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  • Computing TCP's Retransmission Timer https://www.rfceditor.org/rfc/rfc6298.txt

    https://www.rfc-editor.org/rfc/rfc6298.txt







    Internet Engineering Task Force (IETF)                         V. Paxson
    Request for Comments: 6298                              ICSI/UC Berkeley
    Obsoletes: 2988                                                M. Allman
    Updates: 1122                                                       ICSI
    Category: Standards Track                                         J. Chu
    ISSN: 2070-1721                                                   Google
                                                                  M. Sargent
                                                                        CWRU
                                                                   June 2011


                      Computing TCP's Retransmission Timer

    Abstract

       This document defines the standard algorithm that Transmission
       Control Protocol (TCP) senders are required to use to compute and
       manage their retransmission timer.  It expands on the discussion in
       Section 4.2.3.1 of RFC 1122 and upgrades the requirement of
       supporting the algorithm from a SHOULD to a MUST.  This document
       obsoletes RFC 2988.

    Status of This Memo

       This is an Internet Standards Track document.

       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
       Internet Standards 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/rfc6298.
















    Paxson, et al.               Standards Track                    [Page 1]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


    Copyright Notice

       Copyright (c) 2011 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.

    1.  Introduction

       The Transmission Control Protocol (TCP) [Pos81] uses a retransmission
       timer to ensure data delivery in the absence of any feedback from the
       remote data receiver.  The duration of this timer is referred to as
       RTO (retransmission timeout).  RFC 1122 [Bra89] specifies that the
       RTO should be calculated as outlined in [Jac88].

       This document codifies the algorithm for setting the RTO.  In
       addition, this document expands on the discussion in Section 4.2.3.1
       of RFC 1122 and upgrades the requirement of supporting the algorithm
       from a SHOULD to a MUST.  RFC 5681 [APB09] outlines the algorithm TCP
       uses to begin sending after the RTO expires and a retransmission is
       sent.  This document does not alter the behavior outlined in RFC 5681
       [APB09].

       In some situations, it may be beneficial for a TCP sender to be more
       conservative than the algorithms detailed in this document allow.
       However, a TCP MUST NOT be more aggressive than the following
       algorithms allow.  This document obsoletes RFC 2988 [PA00].

       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 [Bra97].

    2.  The Basic Algorithm

       To compute the current RTO, a TCP sender maintains two state
       variables, SRTT (smoothed round-trip time) and RTTVAR (round-trip
       time variation).  In addition, we assume a clock granularity of G
       seconds.





    Paxson, et al.               Standards Track                    [Page 2]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


       The rules governing the computation of SRTT, RTTVAR, and RTO are as
       follows:

       (2.1) Until a round-trip time (RTT) measurement has been made for a
             segment sent between the sender and receiver, the sender SHOULD
             set RTO <- 1 second, though the "backing off" on repeated
             retransmission discussed in (5.5) still applies.

             Note that the previous version of this document used an initial
             RTO of 3 seconds [PA00].  A TCP implementation MAY still use
             this value (or any other value > 1 second).  This change in the
             lower bound on the initial RTO is discussed in further detail
             in Appendix A.

       (2.2) When the first RTT measurement R is made, the host MUST set

                SRTT <- R
                RTTVAR <- R/2
                RTO <- SRTT + max (G, K*RTTVAR)

             where K = 4.

       (2.3) When a subsequent RTT measurement R' is made, a host MUST set

                RTTVAR <- (1 - beta) * RTTVAR + beta * |SRTT - R'|
                SRTT <- (1 - alpha) * SRTT + alpha * R'

             The value of SRTT used in the update to RTTVAR is its value
             before updating SRTT itself using the second assignment.  That
             is, updating RTTVAR and SRTT MUST be computed in the above
             order.

             The above SHOULD be computed using alpha=1/8 and beta=1/4 (as
             suggested in [JK88]).

             After the computation, a host MUST update
             RTO <- SRTT + max (G, K*RTTVAR)

       (2.4) Whenever RTO is computed, if it is less than 1 second, then the
             RTO SHOULD be rounded up to 1 second.

             Traditionally, TCP implementations use coarse grain clocks to
             measure the RTT and trigger the RTO, which imposes a large
             minimum value on the RTO.  Research suggests that a large
             minimum RTO is needed to keep TCP conservative and avoid
             spurious retransmissions [AP99].  Therefore, this specification
             requires a large minimum RTO as a conservative approach, while




    Paxson, et al.               Standards Track                    [Page 3]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


             at the same time acknowledging that at some future point,
             research may show that a smaller minimum RTO is acceptable or
             superior.

       (2.5) A maximum value MAY be placed on RTO provided it is at least 60
             seconds.

