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+Network Working Group K. Sklower
+Request for Comments: 1990 University of California, Berkeley
+Obsoletes: 1717 B. Lloyd
+Category: Standards Track G. McGregor
+ Lloyd Internetworking
+ D. Carr
+ Newbridge Networks Corporation
+ T. Coradetti
+ Sidewalk Software
+ August 1996
+
+
+ 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.
+
+ The differences between the current PPP Multilink specification (RFC
+ 1717) and this memo are explained in Section 11. Any system
+ implementing the additional restrictions required by this memo will
+ be backwards compatible with conforming RFC 1717 implementations.
+
+Acknowledgements
+
+ The authors specifically wish to thank Fred Baker of ACC, Craig Fox
+ of Network Systems, Gerry Meyer of Spider Systems, 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.
+
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 1]
+
+RFC 1990 PPP Multilink August 1996
+
+
+Table of Contents
+
+ 1. Introduction ................................................ 2
+ 1.1. Motivation ................................................ 2
+ 1.2. Functional Description .................................... 3
+ 1.3. Conventions ............................................... 4
+ 2. General Overview ............................................ 4
+ 3. Packet Formats .............................................. 7
+ 3.1. Padding Considerations .................................... 10
+ 4. Trading Buffer Space Against Fragment Loss .................. 10
+ 4.1. Detecting Fragment Loss ................................... 11
+ 4.2. Buffer Space Requirements ................................. 12
+ 5. PPP Link Control Protocol Extensions ........................ 13
+ 5.1. Configuration Option Types ................................ 13
+ 5.1.1. Multilink MRRU LCP option ............................... 14
+ 5.1.2. Short Sequence Number Header Format Option .............. 15
+ 5.1.3. Endpoint Discriminator Option ........................... 15
+ 6. Initiating use of Multilink Headers ......................... 19
+ 7. Closing Member links ........................................ 20
+ 8. Interaction with Other Protocols ............................ 20
+ 9. Security Considerations ..................................... 21
+ 10. References ................................................. 21
+ 11. Differences from RFC 1717 .................................. 22
+ 11.1. Negotiating Multilink, per se ............................ 22
+ 11.2. Initial Sequence Number defined .......................... 22
+ 11.3. Default Value of the MRRU ................................ 22
+ 11.4. Config-Nak of EID prohibited ............................. 22
+ 11.5. Uniformity of Sequence Space ............................. 22
+ 11.6. Commencing and Abating use of Multilink Headers .......... 23
+ 11.7. Manual Configuration and Bundle Assignment ............... 23
+ 12. Authors' Addresses ......................................... 24
+
+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.
+
+
+
+Sklower, et. al. Standards Track [Page 2]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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.
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 3]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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.
+
+
+
+Sklower, et. al. Standards Track [Page 4]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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
+
+ According to the rules specified in RFC1661, this means that an
+ implementation MUST accept reassembled packets with and without
+ leading zeroes present in the Protocol Field of the reassembled
+ packet. Although it is explicitly forbidden below to include the
+ Address and Control fields (usually, the two bytes FF 03) in the
+ material to be fragmented, it is a good defensive programming
+ practice to accept the packet anyway, ignoring the two bytes if
+ present, as that is what RFC1661 specifies.
+
+ As a courtesy to implementations that perform better when certain
+ alignment obtains, it is suggested that a determination be made when
+ a bundle is created on whether to transmit leading zeroes by
+ examining whether PFC has been negotiated on the first link admitted
+ into a bundle. This determination should be kept in force so long as
+ a bundle persists.
+
+ 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. Since the Protocol Field Compression mode on the member
+ link allows a sending system to include a leading byte of zero or not
+ at its discretion, this is an alternative mechanism for generating
+ even-length packets.
+
+ 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.
+
+
+
+
+Sklower, et. al. Standards Track [Page 5]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 6]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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.
+ Although it would otherwise be permitted by the PPP spec,
+ implementations MUST NOT include the Address and Control Field in the
+ logical entity to be fragmented. 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).
