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RFC1717 - The PPP Multilink Protocol (MP)

王朝other·作者佚名  2008-05-31
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Network Working Group K. Sklower

Request for Comments: 1717 University of California, Berkeley

Category: Standards Track B. Lloyd

G. McGregor

Lloyd Internetworking

D. Carr

Newbridge Networks Corporation

November 1994

The PPP Multilink Protocol (MP)

Status of This Memo

This document specifies an Internet standards track protocol for the

Internet community, and requests discussion and suggestions for

improvements. Please refer to the current edition of the "Internet

Official Protocol Standards" (STD 1) for the standardization state

and status of this protocol. Distribution of this memo is unlimited.

Abstract

This document proposes a method for splitting, recombining and

sequencing datagrams across multiple logical data links. This work

was originally motivated by the desire to eXPloit multiple bearer

channels in ISDN, but is equally applicable to any situation in which

multiple PPP links connect two systems, including async links. This

is accomplished by means of new PPP [2] options and protocols.

Acknowledgements

The authors specifically wish to thank Fred Baker of ACC, Craig Fox

of Network Systems, Gerry Meyer of Spider Systems, Tom Coradetti of

Digiboard (for the Endpoint Discriminator option), Dan Brennan of

Penril Datability Networks, Vernon Schryver of SGI (for the

comprehensive discussion of padding), and the members of the IP over

Large Public Data Networks and PPP Extensions working groups, for

mUCh useful discussion on the subject.

Table of Contents

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

1.1. Motivation ................................................ 2

1.2. Functional Description .................................... 3

1.3. Conventions ............................................... 3

2. General Overview ............................................ 4

3. Packet Formats .............................................. 6

3.1. Padding Considerations .................................... 9

4. Trading Buffer Space Against Fragment Loss .................. 9

4.1. Detecting Fragment Loss ................................... 10

4.2. Buffer Space Requirements ................................. 11

5. PPP Link Control Protocol Extensions ........................ 12

5.1. Configuration Option Types ................................ 12

5.1.1. Multilink MRRU LCP option ............................... 13

5.1.2. Short Sequence Number Header Format Option .............. 13

5.1.3. Endpoint Discriminator Option ........................... 14

6. Closing Member links ........................................ 18

7. Interaction with Other Protocols ............................ 19

8. Security Considerations ..................................... 19

9. References .................................................. 20

10. Authors' Addresses ......................................... 21

1. Introduction

1.1. Motivation

Basic Rate and Primary Rate ISDN both offer the possibility of

opening multiple simultaneous channels between systems, giving users

additional bandwidth on demand (for additional cost). Previous

proposals for the transmission of internet protocols over ISDN have

stated as a goal the ability to make use of this capability, (e.g.,

Leifer et al., [1]).

There are proposals being advanced for providing synchronization

between multiple streams at the bit level (the BONDING proposals);

such features are not as yet widely deployed, and may require

additional hardware for end system. Thus, it may be useful to have a

purely software solution, or at least an interim measure.

There are other instances where bandwidth on demand can be exploited,

such as using a dialup async line at 28,800 baud to back up a leased

synchronous line, or opening additional X.25 SVCs where the window

size is limited to two by international agreement.

The simplest possible algorithms of alternating packets between

channels on a space available basis (which might be called the Bank

Teller's algorithm) may have undesirable side effects due to

reordering of packets.

By means of a four-byte sequencing header, and simple synchronization

rules, one can split packets among parallel virtual circuits between

systems in such a way that packets do not become reordered, or at

least the likelihood of this is greatly reduced.

1.2. Functional Description

The method discussed here is similar to the multilink protocol

described in ISO 7776 [4], but offers the additional ability to split

and recombine packets, thereby reducing latency, and potentially

increase the effective maximum receive unit (MRU). Furthermore,

there is no requirement here for acknowledged-mode operation on the

link layer, although that is optionally permitted.

