in directly from projects within ISO to incorporate multicast

transmission capabilities into CLNP [MULT-AMDS].

2. Levels of Conformance

There are three levels of conformance for End Systems to this

specification:

Level 0: no support for CLNP multicasting.

There is no requirement for a CLNP End System (or Intermediate

System) to support CLNP multicasting. Level 0 hosts should be

unaffected by the presence of multicast activity. The destination

addresses used in support of multicast transfers, the GNA, should not

be enabled by a non-multicast capable End System and the PDUs

themselves are marked differently than unicast PDUs and thus should

be quietly discarded.

Level 1: support for sending but not receiving CLNP multicast PDUs.

An End System originating multicast PDUs is required to know whether

a multicast capable Intermediate System is attached to the

subnetwork(s) that it originates multicast PDUs (i.e., to determine

the destination SNPA (subnet) address). An End System with Level 1

conformance is required to implement all parts of this specification

except for those supporting only Multicast Announcement. An End

System is not required to know the current Multicast Address Mapping

to start originating multicast PDUs.

Note: It is possible for End System not implementing Multicast

Address Mapping to successfully originate multicast PDUs (but with

the End System knowing of the existence of a multicast capable

Intermediate System). Such operation may lead to inefficient

subnetworks use. Thus when an End System continues (or may continue)

to originate multicast PDUs destined for the same group,

implementations are to provide Multicast Address Mapping support.

Level 2: full support for CLNP multicasting.

Level 2 allows a host to join and leave host groups as well as send

CLNP PDUs to host groups. It requires implementation by the End

System of all parts of this specification.

3. Group Network Addresses

Individual Network addresses used by CLNP for End System addressing

are called Network Service Access Points (NSAPs). RFC1237 defines

the NSAP address for use in the Internet. In order to provide an

address for a group of End Systems, this specification does not

change the definition of the NSAP address, but adds a new type of

identifier - the group Network address - that supports a multicast

Network service (i.e., between a single source NSAP, identified by an

individual Network address, and a group of destination NSAPs,

identified by a group Network address). Host groups are identified by

group Network addresses.

In the development of multicast address extensions to CLNP,

requirements were identified for: (1)"easily distinguishing" group

addresses at the Network layer from NSAP addresses; (2)leaving the

currently allocated address families unaffected and (3)ensuring that

the approach taken would not require the establishment of new

addressing authorities. In addition, it was agreed that providing

multicast options for all OSI Network layer users was desirable and

thus the group Network addressing solution should support options for

all address formats covered by ISO/IEC 8348 CCITT Recommendation

X.213. The only viable means identified for meeting all requirements

was via creating a new set of AFI values with a fixed one-to-one

mapping between each of the existing AFI values and a corresponding

group AFI value.

Group Network addresses are defined by creating a new set of AFI

values, one for each existing AFI value, and a fixed one-to-one

mapping between each of the existing AFI values and a corresponding

group AFI value. The syntax of a group Network address is identical

to the syntax of an individual Network address, except that the value

of the AFI in an individual Network address may be only one of the

values already allocated for individual Network addresses, whereas

the value of the AFI in a group Network address may be only one of

the values allocated here for group Network addresses. The AFI values

allocated for group Network addresses have been chosen in such a way

that they do not overlap, in the preferred encoding defined by

ISO/IEC 8348 CCITT Recommendation X.213, with any of the AFI values

that have already been allocated for individual Network addresses.

3.1 Definitions

group Network address: an address that identifies a set of zero or

more Network service access points; these may belong to multiple

Network entities, in different End Systems.

individual Network address: an address that identifies a single NSAP.

3.2 CLNP Addresses

A discussion of the CLNP address format is contained in RFC1237. The

structure of all CLNP addresses is divided into two parts the Initial

Domain Part (IDP) and the Domain Specific Part (DSP). The first two

octets of the IDP are the Authority and Format Identifier (AFI)

field. The AFI has an abstract syntax of two hexadecimal digits with

a value in the range of 00 to FF. In addition to identifying the

address authority responsible for allocating a particular address and

the format of the address, the AFI also identifies whether an address

is an individual Network address or a group Network address. There

are 90 possible AFI values to support individual Network address

allocations. In addition, when the AFI value starts with the value

"0" this identifies that the field contains an incomplete individual

Network address (i.e., identifies an escape code).

Table 1 allocates 90 possible AFI values to support group Network

address allocations. In addition if the first two digits of the IDP

are hexadecimal FF, this indicates the presence of an incomplete

group Network address. The allocation of group addresses is

restricted to be only from the AFI values allocated for the

assignment of group addresses in Table 1. An addressing authority in

allocating either Network addresses or authorizing one or more

authorities to allocate addresses, allocates both individual and the

corresponding group addresses. Thus each block of addresses allocated

by an addressing authority (or its sub-authority) contains a block of

individual Network addresses and group Network addresses. The

individual and group address block allocated are differentiated by

the AFI values used which are related as shown in Table 1.

Group Network addresses are only used as the destination address

parameter of a CLNP PDU. Source Address parameters are never

permitted to be group Network addresses.

Table 2 lists the AFI values which have not been assigned, at this

time, for the support of neither individual nor group address

allocation. Future assignment of these AFI values is possible.

Additional information concerning individual Network addresses (i.e.,

NSAP and NET (Network Entity Titles)) is contained in RFC1237.

Note: While the format of the Initial Domain Part of a group Network

address is assigned, the format for the Domain Specific Part of the

group Network address is specified by an addressing authority and is

out of the scope of this memo. While NSAP address assignments are

typically made to support hierarchical unicast routing, a similar

consideration for group Network address assignments may not exist.

TABLE 1 - Relationship of AFI Individual and Group Values

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

Individual Group Individual Group Individual Group

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

0x FF

10 A0 40 BE 70 DC

11 A1 41 BF 71 DD

12 A2 42 C0 72 DE

13 A3 43 C1 73 DF

14 A4 44 C2 74 E0

15 A5 45 C3 75 E1

16 A6 46 C4 76 E2

17 A7 47 C5 77 E3

18 A8 48 C6 78 E4

19 A9 49 C7 79 E5

20 AA 50 C8 80 E6

21 AB 51 C9 81 E7

22 AC 52 CA 82 E8

23 AD 53 CB 83 E9

24 AE 54 CC 84 EA

25 AF 55 CD 85 EB

26 B0 56 CE 86 EC

27 B1 57 CF 87 ED

28 B2 58 D0 88 EE

29 B3 59 D1 89 EF

30 B4 60 D2 90 F0

31 B5 61 D3 91 F1

32 B6 62 D4 92 F2

33 B7 63 D5 93 F3

34 B8 64 D6 94 F4

35 B9 65 D7 95 F5

36 BA 66 D8 96 F6

37 BB 67 D9 97 F7

38 BC 68 DA 98 F8

39 BD 69 DB 99 F9

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

TABLE 2 - AFI values reserved for future allocation

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

1A-1F

2A-2F

3A-3F

4A-4F

5A-5F

6A-6F

7A-7F

8A-8F

9A-9F

FA-FE

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

4. Model of a CLNP End System Multicast Implementation

The use of multicast transmission by a CLNP End System involves

extensions to two protocols: CLNP and the ES-IS Routeing Protocol. To

provide level 0 service (no support for CLNP multicast), no

extensions to these two protocols are required. To provide level 1

service (support for sending but not receiving CLNP multicast PDUs)

all extensions contained in the following sections are required

except for those supporting only Multicast Announcement. In order to

support level 2 service (full support for CLNP multicasting), the

extensions contained in the following sections are required.

Extensions identified for Intermediate Systems are not required (or

appropriate) for End Systems. Multicast transmission also requires

the use of a group Network address (as previously described) as the

destination address parameter.

5. Extensions to the CLNP protocol

This section provides extensions to the CLNP Protocol [CLNP] ISO

8473-1, to support multicast transmission. These additions provide

procedures for the connectionless transmission of data and control

information from one network-entity to one or more peer network-

entities.

In developing the multicast extensions for CLNP a decision was needed

on how to "mark" a packet as multicast (versus the current unicast

packets). Such marking is necessary since the forwarding behavior

for multicast packets is different (e.g., multiple copies of a packet

may need to be forwarded). The two alternatives considered were to

mark the packet (via a particular field) or to mark the destination

address, in the end both were done. The destination address for a

multicast PDU identifies a host group which is of a very different

nature than the unicast NSAP address. Rather than changing the

nature of NSAP addresses, a new set of addresses were created named

group Network addresses which are marked within the first octet

(i.e., the AFI field) with values reserved for group Network

addresses.

Consideration was given to no further marking of the PDU; however, a

problem was identified with only using the group Network address to

identify multicast packets. Currently routers implementing the IS-IS

Intra-Domain protocol as Level 1 routers when receiving a packet with

an unknown destination address are permitted to either discard the

packet or send it to a Level 2 router. Such actions by non-multicast

capable routers to multicast packets can lead to non-deterministic

behavior. Level 1 routers upon receiving a packet containing a group

Network address might pass the packet up to a Level 2 router (which

may or may not be multicast capable) or it might discard it.

