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Internet Engineering Task Force                                M. Allman
INTERNET-DRAFT                                                      ICSI
File: draft-ietf-tcpm-rto-consider-10.txt               February 4, 2020
Intended Status: Best Current Practice
Expires: August 4, 2020


               Requirements for Time-Based Loss Detection

Status of this Memo

    This Internet-Draft is submitted in full conformance with the
    provisions of BCP 78 and BCP 79.  Internet-Drafts are working
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    This Internet-Draft will expire on August 4, 2020.

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    Copyright (c) 2020 IETF Trust and the persons identified as the
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Abstract

    Many protocols must detect packet loss for various reasons (e.g., to
    ensure reliability using retransmissions or to understand the level
    of congestion along a network path).  While many mechanisms have
    been designed to detect loss, protocols ultimately can only count on
    the passage of time without delivery confirmation to declare a
    packet "lost".  Each implementation of a time-based loss detection
    mechanism represents a balance between correctness and timeliness
    and therefore no implementation suits all situations.  This document

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    provides high-level requirements for time-based loss detectors
    appropriate for general use in the Internet.  Within the
    requirements, implementations have latitude to define particulars
    that best address each situation.

Terminology

    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 BCP 14, RFC 2119
    [RFC2119].

1   Introduction

    Loss detection is a crucial activity for many protocols and
    applications and is generally undertaken for two major reasons:

      (1) Ensuring reliable data delivery.

            This requires a data sender to develop an understanding of
            which transmitted packets have not arrived at the receiver.
            This knowledge allows the sender to retransmit missing data.

      (2) Congestion control.

            Packet loss is often taken as an indication that the sender
            is transmitting too fast and is overwhelming some portion of
            the network path.  Data senders can therefore use loss to
            trigger transmission rate reductions.

    Various mechanisms are used to detect losses in a packet stream.
    Often we use continuous or periodic acknowledgments from the
    recipient to inform the sender's notion of which pieces of data are
    missing.  However, despite our best intentions and most robust
    mechanisms we cannot place ultimate faith in receiving such
    acknowledgments, but can only truly depend on the passage of time.
    Therefore, our ultimate backstop to ensuring that we detect all loss
    is a timeout.  That is, the sender sets some expectation for how
    long to wait for confirmation of delivery for a given piece of data.
    When this time period passes without delivery confirmation the
    sender concludes the data was lost in transit.

    The specifics of time-based loss detection schemes represent a
    tradeoff between correctness and responsiveness.  In other words we
    wish to simultaneously:

      - wait long enough to ensure the detection of loss is correct, and

      - minimize the amount of delay we impose on applications (before
        repairing loss) and the network (before we reduce the
        congestion).

    Serving both of these goals is difficult as they pull in opposite
    directions [AP99].  By not waiting long enough to accurately

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    determine a packet has been lost we risk sending unnecessary
    ("spurious") retransmissions and needlessly lowering the
    transmission rate.  By waiting long enough that we are unambiguously
    certain a packet has been lost we cannot repair losses in a timely
    manner and we risk prolonging network congestion.

    Many protocols and applications use their own time-based loss
    detection mechanisms (e.g., TCP [RFC6298], SCTP [RFC4960], SIP
    [RFC3261]).  At this point, our experience has lead to a recognition
    that often specific tweaks that deviate from standardized time-based
    loss detectors do not materially impact network safety.  Therefore,
    in this document we outline a set of high-level protocol-agnostic
    requirements for time-based loss detection.  The intent is to
    provide a safe foundation on which implementations have the
    flexibility to instantiate mechanisms that best realize their
    specific goals.

2   Context

    This document is different from other standards documents in that it
    is backwards from the way we generally like to engineer systems.
    Usually, we strive to understand high-level requirements as a
    starting point.  We then methodically engineer specific protocols,
    algorithms and systems that meet these requirements.  Within the
    standards process we have derived many time-based loss detection
    schemes without benefit from some over-arching requirements
    document---because we had no idea how to write such a document!
    Therefore, we made the best specific decisions we could in response
    to specific needs.