Multilink is based on an LCP option negotiation that permits a system

to indicate to its peer that it is capable of combining multiple

physical links into a "bundle". Only under exceptional conditions

would a given pair of systems require the operation of more than one

bundle connecting them.

Multilink is negotiated during the initial LCP option negotiation. A

system indicates to its peer that it is willing to do multilink by

sending the multilink option as part of the initial LCP option

negotiation. This negotiation indicates three things:

1. The system offering the option is capable of combining

multiple physical links into one logical link;

2. The system is capable of receiving upper layer protocol data

units (PDU) fragmented using the multilink header (described

later) and reassembling the fragments back into the original

PDU for processing;

3. The system is capable of receiving PDUs of size N octets

where N is specified as part of the option even if N is larger

than the maximum receive unit (MRU) for a single physical

link.

Once multilink has been successfully negotiated, the sending system

is free to send PDUs encapsulated and/or fragmented with the

multilink header.

1.3. Conventions

The following language conventions are used in the items of

specification in this document:

o MUST, SHALL or MANDATORY -- the item is an absolute requirement

of the specification.

o SHOULD or RECOMMENDED -- the item should generally be followed

for all but exceptional circumstances.

o MAY or OPTIONAL -- the item is truly optional and may be

followed or ignored according to the needs of the implementor.

2. General Overview

In order to establish communications over a point-to-point link, each

end of the PPP link must first send LCP packets to configure the data

link during Link Establishment phase. After the link has been

established, PPP provides for an Authentication phase in which the

authentication protocols can be used to determine identifiers

associated with each system connected by the link.

The goal of multilink operation is to coordinate multiple independent

links between a fixed pair of systems, providing a virtual link with

greater bandwidth than any of the constituent members. The aggregate

link, or bundle, is named by the pair of identifiers for two systems

connected by the multiple links. A system identifier may include

information provided by PPP Authentication [3] and information

provided by LCP negotiation. The bundled links can be different

physical links, as in multiple async lines, but may also be instances

of multiplexed links, such as ISDN, X.25 or Frame Relay. The links

may also be of different kinds, such as pairing dialup async links

with leased synchronous links.

We suggest that multilink operation can be modeled as a virtual PPP

link-layer entity wherein packets received over different physical

link-layer entities are identified as belonging to a separate PPP

network protocol (the Multilink Protocol, or MP) and recombined and

sequenced according to information present in a multilink

fragmentation header. All packets received over links identified as

belonging to the multilink arrangement are presented to the same

network-layer protocol processing machine, whether they have

multilink headers or not.

The packets to be transmitted using the multilink procedure are

encapsulated according to the rules for PPP where the following

options would have been manually configured:

o No async control character Map

o No Magic Number

o No Link Quality Monitoring

o Address and Control Field Compression

o Protocol Field Compression

o No Compound Frames

o No Self-Describing-Padding

Of course, individual links are permitted to have different settings

for these options. As described below, member links SHOULD negotiate

Self-Describing-Padding, even though pre-fragmented packets MUST NOT

be padded.

LCP negotiations are not permitted on the bundle itself. An

implementation MUST NOT transmit LCP Configure-Request, -Reject,

-Ack, -Nak, Terminate-Request or -Ack packets via the multilink

procedure, and an implementation receiving them MUST silently discard

them. (By "silently discard" we mean to not generate any PPP packets

in response; an implementation is free to generate a log entry

registering the reception of the unexpected packet). By contrast,

other LCP packets having control functions not associated with

changing the defaults for the bundle itself are permitted. An

implementation MAY transmit LCP Code-Reject, Protocol-Reject, Echo-

Request, Echo-Reply and Discard-Request Packets.

The effective MRU for the logical-link entity is negotiated via an

LCP option. It is irrelevant whether Network Control Protocol

packets are encapsulated in multilink headers or not, or even over

which link they are sent, once that link identifies itself as

belonging to a multilink arrangement.

Note that network protocols that are not sent using multilink headers

cannot be sequenced. (And consequently will be delivered in any

convenient way).