Depending upon the circumstances this might lead to whole regions

missing packets or packet duplication (possibly even explosion). The

result was to seek deterministic behavior by non-multicast capable

routers by creating a new PDU type (Multicast Data PDU) and inserting

into the CLNP reasons for discard: receiving a PDU of unknown type.

Note that this reason for discard is mandatory on multicast capable

and non-multicast capable CLNP implementations.

5.1 Definitions

multicast: Data transmission to one or more destinations in a

selected group in a single service invocation.

multicast capable Intermediate System: An Intermediate System which

incorporates the multicast features of the Network layer.

5.2 Addresses

The destination address parameter of a multicast PDU shall contain a

group Network address. The source address parameter shall be an

individual Network address.

5.3 Extensions to the current protocol functions

In order to support multicast transmissions the following optional

CLNP protocol functions will be implemented:

5.3.1 Header Format Analysis function

The header format analysis function optionally provides capabilities

to Network entities which support multicast transfer to supply

applicable PDUs directly to End Systems served by such a Network

entity as well as to forward such PDUs on to other Network entities.

This optional functionality is realized through a Network entity with

multicast capability identifying a PDU as using multicast transfer

via the PDU type and the PDU's destination address field.

If a Network entity supports multicast transmission, then the header

format analysis function shall provide checking to ensure that a PDU

does not contain a group Network address in the source address field.

Any PDU header analyzed to have a group address in the source address

field shall be discarded.

5.3.2 Route PDU function

The route PDU function optionally provides capabilities to Network

entities which support multicast transfer for determining multiple

Network entities to which a single PDU shall be forwarded to. This

may result in multiple invocations of the forward PDU function and

hence the need to make multiple copies of the PDU. For PDUs that are

received from a different Network entity, the optional functionality

for the route PDU function is realized as a result of the header

format analysis function's recognition of the PDU as being a

multicast PDU. A Network entity attached to more than one subnetwork

when originating a multicast PDU is permitted to originate the PDU on

more than one subnetwork.

Note: The ES-IS function "Extensions to the ISO CLNP Route Function

by End Systems" discussed in section 6.10 identifies on which

subnetworks an End System attached to more than one subnetwork must

originate multicast PDUs on.

Note: The purpose in allowing an originating Network entity to

originate a multicast PDU on multiple subnetworks is to support the

development of multicast IS-IS protocols which will need to determine

on which subnetworks a multicast PDU has visited. This behavior is

predicated on the assumption that the Intermediate Systems in the OSI

environment performing multicast forwarding form a connected set.

5.3.3 Forward PDU function

This function issues an SN-UNITDATA request primitive, supplying the

subnetwork or Subnetwork Dependent Convergence Function (SNDCF)

identified by the route PDU function with the protocol data unit as

user data to be transmitted, the address information required by that

subnetwork or SNDCF to identify the "next" system or systems within

the subnetwork-specific addressing domain (this may be one or more

Intermediate Systems and/or one or more destination End Systems), and

quality of service constraints (if any) to be considered in the

processing of the user data.

5.3.4 Discard PDU function

Add an additional reason for discard - a PDU is received with an

unknown type code.

5.3.5 Error reporting function

It is important to carefully control the use of the error reporting

capability in the case of multicast transfers. The primary concern

is to avoid the occurrence of broadcast storms and thus a multicast

PDU may not cause the origination of another multicast PDU. This is

the primary reason that the source address is not permitted to be a

group address. In addition, a multicast PDU with error reporting

permitted can result in flooding the source network-entity (as well

as the networks used) with Error Report PDUs.

While error reports are permitted on multicast PDUs, a PDU with a

group Network address in the source address field shall not be

responded to with an Error Report. This is to ensure that a multicast

PDU does not generate another multicast PDU. If the source address is

identified as a group address then an error report PDU shall not be

generated and the original PDU shall be discarded.

5.3.6 Source routing functions

No source routing capability is provided for multicast PDU transfer.

The NS provider shall not accept a multicast PDU with source route

parameters.

5.4 Scope control function

5.4.1 Overview

The scope control function is an option for multicast PDU forwarding

only. The scope control function allows the originator to limit the

forwarding of the multicast PDU. The scope control function provides

the capability to limit the relaying of a particular PDU based on the

individual Network addressing hierarchy and/or limit the amount of

multicast expansion which can take place. In cases where both forms

of scope control are applied to the same PDU, forwarding will cease

once either has reached its scope control limit.

5.4.2 Prefix Based Scope Control

The prefix based scope control function allows the originator to

specify a specific set of address prefixes where the multicast

forwarding of a PDU by an Intermediate System occurs only if one of

the prefixes matches the Network Entity Title (NET) of the

Intermediate System. Prefix based scope control may be selected only

by the originator of a PDU. Prefix based scope control is

accomplished using one or more address prefixes held in a parameter

within the options part of the PDU header. The length of this

parameter is determined by the originating network entity, and does

not change during the lifetime of a PDU.

When an Intermediate System receives a multicast PDU containing a

prefix based scope control parameter, forwarding is only performed if

every octet of one of the prefixes contained in the prefix based

scope control parameter matches that Intermediate System's NET,

starting from the beginning of its NET. If no such prefix match

exists, the Intermediate System discards the PDU. The error reporting

function shall not be invoked upon PDU discard.

5.4.3 Radius Scope Control

The radius scope control function allows the originator to specify a

maximum logical distance where multicast expansion can occur. It is

closely associated with the header format analysis function. Each IS

receiving a multicast PDU which is capable of expanding and which

contains a Radius Scope Control parameter, decrements the Radius

Scope Control field in the PDU by an administratively set amount

between 0 and the maximum value of the field. An IS, when it

decrements the Radius Scope Control field, shall place a value of 0

into this field if its current value is less than the amount it is to

decrement by. This function determines whether the PDU received may

be forwarded or whether its Radius has been reached, in which case it

shall be discarded. An Intermediate System shall not forward a

multicast PDU containing a Radius Scope Control parameter with a

value of 0. The error reporting function shall not be invoked upon

PDU discard.

5.4.3.1 Radius Scope Control Example

The Radius Scope Control parameter is useful where policies have been

established across the potential forwarding path. One possible

policy for Internet use is for multicast capable routers to treat

this field as a hop count within a domain (decrement by one unit) and

for inter-domain routers to either decrement this field to an even

multiple of 256 when crossing domains where prior agreements have

been made or decrement this field to 0 (i.e., discard the packet) for

other domains.

5.5 Structure and Encoding of PDUs

Multicast transmission is accomplished via the transfer of Multicast

Data (MD) PDUs. The PDU type code for a MD PDU is "1 1 1 0 1". The

format of the MD PDU is identical to that of the Data (DT) PDU. The

MD and DT PDU may contain the same optional parameters with the

following exceptions: (1)The source routing parameter is permitted

within DT PDUs but not MD PDUs; and (2)The scope control parameter is

permitted within MD PDUs but not DT PDUs.

5.6 Optional parameters for multicast support

5.6.1 Prefix Based Scope Control

The prefix based scope control parameter specifies one or more

address prefixes for which Intermediate System forwarding requires a

match of one of the contained prefixes with the beginning of the

Intermediate System's NET.

Parameter Code: 1100 0100

Parameter Length: variable

Parameter Value: a concatenation of address prefix entries

The parameter value contains an address prefix list. The list

consists of variable length address prefix entries. The first octet

of each entry gives the length of the address prefix denominated in

bits that comprises the remainder of the entry. If the length field

does not specify an integral number of octets then the prefix entry

is followed by enough trailing zeroes to make the end of the entry

fall on an octet boundary. The list must contain at least one entry.

The prefix shall end on a boundary that is legal in the abstract

syntax of the address family from which it is derived. For example,

the encoding of a prefix whose DSP is expressed in decimal syntax

must end on a semi-octet boundary, while the encoding of a prefix

whose DSP is expressed in binary syntax can end on an arbitrary bit

boundary. If the end of the prefix falls within the IDP, then the

prefix must end on a semi-octet boundary and must not contain any

padding characters.

Note: The length of the prefix based scope control parameter is

determined by the originator of the PDU and is not changed during the

lifetime of the PDU.

5.6.1.1 Prefix matching

A prefix that extends into the DSP shall be compared directly against

the encoded NET address, including any padding characters that may be

present. A prefix which does not extend into the DSP shall be

compared against the derived quantity NET', which is oBTained from

the NET address by removing all padding characters (as defined by the

binary encoding process of ISO 8348).

