Internet Draft


Internet Engineering Task Force                            Juha Heinanen
INTERNET DRAFT                                             Telia Finland
Expires August 1999                                           Fred Baker
                                                           Cisco Systems
                                                            Walter Weiss
                                                     Lucent Technologies
                                                         John Wroclawski
                                                                 MIT LCS
                                                          February, 1999


                      Assured Forwarding PHB Group
                    <draft-ietf-diffserv-af-06.txt>


Status of this Memo

   This document is an Internet-Draft and is in full conformance with
   all provisions of Section 10 of RFC2026.

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Copyright Notice

   Copyright (C) The Internet Society (1998).  All Rights Reserved.

Abstract

   This document defines a general use Differentiated Services (DS)
   [Blake] Per-Hop-Behavior (PHB) Group called Assured Forwarding (AF).
   The AF PHB group provides delivery of IP packets in four
   independently forwarded AF classes.  Within each AF class, an IP
   packet can be assigned one of three different levels of drop
   precedence.  A DS node does not reorder IP packets of the same
   microflow if they belong to the same AF class.

1. Purpose and Overview

   There is a demand to provide assured forwarding of IP packets over
   the Internet.  In a typical application, a company uses the Internet
   to interconnect its geographically distributed sites and wants an
   assurance that IP packets within this intranet are forwarded with
   high probability as long as the aggregate traffic from each site does
   not exceed the subscribed information rate (profile).  It is
   desirable that a site may exceed the subscribed profile with the
   understanding that the excess traffic is not delivered with as high
   probability as the traffic that is within the profile.  It is also
   important that the network does not reorder packets that belong to
   the same microflow no matter if they are in or out of the profile.

   Assured Forwarding (AF) PHB group is a means for a provider DS domain
   to offer different levels of forwarding assurances for IP packets
   received from a customer DS domain.  Four AF classes are defined,
   where each AF class is in each DS node allocated a certain amount of
   forwarding resources (buffer space and bandwidth). IP packets that
   wish to use the services provided by the AF PHB group are assigned by
   the customer or the provider DS domain into one or more of these AF
   classes according to the services that the customer has subscribed
   to. Further background about this capability and some ways to use it
   may be found in [Clark].

   Within each AF class IP packets are marked (again by the customer or
   the provider DS domain) with one of three possible drop precedence
   values.  In case of congestion, the drop precedence of a packet
   determines the relative importance of the packet within the AF class.
   A congested DS node tries to protect packets with a lower drop
   precedence value from being lost by preferably discarding packets
   with a higher drop precedence value.

   In a DS node, the level of forwarding assurance of an IP packet thus
   depends on (1) how much forwarding resources has been allocated to
   the AF class that the packet belongs to, (2) what is the current load
   of the AF class, and, in case of congestion within the class, (3)
   what is the drop precedence of the packet.

   For example, if traffic conditioning actions at the ingress of the
   provider DS domain make sure that an AF class in the DS nodes is only
   moderately loaded by packets with the lowest drop precedence value
   and is not overloaded by packets with the two lowest drop precedence
   values, then the AF class can offer a high level of forwarding



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   assurance for packets that are within the subscribed profile (i.e.,
   marked with the lowest drop precedence value) and offer up to two
   lower levels of forwarding assurance for the excess traffic.

   This document describes the AF PHB group. An otherwise DS-compliant
   node is not required to implement this PHB group in order to be
   considered DS-compliant, but when a DS-compliant node is said to
   implement an AF PHB group, it must conform to the specification in
   this document.

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in [Bradner].

2. The AF PHB Group

   Assured Forwarding (AF) PHB group provides forwarding of IP packets
   in N independent AF classes.  Within each AF class, an IP packet is
   assigned one of M different levels of drop precedence.  An IP packet
   that belongs to an AF class i and has drop precedence j is marked
   with the AF codepoint AFij, where 1 <= i <= N and 1 <= j <= M.
   Currently, four classes (N=4) with three levels of drop precedence in
   each class (M=3) are defined for general use.  More AF classes or
   levels of drop precedence MAY be defined for local use.

   A DS node SHOULD implement all four general use AF classes.  Packets
   in one AF class MUST be forwarded independently from packets in
   another AF class, i.e., a DS node MUST NOT aggregate two or more AF
   classes together.