    3.  Taking RTT Samples

       TCP MUST use Karn's algorithm [KP87] for taking RTT samples.  That
       is, RTT samples MUST NOT be made using segments that were
       retransmitted (and thus for which it is ambiguous whether the reply
       was for the first instance of the packet or a later instance).  The
       only case when TCP can safely take RTT samples from retransmitted
       segments is when the TCP timestamp option [JBB92] is employed, since
       the timestamp option removes the ambiguity regarding which instance
       of the data segment triggered the acknowledgment.

       Traditionally, TCP implementations have taken one RTT measurement at
       a time (typically, once per RTT).  However, when using the timestamp
       option, each ACK can be used as an RTT sample.  RFC 1323 [JBB92]
       suggests that TCP connections utilizing large congestion windows
       should take many RTT samples per window of data to avoid aliasing
       effects in the estimated RTT.  A TCP implementation MUST take at
       least one RTT measurement per RTT (unless that is not possible per
       Karn's algorithm).

       For fairly modest congestion window sizes, research suggests that
       timing each segment does not lead to a better RTT estimator [AP99].
       Additionally, when multiple samples are taken per RTT, the alpha and
       beta defined in Section 2 may keep an inadequate RTT history.  A
       method for changing these constants is currently an open research
       question.

    4.  Clock Granularity

       There is no requirement for the clock granularity G used for
       computing RTT measurements and the different state variables.
       However, if the K*RTTVAR term in the RTO calculation equals zero, the
       variance term MUST be rounded to G seconds (i.e., use the equation
       given in step 2.3).

           RTO <- SRTT + max (G, K*RTTVAR)

       Experience has shown that finer clock granularities (<= 100 msec)
       perform somewhat better than coarser granularities.





    Paxson, et al.               Standards Track                    [Page 4]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


       Note that [Jac88] outlines several clever tricks that can be used to
       obtain better precision from coarse granularity timers.  These
       changes are widely implemented in current TCP implementations.

    5.  Managing the RTO Timer

       An implementation MUST manage the retransmission timer(s) in such a
       way that a segment is never retransmitted too early, i.e., less than
       one RTO after the previous transmission of that segment.

       The following is the RECOMMENDED algorithm for managing the
       retransmission timer:

       (5.1) Every time a packet containing data is sent (including a
             retransmission), if the timer is not running, start it running
             so that it will expire after RTO seconds (for the current value
             of RTO).

       (5.2) When all outstanding data has been acknowledged, turn off the
             retransmission timer.

       (5.3) When an ACK is received that acknowledges new data, restart the
             retransmission timer so that it will expire after RTO seconds
             (for the current value of RTO).

       When the retransmission timer expires, do the following:

       (5.4) Retransmit the earliest segment that has not been acknowledged
             by the TCP receiver.

       (5.5) The host MUST set RTO <- RTO * 2 ("back off the timer").  The
             maximum value discussed in (2.5) above may be used to provide
             an upper bound to this doubling operation.

       (5.6) Start the retransmission timer, such that it expires after RTO
             seconds (for the value of RTO after the doubling operation
             outlined in 5.5).

       (5.7) If the timer expires awaiting the ACK of a SYN segment and the
             TCP implementation is using an RTO less than 3 seconds, the RTO
             MUST be re-initialized to 3 seconds when data transmission
             begins (i.e., after the three-way handshake completes).

             This represents a change from the previous version of this
             document [PA00] and is discussed in Appendix A.






    Paxson, et al.               Standards Track                    [Page 5]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


       Note that after retransmitting, once a new RTT measurement is
       obtained (which can only happen when new data has been sent and
       acknowledged), the computations outlined in Section 2 are performed,
       including the computation of RTO, which may result in "collapsing"
       RTO back down after it has been subject to exponential back off (rule
       5.5).

       Note that a TCP implementation MAY clear SRTT and RTTVAR after
       backing off the timer multiple times as it is likely that the current
       SRTT and RTTVAR are bogus in this situation.  Once SRTT and RTTVAR
       are cleared, they should be initialized with the next RTT sample
       taken per (2.2) rather than using (2.3).

    6.  Security Considerations

       This document requires a TCP to wait for a given interval before
       retransmitting an unacknowledged segment.  An attacker could cause a
       TCP sender to compute a large value of RTO by adding delay to a timed
       packet's latency, or that of its acknowledgment.  However, the
       ability to add delay to a packet's latency often coincides with the
       ability to cause the packet to be lost, so it is difficult to see
       what an attacker might gain from such an attack that could cause more
       damage than simply discarding some of the TCP connection's packets.