The existence of a match shall be determined as follows:

a) If the encoded NET (or NET') contains fewer bits than the pre-

fix, then there is no match.

b) If the encoded NET (or NET') contains at least as many bits as

the prefix, and all bits of the prefix are identical to the

corresponding leading bits of the encoded NET (or NET'), there

is a match. Otherwise, there is no match.

5.6.2 Radius Scope Control

The radius scope control parameter specifies the logical distance

that a multicast PDU can be forwarded.

Parameter Code: 1100 0110

Parameter Length: two octets

Parameter Value: two octets which represents the remaining

distance, that the PDU can be forwarded,

in administratively set units.

5.7 Provision of the Underlying Service

For a subnetwork that provides an inherent multicast capability, it

is the functionality of the SNDCF to provide the mapping between

group Network addresses and the corresponding addressing capability

of the subnetwork.

5.8 Conformance

All of the extensions provided to the functions to support multicast

capability are optional. For an End System or Intermediate System

which is not multicast capable these extensions are not applicable.

An implementation claiming conformance as a multicast capable End

System shall meet all of the requirements for an End System which is

not multicast capable and also provide all of the multicast

extensions provided here. An implementation claiming conformance as a

multicast capable Intermediate System shall meet all of the

requirements for an Intermediate System which is not multicast

capable and also provide all of the multicast extensions provided

here.

6. Extensions to the ES-IS Routeing Protocol

This section provides optional extensions to the ES-IS Routeing

Protocol [ES-IS], ISO 9542 to support the transfer of multicast PDUs.

It is an explicit goal of this specification that ESs and ISs, some

of which will have multicast capabilities and some without, will be

able to fully function on the same subnetworks. This specification

does not change any ASPect of a currently defined (i.e., non-

multicast) ISO 9542 implementation, it adds new optional

functionality not modifying current functionality. Two basic

functions are provided: multicast announcement and multicast address

mapping.

6.1 Overview of the protocol

6.1.1 Operation of ESs receiving multicast PDUs

ESs, upon initialization and periodically thereafter, will construct

End System Group Hello (ESGH) PDUs identifying, by particular group

Network addresses, the multicast PDUs it wishes to receive. The ES

will periodically originate (announce) these ESGH PDUs on the

subnetwork it wishes to receive these on. Reporting the same group

Network address on multiple subnetworks may result in the reception

of duplicate PDUs. ES-IS operations related to requesting the same

group Network address on multiple subnetworks are handled totally

independently (e.g., using different logical timers,...). It is

permitted for an ES to report a number of group Network addresses in

the same ESGH PDU. The only restrictions placed on providing

multiple group Network addresses within the same ESGH PDU are that

all packets requested are to be received on the same subnet, with the

same holding time and that the ESGH PDU be of length equal to or less

that its maximum packet size constraint. Note that each group

Network address in the ESGH PDU is paired with its own SNPA

(subnetwork point of attachment) address.

An ES will always have an SNPA address associated with each of its

active group Network addresses. An SNPA address is a subnetwork

address, in the case of a subnetwork which uses IEEE 802 addresses

the SNPA address is a 48 bit IEEE 802 MAC (media access control)

address. Of particular interest is the address used to mark the

destination group. For a subnetwork using IEEE 802 addressing a

group SNPA address uses a particular bit position to "mark" group

SNPA addresses.

Upon initialization the ES may have static SNPA address associations

(Pre-configured SNPA addresses). For any group Network address

without a Pre-configured SNPA address that the ES wishes to receive,

the ES will associate the "All Multicast Capable End Systems" SNPA

address. Upon receiving a Multicast Address Mapping (MAM) PDU

containing a group Network address that the ES is announcing, the ES

will use the SNPA address pairing contained in the MAM PDU for that

group Network address. Upon the expiration of the Mapping Holding

Timer, the ES shall revert back to associating either the Pre-

configured SNPA address if one exists or the "All Multicast Capable

End Systems" SNPA address for the specific group Network address.

While an ES is permitted to listen in on other ESs announcements

(needed for the damping option), an ES is not permitted to change its

group Network address to SNPA address mapping based on the

announcement of other ESs.

Optionally, the ES may perform damping (resetting a Multicast

Announcement Timer corresponding to a particular group Network

address) if the conditions necessary to withhold a particular

announcement are met. In order to perform damping the following

conditions must be met: (1)The ES must be processing other ES's

announcements; (2)An ESGH PDU is received that identifies the exact

same group Network address and SNPA address pairing on a particular

subnetwork that this ES is announcing on; (3) The Multicast Holding

Timer parameter value in the ESGH PDU received is equal to or greater

than the Multicast Holding Timer value, for this subnetwork, that is

being used by the ES processing this ESGH PDU.

ESs will utilize a local default value for their Multicast

Announcement Timer to control the period for sending out their ESGH

PDUs. The Active Multicast IS, if one exists on a particular

subnetwork, may suggest a value for ESs on the subnetwork to use for

their Multicast Announcement Timer for a specific group Network

address. In order to support the optional damping function, ESs are

required to incorporate a 25% jittering to the timer values that they

are using.

6.1.2 Operation of ESs originating multicast PDUs

The ES originating multicast packets identified by a specific group

Network address is not required to be a receiver of such packets (and

thus is not announcing that particular group Network address). The

origination of multicast PDUs involves two differences to the

origination of unicast PDUs. The two differences are: (1)The

mechanism for selecting a destination SNPA address and (2)For End

Systems attached to more than one subnet, the decision on which

subnet(s) to originate the PDUs.

The destination SNPA address used for originating each multicast

packet depends on whether there is a multicast capable IS attached to

the subnetworks. When a multicast capable IS is attached, the

decision depends on whether there is multicast address mapping

information available for that subnetwork corresponding to the group

Network address used as the destination address parameter of the

multicast packet. When there is a multicast capable IS attached to a

subnetwork and there is multicast address mapping information

available corresponding to the group Network address, then the SNPA

address obtained from the multicast address mapping information is

used. Originating multicast packets using the destination SNPA

address used for receiving such multicast packets ensures that the

multicast packets will not require additional forwarding on the

originating subnetwork(s). When there is a multicast capable IS

attached to a subnetwork but for which there is no multicast address

mapping information available corresponding to the the group Network

address, then the SNPA address used is the "All Multicast Capable

Intermediate Systems" address.

When there is no multicast capable IS attached to a subnetwork then

the ES originating a multicast PDU uses pre-configured information if

it is available or the "All Multicast Capable End Systems" SNPA

address when no pre-configured information is available.

ES's attached to more than one subnetwork forward each multicast

packet that they originate onto every attached subnetwork for which

the NSAP address being used as the source address of the multicast

packet is actively being reported through the unicast ES-IS Report

Configuration function.

6.1.3 Operation of the Active Multicast IS

The Active Multicast IS listens in on all ESGH PDUs originated on the

subnetwork for which it is serving as the Active Multicast IS. All

subnetworks are handled independently (even if multiple subnetworks

have the same ESs attached and the IS is serving as the Active

Multicast IS for these subnetworks).

The Active Multicast IS originates MAM PDUs, for all group Network

addresses for which it has received ESGH PDUs, on the subnetwork due

to the following operational conditions:

1) The IS initializes either as the Active Multicast IS after an

election with other multicast capable ISs or initializes

believing it is the only multicast capable IS;

Note: The determination of such conditions is outside of the scope of

this specification;

2) The IS receives an ESGH PDU with a group Network address paired

to an incorrect SNPA address;

3) The expiration of the IS's Multicast Address Mapping Timer for

that group Network address; or

Note: This is to prevent the expiration of Mapping Holding Timers in

ESs.

4) The IS receives a multicast PDU originated on the subnetwork

which used an incorrect destination SNPA address.

Note: Of particular concern are those multicast packets using the

"All Multicast Capable Intermediate Systems" SNPA address when

another SNPA address should have been used. In addition the

multicast capable ISs are responsible for listening in on all

multicast packets using destination SNPA addresses that are contained

within the current multicast address mapping information.

As a result of the event driven conditions (i.e., conditions 2 or 4

above), the Active Multicast IS sends a MAM PDU with direct

information (i.e., not needing analysis of the Mask parameters). The

Active Multicast IS limits the number of MAM PDUs that are sent out

per unit of time. Particular MAM PDUs with direct information will

not be sent more than once per second. MAM PDU will be sent in

response to continuing event driven conditions such that events

occurring greater than 10 seconds after the issuance of such a MAM

PDU will result in the issuance of another MAM PDU.

The Active Multicast IS is responsible for forwarding a multicast

packet back on the subnetwork it was originated when a multicast

packet used the "All Multicast Capable Intermediate System" SNPA

address when another SNPA address should have been used. A packet

forwarded back onto the subnetwork the multicast packet was

originated on will be given a CLNP Lifetime of "1" to prevent the

continued relaying of duplicate packets by the multicast ISs.

The further relaying of any multicast packet originated on a

subnetwork is the responsibility of the multicast routing protocol

used and is outside the scope of this specification.