    At this point, however, the community's experience has matured to
    the point where we can define a set of high-level requirements for
    time-based loss detection schemes.  We now understand how to
    separate the strategies these mechanisms use that are crucial for
    network safety from those small details that do not materially
    impact network safety.  However, adding a requirements umbrella to a
    body of existing specifications is inherently messy and we run the
    risk of creating inconsistencies with both past and future
    mechanisms.  The correct way to view this document is as the default
    case.  Specifically:

      - This document does not update or obsolete any existing RFC.
        These previous specifications---while generally consistent with
        the requirements in this document---reflect community consensus
        and this document does not change that consensus.

      - The requirements in this document are meant to provide for
        network safety and, as such, SHOULD be used by all time-based
        loss detection mechanisms.

      - The requirements in this document may not be appropriate in all
        cases and, therefore, inconsistent deviations may be necessary
        (hence the "SHOULD" in the last bullet).  However,
        inconsistencies MUST be (a) explained and (b) gather consensus.

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3   Scope

    The principles we outline in this document are protocol-agnostic and
    widely applicable.  We make the following scope statements about
    the application of the requirements discussed in Section 4:

    (S.1) The requirements in this document apply only to time-based
          loss detection.

          While there are a bevy of uses for timers in protocols---from
          rate-based pacing to connection failure detection and
          beyond---these are outside the scope of this document.

    (S.2) The requirements in this document apply only to endpoint-to-
          endpoint unicast communication.  Reliable multicast (e.g.,
          [RFC5740]) protocols are explicitly outside the scope of this
          document.

          Protocols such as SCTP [RFC4960] and MP-TCP [RFC6182] that
          communicate in a unicast fashion with multiple specific
          endpoints can leverage the requirements in this document
          provided they track state and follow the requirements for each
          endpoint independently.  I.e., if host A communicates with
          hosts B and C, A needs to use independent time-based loss
          detector instances for traffic sent to B and C.

    (S.3) There are cases where state is shared across connections
          or flows (e.g., [RFC2140], [RFC3124]).  State pertaining to
          time-based loss detection is often discussed as sharable.
          These situations raise issues that the simple flow-oriented
          time-based loss detection mechanism discussed in this document
          does not consider (e.g., how long to preserve state between
          connections).  Therefore, while the general principles given
          in Section 4 are likely applicable, sharing time-based loss
          detection information across flows is outside the scope of
          this document.

    (S.4) The requirements for time-based loss detection mechanisms in
          this document can be applied regardless of whether the
          mechanism is the sole loss repair strategy or works in concert
          with other mechanisms.

          E.g., for a simple protocol like UDP-based DNS
          [RFC1034,RFC1035] a timeout and re-try mechanism is likely to
          act alone to ensure reliability.

          E.g., complex protocols like TCP or SCTP have methods to
          detect (and repair) loss based on explicit endpoint state
          sharing [RFC2018,RFC4960,RFC6675].  These mechanisms are
          preferred over a time-based loss detection as they are often
          more timely and precise than time-based schemes.  In these
          cases, a time-based scheme---called a "retransmission timeout"
          or "RTO"---becomes a last resort when the more advanced

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          mechanisms fail.

          E.g., some protocols may leverage more than one time-based
          loss detector simultaneously.  In these cases, the general
          guidance in this document can be applied to all such timers.

4   Requirements

    We now list the requirements that apply when designing time-based
    loss detection mechanisms.  For historical reasons and ease of
    exposition, we refer to the time between sending a packet and
    determining the packet has been lost due to lack of delivery
    confirmation as the "retransmission timeout" or "RTO".  However, the
    detected loss need not be repaired (i.e., the loss could be detected
    only for congestion control and not reliability purposes).

    (1) As we note above, loss detection happens when a sender does not
        receive delivery confirmation within an some expected period of
        time.  In the absence of any knowledge about the latency of a
        path, the initial RTO MUST be conservatively set to no less than
        1 second.