       The Internet, to a considerable degree, relies on the correct
       implementation of the RTO algorithm (as well as those described in
       RFC 5681) in order to preserve network stability and avoid congestion
       collapse.  An attacker could cause TCP endpoints to respond more
       aggressively in the face of congestion by forging acknowledgments for
       segments before the receiver has actually received the data, thus
       lowering RTO to an unsafe value.  But to do so requires spoofing the
       acknowledgments correctly, which is difficult unless the attacker can
       monitor traffic along the path between the sender and the receiver.
       In addition, even if the attacker can cause the sender's RTO to reach
       too small a value, it appears the attacker cannot leverage this into
       much of an attack (compared to the other damage they can do if they
       can spoof packets belonging to the connection), since the sending TCP
       will still back off its timer in the face of an incorrectly
       transmitted packet's loss due to actual congestion.

       The security considerations in RFC 5681 [APB09] are also applicable
       to this document.









    Paxson, et al.               Standards Track                    [Page 6]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


    7.  Changes from RFC 2988

       This document reduces the initial RTO from the previous 3 seconds
       [PA00] to 1 second, unless the SYN or the ACK of the SYN is lost, in
       which case the default RTO is reverted to 3 seconds before data
       transmission begins.

    8.  Acknowledgments

       The RTO algorithm described in this memo was originated by Van
       Jacobson in [Jac88].

       Much of the data that motivated changing the initial RTO from 3
       seconds to 1 second came from Robert Love, Andre Broido, and Mike
       Belshe.

    9.  References

    9.1.  Normative References

       [APB09] Allman, M., Paxson, V., and E. Blanton, "TCP Congestion
               Control", RFC 5681, September 2009.

       [Bra89] Braden, R., Ed., "Requirements for Internet Hosts -
               Communication Layers", STD 3, RFC 1122, October 1989.

       [Bra97] Bradner, S., "Key words for use in RFCs to Indicate
               Requirement Levels", BCP 14, RFC 2119, March 1997.

       [JBB92] Jacobson, V., Braden, R., and D. Borman, "TCP Extensions for
               High Performance", RFC 1323, May 1992.

       [Pos81] Postel, J., "Transmission Control Protocol", STD 7, RFC 793,
               September 1981.

    9.2.  Informative References

       [AP99]  Allman, M. and V. Paxson, "On Estimating End-to-End Network
               Path Properties", SIGCOMM 99.

       [Chu09] Chu, J., "Tuning TCP Parameters for the 21st Century",
               http://www.ietf.org/proceedings/75/slides/tcpm-1.pdf, July
               2009.

       [SLS09] Schulman, A., Levin, D., and Spring, N., "CRAWDAD data set
               umd/sigcomm2008 (v. 2009-03-02)",
               http://crawdad.cs.dartmouth.edu/umd/sigcomm2008, March, 2009.




    Paxson, et al.               Standards Track                    [Page 7]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


       [HKA04] Henderson, T., Kotz, D., and Abyzov, I., "CRAWDAD trace
               dartmouth/campus/tcpdump/fall03 (v. 2004-11-09)",
               http://crawdad.cs.dartmouth.edu/dartmouth/campus/
               tcpdump/fall03, November 2004.

       [Jac88] Jacobson, V., "Congestion Avoidance and Control", Computer
               Communication Review, vol. 18, no. 4, pp. 314-329, Aug.
               1988.

       [JK88]  Jacobson, V. and M. Karels, "Congestion Avoidance and
               Control", ftp://ftp.ee.lbl.gov/papers/congavoid.ps.Z.

       [KP87]  Karn, P. and C. Partridge, "Improving Round-Trip Time
               Estimates in Reliable Transport Protocols", SIGCOMM 87.

       [PA00]  Paxson, V. and M. Allman, "Computing TCP's Retransmission
               Timer", RFC 2988, November 2000.


































    Paxson, et al.               Standards Track                    [Page 8]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


    Appendix A.  Rationale for Lowering the Initial RTO

       Choosing a reasonable initial RTO requires balancing two competing
       considerations:

       1. The initial RTO should be sufficiently large to cover most of the
          end-to-end paths to avoid spurious retransmissions and their
          associated negative performance impact.

       2. The initial RTO should be small enough to ensure a timely recovery
          from packet loss occurring before an RTT sample is taken.

       Traditionally, TCP has used 3 seconds as the initial RTO [Bra89]
       [PA00].  This document calls for lowering this value to 1 second
       using the following rationale:

       - Modern networks are simply faster than the state-of-the-art was at
         the time the initial RTO of 3 seconds was defined.

       - Studies have found that the round-trip times of more than 97.5% of
         the connections observed in a large scale analysis were less than 1
         second [Chu09], suggesting that 1 second meets criterion 1 above.

       - In addition, the studies observed retransmission rates within the
         three-way handshake of roughly 2%.  This shows that reducing the
         initial RTO has benefit to a non-negligible set of connections.

       - However, roughly 2.5% of the connections studied in [Chu09] have an
         RTT longer than 1 second.  For those connections, a 1 second
         initial RTO guarantees a retransmission during connection
         establishment (needed or not).

