[Note that this file is a concatenation of more than one RFC.]





Network Working Group                                         S. Floyd
Request for Comments: 2914                                       ACIRI
BCP: 41                                                 September 2000
Category: Best Current Practice


                     Congestion Control Principles

Status of this Memo

   This document specifies an Internet Best Current Practices for the
   Internet Community, and requests discussion and suggestions for
   improvements.  Distribution of this memo is unlimited.

Copyright Notice

   Copyright (C) The Internet Society (2000).  All Rights Reserved.

Abstract

   The goal of this document is to explain the need for congestion
   control in the Internet, and to discuss what constitutes correct
   congestion control.  One specific goal is to illustrate the dangers
   of neglecting to apply proper congestion control.  A second goal is
   to discuss the role of the IETF in standardizing new congestion
   control protocols.

1.  Introduction

   This document draws heavily from earlier RFCs, in some cases
   reproducing entire sections of the text of earlier documents
   [RFC2309, RFC2357].  We have also borrowed heavily from earlier
   publications addressing the need for end-to-end congestion control
   [FF99].

2.  Current standards on congestion control

   IETF standards concerning end-to-end congestion control focus either
   on specific protocols (e.g., TCP [RFC2581], reliable multicast
   protocols [RFC2357]) or on the syntax and semantics of communications
   between the end nodes and routers about congestion information (e.g.,
   Explicit Congestion Notification [RFC2481]) or desired quality-of-
   service (diff-serv)).  The role of end-to-end congestion control is
   also discussed in an Informational RFC on "Recommendations on Queue
   Management and Congestion Avoidance in the Internet" [RFC2309].  RFC
   2309 recommends the deployment of active queue management mechanisms
   in routers, and the continuation of design efforts towards mechanisms




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   in routers to deal with flows that are unresponsive to congestion
   notification.  We freely borrow from RFC 2309 some of their general
   discussion of end-to-end congestion control.

   In contrast to the RFCs discussed above, this document is a more
   general discussion of the principles of congestion control.  One of
   the keys to the success of the Internet has been the congestion
   avoidance mechanisms of TCP.  While TCP is still the dominant
   transport protocol in the Internet, it is not ubiquitous, and there
   are an increasing number of applications that, for one reason or
   another, choose not to use TCP.  Such traffic includes not only
   multicast traffic, but unicast traffic such as streaming multimedia
   that does not require reliability; and traffic such as DNS or routing
   messages that consist of short transfers deemed critical to the
   operation of the network.  Much of this traffic does not use any form
   of either bandwidth reservations or end-to-end congestion control.
   The continued use of end-to-end congestion control by best-effort
   traffic is critical for maintaining the stability of the Internet.

   This document also discusses the general role of the IETF in the
   standardization of new congestion control protocols.

   The discussion of congestion control principles for differentiated
   services or integrated services is not addressed in this document.
   Some categories of integrated or differentiated services include a
   guarantee by the network of end-to-end bandwidth, and as such do not
   require end-to-end congestion control mechanisms.

3.  The development of end-to-end congestion control.

3.1.  Preventing congestion collapse.

   The Internet protocol architecture is based on a connectionless end-
   to-end packet service using the IP protocol.  The advantages of its
   connectionless design, flexibility and robustness, have been amply
   demonstrated.  However, these advantages are not without cost:
   careful design is required to provide good service under heavy load.
   In fact, lack of attention to the dynamics of packet forwarding can
   result in severe service degradation or "Internet meltdown".  This
   phenomenon was first observed during the early growth phase of the
   Internet of the mid 1980s [RFC896], and is technically called
   "congestion collapse".

   The original specification of TCP [RFC793] included window-based flow
   control as a means for the receiver to govern the amount of data sent
   by the sender.  This flow control was used to prevent overflow of the
   receiver's data buffer space available for that connection.  [RFC793]




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   reported that segments could be lost due either to errors or to
   network congestion, but did not include dynamic adjustment of the
   flow-control window in response to congestion.

   The original fix for Internet meltdown was provided by Van Jacobson.
   Beginning in 1986, Jacobson developed the congestion avoidance
   mechanisms that are now required in TCP implementations [Jacobson88,
   RFC 2581].  These mechanisms operate in the hosts to cause TCP
   connections to "back off" during congestion.  We say that TCP flows
   are "responsive" to congestion signals (i.e., dropped packets) from
   the network.  It is these TCP congestion avoidance algorithms that
   prevent the congestion collapse of today's Internet.

   However, that is not the end of the story.  Considerable research has
   been done on Internet dynamics since 1988, and the Internet has
   grown.  It has become clear that the TCP congestion avoidance
   mechanisms [RFC2581], while necessary and powerful, are not
   sufficient to provide good service in all circumstances.  In addition
   to the development of new congestion control mechanisms [RFC2357],
   router-based mechanisms are in development that complement the
   endpoint congestion avoidance mechanisms.

   A major issue that still needs to be addressed is the potential for
   future congestion collapse of the Internet due to flows that do not
   use responsible end-to-end congestion control.  RFC 896 [RFC896]
   suggested in 1984 that gateways should detect and `squelch'
   misbehaving hosts: "Failure to  respond  to  an  ICMP  Source  Quench
   message, though,  should be regarded as grounds for action by a
   gateway to disconnect a host.  Detecting such failure is non-trivial
   but  is a worthwhile area for further research."  Current papers
   still propose that routers detect and penalize flows that are not
   employing acceptable end-to-end congestion control [FF99].

3.2.  Fairness

   In addition to a concern about congestion collapse, there is a
   concern about `fairness' for best-effort traffic.  Because TCP "backs
   off" during congestion, a large number of TCP connections can share a
   single, congested link in such a way that bandwidth is shared
   reasonably equitably among similarly situated flows.  The equitable
   sharing of bandwidth among flows depends on the fact that all flows
   are running compatible congestion control algorithms.  For TCP, this
   means congestion control algorithms conformant with the current TCP
   specification [RFC793, RFC1122, RFC2581].

   The issue of fairness among competing flows has become increasingly
   important for several reasons.  First, using window scaling
   [RFC1323], individual TCPs can use high bandwidth even over high-



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   propagation-delay paths.  Second, with the growth of the web,
   Internet users increasingly want high-bandwidth and low-delay
   communications, rather than the leisurely transfer of a long file in
   the background.  The growth of best-effort traffic that does not use
   TCP underscores this concern about fairness between competing best-
   effort traffic in times of congestion.

   The popularity of the Internet has caused a proliferation in the
   number of TCP implementations.  Some of these may fail to implement
   the TCP congestion avoidance mechanisms correctly because of poor
   implementation [RFC2525].  Others may deliberately be implemented
   with congestion avoidance algorithms that are more aggressive in
   their use of bandwidth than other TCP implementations; this would
   allow a vendor to claim to have a "faster TCP".  The logical
   consequence of such implementations would be a spiral of increasingly
   aggressive TCP implementations, or increasingly aggressive transport
   protocols, leading back to the point where there is effectively no
   congestion avoidance and the Internet is chronically congested.

   There is a well-known way to achieve more aggressive performance
   without even changing the transport protocol, by changing the level
   of granularity: open multiple connections to the same place, as has
   been done in the past by some Web browsers.  Thus, instead of a
   spiral of increasingly aggressive transport protocols, we would
   instead have a spiral of increasingly aggressive web browsers, or
   increasingly aggressive applications.

   This raises the issue of the appropriate granularity of a "flow",
   where we define a `flow' as the level of granularity appropriate for
   the application of both fairness and congestion control.  From RFC
   2309:  "There are a few `natural' answers: 1) a TCP or UDP connection
   (source address/port, destination address/port); 2) a
   source/destination host pair; 3) a given source host or a given
   destination host.  We would guess that the source/destination host
   pair gives the most appropriate granularity in many circumstances.
   The granularity of flows for congestion management is, at least in
   part, a policy question that needs to be addressed in the wider IETF
   community."

   Again borrowing from RFC 2309, we use the term "TCP-compatible" for a
   flow that behaves under congestion like a flow produced by a
   conformant TCP.  A TCP-compatible flow is responsive to congestion
   notification, and in steady-state uses no more bandwidth than a
   conformant TCP running under comparable conditions (drop rate, RTT,
   MTU, etc.)






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   It is convenient to divide flows into three classes: (1) TCP-
   compatible flows, (2) unresponsive flows, i.e., flows that do not
   slow down when congestion occurs, and (3) flows that are responsive
   but are not TCP-compatible.  The last two classes contain more
   aggressive flows that pose significant threats to Internet
   performance, as we discuss below.

   In addition to steady-state fairness, the fairness of the initial
   slow-start is also a concern.  One concern is the transient effect on
   other flows of a flow with an overly-aggressive slow-start procedure.
   Slow-start performance is particularly important for the many flows
   that are short-lived, and only have a small amount of data to
   transfer.

3.3.  Optimizing performance regarding throughput, delay, and loss.

   In addition to the prevention of congestion collapse and concerns
   about fairness, a third reason for a flow to use end-to-end
   congestion control can be to optimize its own performance regarding
   throughput, delay, and loss.  In some circumstances, for example in
   environments of high statistical multiplexing, the delay and loss
   rate experienced by a flow are largely independent of its own sending
   rate.  However, in environments with lower levels of statistical
   multiplexing or with per-flow scheduling, the delay and loss rate
   experienced by a flow is in part a function of the flow's own sending
   rate.  Thus, a flow can use end-to-end congestion control to limit
   the delay or loss experienced by its own packets.  We would note,
   however, that in an environment like the current best-effort
   Internet, concerns regarding congestion collapse and fairness with
   competing flows limit the range of congestion control behaviors
   available to a flow.

4.  The role of the standards process

   The standardization of a transport protocol includes not only
   standardization of aspects of the protocol that could affect
   interoperability (e.g., information exchanged by the end-nodes), but
   also standardization of mechanisms deemed critical to performance
   (e.g., in TCP, reduction of the congestion window in response to a
   packet drop).  At the same time, implementation-specific details and
   other aspects of the transport protocol that do not affect
   interoperability and do not significantly interfere with performance
   do not require standardization.  Areas of TCP that do not require
   standardization include the details of TCP's Fast Recovery procedure
   after a Fast Retransmit [RFC2582].  The appendix uses examples from
   TCP to discuss in more detail the role of the standards process in
   the development of congestion control.




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4.1.  The development of new transport protocols.

   In addition to addressing the danger of congestion collapse, the
   standardization process for new transport protocols takes care to
   avoid a congestion control `arms race' among competing protocols.  As
   an example, in RFC 2357 [RFC2357] the TSV Area Directors and their
   Directorate outline criteria for the publication as RFCs of
   Internet-Drafts on reliable multicast transport protocols.  From
   [RFC2357]:  "A particular concern for the IETF is the impact of
   reliable multicast traffic on other traffic in the Internet in times
   of congestion, in particular the effect of reliable multicast traffic
   on competing TCP traffic....  The challenge to the IETF is to
   encourage research and implementations of reliable multicast, and to
   enable the needs of applications for reliable multicast to be met as
   expeditiously as possible, while at the same time protecting the
   Internet from the congestion disaster or collapse that could result
   from the widespread use of applications with inappropriate reliable
   multicast mechanisms."

   The list of technical criteria that must be addressed by RFCs on new
   reliable multicast transport protocols include the following:  "Is
   there a congestion control mechanism? How well does it perform? When
   does it fail?  Note that congestion control mechanisms that operate
   on the network more aggressively than TCP will face a great burden of
   proof that they don't threaten network stability."

   It is reasonable to expect that these concerns about the effect of
   new transport protocols on competing traffic will apply not only to
   reliable multicast protocols, but to unreliable unicast, reliable
   unicast, and unreliable multicast traffic as well.

4.2.  Application-level issues that affect congestion control

   The specific issue of a browser opening multiple connections to the
   same destination has been addressed by RFC 2616 [RFC2616], which
   states in Section 8.1.4 that "Clients that use persistent connections
   SHOULD limit the number of simultaneous connections that they
   maintain to a given server.  A single-user client SHOULD NOT maintain
   more than 2 connections with any server or proxy."

4.3.  New developments in the standards process

   The most obvious developments in the IETF that could affect the
   evolution of congestion control are the development of integrated and
   differentiated services [RFC2212, RFC2475] and of Explicit Congestion
   Notification (ECN) [RFC2481].  However, other less dramatic
   developments are likely to affect congestion control as well.




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   One such effort is that to construct Endpoint Congestion Management
   [BS00], to enable multiple concurrent flows from a sender to the same
   receiver to share congestion control state.  By allowing multiple
   connections to the same destination to act as one flow in terms of
   end-to-end congestion control, a Congestion Manager could allow
   individual connections slow-starting to take advantage of previous
   information about the congestion state of the end-to-end path.
   Further, the use of a Congestion Manager could remove the congestion
   control dangers of multiple flows being opened between the same
   source/destination pair, and could perhaps be used to allow a browser
   to open many simultaneous connections to the same destination.

5.  A description of congestion collapse

   This section discusses congestion collapse from undelivered packets
   in some detail, and shows how unresponsive flows could contribute to
   congestion collapse in the Internet.  This section draws heavily on
   material from [FF99].

   Informally, congestion collapse occurs when an increase in the
   network load results in a decrease in the useful work done by the
   network.  As discussed in Section 3, congestion collapse was first
   reported in the mid 1980s [RFC896], and was largely due to TCP
   connections unnecessarily retransmitting packets that were either in
   transit or had already been received at the receiver.  We call the
   congestion collapse that results from the unnecessary retransmission
   of packets classical congestion collapse.  Classical congestion
   collapse is a stable condition that can result in throughput that is
   a small fraction of normal [RFC896].  Problems with classical
   congestion collapse have generally been corrected by the timer
   improvements and congestion control mechanisms in modern
   implementations of TCP [Jacobson88].

   A second form of potential congestion collapse occurs due to
   undelivered packets.  Congestion collapse from undelivered packets
   arises when bandwidth is wasted by delivering packets through the
   network that are dropped before reaching their ultimate destination.
   This is probably the largest unresolved danger with respect to
   congestion collapse in the Internet today.  Different scenarios can
   result in different degrees of congestion collapse, in terms of the
   fraction of the congested links' bandwidth used for productive work.
   The danger of congestion collapse from undelivered packets is due
   primarily to the increasing deployment of open-loop applications not
   using end-to-end congestion control.  Even more destructive would be
   best-effort applications that *increase* their sending rate in
   response to an increased packet drop rate (e.g., automatically using
   an increased level of FEC).