For example, consider the case in Figure 1. Link 1 has negotiated

network layers NL 1, NL 2, and MP between two systems. The two

systems then negotiate MP over Link 2.

Frames received on link 1 are demultiplexed at the data link layer

according the PPP network protocol identifier and can be sent to NL

1, NL 2, or MP. Link 2 will accept frames with all network protocol

identifiers that Link 1 does.

Frames received by MP are further demultiplexed at the network layer

according to the PPP network protocol identifier and sent to NL 1 or

NL 2. Any frames received by MP for any other network layer

protocols are rejected using the normal protocol reject mechanism.

Figure 1. Multilink Overview.

Network Layer

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

______ ______

/ \ / NL 1 NL 2

\______/ \______/

+-------------o-o-o-+

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

+------o--o-------+ +

___

/ \

MLCP <--- Link Layer

\______/ Demultiplexing

<--- Virtual Link

+

____ ____

/ \ / LCP ------+----- LCP <--- Link Layer

\______/ \______/ Demultiplexing

Link 1 Link 2

3. Packet Formats

In this section we describe the layout of individual fragments, which

are the "packets" in the Multilink Protocol. Network Protocol

packets are first encapsulated (but not framed) according to normal

PPP procedures, and large packets are broken up into multiple

segments sized appropriately for the multiple physical links. A new

PPP header consisting of the Multilink Protocol Identifier, and the

Multilink header is inserted before each section. (Thus the first

fragment of a multilink packet in PPP will have two headers, one for

the fragment, followed by the header for the packet itself).

Systems implementing the multilink procedure are not required to

fragment small packets. There is also no requirement that the

segments be of equal sizes, or that packets must be broken up at all.

A possible strategy for contending with member links of differing

transmission rates would be to divide the packets into segments

proportion to the transmission rates. Another strategy might be to

divide them into many equal fragments and distribute multiple

fragments per link, the numbers being proportional to the relative

speeds of the links.

PPP multilink fragments are encapsulated using the protocol

identifier 0x00-0x3d. Following the protocol identifier is a four

byte header containing a sequence number, and two one bit fields

indicating that the fragment begins a packet or terminates a packet.

After negotiation of an additional PPP LCP option, the four byte

header may be optionally replaced by a two byte header with only a 12

bit sequence space. Address & Control and Protocol ID compression

are assumed to be in effect. Individual fragments will, therefore,

have the following format:

Figure 2: Long Sequence Number Fragment Format.

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

PPP Header: Address 0xff Control 0x03

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

PID(H) 0x00 PID(L) 0x3d

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

MP Header: BE000000sequence number

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

sequence number (L)

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

fragment data

.

.

.

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

PPP FCS: FCS

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

Figure 3: Short Sequence Number Fragment Format.

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

PPP Header: Address 0xff Control 0x03

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

PID(H) 0x00 PID(L) 0x3d

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

MP Header: BE00 sequence number

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

fragment data

.

.

.

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

PPP FCS: FCS

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

The (B)eginning fragment bit is a one bit field set to 1 on the first

fragment derived from a PPP packet and set to 0 for all other

fragments from the same PPP packet.

The (E)nding fragment bit is a one bit field set to 1 on the last

fragment and set to 0 for all other fragments. A fragment may have

both the (B)eginning and (E)nding fragment bits set to 1.

The sequence field is a 24 bit or 12 bit number that is incremented

for every fragment transmitted. By default, the sequence field is 24

bits long, but can be negotiated to be only 12 bits with an LCP

configuration option described below.

Between the (E)nding fragment bit and the sequence number is a

reserved field, whose use is not currently defined, which MUST be set

to zero. It is 2 bits long when the use of short sequence numbers

has been negotiated, 6 bits otherwise.

In this multilink protocol, a single reassembly structure is

associated with the bundle. The multilink headers are interpreted in

the context of this structure.

The FCS field shown in the diagram is inherited from the normal

framing mechanism from the member link on which the packet is

transmitted. There is no separate FCS applied to the reconstituted

packet as a whole if transmitted in more than one fragment.