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 7]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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: |B|E|0|0|0|0|0|0|sequence number|
+ +-+-+-+-+-+-+-+-+---------------+
+ | sequence number (L) |
+ +---------------+---------------+
+ | fragment data |
+ | . |
+ | . |
+ | . |
+ +---------------+---------------+
+ PPP FCS: | FCS |
+ +---------------+---------------+
+
+
+
+
+
+
+
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 8]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ Figure 3: Short Sequence Number Fragment Format.
+
+
+ +---------------+---------------+
+ PPP Header: | Address 0xff | Control 0x03 |
+ +---------------+---------------+
+ | PID(H) 0x00 | PID(L) 0x3d |
+ +-+-+-+-+-------+---------------+
+ MP Header: |B|E|0|0| 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.
+
+
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 9]
+
+RFC 1990 PPP Multilink August 1996
+
+
+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 RFC 1570. 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.
+
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 10]
+
+RFC 1990 PPP Multilink August 1996
+
+
+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. Any sequence number so
+ detected is assumed to correspond to a fragment which has been lost.
+
+ 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, whose sequence number was deduced
+ to be U, causes the receiver to discard all fragments up to the
+ lowest numbered fragment with an ending bit (possibly deduced)
+ greater than or equal to U. However, the quantity M may jump into
+ the middle of a chain of packets which can be successful completed.
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 11]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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
+
+
+
+Sklower, et. al. Standards Track [Page 12]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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
+
+
+
+
+
+
+
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 13]
+
+RFC 1990 PPP Multilink August 1996
+
+
+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 LCP option indicates that the system sending it
+ implements the PPP Multilink Protocol. If not rejected, the system
+ will construe all packets received 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.
+
+ The Max-Receive-Reconstructed unit field is two octets, and specifies
+ the maximum number of octets in the Information fields of reassembled
+ packets. A system MUST be able to receive the full 1500 octet
+ Information field of any reassembled PPP packet although it MAY
+ attempt to negotiate a smaller, or larger value. The number 1500
+ here comes from the specification for the MRU LCP option in PPP; if
+ this requirement is changed in a future version of RFC 1661, the same
+ rules will apply here.
+
+ A system MUST include the LCP MRRU option in every LCP negotiation
+ intended to instantiate a bundle or to join an existing bundle. If
+ the LCP MRRU option is offered on a link which is intended to join an
+ existing bundle, a system MUST offer the same Max-Receive-
+ Reconstruct-Unit value previously negotiated for the bundle.
+
+ A system MUST NOT send any multilink packets on any link unless its
+ peer has offered the MMRU LCP option and the system has configure-
+ Ack'ed it during the most recent LCP negotiation on that link. A
+ system MAY include the MMRU LCP option in a configure-NAK, if its
+ peer has not offered it (until, according to PPP rules, the peer
+ configure-Reject's it).
+
+ Note: the MRRU value conveyed im this option corresponds to the MRU
+ of the bundle when conceptualized as a PPP entity; but the rules for
+ the Multilink MRRU option are different from the LCP MRU option, as
+ some value MUST be offered in every LCP negotiation, and that
+ confirmation of this option is required prior to multilink
+ interpretation.
+
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 14]
+
+RFC 1990 PPP Multilink August 1996
+
+
+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. When a peer
+ system configure-Ack's this option, it MUST transmit all multilink
+ packets on all links of the bundle with 12 bit sequence numbers or
+ configure-Reject the option. If 12 bit sequence numbers are desired,
+ this option MUST be negotiated when the bundle is instantiated, and
+ MUST be explicitly included in every LCP configure request offered by
+ a system when the system intends to include that link in an existing
+ bundle using 12 bit sequence numbers. If this option is never
+ negotiated during the life of a bundle, sequence numbers are 24 bits
+ long.
+
+ 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.
+
+
+
+Sklower, et. al. Standards Track [Page 15]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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 the Multilink MRRU option, 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, unless
+ there is manual configuration to the contrary.
+ It is also permissible to have more than one manually
+ configured bundle connecting two given systems.
+
+ (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
+
+
+
+Sklower, et. al. Standards Track [Page 16]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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 for any
+ reason; 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
+
+
+
+
+Sklower, et. al. Standards Track [Page 17]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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.