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   Table 1 gives the results from a scenario with congestion collapse
   from undelivered packets, where scarce bandwidth is wasted by packets
   that never reach their destination.  The simulation uses a scenario
   with three TCP flows and one UDP flow competing over a congested 1.5
   Mbps link.  The access links for all nodes are 10 Mbps, except that
   the access link to the receiver of the UDP flow is 128 Kbps, only 9%
   of the bandwidth of shared link.  When the UDP source rate exceeds
   128 Kbps, most of the UDP packets will be dropped at the output port
   to that final link.

        UDP
        Arrival   UDP       TCP       Total
        Rate      Goodput   Goodput   Goodput
       --------------------------------------
         0.7       0.7      98.5      99.2
         1.8       1.7      97.3      99.1
         2.6       2.6      96.0      98.6
         5.3       5.2      92.7      97.9
         8.8       8.4      87.1      95.5
        10.5       8.4      84.8      93.2
        13.1       8.4      81.4      89.8
        17.5       8.4      77.3      85.7
        26.3       8.4      64.5      72.8
        52.6       8.4      38.1      46.4
        58.4       8.4      32.8      41.2
        65.7       8.4      28.5      36.8
        75.1       8.4      19.7      28.1
        87.6       8.4      11.3      19.7
       105.2       8.4       3.4      11.8
       131.5       8.4       2.4      10.7

   Table 1.  A simulation with three TCP flows and one UDP flow.

   Table 1 shows the UDP arrival rate from the sender, the UDP goodput
   (defined as the bandwidth delivered to the receiver), the TCP goodput
   (as delivered to the TCP receivers), and the aggregate goodput on the
   congested 1.5 Mbps link.  Each rate is given as a fraction of the
   bandwidth of the congested link.  As the UDP source rate increases,
   the TCP goodput decreases roughly linearly, and the UDP goodput is
   nearly constant.  Thus, as the UDP flow increases its offered load,
   its only effect is to hurt the TCP and aggregate goodput.  On the
   congested link, the UDP flow ultimately `wastes' the bandwidth that
   could have been used by the TCP flow, and reduces the goodput in the
   network as a whole down to a small fraction of the bandwidth of the
   congested link.






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   The simulations in Table 1 illustrate both unfairness and congestion
   collapse.  As [FF99] discusses, compatible congestion control is not
   the only way to provide fairness; per-flow scheduling at the
   congested routers is an alternative mechanism at the routers that
   guarantees fairness.  However, as discussed in [FF99], per-flow
   scheduling can not be relied upon to prevent congestion collapse.

   There are only two alternatives for eliminating the danger of
   congestion collapse from undelivered packets.  The first alternative
   for preventing congestion collapse from undelivered packets is the
   use of effective end-to-end congestion control by the end nodes.
   More specifically, the requirement would be that a flow avoid a
   pattern of significant losses at links downstream from the first
   congested link on the path.  (Here, we would consider any link a
   `congested link' if any flow is using bandwidth that would otherwise
   be used by other traffic on the link.) Given that an end-node is
   generally unable to distinguish between a path with one congested
   link and a path with multiple congested links, the most reliable way
   for a flow to avoid a pattern of significant losses at a downstream
   congested link is for the flow to use end-to-end congestion control,
   and reduce its sending rate in the presence of loss.

   A second alternative for preventing congestion collapse from
   undelivered packets would be a guarantee by the network that packets
   accepted at a congested link in the network will be delivered all the
   way to the receiver [RFC2212, RFC2475].  We note that the choice
   between the first alternative of end-to-end congestion control and
   the second alternative of end-to-end bandwidth guarantees does not
   have to be an either/or decision; congestion collapse can be
   prevented by the use of effective end-to-end congestion by some of
   the traffic, and the use of end-to-end bandwidth guarantees from the
   network for the rest of the traffic.

6.  Forms of end-to-end congestion control

   This document has discussed concerns about congestion collapse and
   about fairness with TCP for new forms of congestion control.  This
   does not mean, however, that concerns about congestion collapse and
   fairness with TCP necessitate that all best-effort traffic deploy
   congestion control based on TCP's Additive-Increase Multiplicative-
   Decrease (AIMD) algorithm of reducing the sending rate in half in
   response to each packet drop.  This section separately discusses the
   implications of these two concerns of congestion collapse and
   fairness with TCP.







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6.1.  End-to-end congestion control for avoiding congestion collapse.

   The avoidance of congestion collapse from undelivered packets
   requires that flows avoid a scenario of a high sending rate, multiple
   congested links, and a persistent high packet drop rate at the
   downstream link.  Because congestion collapse from undelivered
   packets consists of packets that waste valuable bandwidth only to be
   dropped downstream, this form of congestion collapse is not possible
   in an environment where each flow traverses only one congested link,
   or where only a small number of packets are dropped at links
   downstream of the first congested link.  Thus, any form of congestion
   control that successfully avoids a high sending rate in the presence
   of a high packet drop rate should be sufficient to avoid congestion
   collapse from undelivered packets.

   We would note that the addition of Explicit Congestion Notification
   (ECN) to the IP architecture would not, in and of itself, remove the
   danger of congestion collapse for best-effort traffic.  ECN allows
   routers to set a bit in packet headers as an indication of congestion
   to the end-nodes, rather than being forced to rely on packet drops to
   indicate congestion.  However, with ECN, packet-marking would replace
   packet-dropping only in times of moderate congestion.  In particular,
   when congestion is heavy, and a router's buffers overflow, the router
   has no choice but to drop arriving packets.

6.2.  End-to-end congestion control for fairness with TCP.

   The concern expressed in [RFC2357] about fairness with TCP places a
   significant though not crippling constraint on the range of viable
   end-to-end congestion control mechanisms for best-effort traffic.  An
   environment with per-flow scheduling at all congested links would
   isolate flows from each other, and eliminate the need for congestion
   control mechanisms to be TCP-compatible.  An environment with
   differentiated services, where flows marked as belonging to a certain
   diff-serv class would be scheduled in isolation from best-effort
   traffic, could allow the emergence of an entire diff-serv class of
   traffic where congestion control was not required to be TCP-
   compatible.  Similarly, a pricing-controlled environment, or a diff-
   serv class with its own pricing paradigm, could supercede the concern
   about fairness with TCP.  However, for the current Internet
   environment, where other best-effort traffic could compete in a FIFO
   queue with TCP traffic, the absence of fairness with TCP could lead
   to one flow `starving out' another flow in a time of high congestion,
   as was illustrated in Table 1 above.

   However, the list of TCP-compatible congestion control procedures is
   not limited to AIMD with the same increase/ decrease parameters as
   TCP.  Other TCP-compatible congestion control procedures include



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   rate-based variants of AIMD; AIMD with different sets of
   increase/decrease parameters that give the same steady-state
   behavior; equation-based congestion control where the sender adjusts
   its sending rate in response to information about the long-term
   packet drop rate; layered multicast where receivers subscribe and
   unsubscribe from layered multicast groups; and possibly other forms
   that we have not yet begun to consider.

7. Acknowledgements

   Much of this document draws directly on previous RFCs addressing
   end-to-end congestion control.  This attempts to be a summary of
   ideas that have been discussed for many years, and by many people.
   In particular, acknowledgement is due to the members of the End-to-
   End Research Group, the Reliable Multicast Research Group, and the
   Transport Area Directorate.  This document has also benefited from
   discussion and feedback from the Transport Area Working Group.
   Particular thanks are due to Mark Allman for feedback on an earlier
   version of this document.

8. References

   [BS00]       Balakrishnan H. and S. Seshan, "The Congestion Manager",
                Work in Progress.

   [DMKM00]     Dawkins, S., Montenegro, G., Kojo, M. and V. Magret,
                "End-to-end Performance Implications of Slow Links",
                Work in Progress.

   [FF99]       Floyd, S. and K. Fall, "Promoting the Use of End-to-End
                Congestion Control in the Internet", IEEE/ACM
                Transactions on Networking, August 1999.  URL
                http://www.aciri.org/floyd/end2end-paper.html

   [HPF00]      Handley, M., Padhye, J. and S. Floyd, "TCP Congestion
                Window Validation", RFC 2861, June 2000.

   [Jacobson88] V. Jacobson, Congestion Avoidance and Control, ACM
                SIGCOMM '88, August 1988.

   [RFC793]     Postel, J., "Transmission Control Protocol", STD 7, RFC
                793, September 1981.

   [RFC896]     Nagle, J., "Congestion Control in IP/TCP", RFC 896,
                January 1984.

   [RFC1122]    Braden, R., Ed., "Requirements for Internet Hosts --
                Communication Layers", STD 3, RFC 1122, October 1989.



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   [RFC1323]    Jacobson, V., Braden, R. and D. Borman, "TCP Extensions
                for High Performance", RFC 1323, May 1992.

   [RFC2119]    Bradner, S., "Key words for use in RFCs to Indicate
                Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC2212]    Shenker, S., Partridge, C. and R. Guerin, "Specification
                of Guaranteed Quality of Service", RFC 2212, September
                1997.

   [RFC2309]    Braden, R., Clark, D., Crowcroft, J., Davie, B.,
                Deering, S., Estrin, D., Floyd, S., Jacobson, V.,
                Minshall, G., Partridge, C., Peterson, L., Ramakrishnan,
                K.K., Shenker, S., Wroclawski, J., and L. Zhang,
                "Recommendations on Queue Management and Congestion
                Avoidance in the Internet", RFC 2309, April 1998.

   [RFC2357]    Mankin, A., Romanow, A., Bradner, S. and V. Paxson,
                "IETF Criteria for Evaluating Reliable Multicast
                Transport and Application Protocols", RFC 2357, June
                1998.

   [RFC2414]    Allman, M., Floyd, S. and C. Partridge, "Increasing
                TCP's Initial Window", RFC 2414, September 1998.

   [RFC2475]    Blake, S., Black, D., Carlson, M., Davies, E., Wang, Z.
                and W.  Weiss, "An Architecture for Differentiated
                Services", RFC 2475, December 1998.

   [RFC2481]    Ramakrishnan K. and S. Floyd, "A Proposal to add
                Explicit Congestion Notification (ECN) to IP", RFC 2481,
                January 1999.

   [RFC2525]    Paxson, V., Allman, M., Dawson, S., Fenner, W., Griner,
                J., Heavens, I., Lahey, K., Semke, J. and B. Volz,
                "Known TCP Implementation Problems", RFC 2525, March
                1999.

   [RFC2581]    Allman, M., Paxson, V. and W. Stevens, "TCP Congestion
                Control", RFC 2581, April 1999.

   [RFC2582]    Floyd, S. and T. Henderson, "The NewReno Modification to
                TCP's Fast Recovery Algorithm", RFC 2582, April 1999.

   [RFC2616]    Fielding, R., Gettys, J., Mogul, J., Frystyk, H.,
                Masinter, L., Leach, P. and T. Berners-Lee, "Hypertext
                Transfer Protocol -- HTTP/1.1", RFC 2616, June 1999.




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   [SCWA99]     S. Savage, N. Cardwell, D. Wetherall, and T. Anderson,
                TCP Congestion Control with a Misbehaving Receiver, ACM
                Computer Communications Review, October 1999.

   [TCPB98]     Hari Balakrishnan, Venkata N. Padmanabhan, Srinivasan
                Seshan, Mark Stemm, and Randy H. Katz, TCP Behavior of a
                Busy Internet Server: Analysis and Improvements, IEEE
                Infocom, March 1998.  Available from:
                "http://www.cs.berkeley.edu/~hari/papers/infocom98.ps.gz".

   [TCPF98]     Dong Lin and H.T. Kung, TCP Fast Recovery Strategies:
                Analysis and Improvements, IEEE Infocom, March 1998.
                Available from:
                "http://www.eecs.harvard.edu/networking/papers/infocom-
                tcp-final-198.pdf".

9.  TCP-Specific issues

   In this section we discuss some of the particulars of TCP congestion
   control, to illustrate a realization of the congestion control
   principles, including some of the details that arise when
   incorporating them into a production transport protocol.

9.1.  Slow-start.

   The TCP sender can not open a new connection by sending a large burst
   of data (e.g., a receiver's advertised window) all at once.  The TCP
   sender is limited by a small initial value for the congestion window.
   During slow-start, the TCP sender can increase its sending rate by at
   most a factor of two in one roundtrip time.  Slow-start ends when
   congestion is detected, or when the sender's congestion window is
   greater than the slow-start threshold ssthresh.

   An issue that potentially affects global congestion control, and
   therefore has been explicitly addressed in the standards process,
   includes an increase in the value of the initial window
   [RFC2414,RFC2581].

   Issues that have not been addressed in the standards process, and are
   generally considered not to require standardization, include such
   issues as the use (or non-use) of rate-based pacing, and mechanisms
   for ending slow-start early, before the congestion window reaches
   ssthresh.  Such mechanisms result in slow-start behavior that is as
   conservative or more conservative than standard TCP.







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9.2.  Additive Increase, Multiplicative Decrease.

   In the absence of congestion, the TCP sender increases its congestion
   window by at most one packet per roundtrip time. In response to a
   congestion indication, the TCP sender decreases its congestion window
   by half.  (More precisely, the new congestion window is half of the
   minimum of the congestion window and the receiver's advertised
   window.)

   An issue that potentially affects global congestion control, and
   therefore would be likely to be explicitly addressed in the standards
   process, would include a proposed addition of congestion control for
   the return stream of `pure acks'.

   An issue that has not been addressed in the standards process, and is
   generally not considered to require standardization, would be a
   change to the congestion window to apply as an upper bound on the
   number of bytes presumed to be in the pipe, instead of applying as a
   sliding window starting from the cumulative acknowledgement.
   (Clearly, the receiver's advertised window applies as a sliding
   window starting from the cumulative acknowledgement field, because
   packets received above the cumulative acknowledgement field are held
   in TCP's receive buffer, and have not been delivered to the
   application.  However, the congestion window applies to the number of
   packets outstanding in the pipe, and does not necessarily have to
   include packets that have been received out-of-order by the TCP
   receiver.)