3.1. Padding Considerations

Systems that support the multilink protocol SHOULD implement Self-

Describing-Padding. A system that implements self-describing-padding

by definition will either include the padding option in its initial

LCP Configure-Requests, or (to avoid the delay of a Configure-Reject)

include the padding option after receiving a NAK containing the

option.

A system that must pad its own transmissions but does not use Self-

Describing-Padding when not using multilink, MAY continue to not use

Self-Describing-Padding if it ensures by careful choice of fragment

lengths that only (E)nding fragments of packets are padded. A system

MUST NOT add padding to any packet that cannot be recognized as

padded by the peer. Non-terminal fragments MUST NOT be padded with

trailing material by any other method than Self-Describing-Padding.

A system MUST ensure that Self-Describing-Padding as described in RFC

1570 [11] is negotiated on the individual link before transmitting

any multilink data packets if it might pad non-terminal fragments or

if it would use network or compression protocols that are vulnerable

to padding, as described in RFC1570. If necessary, the system that

adds padding MUST use LCP Configure-NAK's to elicit a Configure-

Request for Self-Describing-Padding from the peer.

Note that LCP Configure-Requests can be sent at any time on any link,

and that the peer will always respond with a Configure-Request of its

own. A system that pads its transmissions but uses no protocols

other than multilink that are vulnerable to padding MAY delay

ensuring that the peer has Configure-Requested Self-Describing-

Padding until it seems desireable to negotiate the use of Multilink

itself. This permits the interoperability of a system that pads with

older peers that support neither Multilink nor Self-Describing-

Padding.

4. Trading Buffer Space Against Fragment Loss

In a multilink procedure one channel may be delayed with respect to

the other channels in the bundle. This can lead to fragments being

received out of order, thus increasing the difficulty in detecting

the loss of a fragment. The task of estimating the amount of space

required for buffering on the receiver becomes more complex because

of this. In this section we discuss a technique for declaring that a

fragment is lost, with the intent of minimizing the buffer space

required, yet minimizing the number of avoidable packet losses.

4.1. Detecting Fragment Loss

On each member link in a bundle, the sender MUST transmit fragments

with strictly increasing sequence numbers (modulo the size of the

sequence space). This requirement supports a strategy for the

receiver to detect lost fragments based on comparing sequence

numbers. The sequence number is not reset upon each new PPP packet,

and a sequence number is consumed even for those fragments which

contain an entire PPP packet, i.e., one in which both the (B)eginning

and (E)nding bits are set.

An implementation MUST set the sequence number of the first fragment

transmited on a newly-constructed bundle to zero. (Joining a

secondary link to an exisiting bundle is invisible to the protocol,

and an implementation MUST NOT reset the sequence number space in

this situation).

The receiver keeps track of the incoming sequence numbers on each

link in a bundle and maintains the current minimum of the most

recently received sequence number over all the member links in the

bundle (call this M). The receiver detects the end of a packet when

it receives a fragment bearing the (E)nding bit. Reassembly of the

packet is complete if all sequence numbers up to that fragment have

been received.

A lost fragment is detected when M advances past the sequence number

of a fragment bearing an (E)nding bit of a packet which has not been

completely reassembled (i.e., not all the sequence numbers between

the fragment bearing the (B)eginning bit and the fragment bearing the

(E)nding bit have been received). This is because of the increasing

sequence number rule over the bundle.

An implementation MUST assume that if a fragment bears a (B)eginning

bit, that the previously numbered fragment bore an (E)nding bit.

Thus if a packet is lost bearing the (E)nding bit, and the packet

whose fragment number is M contains a (B)eginning bit, the

implementation MUST discard fragments for all unassembled packets

through M-1, but SHOULD NOT discard the fragment bearing the new

(B)eginning bit on this basis alone.