        Correctness is of the utmost importance when transmitting into a
        network with unknown properties because:

        - Premature loss detection can trigger spurious retransmits that
          could cause issues when a network is already congested.

        - Premature loss detection can needlessly cause congestion
          control to dramatically lower the sender's allowed
          transmission rate---especially since the rate is already
          likely low at this stage of the communication.  Recovering
          from such a rate change can taken a relatively long time.

        - Finally, as discussed below, sometimes using time-based
          loss detection and retransmissions can cause ambiguities in
          assessing the latency of a network path.  Therefore, it is
          especially important for the first latency sample to be free
          of ambiguities such that there is a baseline for the remainder
          of the communication.

        The specific constant (1 second) comes from the analysis of
        Internet RTTs found in Appendix A of [RFC6298].

    (2) We now specify four requirements that pertain to setting
        an expected time interval for delivery confirmation.

        Often measuring the time required for delivery confirmation is
        is framed as assessing the "round-trip time (RTT)" of the
        network path as this is the minimum amount of time required to
        receive delivery confirmation and also often follows protocol
        behavior whereby acknowledgments are generated quickly after
        data arrives.  For instance, this is the case for the RTO used
        by TCP [RFC6298] and SCTP [RFC4960].  However, this is somewhat

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        mis-leading and the expected latency is better framed as the
        "feedback time" (FT).  In other words, the expectation is not
        always simply a network property, but can include additional
        time before a sender should reasonably expect a response.

        For instance, consider a UDP-based DNS request from a client to
        a recursive resolver.  When the request can be served from the
        resolver's cache the FT likely well approximates the network RTT
        between the client and resolver.  However, on a cache miss the
        resolver will request the needed information from one or more
        authoritative DNS servers, which will non-trivially increase the
        FT compared to the network RTT between the client and resolver.

        Therefore, we express the requirements in terms of FT.  Again,
        for ease of exposition we use "RTO" to indicate the interval
        between a packet transmission and the decision the packet has
        been lost---regardless of whether the packet will be
        retransmitted.

        (a) In steady state the RTO SHOULD be set based on observations
            of both the FT and the variance of the FT.

            In other words, the RTO should represent an empirically-
            derived reasonable amount of time that the sender should
            wait for delivery confirmation before deciding the given
            data is lost.  Networks are inherently dynamic and therefore
            it is crucial to allow for some variance in the FT when
            developing the expectation.


        (b) FT observations SHOULD be taken and incorporated into the
            RTO at least once per RTT or as frequently as data is
            exchanged in cases where that happens less frequently than
            once per RTT.

            Internet measurements show that taking only a single FT
            sample per TCP connection results in a relatively poorly
            performing RTO mechanism [AP99], hence this requirement that
            the FT be sampled continuously throughout the lifetime of
            communication.

            As an example, TCP takes an FT sample roughly once per RTT,
            or if using the timestamp option [RFC7323] on each
            acknowledgment arrival.  [AP99] shows that both these
            approaches result in roughly equivalent performance for the
            RTO estimator.

        (c) FT observations MAY be taken from non-data exchanges.

            Some protocols use keepalives, heartbeats or other messages
            to exchange control information.  To the extent that the
            latency of these transactions mirrors data exchange, they
            can be leveraged to take FT samples within the RTO
            mechanism.  Such samples can help protocols keep their RTO

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            accurate during lulls in data transmission.  However, given
            that these messages may not be subject to the same delays as
            data transmission, we do not take a general view on whether
            this is useful or not.

        (d) An RTO mechanism MUST NOT use ambiguous FT samples.

            Assume two copies of some segment X are transmitted at times
            t0 and t1 and then at time t2 the sender receives
            confirmation that X in fact arrived.  In some cases, it is
            not clear which copy of X triggered the confirmation and
            hence the actual FT is either t2-t1 or t2-t0, but which is a
            mystery.  Therefore, in this situation an implementation
            MUST use Karn's algorithm [KP87,RFC6298] and use neither
            version of the FT sample and hence not update the RTO.