9.3.  Retransmit timers.

   The TCP sender sets a retransmit timer to infer that a packet has
   been dropped in the network.  When the retransmit timer expires, the
   sender infers that a packet has been lost, sets ssthresh to half of
   the current window, and goes into slow-start, retransmitting the lost
   packet.  If the retransmit timer expires because no acknowledgement
   has been received for a retransmitted packet, the retransmit timer is
   also "backed-off", doubling the value of the next retransmit timeout
   interval.

   An issue that potentially affects global congestion control, and
   therefore would be likely to be explicitly addressed in the standards
   process, might include a modified mechanism for setting the
   retransmit timer that could significantly increase the number of
   retransmit timers that expire prematurely, when the acknowledgement
   has not yet arrived at the sender, but in fact no packets have been
   dropped.  This could be of concern to the Internet standards process





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   because retransmit timers that expire prematurely could lead to an
   increase in the number of packets unnecessarily transmitted on a
   congested link.

9.4.  Fast Retransmit and Fast Recovery.

   After seeing three duplicate acknowledgements, the TCP sender infers
   a packet loss.  The TCP sender sets ssthresh to half of the current
   window, reduces the congestion window to at most half of the previous
   window, and retransmits the lost packet.

   An issue that potentially affects global congestion control, and
   therefore would be likely to be explicitly addressed in the standards
   process, might include a proposal (if there was one) for inferring a
   lost packet after only one or two duplicate acknowledgements.  If
   poorly designed, such a proposal could lead to an increase in the
   number of packets unnecessarily transmitted on a congested path.

   An issue that has not been addressed in the standards process, and
   would not be expected to require standardization, would be a proposal
   to send a "new" or presumed-lost packet in response to a duplicate or
   partial acknowledgement, if allowed by the congestion window.  An
   example of this would be sending a new packet in response to a single
   duplicate acknowledgement, to keep the `ack clock' going in case no
   further acknowledgements would have arrived.  Such a proposal is an
   example of a beneficial change that does not involve interoperability
   and does not affect global congestion control, and that therefore
   could be implemented by vendors without requiring the intervention of
   the IETF standards process.  (This issue has in fact been addressed
   in [DMKM00], which suggests that "researchers may wish to experiment
   with injecting new traffic into the network when duplicate
   acknowledgements are being received, as described in [TCPB98] and
   [TCPF98]."

9.5.  Other aspects of TCP congestion control.

   Other aspects of TCP congestion control that have not been discussed
   in any of the sections above include TCP's recovery from an idle or
   application-limited period [HPF00].

10. Security Considerations

   This document has been about the risks associated with congestion
   control, or with the absence of congestion control.  Section 3.2
   discusses the potentials for unfairness if competing flows don't use
   compatible congestion control mechanisms, and Section 5 considers the
   dangers of congestion collapse if flows don't use end-to-end
   congestion control.



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   Because this document does not propose any specific congestion
   control mechanisms, it is also not necessary to present specific
   security measures associated with congestion control.  However, we
   would note that there are a range of security considerations
   associated with congestion control that should be considered in IETF
   documents.

   For example, individual congestion control mechanisms should be as
   robust as possible to the attempts of individual end-nodes to subvert
   end-to-end congestion control [SCWA99].  This is a particular concern
   in multicast congestion control, because of the far-reaching
   distribution of the traffic and the greater opportunities for
   individual receivers to fail to report congestion.

   RFC 2309 also discussed the potential dangers to the Internet of
   unresponsive flows, that is, flows that don't reduce their sending
   rate in the presence of congestion, and describes the need for
   mechanisms in the network to deal with flows that are unresponsive to
   congestion notification.  We would note that there is still a need
   for research, engineering, measurement, and deployment in these
   areas.

   Because the Internet aggregates very large numbers of flows, the risk
   to the whole infrastructure of subverting the congestion control of a
   few individual flows is limited.  Rather, the risk to the
   infrastructure would come from the widespread deployment of many
   end-nodes subverting end-to-end congestion control.

AUTHOR'S ADDRESS

   Sally Floyd
   AT&T Center for Internet Research at ICSI (ACIRI)

   Phone: +1 (510) 642-4274 x189
   EMail: floyd@aciri.org
   URL: http://www.aciri.org/floyd/















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Full Copyright Statement

   Copyright (C) The Internet Society (2000).  All Rights Reserved.

   This document and translations of it may be copied and furnished to
   others, and derivative works that comment on or otherwise explain it
   or assist in its implementation may be prepared, copied, published
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   The limited permissions granted above are perpetual and will not be
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   This document and the information contained herein is provided on an
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Acknowledgement

   Funding for the RFC Editor function is currently provided by the
   Internet Society.



















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=========================================================================





Internet Engineering Task Force (IETF)                        B. Briscoe
Request for Comments: 7141                                            BT
BCP: 41                                                        J. Manner
Updates: 2309, 2914                                     Aalto University
Category: Best Current Practice                            February 2014
ISSN: 2070-1721


                Byte and Packet Congestion Notification

Abstract

   This document provides recommendations of best current practice for
   dropping or marking packets using any active queue management (AQM)
   algorithm, including Random Early Detection (RED), BLUE, Pre-
   Congestion Notification (PCN), and newer schemes such as CoDel
   (Controlled Delay) and PIE (Proportional Integral controller
   Enhanced).  We give three strong recommendations: (1) packet size
   should be taken into account when transports detect and respond to
   congestion indications, (2) packet size should not be taken into
   account when network equipment creates congestion signals (marking,
   dropping), and therefore (3) in the specific case of RED, the byte-
   mode packet drop variant that drops fewer small packets should not be
   used.  This memo updates RFC 2309 to deprecate deliberate
   preferential treatment of small packets in AQM algorithms.

Status of This Memo

   This memo documents an Internet Best Current Practice.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Further information on
   BCPs is available in Section 2 of RFC 5741.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   http://www.rfc-editor.org/info/rfc7141.












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Copyright Notice

   Copyright (c) 2014 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (http://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.  Code Components extracted from this document must
   include Simplified BSD License text as described in Section 4.e of
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.





































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Table of Contents

   1.  Introduction  . . . . . . . . . . . . . . . . . . . . . . . .   4
     1.1.  Terminology and Scoping . . . . . . . . . . . . . . . . .   6
     1.2.  Example Comparing Packet-Mode Drop and Byte-Mode Drop . .   7
   2.  Recommendations . . . . . . . . . . . . . . . . . . . . . . .   9
     2.1.  Recommendation on Queue Measurement . . . . . . . . . . .   9
     2.2.  Recommendation on Encoding Congestion Notification  . . .  10
     2.3.  Recommendation on Responding to Congestion  . . . . . . .  11
     2.4.  Recommendation on Handling Congestion Indications When
           Splitting or Merging Packets  . . . . . . . . . . . . . .  12
   3.  Motivating Arguments  . . . . . . . . . . . . . . . . . . . .  13
     3.1.  Avoiding Perverse Incentives to (Ab)use Smaller Packets .  13
     3.2.  Small != Control  . . . . . . . . . . . . . . . . . . . .  14
     3.3.  Transport-Independent Network . . . . . . . . . . . . . .  14
     3.4.  Partial Deployment of AQM . . . . . . . . . . . . . . . .  16
     3.5.  Implementation Efficiency . . . . . . . . . . . . . . . .  17
   4.  A Survey and Critique of Past Advice  . . . . . . . . . . . .  17
     4.1.  Congestion Measurement Advice . . . . . . . . . . . . . .  18
       4.1.1.  Fixed-Size Packet Buffers . . . . . . . . . . . . . .  18
       4.1.2.  Congestion Measurement without a Queue  . . . . . . .  19
     4.2.  Congestion Notification Advice  . . . . . . . . . . . . .  20
       4.2.1.  Network Bias When Encoding  . . . . . . . . . . . . .  20
       4.2.2.  Transport Bias When Decoding  . . . . . . . . . . . .  22
       4.2.3.  Making Transports Robust against Control Packet
               Losses  . . . . . . . . . . . . . . . . . . . . . . .  23
       4.2.4.  Congestion Notification: Summary of Conflicting
               Advice  . . . . . . . . . . . . . . . . . . . . . . .  24
   5.  Outstanding Issues and Next Steps . . . . . . . . . . . . . .  25
     5.1.  Bit-congestible Network . . . . . . . . . . . . . . . . .  25
     5.2.  Bit- and Packet-Congestible Network . . . . . . . . . . .  26
   6.  Security Considerations . . . . . . . . . . . . . . . . . . .  26
   7.  Conclusions . . . . . . . . . . . . . . . . . . . . . . . . .  27
   8.  Acknowledgements  . . . . . . . . . . . . . . . . . . . . . .  28
   9.  References  . . . . . . . . . . . . . . . . . . . . . . . . .  28
     9.1.  Normative References  . . . . . . . . . . . . . . . . . .  28
     9.2.  Informative References  . . . . . . . . . . . . . . . . .  29
   Appendix A.  Survey of RED Implementation Status  . . . . . . . .  33
   Appendix B.  Sufficiency of Packet-Mode Drop  . . . . . . . . . .  34
     B.1.  Packet-Size (In)Dependence in Transports  . . . . . . . .  35
     B.2.  Bit-Congestible and Packet-Congestible Indications  . . .  38
   Appendix C.  Byte-Mode Drop Complicates Policing Congestion
                Response . . . . . . . . . . . . . . . . . . . . . .  39








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1.  Introduction

   This document provides recommendations of best current practice for
   how we should correctly scale congestion control functions with
   respect to packet size for the long term.  It also recognises that
   expediency may be necessary to deal with existing widely deployed
   protocols that don't live up to the long-term goal.

   When signalling congestion, the problem of how (and whether) to take
   packet sizes into account has exercised the minds of researchers and
   practitioners for as long as active queue management (AQM) has been
   discussed.  Indeed, one reason AQM was originally introduced was to
   reduce the lock-out effects that small packets can have on large
   packets in tail-drop queues.  This memo aims to state the principles
   we should be using and to outline how these principles will affect
   future protocol design, taking into account pre-existing deployments.

   The question of whether to take into account packet size arises at
   three stages in the congestion notification process:

   Measuring congestion:  When a congested resource measures locally how
      congested it is, should it measure its queue length in time,
      bytes, or packets?

   Encoding congestion notification into the wire protocol:  When a
      congested network resource signals its level of congestion, should
      the probability that it drops/marks each packet depend on the size
      of the particular packet in question?

   Decoding congestion notification from the wire protocol:  When a
      transport interprets the notification in order to decide how much
      to respond to congestion, should it take into account the size of
      each missing or marked packet?

   Consensus has emerged over the years concerning the first stage,
   which Section 2.1 records in the RFC Series.  In summary: If
   possible, it is best to measure congestion by time in the queue;
   otherwise, the choice between bytes and packets solely depends on
   whether the resource is congested by bytes or packets.

   The controversy is mainly around the last two stages: whether to
   allow for the size of the specific packet notifying congestion i)
   when the network encodes or ii) when the transport decodes the
   congestion notification.

   Currently, the RFC series is silent on this matter other than a paper
   trail of advice referenced from [RFC2309], which conditionally
   recommends byte-mode (packet-size dependent) drop [pktByteEmail].



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   Reducing the number of small packets dropped certainly has some
   tempting advantages: i) it drops fewer control packets, which tend to
   be small and ii) it makes TCP's bit rate less dependent on packet
   size.  However, there are ways of addressing these issues at the
   transport layer, rather than reverse engineering network forwarding
   to fix the problems.

   This memo updates [RFC2309] to deprecate deliberate preferential
   treatment of packets in AQM algorithms solely because of their size.
   It recommends that (1) packet size should be taken into account when
   transports detect and respond to congestion indications, (2) not when
   network equipment creates them.  This memo also adds to the
   congestion control principles enumerated in BCP 41 [RFC2914].

   In the particular case of Random Early Detection (RED), this means
   that the byte-mode packet drop variant should not be used to drop
   fewer small packets, because that creates a perverse incentive for
   transports to use tiny segments, consequently also opening up a DoS
   vulnerability.  Fortunately, all the RED implementers who responded
   to our admittedly limited survey (Section 4.2.4) have not followed
   the earlier advice to use byte-mode drop, so the position this memo
   argues for seems to already exist in implementations.

   However, at the transport layer, TCP congestion control is a widely
   deployed protocol that doesn't scale with packet size (i.e., its
   reduction in rate does not take into account the size of a lost
   packet).  To date, this hasn't been a significant problem because
   most TCP implementations have been used with similar packet sizes.
   But, as we design new congestion control mechanisms, this memo
   recommends that we build in scaling with packet size rather than
   assuming that we should follow TCP's example.

   This memo continues as follows.  First, it discusses terminology and
   scoping.  Section 2 gives concrete formal recommendations, followed
   by motivating arguments in Section 3.  We then critically survey the
   advice given previously in the RFC Series and the research literature
   (Section 4), referring to an assessment of whether or not this advice
   has been followed in production networks (Appendix A).  To wrap up,
   outstanding issues are discussed that will need resolution both to
   inform future protocol designs and to handle legacy AQM deployments
   (Section 5).  Then security issues are collected together in
   Section 6 before conclusions are drawn in Section 7.  The interested
   reader can find discussion of more detailed issues on the theme of
   byte vs. packet in the appendices.

   This memo intentionally includes a non-negligible amount of material
   on the subject.  For the busy reader, Section 2 summarises the
   recommendations for the Internet community.



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1.1.  Terminology and Scoping

   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 [RFC2119].

   This memo applies to the design of all AQM algorithms, for example,
   Random Early Detection (RED) [RFC2309], BLUE [BLUE02], Pre-Congestion
   Notification (PCN) [RFC5670], Controlled Delay (CoDel) [CoDel], and
   the Proportional Integral controller Enhanced (PIE) [PIE].
   Throughout, RED is used as a concrete example because it is a widely
   known and deployed AQM algorithm.  There is no intention to imply
   that the advice is any less applicable to the other algorithms, nor
   that RED is preferred.

   Congestion Notification:  Congestion notification is a changing
      signal that aims to communicate the probability that the network
      resource(s) will not be able to forward the level of traffic load
      offered (or that there is an impending risk that they will not be
      able to).