The detection of a lost fragment causes the receiver to discard all

fragments up to M. If the fragment with sequence number M has the

(B)eginning bit set then the receiver starts reassembling the new

packet, otherwise the receiver resynchronizes on the next fragment

bearing the (B)eginning bit. All fragments received while the

receiver is attempting to resynchronize not bearing the (B)eginning

bit SHOULD be discarded.

Fragments may be lost due to corruption of individual packets or

catastrophic loss of the link (which may occur only in one

direction). This version of the multilink protocol mandates no

specific procedures for the detection of failed links. The PPP link

quality management facility, or the periodic issuance of LCP echo-

requests could be used to achieve this.

Senders SHOULD avoid keeping any member links idle to maximize early

detection of lost fragments by the receiver, since the value of M is

not incremented on idle links. Senders SHOULD rotate traffic among

the member links if there isn't sufficient traffic to overflow the

capacity of one link to avoid idle links.

Loss of the final fragment of a transmission can cause the receiver

to stall until new packets arrive. The likelihood of this may be

decreased by sending a null fragment on each member link in a bundle

that would otherwise become idle immediately after having transmitted

a fragment bearing the (E)nding bit, where a null fragment is one

consisting only of a multilink header bearing both the (B)egin and

(E)nding bits (i.e., having no payload). Implementations concerned

about either wasting bandwidth or per packet costs are not required

to send null fragments and may elect to defer sending them until a

timer expires, with the marginally increased possibility of lengthier

stalls in the receiver. The receiver SHOULD implement some type of

link idle timer to guard against indefinite stalls.

The increasing sequence per link rule prohibits the reallocation of

fragments queued up behind a failing link to a working one, a

practice which is not unusual for implementations of ISO multilink

over LAPB [4].

4.2. Buffer Space Requirements

There is no amount of buffering that will guarantee correct detection

of fragment loss, since an adversarial peer may withhold a fragment

on one channel and send arbitrary amounts on the others. For the

usual case where all channels are transmitting, you can show that

there is a minimum amount below which you could not correctly detect

packet loss. The amount depends on the relative delay between the

channels, (D[channel-i,channel-j]), the data rate of each channel,

R[c], the maximum fragment size permitted on each channel, F[c], and

the total amount of buffering the transmitter has allocated amongst

the channels.

When using PPP, the delay between channels could be estimated by

using LCP echo request and echo reply packets. (In the case of links

of different transmission rates, the round trip times should be

adjusted to take this into account.) The slippage for each channel

is defined as the bandwidth times the delay for that channel relative

to the channel with the longest delay, S[c] = R[c] * D[c,c-worst].

(S[c-worst] will be zero, of course!)

A situation which would exacerbate sequence number skew would be one

in which there is extremely bursty traffic (almost allowing all

channels to drain), and then where the transmitter would first queue

up as many consecutively numbered packets on one link as it could,

then queue up the next batch on a second link, and so on. Since

transmitters must be able to buffer at least a maximum- sized

fragment for each link (and will usually buffer up at least two) A

receiver that allocates any less than S[1] + S[2] + ... + S[N] + F[1]

+ ... + F[N], will be at risk for incorrectly assuming packet loss,

and therefore, SHOULD allocate at least twice that.

5. PPP Link Control Protocol Extensions

If reliable multilink operation is desired, PPP Reliable Transmission

[6] (essentially the use of ISO LAPB) MUST be negotiated prior to the

use of the Multilink Protocol on each member link.

Whether or not reliable delivery is employed over member links, an

implementation MUST present a signal to the NCP's running over the

multilink arrangement that a loss has occurred.

Compression may be used separately on each member link, or run over

the bundle (as a logical group link). The use of multiple

compression streams under the bundle (i.e., on each link separately)

is indicated by running the Compression Control Protocol [5] but with

an alternative PPP protocol ID.