   A DS node MUST allocate a configurable, minimum amount of forwarding
   resources (buffer space and bandwidth) to each implemented AF class.
   Each class SHOULD be serviced in a manner to achieve the configured
   service rate (bandwidth) over both small and large time scales.

   An AF class MAY also be configurable to receive more forwarding
   resources than the minimum when excess resources are available either
   from other AF classes or from other PHB groups.  This memo does not
   specify how the excess resources should be allocated, but
   implementations MUST specify what algorithms are actually supported
   and how they can be parameterized.

   Within an AF class, a DS node MUST NOT forward an IP packet with
   smaller probability if it contains a drop precedence value p than if
   it contains a drop precedence value q when p < q.  Note that this
   requirement can be fulfilled without needing to dequeue and discard
   already-queued packets.




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   Within each AF class, a DS node MUST accept all three drop precedence
   codepoints and they MUST yield at least two different levels of loss
   probability.  In some networks, particularly in enterprise networks,
   where transient congestion is a rare and brief occurrence, it may be
   reasonable for a DS node to implement only two different levels of
   loss probability per AF class.  While this may suffice for some
   networks, three different levels of loss probability SHOULD be
   supported in DS domains where congestion is a common occurrence.

   If a DS node only implements two different levels of loss probability
   for an AF class x, the codepoint AFx1 MUST yield the lower loss
   probability and the codepoints AFx2 and AFx3 MUST yield the higher
   loss probability.

   A DS node MUST NOT reorder AF packets of the same microflow when they
   belong to the same AF class regardless of their drop precedence.
   There are no quantifiable timing requirements (delay or delay
   variation) associated with the forwarding of AF packets.

   The relationship between AF classes and other PHBs is described in
   Section 7 of this memo.

   The AF PHB group MAY be used to implement both end-to-end and domain
   edge-to-domain edge services.

3. Traffic Conditioning Actions

   A DS domain MAY at the edge of a domain control the amount of AF
   traffic that enters or exits the domain at various levels of drop
   precedence.  Such traffic conditioning actions MAY include traffic
   shaping, discarding of packets, increasing or decreasing the drop
   precedence of packets, and reassigning of packets to other AF
   classes.  The traffic conditioning actions MUST NOT cause reordering
   of packets of the same microflow.

4. Queueing and Discard Behavior

   This section defines the queueing and discard behavior of the AF PHB
   group.  Other aspects of the PHB group's behavior are defined in
   Section 2.

   An AF implementation MUST attempt to minimize long-term congestion
   within each class, while allowing short-term congestion resulting
   from bursts. This requires an active queue management algorithm.  An
   example of such an algorithm is Random Early Drop (RED) [Floyd].
   This memo does not specify the use of a particular algorithm, but
   does require that several properties hold.




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   An AF implementation MUST detect and respond to long-term congestion
   within each class by dropping packets, while handling short-term
   congestion (packet bursts) by queueing packets.  This implies the
   presence of a smoothing or filtering function that monitors the
   instantaneous congestion level and computes a smoothed congestion
   level.  The dropping algorithm uses this smoothed congestion level to
   determine when packets should be discarded.

   The dropping algorithm MUST be insensitive to the short-term traffic
   characteristics of the microflows using an AF class.  That is, flows
   with different short-term burst shapes but identical longer-term
   packet rates should have packets discarded with essentially equal
   probability.  One way to achieve this is to use randomness within the
   dropping function.

   The dropping algorithm MUST treat all packets within a single class
   and precedence level identically.  This implies that for any given
   smoothed congestion level, the discard rate of a particular
   microflow's packets within a single precedence level will be
   proportional to that flow's percentage of the total amount of traffic
   passing through that precedence level.

   The congestion indication feedback to the end nodes, and thus the
   level of packet discard at each drop precedence in relation to
   congestion, MUST be gradual rather than abrupt, to allow the overall
   system to reach a stable operating point.  One way to do this (RED)
   uses two (configurable) smoothed congestion level thresholds.  When
   the smoothed congestion level is below the first threshold, no
   packets of the relevant precedence are discarded.  When the smoothed
   congestion level is between the first and the second threshold,
   packets are discarded with linearly increasing probability, ranging
   from zero to a configurable value reached just prior to the second
   threshold.  When the smoothed congestion level is above the second
   threshold, packets of the relevant precedence are discarded with 100%
   probability.