      The 'impending risk' qualifier is added, because AQM systems set a
      virtual limit smaller than the actual limit to the resource, then
      notify the transport when this virtual limit is exceeded in order
      to avoid uncontrolled congestion of the actual capacity.

      Congestion notification communicates a real number bounded by the
      range [ 0 , 1 ].  This ties in with the most well-understood
      measure of congestion notification: drop probability.

   Explicit and Implicit Notification:  The byte vs. packet dilemma
      concerns congestion notification irrespective of whether it is
      signalled implicitly by drop or explicitly using ECN [RFC3168] or
      PCN [RFC5670].  Throughout this document, unless clear from the
      context, the term 'marking' will be used to mean notifying
      congestion explicitly, while 'congestion notification' will be
      used to mean notifying congestion either implicitly by drop or
      explicitly by marking.

   Bit-congestible vs. Packet-congestible:  If the load on a resource
      depends on the rate at which packets arrive, it is called 'packet-
      congestible'.  If the load depends on the rate at which bits
      arrive, it is called 'bit-congestible'.








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      Examples of packet-congestible resources are route look-up engines
      and firewalls, because load depends on how many packet headers
      they have to process.  Examples of bit-congestible resources are
      transmission links, radio power, and most buffer memory, because
      the load depends on how many bits they have to transmit or store.
      Some machine architectures use fixed-size packet buffers, so
      buffer memory in these cases is packet-congestible (see
      Section 4.1.1).

      The path through a machine will typically encounter both packet-
      congestible and bit-congestible resources.  However, currently, a
      design goal of network processing equipment such as routers and
      firewalls is to size the packet-processing engine(s) relative to
      the lines in order to keep packet processing uncongested, even
      under worst-case packet rates with runs of minimum-size packets.
      Therefore, packet congestion is currently rare (see Section 3.3 of
      [RFC6077]), but there is no guarantee that it will not become more
      common in the future.

      Note that information is generally processed or transmitted with a
      minimum granularity greater than a bit (e.g., octets).  The
      appropriate granularity for the resource in question should be
      used, but for the sake of brevity we will talk in terms of bytes
      in this memo.

   Coarser Granularity:  Resources may be congestible at higher levels
      of granularity than bits or packets, for instance stateful
      firewalls are flow-congestible and call-servers are session-
      congestible.  This memo focuses on congestion of connectionless
      resources, but the same principles may be applicable for
      congestion notification protocols controlling per-flow and per-
      session processing or state.

   RED Terminology:  In RED, whether to use packets or bytes when
      measuring queues is called, respectively, 'packet-mode queue
      measurement' or 'byte-mode queue measurement'.  And whether the
      probability of dropping a particular packet is independent or
      dependent on its size is called, respectively, 'packet-mode drop'
      or 'byte-mode drop'.  The terms 'byte-mode' and 'packet-mode'
      should not be used without specifying whether they apply to queue
      measurement or to drop.

1.2.  Example Comparing Packet-Mode Drop and Byte-Mode Drop

   Taking RED as a well-known example algorithm, a central question
   addressed by this document is whether to recommend RED's packet-mode
   drop variant and to deprecate byte-mode drop.  Table 1 compares how
   packet-mode and byte-mode drop affect two flows of different size



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   packets.  For each it gives the expected number of packets and of
   bits dropped in one second.  Each example flow runs at the same bit
   rate of 48 Mbps, but one is broken up into small 60 byte packets and
   the other into large 1,500 byte packets.

   To keep up the same bit rate, in one second there are about 25 times
   more small packets because they are 25 times smaller.  As can be seen
   from the table, the packet rate is 100,000 small packets versus 4,000
   large packets per second (pps).

     Parameter            Formula         Small packets Large packets
     -------------------- --------------- ------------- -------------
     Packet size          s/8                      60 B       1,500 B
     Packet size          s                       480 b      12,000 b
     Bit rate             x                     48 Mbps       48 Mbps
     Packet rate          u = x/s              100 kpps        4 kpps

     Packet-mode Drop
     Pkt-loss probability p                        0.1%          0.1%
     Pkt-loss rate        p*u                   100 pps         4 pps
     Bit-loss rate        p*u*s                 48 kbps       48 kbps

     Byte-mode Drop       MTU, M=12,000 b
     Pkt-loss probability b = p*s/M              0.004%          0.1%
     Pkt-loss rate        b*u                     4 pps         4 pps
     Bit-loss rate        b*u*s               1.92 kbps       48 kbps

         Table 1: Example Comparing Packet-Mode and Byte-Mode Drop

   For packet-mode drop, we illustrate the effect of a drop probability
   of 0.1%, which the algorithm applies to all packets irrespective of
   size.  Because there are 25 times more small packets in one second,
   it naturally drops 25 times more small packets, that is, 100 small
   packets but only 4 large packets.  But if we count how many bits it
   drops, there are 48,000 bits in 100 small packets and 48,000 bits in
   4 large packets -- the same number of bits of small packets as large.

      The packet-mode drop algorithm drops any bit with the same
      probability whether the bit is in a small or a large packet.

   For byte-mode drop, again we use an example drop probability of 0.1%,
   but only for maximum size packets (assuming the link maximum
   transmission unit (MTU) is 1,500 B or 12,000 b).  The byte-mode
   algorithm reduces the drop probability of smaller packets
   proportional to their size, making the probability that it drops a
   small packet 25 times smaller at 0.004%.  But there are 25 times more
   small packets, so dropping them with 25 times lower probability
   results in dropping the same number of packets: 4 drops in both



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   cases.  The 4 small dropped packets contain 25 times less bits than
   the 4 large dropped packets: 1,920 compared to 48,000.

      The byte-mode drop algorithm drops any bit with a probability
      proportionate to the size of the packet it is in.

2.  Recommendations

   This section gives recommendations related to network equipment in
   Sections 2.1 and 2.2, and we discuss the implications on transport
   protocols in Sections 2.3 and 2.4.

2.1.  Recommendation on Queue Measurement

   Ideally, an AQM would measure the service time of the queue to
   measure congestion of a resource.  However service time can only be
   measured as packets leave the queue, where it is not always expedient
   to implement a full AQM algorithm.  To predict the service time as
   packets join the queue, an AQM algorithm needs to measure the length
   of the queue.

   In this case, if the resource is bit-congestible, the AQM
   implementation SHOULD measure the length of the queue in bytes and,
   if the resource is packet-congestible, the implementation SHOULD
   measure the length of the queue in packets.  Subject to the
   exceptions below, no other choice makes sense, because the number of
   packets waiting in the queue isn't relevant if the resource gets
   congested by bytes and vice versa.  For example, the length of the
   queue into a transmission line would be measured in bytes, while the
   length of the queue into a firewall would be measured in packets.

   To avoid the pathological effects of tail drop, the AQM can then
   transform this service time or queue length into the probability of
   dropping or marking a packet (e.g., RED's piecewise linear function
   between thresholds).

   What this advice means for RED as a specific example:

   1.  A RED implementation SHOULD use byte-mode queue measurement for
       measuring the congestion of bit-congestible resources and packet-
       mode queue measurement for packet-congestible resources.

   2.  An implementation SHOULD NOT make it possible to configure the
       way a queue measures itself, because whether a queue is bit-
       congestible or packet-congestible is an inherent property of the
       queue.





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   Exceptions to these recommendations might be necessary, for instance
   where a packet-congestible resource has to be configured as a proxy
   bottleneck for a bit-congestible resource in an adjacent box that
   does not support AQM.

   The recommended approach in less straightforward scenarios, such as
   fixed-size packet buffers, resources without a queue, and buffers
   comprising a mix of packet and bit-congestible resources, is
   discussed in Section 4.1.  For instance, Section 4.1.1 explains that
   the queue into a line should be measured in bytes even if the queue
   consists of fixed-size packet buffers, because the root cause of any
   congestion is bytes arriving too fast for the line -- packets filling
   buffers are merely a symptom of the underlying congestion of the
   line.

2.2.  Recommendation on Encoding Congestion Notification

   When encoding congestion notification (e.g., by drop, ECN, or PCN),
   the probability that network equipment drops or marks a particular
   packet to notify congestion SHOULD NOT depend on the size of the
   packet in question.  As the example in Section 1.2 illustrates, to
   drop any bit with probability 0.1%, it is only necessary to drop
   every packet with probability 0.1% without regard to the size of each
   packet.

   This approach ensures the network layer offers sufficient congestion
   information for all known and future transport protocols and also
   ensures no perverse incentives are created that would encourage
   transports to use inappropriately small packet sizes.

   What this advice means for RED as a specific example:

   1.  The RED AQM algorithm SHOULD NOT use byte-mode drop, i.e., it
       ought to use packet-mode drop.  Byte-mode drop is more complex,
       it creates the perverse incentive to fragment segments into tiny
       pieces and it is vulnerable to floods of small packets.

   2.  If a vendor has implemented byte-mode drop, and an operator has
       turned it on, it is RECOMMENDED that the operator use packet-mode
       drop instead, after establishing if there are any implications on
       the relative performance of applications using different packet
       sizes.  The unlikely possibility of some application-specific
       legacy use of byte-mode drop is the only reason that all the
       above recommendations on encoding congestion notification are not
       phrased more strongly.






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       RED as a whole SHOULD NOT be switched off.  Without RED, a tail-
       drop queue biases against large packets and is vulnerable to
       floods of small packets.

   Note well that RED's byte-mode queue drop is completely orthogonal to
   byte-mode queue measurement and should not be confused with it.  If a
   RED implementation has a byte-mode but does not specify what sort of
   byte-mode, it is most probably byte-mode queue measurement, which is
   fine.  However, if in doubt, the vendor should be consulted.

   A survey (Appendix A) showed that there appears to be little, if any,
   installed base of the byte-mode drop variant of RED.  This suggests
   that deprecating byte-mode drop will have little, if any, incremental
   deployment impact.

2.3.  Recommendation on Responding to Congestion

   When a transport detects that a packet has been lost or congestion
   marked, it SHOULD consider the strength of the congestion indication
   as proportionate to the size in octets (bytes) of the missing or
   marked packet.

   In other words, when a packet indicates congestion (by being lost or
   marked), it can be considered conceptually as if there is a
   congestion indication on every octet of the packet, not just one
   indication per packet.

   To be clear, the above recommendation solely describes how a
   transport should interpret the meaning of a congestion indication, as
   a long term goal.  It makes no recommendation on whether a transport
   should act differently based on this interpretation.  It merely aids
   interoperability between transports, if they choose to make their
   actions depend on the strength of congestion indications.

   This definition will be useful as the IETF transport area continues
   its programme of:

   o  updating host-based congestion control protocols to take packet
      size into account, and

   o  making transports less sensitive to losing control packets like
      SYNs and pure ACKs.









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   What this advice means for the case of TCP:

   1.  If two TCP flows with different packet sizes are required to run
       at equal bit rates under the same path conditions, this SHOULD be
       done by altering TCP (Section 4.2.2), not network equipment (the
       latter affects other transports besides TCP).

   2.  If it is desired to improve TCP performance by reducing the
       chance that a SYN or a pure ACK will be dropped, this SHOULD be
       done by modifying TCP (Section 4.2.3), not network equipment.

   To be clear, we are not recommending at all that TCPs under
   equivalent conditions should aim for equal bit rates.  We are merely
   saying that anyone trying to do such a thing should modify their TCP
   algorithm, not the network.

   These recommendations are phrased as 'SHOULD' rather than 'MUST',
   because there may be cases where expediency dictates that
   compatibility with pre-existing versions of a transport protocol make
   the recommendations impractical.

2.4.  Recommendation on Handling Congestion Indications When Splitting
      or Merging Packets

   Packets carrying congestion indications may be split or merged in
   some circumstances (e.g., at an RTP / RTP Control Protocol (RTCP)
   transcoder or during IP fragment reassembly).  Splitting and merging
   only make sense in the context of ECN, not loss.

   The general rule to follow is that the number of octets in packets
   with congestion indications SHOULD be equivalent before and after
   merging or splitting.  This is based on the principle used above;
   that an indication of congestion on a packet can be considered as an
   indication of congestion on each octet of the packet.

   The above rule is not phrased with the word 'MUST' to allow the
   following exception.  There are cases in which pre-existing protocols
   were not designed to conserve congestion-marked octets (e.g., IP
   fragment reassembly [RFC3168] or loss statistics in RTCP receiver
   reports [RFC3550] before ECN was added [RFC6679]).  When any such
   protocol is updated, it SHOULD comply with the above rule to conserve
   marked octets.  However, the rule may be relaxed if it would
   otherwise become too complex to interoperate with pre-existing
   implementations of the protocol.

   One can think of a splitting or merging process as if all the
   incoming congestion-marked octets increment a counter and all the
   outgoing marked octets decrement the same counter.  In order to



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   ensure that congestion indications remain timely, even the smallest
   positive remainder in the conceptual counter should trigger the next
   outgoing packet to be marked (causing the counter to go negative).

3.  Motivating Arguments

   This section is informative.  It justifies the recommendations made
   in the previous section.

3.1.  Avoiding Perverse Incentives to (Ab)use Smaller Packets

   Increasingly, it is being recognised that a protocol design must take
   care not to cause unintended consequences by giving the parties in
   the protocol exchange perverse incentives [Evol_cc] [RFC3426].  Given
   there are many good reasons why larger path maximum transmission
   units (PMTUs) would help solve a number of scaling issues, we do not
   want to create any bias against large packets that is greater than
   their true cost.

   Imagine a scenario where the same bit rate of packets will contribute
   the same to bit congestion of a link irrespective of whether it is
   sent as fewer larger packets or more smaller packets.  A protocol
   design that caused larger packets to be more likely to be dropped
   than smaller ones would be dangerous in both of the following cases:

   Malicious transports:  A queue that gives an advantage to small
      packets can be used to amplify the force of a flooding attack.  By
      sending a flood of small packets, the attacker can get the queue
      to discard more large-packet traffic, allowing more attack traffic
      to get through to cause further damage.  Such a queue allows
      attack traffic to have a disproportionately large effect on
      regular traffic without the attacker having to do much work.