         When this happens, this document calls for reverting to an initial
         RTO of 3 seconds for the data transmission phase.  Therefore, the
         implications of the spurious retransmission are modest: (1) an
         extra SYN is transmitted into the network, and (2) according to RFC
         5681 [APB09] the initial congestion window will be limited to 1
         segment.  While (2) clearly puts such connections at a
         disadvantage, this document at least resets the RTO such that the
         connection will not continually run into problems with a short
         timeout.  (Of course, if the RTT is more than 3 seconds, the
         connection will still encounter difficulties.  But that is not a
         new issue for TCP.)

         In addition, we note that when using timestamps, TCP will be able
         to take an RTT sample even in the presence of a spurious
         retransmission, facilitating convergence to a correct RTT estimate
         when the RTT exceeds 1 second.



    Paxson, et al.               Standards Track                    [Page 9]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


       As an additional check on the results presented in [Chu09], we
       analyzed packet traces of client behavior collected at four different
       vantage points at different times, as follows:

       Name       Dates            Pkts.   Cnns.  Clnts. Servs.
       --------------------------------------------------------
       LBL-1      Oct/05--Mar/06   292M    242K   228    74K
       LBL-2      Nov/09--Feb/10   1.1B    1.2M   1047   38K
       ICSI-1     Sep/11--18/07    137M    2.1M   193    486K
       ICSI-2     Sep/11--18/08    163M    1.9M   177    277K
       ICSI-3     Sep/14--21/09    334M    3.1M   170    253K
       ICSI-4     Sep/11--18/10    298M    5M     183    189K
       Dartmouth  Jan/4--21/04     1B      4M     3782   132K
       SIGCOMM    Aug/17--21/08    11.6M   133K   152    29K

       The "LBL" data was taken at the Lawrence Berkeley National
       Laboratory, the "ICSI" data from the International Computer Science
       Institute, the "SIGCOMM" data from the wireless network that served
       the attendees of SIGCOMM 2008, and the "Dartmouth" data was collected
       from Dartmouth College's wireless network.  The latter two datasets
       are available from the CRAWDAD data repository [HKA04] [SLS09].  The
       table lists the dates of the data collections, the number of packets
       collected, the number of TCP connections observed, the number of
       local clients monitored, and the number of remote servers contacted.
       We consider only connections initiated near the tracing vantage
       point.

       Analysis of these datasets finds the prevalence of retransmitted SYNs
       to be between 0.03% (ICSI-4) to roughly 2% (LBL-1 and Dartmouth).

       We then analyzed the data to determine the number of additional and
       spurious retransmissions that would have been incurred if the initial
       RTO was assumed to be 1 second.  In most of the datasets, the
       proportion of connections with spurious retransmits was less than
       0.1%.  However, in the Dartmouth dataset, approximately 1.1% of the
       connections would have sent a spurious retransmit with a lower
       initial RTO.  We attribute this to the fact that the monitored
       network is wireless and therefore susceptible to additional delays
       from RF effects.

       Finally, there are obviously performance benefits from retransmitting
       lost SYNs with a reduced initial RTO.  Across our datasets, the
       percentage of connections that retransmitted a SYN and would realize
       at least a 10% performance improvement by using the smaller initial
       RTO specified in this document ranges from 43% (LBL-1) to 87%
       (ICSI-4).  The percentage of connections that would realize at least
       a 50% performance improvement ranges from 17% (ICSI-1 and SIGCOMM) to
       73% (ICSI-4).



    Paxson, et al.               Standards Track                   [Page 10]

    RFC 6298          Computing TCP's Retransmission Timer         June 2011


       From the data to which we have access, we conclude that the lower
       initial RTO is likely to be beneficial to many connections, and
       harmful to relatively few.

       Authors' Addresses

       Vern Paxson
       ICSI/UC Berkeley
       1947 Center Street
       Suite 600
       Berkeley, CA 94704-1198

       Phone: 510-666-2882
       EMail: vern@icir.org
       http://www.icir.org/vern/


       Mark Allman
       ICSI
       1947 Center Street
       Suite 600
       Berkeley, CA 94704-1198

       Phone: 440-235-1792
       EMail: mallman@icir.org
       http://www.icir.org/mallman/


       H.K. Jerry Chu
       Google, Inc.
       1600 Amphitheatre Parkway
       Mountain View, CA 94043

       Phone: 650-253-3010
       EMail: hkchu@google.com


       Matt Sargent
       Case Western Reserve University
       Olin Building
       10900 Euclid Avenue
       Room 505
       Cleveland, OH 44106

       Phone: 440-223-5932
       EMail: mts71@case.edu





    Paxson, et al.               Standards Track                   [Page 11]

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