5.1. Configuration Option Types

The Multilink Protocol introduces the use of additional LCP

Configuration Options:

o Multilink Maximum Received Reconstructed Unit

o Multilink Short Sequence Number Header Format

o Endpoint Discriminator

5.1.1. Multilink MRRU LCP option

Figure 4: Multilink MRRU LCP option

0 1 2 3

0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1

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

Type = 17 Length = 4 Max-Receive-Reconstructed-Unit

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

The presence of this option indicates that the system sending it

implements the PPP Multilink Protocol, and unless rejected, will

construe all packets receive on this link as being able to be

processed by a common protocol machine with any other packets

received from the same peer on any other link on which this option

has been accepted. A system MUST NOT accept the Multilink MRRU LCP

Option if it is not willing to symmetrically have the packets it

sends interpreted in the same fashion.

This option also advises the peer that the implementation will be

able to reconstruct a PPP packet whose payload will contain the

number of bytes as Max-Receive-Reconstructed-Unit.

A system MAY indicate the desire to conduct multilink operation

solely by use of the Multilink Short Sequence Number Header Format

LCP option (discussed next); the default value for MRRU option is

1600 bytes if not otherwise explicitly negotiated.

Note: this option corresponds to what would have been the MRU of the

bundle when conceptualized as a PPP-like entity.

5.1.2. Short Sequence Number Header Format Option

Figure 5: Short Sequence Number Header Format Option

0 1

0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5

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

Type = 18 Length = 2

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

This option advises the peer that the implementation wishes to

receive fragments with short, 12 bit sequence numbers. By default

sequence, numbers are 24 bits long. When this option is received, an

implementation MUST either transmit all subsequent multilink packets

on all links of the bundle with 12 bit sequence numbers or

configure-NAK or configure-Reject the option.

An implementation wishing to transmit multilink fragments with short

sequence numbers MAY include the multilink short sequence number in a

configure-NAK to ask that the peer respond with a request to receive

short sequence numbers. The peer is not compelled to respond with

the option.

5.1.3. Endpoint Discriminator Option

Figure 7: Endpoint Discriminator Option

0 1 2 3

0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1

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

Type = 19 Length Class Address ...

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

The Endpoint Discriminator Option represents identification of the

system transmitting the packet. This option advises a system that

the peer on this link could be the same as the peer on another

existing link. If the option distinguishes this peer from all

others, a new bundle MUST be established from the link being

negotiated. If this option matches the class and address of some

other peer of an existing link, the new link MUST be joined to the

bundle containing the link to the matching peer or MUST establish a

new bundle, depending on the decision tree shown in (1) through (4)

below.

To securely join an existing bundle, a PPP authentication protocol

[3] must be used to oBTain authenticated information from the peer to

prevent a hostile peer from joining an existing bundle by presenting

a falsified discriminator option.

This option is not required for multilink operation. If a system

does not receive either of the Multilink MRRU or Short Sequence

options, but does receive the Endpoint Discriminator Option, and

there is no manual configuration providing outside information, the

implementation MUST NOT assume that multilink operation is being

requested on this basis alone.

As there is also no requirement for authentication, there are four

sets of scenarios:

(1) No authentication, no discriminator:

All new links MUST be joined to one bundle.

(2) Discriminator, no authentication:

Discriminator match -> MUST join matching bundle,

discriminator mismatch -> MUST establish new bundle.

(3) No discriminator, authentication:

Authenticated match -> MUST join matching bundle,

authenticated mismatch -> MUST establish new bundle.

(4) Discriminator, authentication:

Discriminator match and authenticated match -> MUST join bundle,

discriminator mismatch -> MUST establish new bundle,

authenticated mismatch -> MUST establish new bundle.

The option contains a Class which selects an identifier address space

and an Address which selects a unique identifier within the class

address space.

This identifier is expected to refer to the mechanical equipment

associated with the transmitting system. For some classes,

uniqueness of the identifier is global and is not bounded by the

scope of a particular administrative domain. Within each class,

uniqueness of address values is controlled by a class dependent

policy for assigning values.

Each endpoint may chose an identifier class without restriction.

Since the objective is to detect mismatches between endpoints

erroneously assumed to be alike, mismatch on class alone is

sufficient. Although no one class is recommended, classes which have

universally unique values are preferred.