   To allow the AF PHB to be used in many different operating
   environments, the dropping algorithm control parameters MUST be
   independently configurable for each packet drop precedence and for
   each AF class.

   Within the limits above, this specification allows for a range of
   packet discard behaviors.  Inconsistent discard behaviors lead to
   inconsistent end-to-end service semantics and limit the range of
   possible uses of the AF PHB in a multi-vendor environment.  As
   experience is gained, future versions of this document may more
   tightly define specific aspects of the desirable behavior.




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5. Tunneling

   When AF packets are tunneled, the PHB of the tunneling packet MUST
   NOT reduce the forwarding assurance of the tunneled AF packet nor
   cause reordering of AF packets belonging to the same microflow.

6. Recommended Codepoints

   Recommended codepoints for the four general use AF classes are given
   below. These codepoints do not overlap with any other general use PHB
   groups.

   The RECOMMENDED values of the AF codepoints are as follows: AF11 =
   '001010', AF12 = '001100', AF13 = '001110', AF21 = '010010', AF22 =
   '010100', AF23 = '010110', AF31 = '011010', AF32 = '011100', AF33 =
   '011110', AF41 = '100010', AF42 = '100100', and AF43 = '100110'.  The
   table below summarizes the recommended AF codepoint values.

                        Class 1    Class 2    Class 3    Class 4
                      +----------+----------+----------+----------+
     Low Drop Prec    |  001010  |  010010  |  011010  |  100010  |
     Medium Drop Prec |  001100  |  010100  |  011100  |  100100  |
     High Drop Prec   |  001110  |  010110  |  011110  |  100110  |
                      +----------+----------+----------+----------+

7. Interactions with Other PHB Groups

   The AF codepoint mappings recommended above do not interfere with the
   local use spaces nor the Class Selector codepoints recommended in
   [Nichols].  The PHBs selected by those Class Selector codepoints may
   thus coexist with the AF PHB group and retain the forwarding behavior
   and relationships that was defined for them.  In particular, the
   Default PHB codepoint of '000000' may remain to be used for
   conventional best effort traffic.  Similarly, the codepoints '11x000'
   may remain to be used for network control traffic.

   The AF PHB group, in conjunction with edge traffic conditioning
   actions that limit the amount of traffic in each AF class to a
   (generally different) percentage of the class's allocated resources,
   can be used to obtain the overall behavior implied by the Class
   Selector PHBs.  In this case it may be appropriate within a DS domain
   to use some or all of the Class Selector codepoints as aliases of AF
   codepoints.

   In addition to the Class Selector PHBs, any other PHB groups may co-
   exist with the AF PHB group within the same DS domain.  However, any
   AF PHB group implementation should document the following:




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   (a) Which, if any, other PHB groups may preempt the forwarding
   resources specifically allocated to each AF PHB class.  This
   preemption MUST NOT happen in normal network operation, but may be
   appropriate in certain unusual situations - for example, the '11x000'
   codepoint may preempt AF forwarding resources, to give precedence to
   unexpectedly high levels of network control traffic when required.

   (b) How "excess" resources are allocated between the AF PHB group and
   other implemented PHB groups.  For example, once the minimum
   allocations are given to each AF class, any remaining resources could
   be allocated evenly between the AF classes and the Default PHB.  In
   an alternative example, any remaining resources could be allocated to
   forwarding excess AF traffic, with resources devoted to the Default
   PHB only when all AF demand is met.

   This memo does not specify that any particular relationship hold
   between AF PHB groups and other implemented PHB groups; it requires
   only that whatever relationship is chosen be documented.
   Implementations MAY allow either or both of these relationships to be
   configurable.  It is expected that this level of configuration
   flexibility will prove valuable to many network administrators.