   Non-malicious transports:  Even if an application designer is not
      actually malicious, if over time it is noticed that small packets
      tend to go faster, designers will act in their own interest and
      use smaller packets.  Queues that give advantage to small packets
      create an evolutionary pressure for applications or transports to
      send at the same bit rate but break their data stream down into
      tiny segments to reduce their drop rate.  Encouraging a high
      volume of tiny packets might in turn unnecessarily overload a
      completely unrelated part of the system, perhaps more limited by
      header processing than bandwidth.

   Imagine that two unresponsive flows arrive at a bit-congestible
   transmission link each with the same bit rate, say 1 Mbps, but one
   consists of 1,500 B and the other 60 B packets, which are 25x
   smaller.  Consider a scenario where gentle RED [gentle_RED] is used,



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   along with the variant of RED we advise against, i.e., where the RED
   algorithm is configured to adjust the drop probability of packets in
   proportion to each packet's size (byte-mode packet drop).  In this
   case, RED aims to drop 25x more of the larger packets than the
   smaller ones.  Thus, for example, if RED drops 25% of the larger
   packets, it will aim to drop 1% of the smaller packets (but, in
   practice, it may drop more as congestion increases; see Appendix B.4
   of [RFC4828]).  Even though both flows arrive with the same bit rate,
   the bit rate the RED queue aims to pass to the line will be 750 kbps
   for the flow of larger packets but 990 kbps for the smaller packets
   (because of rate variations, it will actually be a little less than
   this target).

   Note that, although the byte-mode drop variant of RED amplifies
   small-packet attacks, tail-drop queues amplify small-packet attacks
   even more (see Security Considerations in Section 6).  Wherever
   possible, neither should be used.

3.2.  Small != Control

   Dropping fewer control packets considerably improves performance.  It
   is tempting to drop small packets with lower probability in order to
   improve performance, because many control packets tend to be smaller
   (TCP SYNs and ACKs, DNS queries and responses, SIP messages, HTTP
   GETs, etc).  However, we must not give control packets preference
   purely by virtue of their smallness, otherwise it is too easy for any
   data source to get the same preferential treatment simply by sending
   data in smaller packets.  Again, we should not create perverse
   incentives to favour small packets rather than to favour control
   packets, which is what we intend.

   Just because many control packets are small does not mean all small
   packets are control packets.

   So, rather than fix these problems in the network, we argue that the
   transport should be made more robust against losses of control
   packets (see Section 4.2.3).

3.3.  Transport-Independent Network

   TCP congestion control ensures that flows competing for the same
   resource each maintain the same number of segments in flight,
   irrespective of segment size.  So under similar conditions, flows
   with different segment sizes will get different bit rates.

   To counter this effect, it seems tempting not to follow our
   recommendation, and instead for the network to bias congestion
   notification by packet size in order to equalise the bit rates of



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   flows with different packet sizes.  However, in order to do this, the
   queuing algorithm has to make assumptions about the transport, which
   become embedded in the network.  Specifically:

   o  The queuing algorithm has to assume how aggressively the transport
      will respond to congestion (see Section 4.2.4).  If the network
      assumes the transport responds as aggressively as TCP NewReno, it
      will be wrong for Compound TCP and differently wrong for Cubic
      TCP, etc.  To achieve equal bit rates, each transport then has to
      guess what assumption the network made, and work out how to
      replace this assumed aggressiveness with its own aggressiveness.

   o  Also, if the network biases congestion notification by packet
      size, it has to assume a baseline packet size -- all proposed
      algorithms use the local MTU (for example, see the byte-mode loss
      probability formula in Table 1).  Then if the non-Reno transports
      mentioned above are trying to reverse engineer what the network
      assumed, they also have to guess the MTU of the congested link.

   Even though reducing the drop probability of small packets (e.g.,
   RED's byte-mode drop) helps ensure TCP flows with different packet
   sizes will achieve similar bit rates, we argue that this correction
   should be made to any future transport protocols based on TCP, not to
   the network in order to fix one transport, no matter how predominant
   it is.  Effectively, favouring small packets is reverse engineering
   of network equipment around one particular transport protocol (TCP),
   contrary to the excellent advice in [RFC3426], which asks designers
   to question "Why are you proposing a solution at this layer of the
   protocol stack, rather than at another layer?"

   In contrast, if the network never takes packet size into account, the
   transport can be certain it will never need to guess any assumptions
   that the network has made.  And the network passes two pieces of
   information to the transport that are sufficient in all cases: i)
   congestion notification on the packet and ii) the size of the packet.
   Both are available for the transport to combine (by taking packet
   size into account when responding to congestion) or not.  Appendix B
   checks that these two pieces of information are sufficient for all
   relevant scenarios.

   When the network does not take packet size into account, it allows
   transport protocols to choose whether or not to take packet size into
   account.  However, if the network were to bias congestion
   notification by packet size, transport protocols would have no
   choice; those that did not take into account packet size themselves
   would unwittingly become dependent on packet size, and those that
   already took packet size into account would end up taking it into
   account twice.



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3.4.  Partial Deployment of AQM

   In overview, the argument in this section runs as follows:

   o  Because the network does not and cannot always drop packets in
      proportion to their size, it shouldn't be given the task of making
      drop signals depend on packet size at all.

   o  Transports on the other hand don't always want to make their rate
      response proportional to the size of dropped packets, but if they
      want to, they always can.

   The argument is similar to the end-to-end argument that says "Don't
   do X in the network if end systems can do X by themselves, and they
   want to be able to choose whether to do X anyway".  Actually the
   following argument is stronger; in addition it says "Don't give the
   network task X that could be done by the end systems, if X is not
   deployed on all network nodes, and end systems won't be able to tell
   whether their network is doing X, or whether they need to do X
   themselves."  In this case, the X in question is "making the response
   to congestion depend on packet size".

   We will now re-run this argument reviewing each step in more depth.
   The argument applies solely to drop, not to ECN marking.

   A queue drops packets for either of two reasons: a) to signal to host
   congestion controls that they should reduce the load and b) because
   there is no buffer left to store the packets.  Active queue
   management tries to use drops as a signal for hosts to slow down
   (case a) so that drops due to buffer exhaustion (case b) should not
   be necessary.

   AQM is not universally deployed in every queue in the Internet; many
   cheap Ethernet bridges, software firewalls, NATs on consumer devices,
   etc implement simple tail-drop buffers.  Even if AQM were universal,
   it has to be able to cope with buffer exhaustion (by switching to a
   behaviour like tail drop), in order to cope with unresponsive or
   excessive transports.  For these reasons networks will sometimes be
   dropping packets as a last resort (case b) rather than under AQM
   control (case a).

   When buffers are exhausted (case b), they don't naturally drop
   packets in proportion to their size.  The network can only reduce the
   probability of dropping smaller packets if it has enough space to
   store them somewhere while it waits for a larger packet that it can
   drop.  If the buffer is exhausted, it does not have this choice.
   Admittedly tail drop does naturally drop somewhat fewer small
   packets, but exactly how few depends more on the mix of sizes than



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   the size of the packet in question.  Nonetheless, in general, if we
   wanted networks to do size-dependent drop, we would need universal
   deployment of (packet-size dependent) AQM code, which is currently
   unrealistic.

   A host transport cannot know whether any particular drop was a
   deliberate signal from an AQM or a sign of a queue shedding packets
   due to buffer exhaustion.  Therefore, because the network cannot
   universally do size-dependent drop, it should not do it all.

   Whereas universality is desirable in the network, diversity is
   desirable between different transport-layer protocols -- some, like
   standards track TCP congestion control [RFC5681], may not choose to
   make their rate response proportionate to the size of each dropped
   packet, while others will (e.g., TCP-Friendly Rate Control for Small
   Packets (TFRC-SP) [RFC4828]).

3.5.  Implementation Efficiency

   Biasing against large packets typically requires an extra multiply
   and divide in the network (see the example byte-mode drop formula in
   Table 1).  Taking packet size into account at the transport rather
   than in the network ensures that neither the network nor the
   transport needs to do a multiply operation -- multiplication by
   packet size is effectively achieved as a repeated add when the
   transport adds to its count of marked bytes as each congestion event
   is fed to it.  Also, the work to do the biasing is spread over many
   hosts, rather than concentrated in just the congested network
   element.  These aren't principled reasons in themselves, but they are
   a happy consequence of the other principled reasons.

4.  A Survey and Critique of Past Advice

   This section is informative, not normative.

   The original 1993 paper on RED [RED93] proposed two options for the
   RED active queue management algorithm: packet mode and byte mode.
   Packet mode measured the queue length in packets and dropped (or
   marked) individual packets with a probability independent of their
   size.  Byte mode measured the queue length in bytes and marked an
   individual packet with probability in proportion to its size
   (relative to the maximum packet size).  In the paper's outline of
   further work, it was stated that no recommendation had been made on
   whether the queue size should be measured in bytes or packets, but
   noted that the difference could be significant.






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   When RED was recommended for general deployment in 1998 [RFC2309],
   the two modes were mentioned implying the choice between them was a
   question of performance, referring to a 1997 email [pktByteEmail] for
   advice on tuning.  A later addendum to this email introduced the
   insight that there are in fact two orthogonal choices:

   o  whether to measure queue length in bytes or packets (Section 4.1),
      and

   o  whether the drop probability of an individual packet should depend
      on its own size (Section 4.2).

   The rest of this section is structured accordingly.

4.1.  Congestion Measurement Advice

   The choice of which metric to use to measure queue length was left
   open in RFC 2309.  It is now well understood that queues for bit-
   congestible resources should be measured in bytes, and queues for
   packet-congestible resources should be measured in packets
   [pktByteEmail].

   Congestion in some legacy bit-congestible buffers is only measured in
   packets not bytes.  In such cases, the operator has to take into
   account a typical mix of packet sizes when setting the thresholds.
   Any AQM algorithm on such a buffer will be oversensitive to high
   proportions of small packets, e.g., a DoS attack, and under-sensitive
   to high proportions of large packets.  However, there is no need to
   make allowances for the possibility of such a legacy in future
   protocol design.  This is safe because any under-sensitivity during
   unusual traffic mixes cannot lead to congestion collapse given that
   the buffer will eventually revert to tail drop, which discards
   proportionately more large packets.

4.1.1.  Fixed-Size Packet Buffers

   The question of whether to measure queues in bytes or packets seems
   to be well understood.  However, measuring congestion is confusing
   when the resource is bit-congestible but the queue into the resource
   is packet-congestible.  This section outlines the approach to take.

   Some, mostly older, queuing hardware allocates fixed-size buffers in
   which to store each packet in the queue.  This hardware forwards
   packets to the line in one of two ways:

   o  With some hardware, any fixed-size buffers not completely filled
      by a packet are padded when transmitted to the wire.  This case
      should clearly be treated as packet-congestible, because both



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      queuing and transmission are in fixed MTU-size units.  Therefore,
      the queue length in packets is a good model of congestion of the
      link.

   o  More commonly, hardware with fixed-size packet buffers transmits
      packets to the line without padding.  This implies a hybrid
      forwarding system with transmission congestion dependent on the
      size of packets but queue congestion dependent on the number of
      packets, irrespective of their size.

      Nonetheless, there would be no queue at all unless the line had
      become congested -- the root cause of any congestion is too many
      bytes arriving for the line.  Therefore, the AQM should measure
      the queue length as the sum of all the packet sizes in bytes that
      are queued up waiting to be serviced by the line, irrespective of
      whether each packet is held in a fixed-size buffer.

   In the (unlikely) first case where use of padding means the queue
   should be measured in packets, further confusion is likely because
   the fixed buffers are rarely all one size.  Typically, pools of
   different-sized buffers are provided (Cisco uses the term 'buffer
   carving' for the process of dividing up memory into these pools
   [IOSArch]).  Usually, if the pool of small buffers is exhausted,
   arriving small packets can borrow space in the pool of large buffers,
   but not vice versa.  However, there is no need to consider all this
   complexity, because the root cause of any congestion is still line
   overload -- buffer consumption is only the symptom.  Therefore, the
   length of the queue should be measured as the sum of the bytes in the
   queue that will be transmitted to the line, including any padding.
   In the (unusual) case of transmission with padding, this means the
   sum of the sizes of the small buffers queued plus the sum of the
   sizes of the large buffers queued.

   We will return to borrowing of fixed-size buffers when we discuss
   biasing the drop/marking probability of a specific packet because of
   its size in Section 4.2.1.  But here, we can repeat the simple rule
   for how to measure the length of queues of fixed buffers: no matter
   how complicated the buffering scheme is, ultimately a transmission
   line is nearly always bit-congestible so the number of bytes queued
   up waiting for the line measures how congested the line is, and it is
   rarely important to measure how congested the buffering system is.

4.1.2.  Congestion Measurement without a Queue

   AQM algorithms are nearly always described assuming there is a queue
   for a congested resource and the algorithm can use the queue length
   to determine the probability that it will drop or mark each packet.
   But not all congested resources lead to queues.  For instance, power-



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   limited resources are usually bit-congestible if energy is primarily
   required for transmission rather than header processing, but it is
   rare for a link protocol to build a queue as it approaches maximum
   power.

   Nonetheless, AQM algorithms do not require a queue in order to work.
   For instance, spectrum congestion can be modelled by signal quality
   using the target bit-energy-to-noise-density ratio.  And, to model
   radio power exhaustion, transmission-power levels can be measured and
   compared to the maximum power available.  [ECNFixedWireless] proposes
   a practical and theoretically sound way to combine congestion
   notification for different bit-congestible resources at different
   layers along an end-to-end path, whether wireless or wired, and
   whether with or without queues.

   In wireless protocols that use request to send / clear to send
   (RTS / CTS) control, such as some variants of IEEE802.11, it is
   reasonable to base an AQM on the time spent waiting for transmission
   opportunities (TXOPs) even though the wireless spectrum is usually
   regarded as congested by bits (for a given coding scheme).  This is
   because requests for TXOPs queue up as the spectrum gets congested by
   all the bits being transferred.  So the time that TXOPs are queued
   directly reflects bit congestion of the spectrum.