6.2 Definitions

Active Multicast IS: The one multicast capable IS selected (via means

outside of this specification) to originate Multicast Address Mapping

information on a particular subnetwork.

Paired SNPA Address: The SNPA address associated with a particular

group Network address on a specific subnetwork.

6.3 Routing information supporting multicast transmission

6.3.1 Multicast Announcement Information

An IS should forward a multicast PDU containing a particular

destination group Network address onto a subnetwork to which it is

attached if and only if one or more of the ESs attached to that

subnetwork have declared an interest in receiving multicast PDUs

destined for that group Network address. Multicast announcement

information enables an IS that supports CLNP multicast to dynamically

discover, for each subnetwork to which it is attached, the group

Network addresses for which ESs attached to that subnetwork have

declared an interest.

On a point-to-point subnetwork the multicast announcement information

informs the Network entity, in the case where it is attached to an

End System, of the group Network addresses for which that End System

expects to receive multicast PDUs.

On a broadcast subnetwork the multicast announcement information

informs the multicast capable Intermediate Systems, of the group

Network addresses for which ESs attached to that subnetwork expect to

receive multicast PDUs.

Note: Intermediate Systems with the optional OSI multicast

capabilities do receive information identifying the SNPA address of

ESs on the broadcast network that want PDUs with particular group

Network addresses as their destination address; however, the critical

information is which multicast PDUs are needed, not which ESs need

them.

6.3.2 Multicast Address Mapping Information

In order to receive multicast packets destined for a particular group

Network address, an ES may need to associate with the group Network

address a specific SNPA address. Multicast address mapping

information enables an IS to inform ESs that they can receive

multicast packets destined for a particular group Network address on

a corresponding specific SNPA address. In addition, multicast

address mapping information may provide the specific destination SNPA

addresses needed by an ES for originating multicast packets.

Multicast address mapping information is not employed on point-to-

point subnetworks.

Multicast address mapping information is employed on broadcast sub-

networks to enable multicast capable Intermediate Systems to inform

the multicast capable End Systems that they can receive, on a

specific broadcast subnetwork, multicast packets destined for a

particular group Network address on a corresponding specific SNPA

address. In addition multicast address mapping information provides

the specific destination SNPA address, that corresponds to a

particular group Network address, for each multicast packet that it

originates on a specific broadcast subnetwork.

6.4 Addresses

All exchanges using this protocol are accomplished over a single

subnetwork. While the control PDU's contain Network addresses (i.e.,

group Network addresses) actual control PDU transfer is accomplished

via Subnetwork based group addresses (i.e., group SNPA addresses).

The following group SNPA addresses are used: (1)All Multicast Capable

End Systems; (2)All Multicast Announcements; (3)All Multicast Capable

Intermediate Systems and (4)a group SNPA address corresponding to a

group Network address

6.5 Timers

Two additional timers are employed: (1)the Multicast Announcement

Timer (MAT) and (2)Multicast Address Mapping Timer (MAMT). Old

multicast announcement or multicast address mapping information shall

be discarded after the Holding Timer expires to ensure the correct

operation of the protocol.

6.5.1 Multicast Announcement Timer

The Multicast Announcement Timer is a local timer (i.e., maintained

independently by each End System, one timer per group Network

address) which assists in performing the Report Multicast

Announcement function. The timer determines how often an End System

reports its desire to receive multicast PDUs with that group Network

address as its destination address parameter. Considerations in

setting this timer are similar to those described for the

Configuration timer in the ES-IS specification.

6.5.2 Multicast Address Mapping Timer

The Multicast Address Mapping Timer is a local timer (i.e.,

maintained independently by an Intermediate System which is actively

participating with End Systems to transfer multicast PDUs) which

assists in performing the Report Multicast Address Mapping function.

The timer determines how often an Intermediate System, actively

participating with End Systems for the transfer of multicast PDUs,

reports the Multicast Address Mapping for a particular group Network

address. The shorter the Multicast Address Mapping Timer, the more

quickly End Systems on the subnetwork will become aware of the

correct address mapping which may change due to the Intermediate

System becoming available or unavailable. There is a trade off

between increased responsiveness and increased use of resources in

the subnetwork and in the End Systems.

6.6 Extensions to the current protocol functions

In order to support multicast transmissions the following optional

ES-IS protocol functions will be implemented:

6.6.1 Report Configuration by Intermediate Systems

All multicast capable Intermediate Systems on a subnetwork shall use

the Multicast Capable option in all ISH PDUs that they originate.

This will provide multicast capable End Systems with a way to

determine that a multicast capable Intermediate System is operating

on a particular subnetwork.

6.6.2 Query Configuration

Note: The Query Configuration function cannot be performed to find

the corresponding SNPA address of a group Network address since the

addressing information needed is the corresponding group SNPA address

and not the SNPA address of a particular End System responding. On a

large broadcast subnetwork, many different Configuration Responses

could result each incorporating a different End System Address. While

it is possible to design a Query Configuration for use with

multicast, this function does not appear to be required given the use

of the "All Multicast Capable End Systems" address for supplying a

SNPA address when the group SNPA address is not known.

6.7 Multicast Announcement

6.7.1 Report Multicast Announcement Function by End Systems

An End System which needs to receive or continue to receive any

multicast PDUs (i.e., PDUs with group Network addresses as their

destination address), constructs and transmits ESGH PDUs to inform

multicast capable Intermediate Systems of the set of group Network

address destinations for which it wishes to receive PDUs. This may be

done by constructing ESGH PDUs for each group Network address.

Alternatively, ESGH PDUs may be constructed which convey information

about more than one group Network address at a time, up to the limits

imposed by the permitted SNSDU size and the maximum header size of

the ESGH PDU. Each ESGH PDU is transmitted by issuing an SN-

UNITDATA.Request with the following parameters:

SN_Userdata (SNSDU) <- ESGH PDU

SN_Destination _Address <- multi-destination address that indicates

"All Multicast Announcements"

If an End System is attached to more than one subnetwork, the

information about each group Network address desired for receiving on

a particular subnetwork serving the End System shall be transmitted

via that subnetwork. It is permissible for an End System to report

group Network addresses on multiple subnetworks; however, duplicate

multicast PDUs should be anticipated.

The Group Address Pair parameter carries a list of Group Network

Addresses, each paired with its associated SNPA address. This

information is used by the Active Multicast IS to determine whether a

Multicast Address Mapping PDU should be emitted to update the

association between Group Network Addresses and SNPA addresses.

The Holding Time (HT) field is set to approximately twice the ES's

Multicast Announcement Timer (MAT) parameter. The value shall be

large enough so that even if every other ESGH PDU is discarded (due

to lack of resources), or otherwise lost in the subnetwork, the

multicast announcement information will still be maintained. The

value should be set small enough so that Intermediate Systems

resources are not needlessly consumed when the ES no longer wishes to

receive PDUs destined to a group Network address.

Note: When combining multiple group Network addresses in a single

ESGH PDU, it should be realized that there is a single Holding Time

parameter associated with all of these addresses.

6.7.1.1 Generating Jitter on Multicast Announcement Timers

The ES shall apply a 25% jitter to its Multicast Announcement Timer

(MAT) parameter. When ESGH PDUs are transmitted as a result of timer

expiration, there is a danger that the timers of individual systems

may become synchronised. The result of this is that the traffic

distribution will contain peaks. Where there are a large number of

synchronised systems, this can cause overloading of both the

transmission medium and the systems receiving the PDUs. In order to

prevent this from occurring, all periodic timers, the expiration of

which can cause the transmission of PDUs, shall have "jitter"

introduced as defined in the following algorithm.

CONSTANT

Jitter = 25;

Resolution = 100;

(* The timer resolution in ms *)

PROCEDURE Random(max: Integer): Integer;

(* This procedure delivers a Uniformly distributed random

integer R such that 0 < R <max *)

PROCEDURE WaitUntil(time: Integer)

(* This procedure waits the specified number of

ms and then returns *)

PROCEDURE CurrentTime(): Integer

(* This procedure returns the current time in ms *)

PROCEDURE

DefineJitteredTimer(baseTimeValueInSeconds : Integer;

expirationAction : Procedure);

VAR

baseTimeValue, maximumTimeModifier, waitTime : Integer;

nextexpiration : Time;

BEGIN

baseTimeValue := baseTimeValueInSeconds * 1000 / Resolution;

maximumTimeModifier := baseTimeValue * Jitter / 100;

(* Compute maximum possible jitter *)

WHILE running DO

BEGIN

(*First compute next expiration time *)

randomTimeModifier := Random(maximumTimeModifier);

waitTime:= baseTimeValue - randomTimeModifier;

nextexpiration := CurrentTime() + waitTime;

(* Then perform expiration Action *)

expirationAction;

WaitUntil(nextexpiration);

END (* of Loop *)

END (* of DefineJitteredTimer *)

Thus the call "DefineJitteredTimer(HelloTime, SendHelloPDU);" where

"HelloTime" is 10 seconds, will cause the action "SendHelloPDU" to be

performed at random intervals of between 7.5 and 10 seconds. The

essential point of this algorithm is that the value of

"randomTimeModifier" is randomised within the inner loop. Note that

the new expiration time is set immediately on expiration of the last

interval, rather than when the expiration action has been completed.