+
+
+
+
+Sklower, et. al. Standards Track [Page 18]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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. Initiating use of Multilink Headers
+
+ When the use of the Multilink protocol has been negotiated on a link
+ (say Y), and the link is being added to a bundle which currently
+ contains a single existing link (say X), a system MUST transmit a
+ Multilink-encapsulated packet on X before transmitting any Multilink-
+
+
+
+Sklower, et. al. Standards Track [Page 19]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ encapsulated packets on Y.
+
+ Since links may be added and removed from a bundle without destroying
+ the state associated with it, the fragment should be assigned the
+ appropriate (next) fragment number. As noted earlier, the first
+ fragment transmitted in the life of a bundle is assigned fragment
+ number 0.
+
+7. 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. However, if the there
+ is a unique link in the bundle, and all the other links were closed
+ gracefully (with Terminate-Ack), an implementation MAY cease using
+ multilink
+ headers.
+
+ 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.
+
+8. 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
+
+
+
+Sklower, et. al. Standards Track [Page 20]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ 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.
+
+9. 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.
+
+10. 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,
+ RFC 1661, 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, RFC 1962, June 1996.
+
+ [6] Rand, D., "PPP Reliable Transmission", RFC 1663, Novell, July
+ 1994
+
+ [7] Reynolds, J., and J. Postel, "Assigned Numbers", STD 2, RFC 1700,
+ USC/Information Sciences Institute, October 1994.
+
+ [8] Postel, J., Editor, "Internet Protocol - DARPA Internet Program
+ Protocol Specification", STD 5, RFC 791, 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.
+
+
+
+
+Sklower, et. al. Standards Track [Page 21]
+
+RFC 1990 PPP Multilink August 1996
+
+
+ [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", RFC 1570, Daydreamer,
+ January 1994.
+
+11. Differences from RFC 1717
+
+ This section documents differences from RFC 1717. There are
+ restrictions placed on implementations that were absent in RFC 1717;
+ systems obeying these restrictions are fully interoperable with RFC
+ 1717 - compliant systems.
+
+11.1. Negotiating Multilink, per se
+
+ RFC 1717 permitted either the use of the Short Sequence Number Header
+ Format (SSNHF) or the Maximum Reconstructed Receive Unit (MRRU)
+ options by themselves to indicate the intent to negotiate multilink.
+ This specification forbids the use of the SSNHF option by itself; but
+ does permit the specific of both options together. Any
+ implementation which otherwise conforms to rfc1717 and also obeys
+ this restriction will interoperate with any RFC 1717 implementation.
+
+11.2. Initial Sequence Number defined
+
+ This specification requires that the first sequence number
+ transmitted after the virtual link has reached to open state be 0.
+
+11.3. Default Value of the MRRU
+
+ This specfication removes the default value for the MRRU, (since it
+ must always be negotiated with some value), and specifies that an
+ implementation must be support an MRRU with same value as the default
+ MRU size for PPP.
+
+11.4. Config-Nak of EID prohibited
+
+ This specification forbids the config-Naking of an EID for any
+ reason.
+
+11.5. Uniformity of Sequence Space
+
+ This specification requires that the same sequence format be employed
+ on all links in a bundle.
+
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 22]
+
+RFC 1990 PPP Multilink August 1996
+
+
+11.6. Commencing and Abating use of Multilink Headers
+
+ This memo specifies how one should start the use of Multilink Headers
+ when a link is added, and under what circumstances it is safe to
+ discontinue their use.
+
+11.7. Manual Configuration and Bundle Assignment
+
+ The document explicitly permits multiple bundles to be manually
+ configured in the absence of both the Endpoint Descriminator and any
+ form of authentication.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Sklower, et. al. Standards Track [Page 23]
+
+RFC 1990 PPP Multilink August 1996
+
+
+13. 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
+
+
+ Tom Coradetti
+ Sidewalk Software
+ 1190 Josephine Road
+ Roseville, MN 55113
+
+ Phone: (612) 490 7856
+ EMail: 70761.1664@compuserve.com
+
+
+
+Sklower, et. al. Standards Track [Page 24]
+
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