4.2.  Congestion Notification Advice

4.2.1.  Network Bias When Encoding

4.2.1.1.  Advice on Packet-Size Bias in RED

   The previously mentioned email [pktByteEmail] referred to by
   [RFC2309] advised that most scarce resources in the Internet were
   bit-congestible, which is still believed to be true (Section 1.1).
   But it went on to offer advice that is updated by this memo.  It said
   that drop probability should depend on the size of the packet being
   considered for drop if the resource is bit-congestible, but not if it
   is packet-congestible.  The argument continued that if packet drops
   were inflated by packet size (byte-mode dropping), "a flow's fraction
   of the packet drops is then a good indication of that flow's fraction
   of the link bandwidth in bits per second".  This was consistent with
   a referenced policing mechanism being worked on at the time for
   detecting unusually high bandwidth flows, eventually published in
   1999 [pBox].  However, the problem could and should have been solved
   by making the policing mechanism count the volume of bytes randomly
   dropped, not the number of packets.






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   A few months before RFC 2309 was published, an addendum was added to
   the above archived email referenced from the RFC, in which the final
   paragraph seemed to partially retract what had previously been said.
   It clarified that the question of whether the probability of
   dropping/marking a packet should depend on its size was not related
   to whether the resource itself was bit-congestible, but a completely
   orthogonal question.  However, the only example given had the queue
   measured in packets but packet drop depended on the size of the
   packet in question.  No example was given the other way round.

   In 2000, Cnodder et al. [REDbyte] pointed out that there was an error
   in the part of the original 1993 RED algorithm that aimed to
   distribute drops uniformly, because it didn't correctly take into
   account the adjustment for packet size.  They recommended an
   algorithm called RED_4 to fix this.  But they also recommended a
   further change, RED_5, to adjust the drop rate dependent on the
   square of the relative packet size.  This was indeed consistent with
   one implied motivation behind RED's byte-mode drop -- that we should
   reverse engineer the network to improve the performance of dominant
   end-to-end congestion control mechanisms.  This memo makes a
   different recommendations in Section 2.

   By 2003, a further change had been made to the adjustment for packet
   size, this time in the RED algorithm of the ns2 simulator.  Instead
   of taking each packet's size relative to a 'maximum packet size', it
   was taken relative to a 'mean packet size', intended to be a static
   value representative of the 'typical' packet size on the link.  We
   have not been able to find a justification in the literature for this
   change; however, Eddy and Allman conducted experiments [REDbias] that
   assessed how sensitive RED was to this parameter, amongst other
   things.  This changed algorithm can often lead to drop probabilities
   of greater than 1 (which gives a hint that there is probably a
   mistake in the theory somewhere).

   On 10-Nov-2004, this variant of byte-mode packet drop was made the
   default in the ns2 simulator.  It seems unlikely that byte-mode drop
   has ever been implemented in production networks (Appendix A);
   therefore, any conclusions based on ns2 simulations that use RED
   without disabling byte-mode drop are likely to behave very
   differently from RED in production networks.

4.2.1.2.  Packet-Size Bias Regardless of AQM

   The byte-mode drop variant of RED (or a similar variant of other AQM
   algorithms) is not the only possible bias towards small packets in
   queuing systems.  We have already mentioned that tail-drop queues
   naturally tend to lock out large packets once they are full.




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   But also, queues with fixed-size buffers reduce the probability that
   small packets will be dropped if (and only if) they allow small
   packets to borrow buffers from the pools for larger packets (see
   Section 4.1.1).  Borrowing effectively makes the maximum queue size
   for small packets greater than that for large packets, because more
   buffers can be used by small packets while less will fit large
   packets.  Incidentally, the bias towards small packets from buffer
   borrowing is nothing like as large as that of RED's byte-mode drop.

   Nonetheless, fixed-buffer memory with tail drop is still prone to
   lock out large packets, purely because of the tail-drop aspect.  So,
   fixed-size packet buffers should be augmented with a good AQM
   algorithm and packet-mode drop.  If an AQM is too complicated to
   implement with multiple fixed buffer pools, the minimum necessary to
   prevent large-packet lockout is to ensure that smaller packets never
   use the last available buffer in any of the pools for larger packets.

4.2.2.  Transport Bias When Decoding

   The above proposals to alter the network equipment to bias towards
   smaller packets have largely carried on outside the IETF process.
   Whereas, within the IETF, there are many different proposals to alter
   transport protocols to achieve the same goals, i.e., either to make
   the flow bit rate take into account packet size, or to protect
   control packets from loss.  This memo argues that altering transport
   protocols is the more principled approach.

   A recently approved experimental RFC adapts its transport-layer
   protocol to take into account packet sizes relative to typical TCP
   packet sizes.  This proposes a new small-packet variant of TCP-
   friendly rate control (TFRC [RFC5348]), which is called TFRC-SP
   [RFC4828].  Essentially, it proposes a rate equation that inflates
   the flow rate by the ratio of a typical TCP segment size (1,500 B
   including TCP header) over the actual segment size [PktSizeEquCC].
   (There are also other important differences of detail relative to
   TFRC, such as using virtual packets [CCvarPktSize] to avoid
   responding to multiple losses per round trip and using a minimum
   inter-packet interval.)

   Section 4.5.1 of the TFRC-SP specification discusses the implications
   of operating in an environment where queues have been configured to
   drop smaller packets with proportionately lower probability than
   larger ones.  But it only discusses TCP operating in such an
   environment, only mentioning TFRC-SP briefly when discussing how to
   define fairness with TCP.  And it only discusses the byte-mode
   dropping version of RED as it was before Cnodder et al. pointed out
   that it didn't sufficiently bias towards small packets to make TCP
   independent of packet size.



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   So the TFRC-SP specification doesn't address the issue of whether the
   network or the transport _should_ handle fairness between different
   packet sizes.  In Appendix B.4 of RFC 4828, it discusses the
   possibility of both TFRC-SP and some network buffers duplicating each
   other's attempts to deliberately bias towards small packets.  But the
   discussion is not conclusive, instead reporting simulations of many
   of the possibilities in order to assess performance but not
   recommending any particular course of action.

   The paper originally proposing TFRC with virtual packets (VP-TFRC)
   [CCvarPktSize] proposed that there should perhaps be two variants to
   cater for the different variants of RED.  However, as the TFRC-SP
   authors point out, there is no way for a transport to know whether
   some queues on its path have deployed RED with byte-mode packet drop
   (except if an exhaustive survey found that no one has deployed it! --
   see Appendix A).  Incidentally, VP-TFRC also proposed that byte-mode
   RED dropping should really square the packet-size compensation factor
   (like that of Cnodder's RED_5, but apparently unaware of it).

   Pre-congestion notification [RFC5670] is an IETF technology to use a
   virtual queue for AQM marking for packets within one Diffserv class
   in order to give early warning prior to any real queuing.  The PCN-
   marking algorithms have been designed not to take into account packet
   size when forwarding through queues.  Instead, the general principle
   has been to take the sizes of marked packets into account when
   monitoring the fraction of marking at the edge of the network, as
   recommended here.

4.2.3.  Making Transports Robust against Control Packet Losses

   Recently, two RFCs have defined changes to TCP that make it more
   robust against losing small control packets [RFC5562] [RFC5690].  In
   both cases, they note that the case for these two TCP changes would
   be weaker if RED were biased against dropping small packets.  We
   argue here that these two proposals are a safer and more principled
   way to achieve TCP performance improvements than reverse engineering
   RED to benefit TCP.

   Although there are no known proposals, it would also be possible and
   perfectly valid to make control packets robust against drop by
   requesting a scheduling class with lower drop probability, which
   would be achieved by re-marking to a Diffserv code point [RFC2474]
   within the same behaviour aggregate.

   Although not brought to the IETF, a simple proposal from Wischik
   [DupTCP] suggests that the first three packets of every TCP flow
   should be routinely duplicated after a short delay.  It shows that
   this would greatly improve the chances of short flows completing



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   quickly, but it would hardly increase traffic levels on the Internet,
   because Internet bytes have always been concentrated in the large
   flows.  It further shows that the performance of many typical
   applications depends on completion of long serial chains of short
   messages.  It argues that, given most of the value people get from
   the Internet is concentrated within short flows, this simple
   expedient would greatly increase the value of the best-effort
   Internet at minimal cost.  A similar but more extensive approach has
   been evaluated on Google servers [GentleAggro].

   The proposals discussed in this sub-section are experimental
   approaches that are not yet in wide operational use, but they are
   existence proofs that transports can make themselves robust against
   loss of control packets.  The examples are all TCP-based, but
   applications over non-TCP transports could mitigate loss of control
   packets by making similar use of Diffserv, data duplication, FEC,
   etc.

4.2.4.  Congestion Notification: Summary of Conflicting Advice

   +-----------+-----------------+-----------------+-------------------+
   | transport |  RED_1 (packet- |  RED_4 (linear  |   RED_5 (square   |
   |        cc |    mode drop)   | byte-mode drop) |  byte-mode drop)  |
   +-----------+-----------------+-----------------+-------------------+
   |    TCP or |    s/sqrt(p)    |    sqrt(s/p)    |     1/sqrt(p)     |
   |      TFRC |                 |                 |                   |
   |   TFRC-SP |    1/sqrt(p)    |   1/sqrt(s*p)   |   1/(s*sqrt(p))   |
   +-----------+-----------------+-----------------+-------------------+

    Table 2: Dependence of flow bit rate per RTT on packet size, s, and
     drop probability, p, when there is network and/or transport bias
                 towards small packets to varying degrees

   Table 2 aims to summarise the potential effects of all the advice
   from different sources.  Each column shows a different possible AQM
   behaviour in different queues in the network, using the terminology
   of Cnodder et al. outlined earlier (RED_1 is basic RED with packet-
   mode drop).  Each row shows a different transport behaviour: TCP
   [RFC5681] and TFRC [RFC5348] on the top row with TFRC-SP [RFC4828]
   below.  Each cell shows how the bits per round trip of a flow depends
   on packet size, s, and drop probability, p.  In order to declutter
   the formulae to focus on packet-size dependence, they are all given
   per round trip, which removes any RTT term.

   Let us assume that the goal is for the bit rate of a flow to be
   independent of packet size.  Suppressing all inessential details, the
   table shows that this should either be achievable by not altering the
   TCP transport in a RED_5 network, or using the small packet TFRC-SP



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   transport (or similar) in a network without any byte-mode dropping
   RED (top right and bottom left).  Top left is the 'do nothing'
   scenario, while bottom right is the 'do both' scenario in which the
   bit rate would become far too biased towards small packets.  Of
   course, if any form of byte-mode dropping RED has been deployed on a
   subset of queues that congest, each path through the network will
   present a different hybrid scenario to its transport.

   Whatever the case, we can see that the linear byte-mode drop column
   in the middle would considerably complicate the Internet.  Even if
   one believes the network should be doing the biasing, linear byte-
   mode drop is a half-way house that doesn't bias enough towards small
   packets.  Section 2 recommends that _all_ bias in network equipment
   towards small packets should be turned off -- if indeed any equipment
   vendors have implemented it -- leaving packet-size bias solely as the
   preserve of the transport layer (solely the leftmost, packet-mode
   drop column).

   In practice, it seems that no deliberate bias towards small packets
   has been implemented for production networks.  Of the 19% of vendors
   who responded to a survey of 84 equipment vendors, none had
   implemented byte-mode drop in RED (see Appendix A for details).

5.  Outstanding Issues and Next Steps

5.1.  Bit-congestible Network

   For a connectionless network with nearly all resources being bit-
   congestible, the recommended position is clear -- the network should
   not make allowance for packet sizes and the transport should.  This
   leaves two outstanding issues:

   o  The question of how to handle any legacy AQM deployments using
      byte-mode drop;

   o  The need to start a programme to update transport congestion
      control protocol standards to take packet size into account.

   A survey of equipment vendors (Section 4.2.4) found no evidence that
   byte-mode packet drop had been implemented, so deployment will be
   sparse at best.  A migration strategy is not really needed to remove
   an algorithm that may not even be deployed.

   A programme of experimental updates to take packet size into account
   in transport congestion control protocols has already started with
   TFRC-SP [RFC4828].





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5.2.  Bit- and Packet-Congestible Network

   The position is much less clear-cut if the Internet becomes populated
   by a more even mix of both packet-congestible and bit-congestible
   resources (see Appendix B.2).  This problem is not pressing, because
   most Internet resources are designed to be bit-congestible before
   packet processing starts to congest (see Section 1.1).

   The IRTF's Internet Congestion Control Research Group (ICCRG) has set
   itself the task of reaching consensus on generic forwarding
   mechanisms that are necessary and sufficient to support the
   Internet's future congestion control requirements (the first
   challenge in [RFC6077]).  The research question of whether packet
   congestion might become common and what to do if it does may in the
   future be explored in the IRTF (the "Challenge 3: Packet Size" in
   [RFC6077]).

   Note that sometimes it seems that resources might be congested by
   neither bits nor packets, e.g., where the queue for access to a
   wireless medium is in units of transmission opportunities.  However,
   the root cause of congestion of the underlying spectrum is overload
   of bits (see Section 4.1.2).

6.  Security Considerations

   This memo recommends that queues do not bias drop probability due to
   packets size.  For instance, dropping small packets less often than
   large ones creates a perverse incentive for transports to break down
   their flows into tiny segments.  One of the benefits of implementing
   AQM was meant to be to remove this perverse incentive that tail-drop
   queues gave to small packets.

   In practice, transports cannot all be trusted to respond to
   congestion.  So another reason for recommending that queues not bias
   drop probability towards small packets is to avoid the vulnerability
   to small-packet DDoS attacks that would otherwise result.  One of the
   benefits of implementing AQM was meant to be to remove tail drop's
   DoS vulnerability to small packets, so we shouldn't add it back
   again.

   If most queues implemented AQM with byte-mode drop, the resulting
   network would amplify the potency of a small-packet DDoS attack.  At
   the first queue, the stream of packets would push aside a greater
   proportion of large packets, so more of the small packets would
   survive to attack the next queue.  Thus a flood of small packets
   would continue on towards the destination, pushing regular traffic
   with large packets out of the way in one queue after the next, but
   suffering much less drop itself.



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   Appendix C explains why the ability of networks to police the
   response of _any_ transport to congestion depends on bit-congestible
   network resources only doing packet-mode drop, not byte-mode drop.
   In summary, it says that making drop probability depend on the size
   of the packets that bits happen to be divided into simply encourages
   the bits to be divided into smaller packets.  Byte-mode drop would
   therefore irreversibly complicate any attempt to fix the Internet's
   incentive structures.