8. Security Implications

   In order to protect itself against denial of service attacks, a
   provider DS domain SHOULD limit the traffic entering the domain to
   the subscribed profiles.  Also, in order to protect a link to a
   customer DS domain from denial of service attacks, the provider DS
   domain SHOULD allow the customer DS domain to specify how the
   resources of the link are allocated to AF packets.  If a service
   offering requires that traffic marked with an AF codepoint be limited
   by such attributes as source or destination address, it is the
   responsibility of the ingress node in a network to verify validity of
   such attributes.

   Other security considerations are covered in [Blake] and [Nichols].

Appendix: Example Services

   The AF PHB group could be used to implement, for example, the so-
   called Olympic service, which consists of three service classes:
   bronze, silver, and gold.  Packets are assigned to these three
   classes so that packets in the gold class experience lighter load
   (and thus have greater probability for timely forwarding) than
   packets assigned to the silver class.  Same kind of relationship
   exists between the silver class and the bronze class.  If desired,
   packets within each class may be further separated by giving them
   either low, medium, or high drop precedence.



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   The bronze, silver, and gold service classes could in the network be
   mapped to the AF classes 1, 2, and 3.  Similarly, low, medium, and
   high drop precedence may be mapped to AF drop precedence levels 1, 2,
   or 3.

   The drop precedence level of a packet could be assigned, for example,
   by using a leaky bucket traffic policer, which has as its parameters
   a rate and a size, which is the sum of two burst values: a committed
   burst size and an excess burst size.  A packet is assigned low drop
   precedence if the number of tokens in the bucket is greater than the
   excess burst size, medium drop precedence if the number of tokens in
   the bucket is greater than zero, but at most the excess burst size,
   and high drop precedence if the bucket is empty.  It may also be
   necessary to set an upper limit to the amount of high drop precedence
   traffic from a customer DS domain in order to avoid the situation
   where an avalanche of undeliverable high drop precedence packets from
   one customer DS domain can deny service to possibly deliverable high
   drop precedence packets from other domains.

   Another way to assign the drop precedence level of a packet could be
   to limit the user traffic of an Olympic service class to a given peak
   rate and distribute it evenly across each level of drop precedence.
   This would yield a proportional bandwidth service, which equally
   apportions available capacity during times of congestion under the
   assumption that customers with high bandwidth microflows have
   subscribed to higher peak rates than customers with low bandwidth
   microflows.

   The AF PHB group could also be used to implement a loss and low
   latency service using an over provisioned AF class, if the maximum
   arrival rate to that class is known a priori in each DS node.
   Specification of the required admission control services, however, is
   beyond the scope of this document.  If low loss is not an objective,
   a low latency service could be implemented without over provisioning
   by setting a low maximum limit to the buffer space available for an
   AF class.

References

   [Blake] Blake, Steve, et al., An Architecture for Differentiated
   Services. RFC 2475, December 1998.

   [Bradner] Bradner, S., Key words for use in RFCs to Indicate
   Requirement Levels. RFC 2119, March 1997.

   [Clark] Clark, D. and Fang, W., Explicit Allocation of Best Effort
   Packet Delivery Service.  IEEE/ACM Transactions on Networking, Volume
   6, Number 4, August 1998, pp. 362-373.



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   [Floyd] Floyd, S., and Jacobson, V., Random Early Detection gateways
   for Congestion Avoidance. IEEE/ACM Transactions on Networking, Volume
   1, Number 4, August 1993, pp. 397-413.

   [Nichols] Nichols, Kathleen, et al., Definition of the Differentiated
   Services Field (DS Field) in the IPv4 and IPv6 Headers. RFC 2474,
   December 1998.

Author Information

   Juha Heinanen
   Telia Finland
   Myyrmaentie 2
   01600 Vantaa, Finland
   Email: jh@telia.fi

   Fred Baker
   Cisco Systems
   519 Lado Drive
   Santa Barbara, California 93111
   E-mail: fred@cisco.com

   Walter Weiss
   Lucent Technologies
   300 Baker Avenue, Suite 100,
   Concord, MA  01742-2168
   E-mail: wweiss@lucent.com

   John Wroclawski
   MIT Laboratory for Computer Science
   545 Technology Sq.
   Cambridge, MA  02139
   Email: jtw@lcs.mit.edu

Full Copyright Statement

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   copyrights defined in the Internet Standards process must be
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