The time resolution shall be less than or equal to 100 ms. It is

recommended to be less than or equal to 10ms. The time resolution is

the maximum interval than can elapse without there being any change

in the value of the timer. The periodic transmission period shall be

random or pseudo-random in the specified range. with uniform

distribution across similar implementations.

Note: Applying jitter to the MAT parameter is required in order to

support the optional Damping function. If no jitter is applied on a

subnetwork where many ESs are requesting a particular multicast PDU

it is likely that they will have the same value for their MAT and

these timers may all become synchronised. Such synchronisation will

result in peaks in the distribution of traffic as described above.

The resulting overloading of the transmission medium and the systems

receiving the PDUs will negate any beneficial use of the Damping

function (since systems may be attempting to transmit their own ESGH

PDUs at the time they receive ESGH PDUs originated by other ESs with

the same group Network address.

6.7.2 Record Multicast Announcement Function

The Record Multicast Announcement function receives ESGH PDUs,

extracts the multicast announcement information and updates the

information in its routing information base.

The receiving system is not required to process any option fields in

a received ESGH PDU.

Note: When a system chooses to process these optional fields, the

precise actions are not specified by this International Standard.

6.7.2.1 Record Multicast Announcement Function by Intermediate Systems

On receipt of an ESGH PDU an IS with the optional multicast

capabilities extracts the configuration information and stores the

{group Network address, subnetwork} in its routing information base

replacing any other information for the same entry.

The Active Multicast IS upon receipt of an ESGH PDU also extracts the

Paired SNPA Address parameter corresponding to each group Network

address in the ESGH PDU. If the Active Multicast IS has a mapping for

a group Network address carried in the ESGH for which the paired SNPA

address does not match, the Report Multicast Address Mapping function

is performed.

6.7.2.2 Optional Damping Function

An ES with the optional capabilities to support multicast transfer

may decide to process ESGH PDUs multicast by other End Systems. There

is potentially some reduction in network traffic by doing this. An ES

requesting to receive multicast PDUs is permitted to reset its

Multicast Announcement Timer corresponding to one group Network

address on one subnetwork upon receiving an ESGH PDU from another ES

under the following circumstances:

a) The {group Network address, paired SNPA address} received on a

particular subnetwork matches that of the ES processing the ESGH

PDU for that subnetwork.

b) The Holding Timer parameter value in the ESGH PDU received is

equal to or greater than the Holding Timer value for the, group

Network address, being used by the ES processing this PDU.

6.7.3 Flush Old Multicast Announcement Function

The Flush Old Multicast Announcement function is executed to remove

multicast announcement entries in its routing information base whose

Holding Timer has expired. When the Holding Timer for a group Network

address expires, this function removes the corresponding entry from

the routing information base of the local IS for the corresponding

subnetwork.

6.8 Multicast Address Mapping

6.8.1 Report Multicast Address Mapping Function by Intermediate Systems

The Active Multicast Intermediate System constructs a MAM PDU,

corresponding to a group Network address for which it received via

the Record Multicast Announcement function, and issues these PDUs

under the following circumstances:

a) The IS initializes either as the Active Multicast IS after an

election with other multicast capable ISs or initializes after

determining it is the only multicast capable IS (the

determination of such conditions are outside of the scope of

this standard), or

b) The IS receives an ESGH PDU with a group Network address paired

to an SNPA address other than the SNPA address contained in the

Active Multicast IS's multicast address mapping information for

that group Network address, or

Note: The Active Multicast IS determines which mappings are correct.

Pre-configured mappings which are used prior to the initialization of

the Active Multicast IS may be determined to be incorrect by the

Active Multicast IS.

c) The expiration of the IS's Multicast Address Mapping Timer for

that group Network address.

Note: This is to prevent the expiration of Holding Timers in ESs.

d) The IS receives a multicast PDU originated on the subnetwork

which used an incorrect destination SNPA address.

Note: Of particular concern are those multicast packets using the

"All Multicast Capable Intermediate Systems" SNPA address when

another SNPA address should have been used. The Originating

Subnetwork Forwarding function is performed if this event occurs (see

section 6.11).

Note: The multicast capable ISs need to receive multicast packets on

all SNPA addresses that are contained in the current multicast

address mapping information for the subnetwork. The multicast

capable ISs are not required to receive multicast packets on any SNPA

addresses other than those contained in the current multicast address

mapping information and the "All Multicast Capable Intermediate

Systems" SNPA address.

Circumstances b) and d) are the event driven conditions for the

Active Multicast IS to construct and issue a MAM PDU. The Active

Multicast IS shall limit the number of MAM PDUs issued per unit of

time. MAM PDUs with identical information shall not be issued more

than once per second. Event conditions occurring 10 seconds after

the last issue of an appropriate MAM PDU shall result in the issuance

of another such MAM PDU.

The IS serving as the Active Multicast Intermediate System may

construct a MAM PDU for each group Network address. Alternatively,

MAM PDUs may be constructed which convey information about more than

one group Network address at a time, up to the limits imposed by the

permitted SNSDU size and the maximum header size of the MAM PDU. The

IS performs all multicast address mapping functions independently for

each of its subnetworks even if this IS is the Active Multicast IS on

multiple subnetworks. Each MAM PDU is transmitted by issuing an SN-

UNITDATA.Request with the following parameters:

SN_Userdata (SNSDU) <- MAM PDU

SN_Destination _Address <- multi-destination address that indicates

"All Multicast Capable End Systems"

The Holding Time (HT) field is set to approximately twice the

Intermediate System's Multicast Address Mapping Timer (MAMT)

parameter. This variable shall be set to a value large enough so

that even if every other MAM PDU, for a particular group Network

address, is discarded (due to lack of resources), or otherwise lost

in the subnetwork, the multicast address mapping information will

still be maintained. The value should be set small enough so that End

Systems will quickly cease to use the multicast address mappings

supplied by ISs that have failed.

Note: -- The Holding Timer parameter value applies to all group

Network addresses called out in the MAM PDU.

The Group Address Pair parameter is used to convey the association

between Group Network Addresses and SNPA addresses.

Optionally, the Active Multicast IS may include information in the

MAM PDU indicating a larger population of group Network addresses to

which the same multicast address mapping information applies. There

are two optional fields for this purpose: the Group Network Address

Mask option and the Paired SNPA Address Mask option.

There are three permitted cases for including or excluding the masks.

In the first case, both masks are absent. In this case the MAM PDU

conveys information about one set of enumerated group Network

addresses only.

Note: -- Multiple group address pairs may be contained in a single

MAM PDU.

In the second case, the MAM PDU contains a Group Network Address Mask

but no Paired SNPA Address Mask. In this case, the MAM PDU conveys

information about an equivalence class of group Network addresses.

The information reveals that multiple group Network addresses are

mapped to the same SNPA address.

In the third case, the MAM PDU contains both masks. As in the second

case, the MAM PDU conveys information about an equivalence class of

group Network addresses. But in this case, the information reveals

that the SNPA addresses for the equivalence class of group Network

address are embedded in the group Network address. In particular the

Paired SNPA Address Mask indicates the location of the SNPA address

in the group Network Address(es).

The Active Multicast IS shall construct a MAM PDU with direct

information, not needing analysis of the Mask parameters, in response

to the occurrence of an event driven condition. The Active Multicast

IS may provide additional information in such a MAM PDU via the use

of Mask parameters.

An IS may suggest a value for End Systems on the local subnetwork to

use as their Multicast Announcement Timers, for a specific group

Network address, by including the Suggested ES Multicast Announcement

Timer (ESMAT) parameter in the transmitted MAM PDU. Setting this

parameter permits the Active Multicast IS to influence the frequency

with which ESs transmit ESGH PDUs.

Note: If the ESMAT parameter is used, the one value permitted in the

MAM PDU is suggested for all group Network addresses called out in

the MAM PDU.

6.8.2 Record Multicast Address Mapping Function by End Systems

The Record Multicast Address Mapping function receives MAM PDUs,

extracts the multicast address mapping information and updates the

information in its routing information base. The receiving system is

not required to process any option fields in a received MAM PDU with

the exception of the Suggested ES Multicast Announcement Timer

(ESMAT) parameter.

Note: When a system chooses to process these optional fields, the

precise actions are not specified by this International Standard.

On receipt of a MAM PDU an ES with the optional multicast

capabilities extracts the multicast address mapping information and

stores the {group Network address, paired SNPA address} for a

particular subnetwork in its routing information base replacing any

other information for the same group Network address and subnetwork.