This option is not required to be supported either by the system or

the peer. If the option is not present in a Configure-Request, the

system MUST NOT generate a Configure-Nak of this option, instead it

SHOULD behave as if it had received the option with Class = 0,

Address = 0. If a system receives a Configure-Nak or Configure-

Reject of this option, it MUST remove it from any additional

Configure-Request.

The size is determined from the Length field of the element. For

some classes, the length is fixed, for others the length is variable.

The option is invalid if the Length field indicates a size below the

minimum for the class.

An implementation MAY use the Endpoint Discriminator to locate

administration or authentication records in a local database. Such

use of this option is incidental to its purpose and is deprecated

when a PPP Authentication protocol [3] can be used instead. Since

some classes permit the peer to generate random or locally assigned

address values, use of this option as a database key requires prior

agreement between peer administrators.

The specification of the subfields are:

Type

19 = for Endpoint Discriminator

Length

3 + length of Address

Class

The Class field is one octet and indicates the identifier

address space. The most up-to-date values of the LCP Endpoint

Discriminator Class field are specified in the most recent

"Assigned Numbers" RFC[7]. Current values are assigned as

follows:

0 Null Class

1 Locally Assigned Address

2 Internet Protocol (IP) Address

3 IEEE 802.1 Globally Assigned MAC Address

4 PPP Magic-Number Block

5 Public Switched Network Directory Number

Address

The Address field is one or more octets and indicates the

identifier address within the selected class. The length and

content depend on the value of the Class as follows:

Class 0 - Null Class

Maximum Length: 0

Content:

This class is the default value if the option is not

present in a received Configure-Request.

Class 1 - Locally Assigned Address

Maximum Length: 20

Content:

This class is defined to permit a local assignment in the

case where use of one of the globally unique classes is not

possible. Use of a device serial number is suggested. The

use of this class is deprecated since uniqueness is not

guaranteed.

Class 2 - Internet Protocol (IP) Address

Fixed Length: 4

Content:

An address in this class contains an IP host address as

defined in [8].

Class 3 - IEEE 802.1 Globally Assigned MAC Address

Fixed Length: 6

Content:

An address in this class contains an IEEE 802.1 MAC address

in canonical (802.3) format [9]. The address MUST have the

global/local assignment bit clear and MUST have the

multicast/specific bit clear. Locally assigned MAC

addresses should be represented using Class 1.

Class 4 - PPP Magic-Number Block

Maximum Length: 20

Content:

This is not an address but a block of 1 to 5 concatenated

32 bit PPP Magic-Numbers as defined in [2]. This class

provides for automatic generation of a value likely but not

guaranteed to be unique. The same block MUST be used by an

endpoint continuously during any period in which at least

one link is in the LCP Open state. The use of this class

is deprecated.

Note that PPP Magic-Numbers are used in [2] to detect

unexpected loopbacks of a link from an endpoint to itself.

There is a small probability that two distinct endpoints

will generate matching magic-numbers. This probability is

geometrically reduced when the LCP negotiation is repeated

in search of the desired mismatch, if a peer can generate

uncorrelated magic-numbers.

As used here, magic-numbers are used to determine if two

links are in fact from the same peer endpoint or from two

distinct endpoints. The numbers always match when there is

one endpoint. There is a small probability that the

numbers will match even if there are two endpoints. To

achieve the same confidence that there is not a false match

as for LCP loopback detection, several uncorrelated magic-

numbers can be combined in one block.

Class 5 - Public Switched Network Directory Number

Maximum Length: 15

Content:

An address in this class contains an octet sequence as

defined by I.331 (E.164) representing an international

telephone directory number suitable for use to Access the

endpoint via the public switched telephone network [10].

6. Closing Member links

Member links may be terminated according to normal PPP LCP procedures

using LCP terminate-request and terminate-ack packets on that member

link. Since it is assumed that member links usually do not reorder

packets, receipt of a terminate ack is sufficient to assume that any

multilink protocol packets ahead of it are at no special risk of

loss.