7.  Conclusions

   This memo identifies the three distinct stages of the congestion
   notification process where implementations need to decide whether to
   take packet size into account.  The recommendations provided in
   Section 2 of this memo are different in each case:

   o  When network equipment measures the length of a queue, if it is
      not feasible to use time; it is recommended to count in bytes if
      the network resource is congested by bytes, or to count in packets
      if is congested by packets.

   o  When network equipment decides whether to drop (or mark) a packet,
      it is recommended that the size of the particular packet should
      not be taken into account.

   o  However, when a transport algorithm responds to a dropped or
      marked packet, the size of the rate reduction should be
      proportionate to the size of the packet.

   In summary, the answers are 'it depends', 'no', and 'yes',
   respectively.

   For the specific case of RED, this means that byte-mode queue
   measurement will often be appropriate, but the use of byte-mode drop
   is very strongly discouraged.

   At the transport layer, the IETF should continue updating congestion
   control protocols to take into account the size of each packet that
   indicates congestion.  Also, the IETF should continue to make
   protocols less sensitive to losing control packets like SYNs, pure
   ACKs, and DNS exchanges.  Although many control packets happen to be
   small, the alternative of network equipment favouring all small
   packets would be dangerous.  That would create perverse incentives to
   split data transfers into smaller packets.

   The memo develops these recommendations from principled arguments
   concerning scaling, layering, incentives, inherent efficiency,
   security, and 'policeability'.  It also addresses practical issues



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   such as specific buffer architectures and incremental deployment.
   Indeed, a limited survey of RED implementations is discussed, which
   shows there appears to be little, if any, installed base of RED's
   byte-mode drop.  Therefore, it can be deprecated with little, if any,
   incremental deployment complications.

   The recommendations have been developed on the well-founded basis
   that most Internet resources are bit-congestible, not packet-
   congestible.  We need to know the likelihood that this assumption
   will prevail in the longer term and, if it might not, what protocol
   changes will be needed to cater for a mix of the two.  The IRTF
   Internet Congestion Control Research Group (ICCRG) is currently
   working on these problems [RFC6077].

8.  Acknowledgements

   Thank you to Sally Floyd, who gave extensive and useful review
   comments.  Also thanks for the reviews from Philip Eardley, David
   Black, Fred Baker, David Taht, Toby Moncaster, Arnaud Jacquet, and
   Mirja Kuehlewind, as well as helpful explanations of different
   hardware approaches from Larry Dunn and Fred Baker.  We are grateful
   to Bruce Davie and his colleagues for providing a timely and
   efficient survey of RED implementation in Cisco's product range.
   Also, grateful thanks to Toby Moncaster, Will Dormann, John Regnault,
   Simon Carter, and Stefaan De Cnodder who further helped survey the
   current status of RED implementation and deployment, and, finally,
   thanks to the anonymous individuals who responded.

   Bob Briscoe and Jukka Manner were partly funded by Trilogy and
   Trilogy 2, research projects (ICT-216372, ICT-317756) supported by
   the European Community under its Seventh Framework Programme.  The
   views expressed here are those of the authors only.

9.  References

9.1.  Normative References

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC2309]  Braden, B., Clark, D., Crowcroft, J., Davie, B., Deering,
              S., Estrin, D., Floyd, S., Jacobson, V., Minshall, G.,
              Partridge, C., Peterson, L., Ramakrishnan, K., Shenker,
              S., Wroclawski, J., and L. Zhang, "Recommendations on
              Queue Management and Congestion Avoidance in the
              Internet", RFC 2309, April 1998.





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   [RFC2914]  Floyd, S., "Congestion Control Principles", BCP 41, RFC
              2914, September 2000.

   [RFC3168]  Ramakrishnan, K., Floyd, S., and D. Black, "The Addition
              of Explicit Congestion Notification (ECN) to IP", RFC
              3168, September 2001.

9.2.  Informative References

   [BLUE02]   Feng, W-c., Shin, K., Kandlur, D., and D. Saha, "The BLUE
              active queue management algorithms", IEEE/ACM Transactions
              on Networking 10(4) 513-528, August 2002,
              <http://dx.doi.org/10.1109/TNET.2002.801399>.

   [CCvarPktSize]
              Widmer, J., Boutremans, C., and J-Y. Le Boudec, "End-to-
              end congestion control for TCP-friendly flows with
              variable packet size", ACM CCR 34(2) 137-151, April 2004,
              <http://doi.acm.org/10.1145/997150.997162>.

   [CHOKe_Var_Pkt]
              Psounis, K., Pan, R., and B. Prabhaker, "Approximate Fair
              Dropping for Variable-Length Packets", IEEE Micro
              21(1):48-56, January-February 2001,
              <http://ieeexplore.ieee.org/xpl/
              articleDetails.jsp?arnumber=903061>.

   [CoDel]    Nichols, K. and V. Jacobson, "Controlled Delay Active
              Queue Management", Work in Progress, February 2013.

   [DRQ]      Shin, M., Chong, S., and I. Rhee, "Dual-Resource TCP/AQM
              for Processing-Constrained Networks", IEEE/ACM
              Transactions on Networking Vol 16, issue 2, April 2008,
              <http://dx.doi.org/10.1109/TNET.2007.900415>.

   [DupTCP]   Wischik, D., "Short messages", Philosophical Transactions
              of the Royal Society A 366(1872):1941-1953, June 2008,
              <http://rsta.royalsocietypublishing.org/content/366/1872/
              1941.full.pdf+html>.

   [ECNFixedWireless]
              Siris, V., "Resource Control for Elastic Traffic in CDMA
              Networks", Proc. ACM MOBICOM'02 , September 2002,
              <http://www.ics.forth.gr/netlab/publications/
              resource_control_elastic_cdma.html>.






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   [Evol_cc]  Gibbens, R. and F. Kelly, "Resource pricing and the
              evolution of congestion control", Automatica
              35(12)1969-1985, December 1999,
              <http://www.sciencedirect.com/science/article/pii/
              S0005109899001351>.

   [GentleAggro]
              Flach, T., Dukkipati, N., Terzis, A., Raghavan, B.,
              Cardwell, N., Cheng, Y., Jain, A., Hao, S., Katz-Bassett,
              E., and R. Govindan, "Reducing web latency: the virtue of
              gentle aggression", ACM SIGCOMM CCR 43(4)159-170, August
              2013, <http://doi.acm.org/10.1145/2486001.2486014>.

   [IOSArch]  Bollapragada, V., White, R., and C. Murphy, "Inside Cisco
              IOS Software Architecture", Cisco Press: CCIE Professional
              Development ISBN13: 978-1-57870-181-0, July 2000.

   [PIE]      Pan, R., Natarajan, P., Piglione, C., Prabhu, M.,
              Subramanian, V., Baker, F., and B. Steeg, "PIE: A
              Lightweight Control Scheme To Address the Bufferbloat
              Problem", Work in Progress, February 2014.

   [PktSizeEquCC]
              Vasallo, P., "Variable Packet Size Equation-Based
              Congestion Control", ICSI Technical Report tr-00-008,
              2000, <http://http.icsi.berkeley.edu/ftp/global/pub/
              techreports/2000/tr-00-008.pdf>.

   [RED93]    Floyd, S. and V. Jacobson, "Random Early Detection (RED)
              gateways for Congestion Avoidance", IEEE/ACM Transactions
              on Networking 1(4) 397--413, August 1993,
              <http://ieeexplore.ieee.org/xpls/
              abs_all.jsp?arnumber=251892>.

   [REDbias]  Eddy, W. and M. Allman, "A Comparison of RED's Byte and
              Packet Modes", Computer Networks 42(3) 261--280, June
              2003,
              <http://www.ir.bbn.com/documents/articles/redbias.ps>.

   [REDbyte]  De Cnodder, S., Elloumi, O., and K. Pauwels, "Effect of
              different packet sizes on RED performance", Proc. 5th IEEE
              Symposium on Computers and Communications (ISCC) 793-799,
              July 2000, <http://ieeexplore.ieee.org/xpls/
              abs_all.jsp?arnumber=860741>.







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   [RFC2474]  Nichols, K., Blake, S., Baker, F., and D. Black,
              "Definition of the Differentiated Services Field (DS
              Field) in the IPv4 and IPv6 Headers", RFC 2474, December
              1998.

   [RFC3426]  Floyd, S., "General Architectural and Policy
              Considerations", RFC 3426, November 2002.

   [RFC3550]  Schulzrinne, H., Casner, S., Frederick, R., and V.
              Jacobson, "RTP: A Transport Protocol for Real-Time
              Applications", STD 64, RFC 3550, July 2003.

   [RFC3714]  Floyd, S. and J. Kempf, "IAB Concerns Regarding Congestion
              Control for Voice Traffic in the Internet", RFC 3714,
              March 2004.

   [RFC4828]  Floyd, S. and E. Kohler, "TCP Friendly Rate Control
              (TFRC): The Small-Packet (SP) Variant", RFC 4828, April
              2007.

   [RFC5348]  Floyd, S., Handley, M., Padhye, J., and J. Widmer, "TCP
              Friendly Rate Control (TFRC): Protocol Specification", RFC
              5348, September 2008.

   [RFC5562]  Kuzmanovic, A., Mondal, A., Floyd, S., and K.
              Ramakrishnan, "Adding Explicit Congestion Notification
              (ECN) Capability to TCP's SYN/ACK Packets", RFC 5562, June
              2009.

   [RFC5670]  Eardley, P., "Metering and Marking Behaviour of PCN-
              Nodes", RFC 5670, November 2009.

   [RFC5681]  Allman, M., Paxson, V., and E. Blanton, "TCP Congestion
              Control", RFC 5681, September 2009.

   [RFC5690]  Floyd, S., Arcia, A., Ros, D., and J. Iyengar, "Adding
              Acknowledgement Congestion Control to TCP", RFC 5690,
              February 2010.

   [RFC6077]  Papadimitriou, D., Welzl, M., Scharf, M., and B. Briscoe,
              "Open Research Issues in Internet Congestion Control", RFC
              6077, February 2011.

   [RFC6679]  Westerlund, M., Johansson, I., Perkins, C., O'Hanlon, P.,
              and K. Carlberg, "Explicit Congestion Notification (ECN)
              for RTP over UDP", RFC 6679, August 2012.





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   [RFC6789]  Briscoe, B., Woundy, R., and A. Cooper, "Congestion
              Exposure (ConEx) Concepts and Use Cases", RFC 6789,
              December 2012.

   [Rate_fair_Dis]
              Briscoe, B., "Flow Rate Fairness: Dismantling a Religion",
              ACM CCR 37(2)63-74, April 2007,
              <http://portal.acm.org/citation.cfm?id=1232926>.

   [gentle_RED]
              Floyd, S., "Recommendation on using the "gentle_" variant
              of RED", Web page , March 2000,
              <http://www.icir.org/floyd/red/gentle.html>.

   [pBox]     Floyd, S. and K. Fall, "Promoting the Use of End-to-End
              Congestion Control", IEEE/ACM Transactions on Networking
              7(4) 458--472, August 1999, <http://ieeexplore.ieee.org/
              xpls/abs_all.jsp?arnumber=793002>.

   [pktByteEmail]
              Floyd, S., "RED: Discussions of Byte and Packet Modes",
              email, March 1997,
              <http://ee.lbl.gov/floyd/REDaveraging.txt>.




























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Appendix A.  Survey of RED Implementation Status

   This Appendix is informative, not normative.

   In May 2007 a survey was conducted of 84 vendors to assess how widely
   drop probability based on packet size has been implemented in RED
   Table 3.  About 19% of those surveyed replied, giving a sample size
   of 16.  Although in most cases we do not have permission to identify
   the respondents, we can say that those that have responded include
   most of the larger equipment vendors, covering a large fraction of
   the market.  The two who gave permission to be identified were Cisco
   and Alcatel-Lucent.  The others range across the large network
   equipment vendors at L3 & L2, firewall vendors, wireless equipment
   vendors, as well as large software businesses with a small selection
   of networking products.  All those who responded confirmed that they
   have not implemented the variant of RED with drop dependent on packet
   size (2 were fairly sure they had not but needed to check more
   thoroughly).  At the time the survey was conducted, Linux did not
   implement RED with packet-size bias of drop, although we have not
   investigated a wider range of open source code.

     +-------------------------------+----------------+--------------+
     |                      Response | No. of vendors | % of vendors |
     +-------------------------------+----------------+--------------+
     |               Not implemented |             14 |          17% |
     |    Not implemented (probably) |              2 |           2% |
     |                   Implemented |              0 |           0% |
     |                   No response |             68 |          81% |
     | Total companies/orgs surveyed |             84 |         100% |
     +-------------------------------+----------------+--------------+

    Table 3: Vendor Survey on byte-mode drop variant of RED (lower drop
                      probability for small packets)

   Where reasons were given for why the byte-mode drop variant had not
   been implemented, the extra complexity of packet-bias code was most
   prevalent, though one vendor had a more principled reason for
   avoiding it -- similar to the argument of this document.

   Our survey was of vendor implementations, so we cannot be certain
   about operator deployment.  But we believe many queues in the
   Internet are still tail drop.  The company of one of the co-authors
   (BT) has widely deployed RED; however, many tail-drop queues are
   bound to still exist, particularly in access network equipment and on
   middleboxes like firewalls, where RED is not always available.






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   Routers using a memory architecture based on fixed-size buffers with
   borrowing may also still be prevalent in the Internet.  As explained
   in Section 4.2.1, these also provide a marginal (but legitimate) bias
   towards small packets.  So even though RED byte-mode drop is not
   prevalent, it is likely there is still some bias towards small
   packets in the Internet due to tail-drop and fixed-buffer borrowing.

Appendix B.  Sufficiency of Packet-Mode Drop

   This Appendix is informative, not normative.

   Here we check that packet-mode drop (or marking) in the network gives
   sufficiently generic information for the transport layer to use.  We
   check against a 2x2 matrix of four scenarios that may occur now or in
   the future (Table 4).  Checking the two scenarios in each of the
   horizontal and vertical dimensions tests the extremes of sensitivity
   to packet size in the transport and in the network respectively.

   Note that this section does not consider byte-mode drop at all.
   Having deprecated byte-mode drop, the goal here is to check that
   packet-mode drop will be sufficient in all cases.