In addition, an ES shall set its Multicast Announcement Timer,

corresponding to the group Network address for which it is performing

the Record Multicast Address Mapping function, based on receipt of a

MAM PDU, corresponding to that group Network address, containing an

ESMAT parameter.

Note: While an ES may process ESGH PDUs multicast by other ESs to

support the optional Damping function, an ES is not permitted to

change its own mapping due to the mapping found in other ES's ESGH

PDUs.

6.8.3 Flush Old Multicast Address Mapping Function by End Systems

The Flush Old Multicast Address Mapping function is executed to

remove multicast address mapping entries in its routing information

base whose corresponding Holding Timer has expired. When such a

Holding Timer for a multicast address mapping expires, this function

removes the corresponding entry from its routing information base for

the corresponding SNPA.

6.9 Paired SNPA Address Selection Function by End Systems

An End System shall pair each group Network address with an

associated SNPA address to support receiving (e.g., performing the

Report Multicast Announcement function) and originating multicast

PDUs.

6.9.1 Paired SNPA Address Selection for Receiving Multicast PDUs

An End System always has a paired SNPA address for every active group

Network address on a particular subnetwork. This mapping is obtained

by:

a) recording a multicast address mapping which is maintaining an

active holding timer, or if there has been no dynamic

information received, by

b) having pre-configured multicast address mapping information, or

if neither dynamic nor pre-configured information is available,

by

c) mapping the "All Multicast Capable End Systems" multi-

destination address to the group Network address.

6.9.2 Paired SNPA Address Selection for Originating Multicast PDUs

An End System, originating a multicast PDU, pairs a SNPA address to

the group Network address. This mapping is obtained in the following

manner:

a) If there is a multicast capable IS reachable on the subnetwork

then the SNPA address used by an End System originating a multi-

cast PDU is either the paired SNPA address obtained from the

multicast address mapping information associated with the group

Network address in the multicast PDU's Destination address

parameter or if there is no valid entry for the group Network

address by using the "All Multicast Capable Intermediate Sys-

tems" multi-destination address, or if there is no multicast

capable Intermediate System on the subnetwork, by

Note: Multicast address mapping information is valid if the Holding

Timer associated with it has not expired.

Note: An ES can determine if a multicast capable IS is reachable on

the subnetwork by having for that subnetwork either (1)multicast

address mapping information or (2)routing information received via an

ISH PDU containing a Multicast Capable optional parameter. In either

case the information must be valid (i.e., the Holding Timer for the

information must not have expired).

b) having pre-configured multicast address mapping information, or

if neither a multicast capable Intermediate System is present on

the subnetwork nor pre-configured information is available, by

c) mapping the "All Multicast Capable End Systems" multi-

destination address to the group Network address.

6.10 Extensions to the ISO CLNP Route Function by End Systems

An End System attached to more than one subnetwork shall determine

when originating a multicast PDU whether to forward this multicast

PDU to more than one subnetwork or not. End Systems shall originate

each multicast PDU on all subnetworks for which the ISO ES-IS

Configuration function is actively reporting the NSAP address

contained in the Source Address parameter of the multicast PDU. As a

result of this function multiple invocations of the ISO CLNP

Forwarding function may result when such an ES originates a multicast

PDU.

6.11 Originating Subnetwork Forwarding Function by Intermediate

Systems

The Active Multicast IS upon receiving a multicast PDU originated on

a subnetwork which used the "All Multicast Capable Intermediate

Systems" SNPA address when another SNPA address should have been

used, performs the Originating Subnetwork Forwarding function. The

multicast address mapping information defines the correct SNPA

address pairings for a given subnetwork. The Originating Subnetwork

Forwarding function forwards the multicast PDU back on subnetwork it

was originated on. In the case that the ES was attached to more than

one subnetwork and originated the multicast PDU on more than one

subnetwork, the Active Multicast IS for each subnetwork performs the

Originating Subnetwork Forwarding function for the subnetwork that

they are responsible for.

The Active Multicast IS obtains the contents for the multicast PDU

for the Originating Subnetwork Forwarding function by using the

contents of the multicast PDU received with the incorrect destination

SNPA address and replacing the original PDU Lifetime field with the

value one (0000 0001). The Active Multicast IS performs the ISO 8473

PDU Composition function and forwards the PDU to the subnetwork that

the PDU was originated on using the ISO 8473 Forwarding function with

the correct destination SNPA address.

Note: The PDU Lifetime field is set to "one" to ensure that ISs

attached to the originating subnetwork do not forward this PDU on.

Such ISs should have received the PDU when it was originated since

this function is only performed in the event of receiving a multicast

PDU incorrectly addressed to the "All Multicast Capable Intermediate

Systems" SNPA address.

6.12 Structure and Encoding of PDUs

The ES-IS multicast control functions are supported via the exchange

of ESGH and MAM PDUs. The one exception to this is that a new

optional parameter, the Multicast Capable parameter, is provided for

use within the ISH PDU.

6.12.1 PDU Type Codes

The Multicast Announcement is accomplished via the transfer of End

System Group Hello (ESGH) PDUs. The PDU type code for an ESGH PDU is

"0 0 1 0 1". The Multicast Address Mapping (MAM) is accomplished via

the transfer of Multicast Address Mapping PDUs. The PDU type code for

a MAM PDU is "0 0 1 1 1".

6.12.2 Hold Time field

The Holding Time field specifies the maximum time for the receiving

Network entity to retain the multicast announcement or multicast

address mapping information contained in the PDU.

6.12.3 Structure of Addressing Parameters

The ESGH and MAM PDUs carry one or more group Network addresses

(GNAs) each with their associated Paired SNPA Address (PSA).

6.12.4 Group Address Pair Parameter for ESGH and MAM PDUs

The Group Address Pair parameter is a list of one or more group

Network addresses each with their associated Paired SNPA address. The

group Network address identifies specific multicast PDUs and the

Paired SNPA address is the SNPA address on which the ES expects to

receive such multicast PDUs on that subnetwork. It is encoded in the

ESGH and MAM PDUs as shown in Figure 1.

Octet

,----------------------------------------------------,

Number of Group Address Pairs 10

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

Group Network Address Length Indicator (GNAL) 11

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

12

: Group Network Address (GNA) :

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

Paired SNPA Address Length Indicator (PSAL)

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

: Paired SNPA Address (PSA) :

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

GNAL

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

: GNA :

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

PSAL

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

: PSA :

m-1

'----------------------------------------------------'

Figure 1 - ESGH and MAM PDUs - - Group Address Pair Parameter

6.12.5 Extensions to the current Option Parameters

The Security and Priority optional parameters may be carried in a

ESGH PDU. There is no Security or Priority option for the MAM PDU.

6.12.6 Suggested ES Multicast Announcement Timer

The ESMAT parameter may appear only in the MAM PDU

The ESMAT parameter conveys the value that an IS requests the

receiving ESs to use as their local Multicast Announcement Timer.

Parameter Code: 1100 0111

Parameter Length: two octets

Parameter Value: ESMAT in units of seconds.

6.12.7 Multicast Capable

The Multicast Capable option may appear only in the ISH PDU

The Multicast Capable options consists only of a one octet code and a

one octet parameter length field, there is no parameter field.

Parameter Code: 1100 1000

Parameter Length: zero octets

Parameter Value: none (parameter does not exist).

6.12.8 Group Network Address Mask

The Group Network Address Mask option may only appear in the MAM PDU.

The Group Network Address Mask parameter indicates that the multicast

address mapping information applies to a larger population of group

Network Addresses than the group Network address(es) contained in the

MAM PDU indicates. When this option is provided in a MAM PDU, the

maSKINg relationship contained must be valid for all group Network

addresses contained in this PDU. An End System may ignore this

parameter.

The Group Network Address Mask establishes an equivalence class of

group Network addresses to which the same multicast address mapping

information applies. To determine whether or not a trial group

Network address falls within the equivalence class, the ES aligns the

trial group Network address with the Group Network Address Mask

padding the latter with trailing zero octets if necessary. If in all

bit positions where the Group Network Address Mask is "1" the trial

group Network address matches the Group Network Address field of the

Group Address Pair parameter of the MAM PDU, then the trial group

Network address belongs to the equivalence class described by the MAM

PDU.

The Group Network Address Mask parameter has additional semantics

when considered with the Paired SNPA Address Mask parameter.

Parameter Code: 1110 0011

Parameter Length: variable, up to 20 octets

Parameter Value: a comparison mask of octets to be

aligned with the Group Network Address

field of the Group Address Pair

parameter of the MAM PDU.

6.12.9 Paired SNPA Address Mask

The Paired SNPA Address Mask option may only appear in the MAM PDU.