Receipt of an LCP terminate-request on one link does not conclude the

procedure on the remaining links.

So long as any member links in the bundle are active, the PPP state

for the bundle persists as a separate entity.

If the multilink procedure is used in conjunction with PPP reliable

transmission, and a member link is not closed gracefully, the

implementation should expect to receive packets which violate the

increasing sequence number rule.

7. Interaction with Other Protocols

In the common case, LCP, and the Authentication Control Protocol

would be negotiated over each member link. The Network Protocols

themselves and associated control exchanges would normally have been

conducted once, on the bundle.

In some instances it may be desirable for some Network Protocols to

be exempted from sequencing requirements, and if the MRU sizes of the

link did not cause fragmentation, those protocols could be sent

directly over the member links.

Although explicitly discouraged above, if there were several member

links connecting two implementations, and independent sequencing of

two protocol sets were desired, but blocking of one by the other was

not, one could describe two multilink procedures by assigning

multiple endpoint identifiers to a given system. Each member link,

however, would only belong to one bundle. One could think of a

physical router as housing two logically separate implementations,

each of which is independently configured.

A simpler solution would be to have one link refuse to join the

bundle, by sending a Configure-Reject in response to the Multilink

LCP option.

8. Security Considerations

Operation of this protocol is no more and no less secure than

operation of the PPP authentication protocols [3]. The reader is

directed there for further discussion.

9. References

[1] Leifer, D., Sheldon, S., and B. Gorsline "A Subnetwork Control

Protocol for ISDN Circuit-Switching", University of Michigan

(unpublished), March 1991.

[2] Simpson, W., Editor, "The Point-to-Point Protocol (PPP)", STD 51,

RFC1661, Daydreamer, July 1994.

[3] Lloyd, B., and W. Simpson, "PPP Authentication Protocols", RFC

1334, Lloyd Internetworking, Daydreamer, October 1992.

[4] International Organisation for Standardization, "HDLC -

Description of the X.25 LAPB-Compatible DTE Data Link

Procedures", International Standard 7776, 1988

[5] Rand, D., "The PPP Compression Control Protocol (CCP)", PPP

Extensions Working Group, Work in Progress.

[6] Rand, D., "PPP Reliable Transmission", PPP Extensions Working

Group, Work in Progress.

[7] Reynolds, J., and J. Postel, "Assigned Numbers", STD 2, RFC1700,

USC/Information Sciences Institute, October 1994.

[8] Postel, J., Editor, "Internet Protocol - DARPA Internet Program

Protocol Specification", STD 5, RFC791, USC/Information Sciences

Institute, September 1981.

[9] Institute of Electrical and Electronics Engineers, Inc., "IEEE

Local and Metropolitan Area Networks: Overview and Architecture",

IEEE Std. 802-1990, 1990.

[10] The International Telegraph and Telephone Consultative Committee

(CCITT), "Numbering Plan for the ISDN Area", Recommendation I.331

(E.164), 1988.

[11] Simpson, W., Editor, "PPP LCP Extensions", RFC1570, Daydreamer,

January 1994.

10. Authors' Addresses

Keith Sklower

Computer Science Department

384 Soda Hall, Mail Stop 1776

University of California

Berkeley, CA 94720-1776

Phone: (510) 642-9587

EMail: sklower@CS.Berkeley.EDU

Brian Lloyd

Lloyd Internetworking

3031 Alhambra Drive

Cameron Park, CA 95682

Phone: (916) 676-1147

EMail:

brian@lloyd.com

Glenn McGregor

Lloyd Internetworking

3031 Alhambra Drive

Cameron Park, CA 95682

Phone: (916) 676-1147

EMail: glenn@lloyd.com

Dave Carr

Newbridge Networks Corporation

600 March Road

P.O. Box 13600

Kanata, Ontario,

Canada, K2K 2E6

Phone: (613) 591-3600

EMail: dcarr@Newbridge.COM

 
 
 
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