   +-------------------------------+-----------------+-----------------+
   |                  Transport -> |  a) Independent | b) Dependent on |
   | ----------------------------- |  of packet size |  packet size of |
   | Network                       |  of congestion  |    congestion   |
   |                               |  notifications  |  notifications  |
   +-------------------------------+-----------------+-----------------+
   | 1) Predominantly bit-         |   Scenario a1)  |   Scenario b1)  |
   | congestible network           |                 |                 |
   | 2) Mix of bit-congestible and |   Scenario a2)  |   Scenario b2)  |
   | pkt-congestible network       |                 |                 |
   +-------------------------------+-----------------+-----------------+

                Table 4: Four Possible Congestion Scenarios

   Appendix B.1 focuses on the horizontal dimension of Table 4 checking
   that packet-mode drop (or marking) gives sufficient information,
   whether or not the transport uses it -- scenarios b) and a)
   respectively.

   Appendix B.2 focuses on the vertical dimension of Table 4, checking
   that packet-mode drop gives sufficient information to the transport
   whether resources in the network are bit-congestible or packet-
   congestible (these terms are defined in Section 1.1).






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   Notation:  To be concrete, we will compare two flows with different
      packet sizes, s_1 and s_2.  As an example, we will take
      s_1 = 60 B = 480 b and s_2 = 1,500 B = 12,000 b.

      A flow's bit rate, x [bps], is related to its packet rate, u
      [pps], by

         x(t) = s*u(t).

      In the bit-congestible case, path congestion will be denoted by
      p_b, and in the packet-congestible case by p_p.  When either case
      is implied, the letter p alone will denote path congestion.

B.1.  Packet-Size (In)Dependence in Transports

   In all cases, we consider a packet-mode drop queue that indicates
   congestion by dropping (or marking) packets with probability p
   irrespective of packet size.  We use an example value of loss
   (marking) probability, p=0.1%.

   A transport like TCP as specified in RFC 5681 treats a congestion
   notification on any packet whatever its size as one event.  However,
   a network with just the packet-mode drop algorithm gives more
   information if the transport chooses to use it.  We will use Table 5
   to illustrate this.

   We will set aside the last column until later.  The columns labelled
   'Flow 1' and 'Flow 2' compare two flows consisting of 60 B and
   1,500 B packets respectively.  The body of the table considers two
   separate cases, one where the flows have an equal bit rate and the
   other with equal packet rates.  In both cases, the two flows fill a
   96 Mbps link.  Therefore, in the equal bit rate case, they each have
   half the bit rate (48Mbps).  Whereas, with equal packet rates, Flow 1
   uses 25 times smaller packets so it gets 25 times less bit rate -- it
   only gets 1/(1+25) of the link capacity (96 Mbps / 26 = 4 Mbps after
   rounding).  In contrast Flow 2 gets 25 times more bit rate (92 Mbps)
   in the equal packet rate case because its packets are 25 times
   larger.  The packet rate shown for each flow could easily be derived
   once the bit rate was known by dividing the bit rate by packet size,
   as shown in the column labelled 'Formula'.











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      Parameter               Formula       Flow 1   Flow 2 Combined
      ----------------------- ----------- -------- -------- --------
      Packet size             s/8             60 B  1,500 B    (Mix)
      Packet size             s              480 b 12,000 b    (Mix)
      Pkt loss probability    p               0.1%     0.1%     0.1%

      EQUAL BIT RATE CASE
      Bit rate                x            48 Mbps  48 Mbps  96 Mbps
      Packet rate             u = x/s     100 kpps   4 kpps 104 kpps
      Absolute pkt-loss rate  p*u          100 pps    4 pps  104 pps
      Absolute bit-loss rate  p*u*s        48 kbps  48 kbps  96 kbps
      Ratio of lost/sent pkts p*u/u           0.1%     0.1%     0.1%
      Ratio of lost/sent bits p*u*s/(u*s)     0.1%     0.1%     0.1%

      EQUAL PACKET RATE CASE
      Bit rate                x             4 Mbps  92 Mbps  96 Mbps
      Packet rate             u = x/s       8 kpps   8 kpps  15 kpps
      Absolute pkt-loss rate  p*u            8 pps    8 pps   15 pps
      Absolute bit-loss rate  p*u*s         4 kbps  92 kbps  96 kbps
      Ratio of lost/sent pkts p*u/u           0.1%     0.1%     0.1%
      Ratio of lost/sent bits p*u*s/(u*s)     0.1%     0.1%     0.1%

    Table 5: Absolute Loss Rates and Loss Ratios for Flows of Small and
                      Large Packets and Both Combined

   So far, we have merely set up the scenarios.  We now consider
   congestion notification in the scenario.  Two TCP flows with the same
   round-trip time aim to equalise their packet-loss rates over time;
   that is, the number of packets lost in a second, which is the packets
   per second (u) multiplied by the probability that each one is dropped
   (p).  Thus, TCP converges on the case labelled 'Equal packet rate' in
   the table, where both flows aim for the same absolute packet-loss
   rate (both 8 pps in the table).

   Packet-mode drop actually gives flows sufficient information to
   measure their loss rate in bits per second, if they choose, not just
   packets per second.  Each flow can count the size of a lost or marked
   packet and scale its rate response in proportion (as TFRC-SP does).
   The result is shown in the row entitled 'Absolute bit-loss rate',
   where the bits lost in a second is the packets per second (u)
   multiplied by the probability of losing a packet (p) multiplied by
   the packet size (s).  Such an algorithm would try to remove any
   imbalance in the bit-loss rate such as the wide disparity in the case
   labelled 'Equal packet rate' (4k bps vs. 92 kbps).  Instead, a
   packet-size-dependent algorithm would aim for equal bit-loss rates,
   which would drive both flows towards the case labelled 'Equal bit
   rate', by driving them to equal bit-loss rates (both 48 kbps in this
   example).



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   The explanation so far has assumed that each flow consists of packets
   of only one constant size.  Nonetheless, it extends naturally to
   flows with mixed packet sizes.  In the right-most column of Table 5,
   a flow of mixed-size packets is created simply by considering Flow 1
   and Flow 2 as a single aggregated flow.  There is no need for a flow
   to maintain an average packet size.  It is only necessary for the
   transport to scale its response to each congestion indication by the
   size of each individual lost (or marked) packet.  Taking, for
   example, the case labelled 'Equal packet rate', in one second about 8
   small packets and 8 large packets are lost (making closer to 15 than
   16 losses per second due to rounding).  If the transport multiplies
   each loss by its size, in one second it responds to 8*480 and
   8*12,000 lost bits, adding up to 96,000 lost bits in a second.  This
   double checks correctly, being the same as 0.1% of the total bit rate
   of 96 Mbps.  For completeness, the formula for absolute bit-loss rate
   is p(u1*s1+u2*s2).

   Incidentally, a transport will always measure the loss probability
   the same, irrespective of whether it measures in packets or in bytes.
   In other words, the ratio of lost packets to sent packets will be the
   same as the ratio of lost bytes to sent bytes.  (This is why TCP's
   bit rate is still proportional to packet size, even when byte
   counting is used, as recommended for TCP in [RFC5681], mainly for
   orthogonal security reasons.)  This is intuitively obvious by
   comparing two example flows; one with 60 B packets, the other with
   1,500 B packets.  If both flows pass through a queue with drop
   probability 0.1%, each flow will lose 1 in 1,000 packets.  In the
   stream of 60 B packets, the ratio of lost bytes to sent bytes will be
   60 B in every 60,000 B; and in the stream of 1,500 B packets, the
   loss ratio will be 1,500 B out of 1,500,000 B.  When the transport
   responds to the ratio of lost to sent packets, it will measure the
   same ratio whether it measures in packets or bytes: 0.1% in both
   cases.  The fact that this ratio is the same whether measured in
   packets or bytes can be seen in Table 5, where the ratio of lost
   packets to sent packets and the ratio of lost bytes to sent bytes is
   always 0.1% in all cases (recall that the scenario was set up with
   p=0.1%).

   This discussion of how the ratio can be measured in packets or bytes
   is only raised here to highlight that it is irrelevant to this memo!
   Whether or not a transport depends on packet size depends on how this
   ratio is used within the congestion control algorithm.

   So far, we have shown that packet-mode drop passes sufficient
   information to the transport layer so that the transport can take bit
   congestion into account, by using the sizes of the packets that
   indicate congestion.  We have also shown that the transport can




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   choose not to take packet size into account if it wishes.  We will
   now consider whether the transport can know which to do.

B.2.  Bit-Congestible and Packet-Congestible Indications

   As a thought-experiment, imagine an idealised congestion notification
   protocol that supports both bit-congestible and packet-congestible
   resources.  It would require at least two ECN flags, one for each of
   the bit-congestible and packet-congestible resources.

   1.  A packet-congestible resource trying to code congestion level p_p
       into a packet stream should mark the idealised 'packet
       congestion' field in each packet with probability p_p
       irrespective of the packet's size.  The transport should then
       take a packet with the packet congestion field marked to mean
       just one mark, irrespective of the packet size.

   2.  A bit-congestible resource trying to code time-varying byte-
       congestion level p_b into a packet stream should mark the 'byte
       congestion' field in each packet with probability p_b, again
       irrespective of the packet's size.  Unlike before, the transport
       should take a packet with the byte congestion field marked to
       count as a mark on each byte in the packet.

   This hides a fundamental problem -- much more fundamental than
   whether we can magically create header space for yet another ECN
   flag, or whether it would work while being deployed incrementally.
   Distinguishing drop from delivery naturally provides just one
   implicit bit of congestion indication information -- the packet is
   either dropped or not.  It is hard to drop a packet in two ways that
   are distinguishable remotely.  This is a similar problem to that of
   distinguishing wireless transmission losses from congestive losses.

   This problem would not be solved, even if ECN were universally
   deployed.  A congestion notification protocol must survive a
   transition from low levels of congestion to high.  Marking two states
   is feasible with explicit marking, but it is much harder if packets
   are dropped.  Also, it will not always be cost-effective to implement
   AQM at every low-level resource, so drop will often have to suffice.

   We are not saying two ECN fields will be needed (and we are not
   saying that somehow a resource should be able to drop a packet in one
   of two different ways so that the transport can distinguish which
   sort of drop it was!).  These two congestion notification channels
   are a conceptual device to illustrate a dilemma we could face in the
   future.  Section 3 gives four good reasons why it would be a bad idea
   to allow for packet size by biasing drop probability in favour of
   small packets within the network.  The impracticality of our thought



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   experiment shows that it will be hard to give transports a practical
   way to know whether or not to take into account the size of
   congestion indication packets.

   Fortunately, this dilemma is not pressing because by design most
   equipment becomes bit-congested before its packet processing becomes
   congested (as already outlined in Section 1.1).  Therefore,
   transports can be designed on the relatively sound assumption that a
   congestion indication will usually imply bit congestion.

   Nonetheless, although the above idealised protocol isn't intended for
   implementation, we do want to emphasise that research is needed to
   predict whether there are good reasons to believe that packet
   congestion might become more common, and if so, to find a way to
   somehow distinguish between bit and packet congestion [RFC3714].

   Recently, the dual resource queue (DRQ) proposal [DRQ] has been made
   on the premise that, as network processors become more cost-
   effective, per-packet operations will become more complex
   (irrespective of whether more function in the network is desirable).
   Consequently the premise is that CPU congestion will become more
   common.  DRQ is a proposed modification to the RED algorithm that
   folds both bit congestion and packet congestion into one signal
   (either loss or ECN).

   Finally, we note one further complication.  Strictly, packet-
   congestible resources are often cycle-congestible.  For instance, for
   routing lookups, load depends on the complexity of each lookup and
   whether or not the pattern of arrivals is amenable to caching.  This
   also reminds us that any solution must not require a forwarding
   engine to use excessive processor cycles in order to decide how to
   say it has no spare processor cycles.

Appendix C.  Byte-Mode Drop Complicates Policing Congestion Response

   This section is informative, not normative.

   There are two main classes of approach to policing congestion
   response: (i) policing at each bottleneck link or (ii) policing at
   the edges of networks.  Packet-mode drop in RED is compatible with
   either, while byte-mode drop precludes edge policing.

   The simplicity of an edge policer relies on one dropped or marked
   packet being equivalent to another of the same size without having to
   know which link the drop or mark occurred at.  However, the byte-mode
   drop algorithm has to depend on the local MTU of the line -- it needs
   to use some concept of a 'normal' packet size.  Therefore, one
   dropped or marked packet from a byte-mode drop algorithm is not



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   necessarily equivalent to another from a different link.  A policing
   function local to the link can know the local MTU where the
   congestion occurred.  However, a policer at the edge of the network
   cannot, at least not without a lot of complexity.

   The early research proposals for type (i) policing at a bottleneck
   link [pBox] used byte-mode drop, then detected flows that contributed
   disproportionately to the number of packets dropped.  However, with
   no extra complexity, later proposals used packet-mode drop and looked
   for flows that contributed a disproportionate amount of dropped bytes
   [CHOKe_Var_Pkt].

   Work is progressing on the Congestion Exposure (ConEx) protocol
   [RFC6789], which enables a type (ii) edge policer located at a user's
   attachment point.  The idea is to be able to take an integrated view
   of the effect of all a user's traffic on any link in the
   internetwork.  However, byte-mode drop would effectively preclude
   such edge policing because of the MTU issue above.

   Indeed, making drop probability depend on the size of the packets
   that bits happen to be divided into would simply encourage the bits
   to be divided into smaller packets in order to confuse policing.  In
   contrast, as long as a dropped/marked packet is taken to mean that
   all the bytes in the packet are dropped/marked, a policer can remain
   robust against sequences of bits being re-divided into different size
   packets or across different size flows [Rate_fair_Dis].

























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Authors' Addresses

   Bob Briscoe
   BT
   B54/77, Adastral Park
   Martlesham Heath
   Ipswich  IP5 3RE
   UK

   Phone: +44 1473 645196
   EMail: bob.briscoe@bt.com
   URI:   http://bobbriscoe.net/

   Jukka Manner
   Aalto University
   Department of Communications and Networking (Comnet)
   P.O. Box 13000
   FIN-00076 Aalto
   Finland

   Phone: +358 9 470 22481
   EMail: jukka.manner@aalto.fi
   URI:   http://www.netlab.tkk.fi/~jmanner/




























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