When the Paired SNPA Address Mask is present, the equivalence class

defined by the Group Network Address Mask also has common structure

below the Group Network Address Mask; i.e., in the portion of the

group Network address where the Group Network Address Mask is

logically "0". The Paired SNPA Address Mask supplies additional

information about the structure, by indicating certain bit positions

within the space "below" the Group Network Address Mask.

Specifically, the Paired SNPA Address Mask indicates the location of

the Paired SNPA address in the Group Network Address.

This parameter may appear in a MAM PDU only if the Group Network

Address Mask is also present. When this option is provided in a MAM

PDU, the masking relationship contained must be valid for all group

Network addresses contained in this PDU. An ES receiving such a MAM

PDU may safely ignore both masks. However (since presence of both

masks dictates different functional behavior than the presence of the

Group Network Address Mask alone) an ES shall not ignore one of the

masks while heeding the other.

Parameter Code: 1110 0100

Parameter Length: variable

Parameter Value: a comparison mask of octets to be

aligned with the Group Network Address

field(s) of the Group Address Pair

parameter of the MAM PDU.

6.12.9.1 Mask Parameters Example

This section provides examples of using the Group Network Address

Mask and the Paired SNPA Address Mask. The examples given are for an

Internet usage of CLNP Multicasting across subnetworks using IEEE 802

addressing. For these examples the group Network address format is:

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

IDP Upper DSP Embedded SNPA address SEL

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

octets: 3 10 6 1

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

Thus the group Network address used is 20 octets. For these

examples, the only field considered is the Embedded SNPA address

field and its placement within the group Network address.

In the first example it is the policy in "this part of the Internet"

to map the Embedded SNPA address into the IEEE 802 address space

reserved by IEEE 802 for group addressing using LOCAL assignment,

this corresponds to all 48 bit values with the two low order bits of

the first octet set to "11".

The Active Multicast Intermediate System on this subnetwork may

construct a MAM PDU to map, for this example, a group Network address

of {13 octets, 03-00-DA-DA-DA-DA, 1 octet} and a paired SNPA address

of 03-00-DA-DA-DA-DA. In addition the Active Multicast Intermediate

System can include in the MAM PDU a Group Network Address Mask of

FF-FF-FF-FF-FF-FF-FF-FF-FF-FF-FF-FF-FF-03-00-00-00-00-00-00.

With this parameter, all group Network addresses which share the

identical first 13 octet and with "11" in the two low order bits of

the 14th octet are put in an equivalence class and share the same

mapping information. If this were the only option present then all of

these group Network addresses would all have a paired SNPA address of

03-00-DA-DA-DA-DA.

In order to map the group Network addresses to the range of IEEE

addresses of this example, the MAM PDU must also contain a Paired

SNPA Address Mask. The Paired SNPA Address Mask identifies where the

SNPA Address is contained within the group Network addresses (defined

by the equivalence class formed by the Group Network Address Mask

within the same PDU). For this example the Paired SNPA Address Mask

is 00-00-00-00-00-00-00-00-00-00-00-00-00-FF-FF-FF-FF-FF-FF-00.

As a second example, all group Network addresses with a specific OUI

(organizationally unique identifier) using the twenty octet group

Network address format provided above are mapped to their embedded

SNPA address. An OUI is assigned by IEEE 802 and is three octets in

length. The OUI is contained in the first three address octets of a

GLOBALLY assigned IEEE 802 address. For this example the MAM PDU

must contain the following:

1. A group Network address contained within the MAM PDU with the

OUI of interest.

2. A group Network address Mask of FF-FF-FF-FF-FF-FF-FF-FF-FF-

FF-FF-FF-FF-FF-FF-FF-00-00-00-00.

3. A Paired SNPA Address of 00-00-00-00-00-00-00-00-00-

00-00-00-00-FF-FF-FF-FF-FF-FF-00.

6.12.10 End System Group Hello (ESGH) PDU

The ESGH PDU has the format shown in figure 2:

Octet

,----------------------------------------------------,

Network Layer Protocol Identifier 1

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

Length Indicator 2

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

Version/Protocol ID Extension 3

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

reserved (must be zero) 4

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

0 0 0 Type (00101 = ESGH) 2

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

Holding Time 6,7

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

Checksum 8,9

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

Number of Group Address Pairs 10

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

Group Network Address Length Indicator (GNAL) 11

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

12

: Group Network Address (GNA) :

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

Paired SNPA Address Length Indicator (PSAL)

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

: Paired SNPA Address (PSA) :

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

GNAL

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

: GNA

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

PSAL

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

: PSA :

m-1

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

m

: Options :

p-1

'----------------------------------------------------'

Figure 2 - ESGH PDU Format

6.12.11 Multicast Address Mapping (MAM) PDU

The MAM PDU has the format shown in figure 3:

Octet

,----------------------------------------------------,

Network Layer Protocol Identifier 1

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

Length Indicator 2

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

Version/Protocol ID Extension 3

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

reserved (must be zero) 4

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

0 0 0 Type (00111 = MAM) 2

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

Holding Time 6,7

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

Checksum 8,9

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

Number of Group Address Pairs 10

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

Group Network Address Length Indicator (GNAL) 11

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

12

: Group Network Address (GNA) :

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

Paired SNPA Address Length Indicator (PSAL)

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

: Paired SNPA Address (PSA) :

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

GNAL

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

: GNA :

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

PSAL

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

: PSA :

m-1

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

m

: Options :

p-1

'----------------------------------------------------'

Figure 3 - MAM PDU Format

6.13 Conformance

All of the extensions provided to the functions to support multicast

capability are optional. For an End System or Intermediate System

which is not multicast capable these extensions are not applicable. A

Network entity may choose to be multicast capable, a multicast

capable Network entity is required to support both multicast

announcement information and multicast address mapping information.

An implementation claiming conformance as a multicast capable End

System shall meet all of the requirements for an End System which is

not multicast capable and shall support multicast announcement

information and shall implement the functions marked as Mandatory (M)

in column 4 of table 3. A multicast capable End System implementation

shall also support multicast address mapping information and shall

implement the functions marked as Mandatory (M) in column 5 of table

3.

An implementation claiming conformance as a multicast capable

Intermediate System shall meet all of the requirements for an

Intermediate System which is not multicast capable and shall support

multicast announcement information and shall implement the functions

marked as Mandatory (M) in column 6 of table 3. A multicast capable

Intermediate System implementation shall also support multicast

address mapping information and shall implement the functions marked

as Mandatory (M) in column 7 of table 3.

Table 3 - Static Conformance Requirements for Multicast Capable

Network Entities

ES IS

Clause --------------

Label Function Reference AI MI AI MI

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

RpMAn Report Multicast Announcement 6.7.1 M - - -

RcMAn Record Multicast Announcement 6.7.2.1 - - M -

RcDamp Record Damping 6.7.2.2 O - - -

FlMAn Flush Old Multicast Announcement 6.7.3 O - M -

RpMAdMa Report Multicast Address Mapping 6.8.1 - - - M

MATGn ESMAT Generation 6.8.1 - - - M

RcMAdMa Record Multicast Address Mapping 6.8.2 - M - -

MATPr ESMAT Processing 6.8.2 - M - -

FlMAdMa Flush Old Multicast Address Map 6.8.3 - M - -

PSAdSel Paired SNPA Address Selection 6.9.1 - M - -

ExtForw Extensions to CLNP Route Function 6.10 - M - -

OSuForw Originating Subnetwork Forwarding 6.11 - - - M

Key:

AI = Multicast Announcement information supported

MI = Multicast Address Mapping information supported

M = Mandatory; O = Optional; - = not applicable

7. Security Considerations

Security issues are not discussed in this memo.

Appendix A. Differences with RFC1112

This appendix is intended to identify differences between the

mechanisms defined for CLNP Multicast in this specification and those

for IP multicast defined in RFC1112. The work on CLNP Multicast

followed the work on IP multicast and was explicitly aimed at

bringing the capabilities described in RFC1112 into a CLNP context.

This appendix is intended to provide some background information on

the difference; however, it is not intended to justify the mechanisms

selected for CLNP multicast use.

Static/Dynamic Address Binding of Multicast Datagrams

IP multicast utilizes a static binding of Class D IP addresses to a

specific range of IEEE 802 48 bit group addresses. The IEEE 802

address range that is used is within the address range that IEEE 802

allocates for "Global" administration and this block of addresses is

under the control of the Internet Assigned Numbers Authority (IANA)

which in turn has allocated this block of addresses for use by IP

multicast. This scheme is very simple and efficient. Given the use

of a 32 bit IP address, the lower 23 bits of the Class D address are

mapped into the lower 23 bits of a 48 bit IEEE 802 address where the

upper 25 bits are fixed. Static binding of this form is global in

scope (all members of a group use the same IEEE 802 address on all

subnets (at least all that use IEEE 802 addressing).