            There are cases where two copies of some data are
            transmitted in a way whereby the sender can tell which is
            being acknowledged by an incoming ACK.  E.g., TCP's
            timestamp option [RFC7323] allows for segments to be
            uniquely identified and hence avoid the ambiguity.  In such
            cases there is no ambiguity and the resulting samples can
            update the RTO.


    (3) Each time the RTO is used to detect a loss, the value of the RTO
        MUST be exponentially backed off such that the next firing
        requires a longer interval.  The backoff SHOULD be removed after
        the subsequent transmission of non-retransmitted data.

        A maximum value MAY be placed on the RTO.  The maximum RTO MUST
        NOT be less than 60 seconds (as specified in [RFC6298]).

        This ensures network safety.

    (4) Loss detected by the RTO mechanism MUST be taken as an
        indication of network congestion and the sending rate adapted
        using a standard mechanism (e.g., TCP collapses the congestion
        window to one segment [RFC5681]).

        This ensures network safety.

        An exception to this rule is if an IETF standardized mechanism
        determines that a particular loss is due to a non-congestion
        event (e.g., packet corruption).  In such a case a congestion
        control action is not required.  Additionally, congestion
        control actions taken based on time-based loss detection could
        be reversed when a standard mechanism post-facto determines that
        the cause of the loss was not congestion (e.g., [RFC5682]).

5   Discussion

    We note that research has shown the tension between the
    responsiveness and correctness of time-based loss detection seems to

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    be a fundamental tradeoff in the context of TCP [AP99].  That is,
    making the RTO more aggressive (e.g., via changing TCP's EWMA gains,
    lowering the minimum RTO, etc.) can reduce the time required to
    detect actual loss.  However, at the same time, such aggressiveness
    leads to more cases of mistakenly declaring packets lost that
    ultimately arrived at the receiver.  Therefore, being as aggressive
    as the requirements given in the previous section allow in any
    particular situation may not be the best course of action because
    detecting loss---even if falsely---carries a requirement to invoke a
    congestion response which will ultimately reduce the transmission
    rate.

    While the tradeoff between responsiveness and correctness seems
    fundamental, the tradeoff can be made less relevant if the sender
    can detect and recover from mistaken loss detection.  Several
    mechanisms have been proposed for this purpose, such as Eifel
    [RFC3522], F-RTO [RFC5682] and DSACK [RFC2883,RFC3708].  Using such
    mechanisms may allow a data originator to tip towards being more
    responsive without incurring (as much of) the attendant costs of
    mistakenly declaring packets to be lost.

    Also, note, that in addition to the experiments discussed in [AP99],
    the Linux TCP implementation has been using various non-standard RTO
    mechanisms for many years seemingly without large scale problems
    (e.g., using different EWMA gains than specified in [RFC6298]).
    Further, a number of implementations use minimum RTOs that are less
    than the 1 second specified in [RFC6298].  While the implication of
    these deviations from the standard may be more spurious retransmits
    (per [AP99]), we are aware of no large scale network safety issues
    caused by this change to the minimum RTO.

    Finally, we note that while allowing implementations to be more
    aggressive could in fact increase the number of needless
    retransmissions the above requirements fail safe in that they insist
    on exponential backoff and a transmission rate reduction.
    Therefore, providing implementers more latitude than they have
    traditionally been given in IETF specifications of RTO mechanisms
    does not somehow open the flood gates to aggressive behavior.  Since
    there is a downside to being aggressive the incentives for proper
    behavior are retained in the mechanism.

6   Security Considerations

    This document does not alter the security properties of time-based
    loss detection mechanisms.  See [RFC6298] for a discussion of these
    within the context of TCP.

Acknowledgments

    This document benefits from years of discussions with Ethan Blanton,
    Sally Floyd, Jana Iyengar, Shawn Ostermann, Vern Paxson, and the
    members of the TCPM and TCP-IMPL working groups.  Ran Atkinson,
    Yuchung Cheng, David Black, Gorry Fairhurst, Mirja Kuhlewind,
    Nicolas Kuhn, Jonathan Looney and Michael Scharf provided useful

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    comments on a previous version of this draft.