CLNP multicast uses a dynamic binding of a group Network address (up

to 20 bytes) to any subnetwork address. In cases where no multicast

capable Intermediate Systems are attached to a subnetwork then a

binding using preconfigured information or the "All Multicast Capable

End Systems" subnetwork addresses is used. The large GNA provides the

room to contain a full 48 bit IEEE 802 address if desired. Mask

capabilities are optionally provided which allow a multicast capable

Intermediate System to specify a "static" binding for a particular

subnetwork. One of the major purposes of providing a dynamic binding

is to customize a host's subnetwork address usage to the capabilities

of the attached systems. There is considerable differences in the

numbers of group subnetwork addresses that a system can recognize

using hardware hooks built into the integrated circuits used. For

example the number of addresses that can be recognized by hardware

may differ by an attached system depending upon the interface it uses

(e.g., Ethernet interface and FDDI within the same system may have

quite different capabilities). Dynamic binding of this form is local

in scope (members of a group may use different subnetwork addresses

(e.g., IEEE 802 addresses) on different subnets).

Originating of Multicast Datagrams

IP multicast originates multicast datagrams directly, where the host

originating a datagram sends it with the group Subnetwork address as

its destination. Hosts attached to the network where the datagram is

originated receive the datagram directly.

CLNP multicast originates multicast datagrams directly using the

group's subnetwork address as its destination when multicast address

mapping information is available. This case occurs when a multicast

capable Intermediate System is attached to the subnetwork and a host

on the subnetwork is announcing an interest in multicast packets

identified by a particular group Network address. The Active

Multicast IS may use MAM PDU mask parameters to provide multicast

address mapping information for a large number of group Network

addresses. When there is no multicast address mapping information for

the particular group Network address on a subnetwork with a multicast

capable IS attached to it, hosts originate packets using such

addresses sends to the "All Multicast Capable Intermediate Systems"

SNPA address. This case occurs when there are no receivers of such

multicast packets on the originating subnetwork. When a multicast

capable Intermediate System is not attached to a subnetwork, the End

System may utilize either preconfigured information (which might be a

direct mapping from a portion of the group Network address) or use

the "All Multicast Capable End Systems" address.

Address Binding of Control Packets

IP multicast sends the control packets related to the IGMP protocol

on the same subnetwork address that is used by the multicast data

traffic.

CLNP multicast sends the control packets related to the ES-IS

protocol extensions on specific group subnetwork addresses (i.e.,

"All Multicast Capable End Systems" and "All Multicast Announcements"

addresses).

Router Requirements for relaying Multicast Datagrams

IP multicast requires that a multicast router run in "promiscuous"

mode where it must receive all multicast datagrams originated on a

subnetwork regardless of the destination. This is a result of the

choices selected in the "Originating of Multicast Datagrams" and

"Address Binding of Control Packets" discussed above.

CLNP multicast allows a multicast router to limit multicast packet

reception to only those datagrams sent to the SNPA addresses where

there is current multicast address mapping information or to the "All

Multicast Capable Intermediate Systems" address. The intention is to

allow the multicast routers to be in control of the SNPA addresses

for multicast packets that they need to receive. This is a result of

the choices selected in the "Originating of Multicast Datagrams" and

"Address Binding of Control Packets" discussed above.

Aggregation of Control Information

In IP multicast, a host is required to withhold an announcement

report upon hearing another host reporting a similar interest in a

particular Class D address on a particular subnetwork. This is an

option for CLNP multicast (upon hearing interest in a particular

group Network address on a particular subnetwork). Such reports are

not combined in IP multicast while CLNP multicast supports providing

multiple announcements (and address mappings) within a single packet.

A mask feature for address mappings supports identifying mappings for

a range of group Network addresses within a single control packet.

Datagram Scope Control

IP multicast supports the use of the IP Hop Count as a means to

support scope control. While not documented in RFC1112, a technique

is also being used to use bits within the Class D address to identify

whether a datagram has single subnetwork, "campus" or global scope.

CLNP has considerable scope control functionality. While the PDU

Lifetime field can be employed in a similar way to the IP Hop Count,

two additional options are available. The Radius scope control

provides a mechanism for "administratively" setting distance values

and de-couples the multicast scope control from the PDU lifetime

function. More importantly, the Prefix based scope control appears to

provide considerable and flexible functionality that can adjust to

situations where a known, hierarchical unicast addressing structure

exists.

Marking of Multicast Datagrams

IP multicast marks a multicast PDU via the use of an IP Class D

address as its destination address parameter. CLNP multicast marks

both the PDU (a different PDU type) and the destination address

(i.e., group Network address) parameter.

Unicast Addressing Differences

An IP address identifies a specific host interface while a CLNP

individual Network address (i.e., NSAP address) identifies a

particular Network entity. This difference has lead to a difference

with RFC1112. IP multicast requires a host which is attached to

more than one subnetwork to originate a multicast packet on only one

subnetwork. CLNP multicast requires a host which is attached to more

than one subnetwork to originate a multicast packet on every

subnetwork that the ISO ES-IS Configuration function is reporting the

NSAP address contained in the source address parameter of the

multicast PDU.

Error Reports

Error reports sent in response to receiving a multicast PDU are not

permitted in IP multicast while they are permitted in CLNP multicast.

Source Routing

Source routing of multicast PDUs are permitted in IP multicast (but

at the present time this is discouraged) while they are not permitted

in CLNP multicast.

Appendix B. Issues Under Study

This appendix is intended to record the current issues (as discussed

at the March 1994 TUBA meeting).

1. Local versus Global address bindings

The extensions to the ES-IS protocol provide a multicast address

mapping function which supports dynamically binding a group Network

address to a subnetwork address. Concern has been expressed that

this is an unnecessary feature which complicates the job of network

administrators without suitable benefit. A static, global binding of

group Network addresses to IEEE 802 subnetwork addresses, as is used

by IP multicast has been suggested.

The two main reasons that the group Network address to subnetwork

(IEEE 802) address was made locally configurable were to support

multicast on subnets with hosts having a mixture of capabilities (as

to how many multicast subnetwork addresses a host could register to

receive at a time) and to support multicast on subnets that do not

use 48 bit IEEE 802 addresses. Thus it was felt that this should be

done per subnetwork versus globally. Even multi-homed hosts with

subnets that use 802 addresses may have varying capabilities (looking

at typical Ethernet, FDDI and 802.5 implementations).

One possible solution is to recommend a direct mapping in any

Internet use of CLNP multicast on subnets which use IEEE 802

addressing. This could be a default for all Internet hosts. A

policy would be needed to identify the Internet's group Network

address format. Given such a mapping the only operational overhead

that would occur is that in the presence of a mapping server (the

Active Multicast IS), which was supporting this mapping, a MAM PDU

would periodically be sent with a Group Network Address Mask which

would identify the direct mapping.

2. "Real Time" Scope Control Features

The scope control features are provided via optional parameters. Use

of multicast transfer of audio and video streams may require scope

control mechanisms which operate very quickly.

One possible solution is to embed scope control mechanisms into the

group Network address itself. For example, a group Network address

using the "Local" AFI is automatically limited to not cross inter-

domain borders. Further, more flexible, address formats may be

developed.

References

[Deering91] Deering, S., "Multicast Routing in a Datagram

Internetwork", PhD thesis, Electrical Engineering Dept., Stanford

University, December 1991.

[RFC1112] Deering, S., "Host Extensions for IP Multicasting",

STD 5, RFC1112, Stanford University, August 1989.

[RFC1237] Colella, R., Gardner, E., and R. Callon, "Guidelines for OSI

NSAP Allocation in the Internet", RFC1237, NIST, Mitre, DEC, July

1991.

[CLNP] Protocol for providing the connectionless-mode network service,

International Standard 8473-1, Second Edition, ISO/IEC JTC 1,

Switzerland 1994. (Available via FTP from

merit.edu:pub/iso/iso8473part1.ps).

[ES-IS] End system to Intermediate system routing exchange protocol

for use in conjunction with the Protocol for providing the

connectionless-mode network service, International Standard 9542,

ISO/IEC JTC 1, Switzerland 1987. (Available via FTP from

merit.edu:pub/iso/iso9542.ps).

[MULT-AMDS]: Amendments to ISO standards to support CLNP multicast

extensions:

ISO 8348 AM5 Amendment to the Network Service to support Group Network

Addressing. International Standard ISO 8348 Amendment 5, ISO/IEC JTC

1, Switzerland 1994.

ISO 8473-1 DAM1 - Draft Amendment to the Second Edition of the

Protocol for providing the connectionless-mode network service [CLNP],

Multicast Extension, 1993.

ISO 9542 DAM2 - Draft Amendment to the ES-IS [ES-IS] protocol,

Addition of connectionless- mode multicast capability, 1993.

Author's Address

Dave Marlow

Code B35

NSWC-DD

Dahlgren, VA. 22448

Phone: (703) 663-1675

 
 
 
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