Normative References

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

Informative References

    [AP99] Allman, M., V. Paxson, "On Estimating End-to-End Network Path
        Properties", Proceedings of the ACM SIGCOMM Technical Symposium,
        September 1999.

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

    [RFC1034] Mockapetris, P.  "Domain Names - Concepts and Facilities",
        RFC 1034, November 1987.

    [RFC1035] Mockapetris, P.  "Domain Names - Implementation and
        Specification", RFC 1035, November 1987.

    [RFC2018] Mathis, M., Mahdavi, J., Floyd, S., and A. Romanow, "TCP
        Selective Acknowledgment Options", RFC 2018, October 1996.

    [RFC2140] Touch, J., "TCP Control Block Interdependence", RFC 2140,
        April 1997.

    [RFC2883] Floyd, S., Mahdavi, J., Mathis, M., and M. Podolsky, "An
        Extension to the Selective Acknowledgement (SACK) Option for
        TCP", RFC 2883, July 2000.

    [RFC3124] Balakrishnan, H., S. Seshan, "The Congestion Manager", RFC
        2134, June 2001.

    [RFC3261] Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston,
        A., Peterson, J., Sparks, R., Handley, M., and E. Schooler,
        "SIP: Session Initiation Protocol", RFC 3261, June 2002.

    [RFC3522] Ludwig, R., M. Meyer, "The Eifel Detection Algorithm for
        TCP", RFC 3522, april 2003.

    [RFC3708] Blanton, E., M. Allman, "Using TCP Duplicate Selective
        Acknowledgement (DSACKs) and Stream Control Transmission
        Protocol (SCTP) Duplicate Transmission Sequence Numbers (TSNs)
        to Detect Spurious Retransmissions", RFC 3708, February 2004.

    [RFC3940] Adamson, B., C. Bormann, M. Handley, J. Macker,
        "Negative-acknowledgment (NACK)-Oriented Reliable Multicast
        (NORM) Protocol", November 2004, RFC 3940.

    [RFC4340] Kohler, E., M. Handley, S. Floyd, "Datagram Congestion
        Control Protocol (DCCP)", March 2006, RFC 4340.


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    [RFC4960] Stweart, R., "Stream Control Transmission Protocol", RFC
        4960, September 2007.

    [RFC5682] Sarolahti, P., M. Kojo, K. Yamamoto, M. Hata, "Forward
        RTO-Recovery (F-RTO): An Algorithm for Detecting Spurious
        Retransmission Timeouts with TCP", RFC 5682, September 2009.

    [RFC5740] Adamson, B., C. Bormann, M. Handley, J. Macker,
        "NACK-Oriented Reliable Multicast (NORM) Transport Protocol",
        November 2009, RFC 5740.

    [RFC6182] Ford, A., C. Raiciu, M. Handley, S. Barre, J. Iyengar,
        "Architectural Guidelines for Multipath TCP Development", March
        2011, RFC 6182.

    [RFC6298] Paxson, V., M. Allman, H.K. Chu, M. Sargent, "Computing
        TCP's Retransmission Timer", June 2011, RFC 6298.

    [RFC6582] Henderson, T., S. Floyd, A. Gurtov, Y. Nishida, "The
        NewReno Modification to TCP's Fast Recovery Algorithm", April
        2012, RFC 6582.

    [RFC6675] Blanton, E., M. Allman, L. Wang, I. Jarvinen, M.  Kojo,
        Y. Nishida, "A Conservative Loss Recovery Algorithm Based on
        Selective Acknowledgment (SACK) for TCP", August 2012, RFC 6675.

    [RFC7323] Borman D., B. Braden, V. Jacobson, R. Scheffenegger, "TCP
        Extensions for High Performance", September 2014, RFC 7323.

Authors' Addresses

    Mark Allman
    International Computer Science Institute
    1947 Center St.  Suite 600
    Berkeley, CA  94704

    EMail: mallman@icir.org
    http://www.icir.org/mallman

















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