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RFC7661

  1. RFC 7661
Internet Engineering Task Force (IETF)                      G. Fairhurst
Request for Comments: 7661                               A. Sathiaseelan
Obsoletes: 2861                                                R. Secchi
Category: Experimental                            University of Aberdeen
ISSN: 2070-1721                                             October 2015


              Updating TCP to Support Rate-Limited Traffic

Abstract

   This document provides a mechanism to address issues that arise when
   TCP is used for traffic that exhibits periods where the sending rate
   is limited by the application rather than the congestion window.  It
   provides an experimental update to TCP that allows a TCP sender to
   restart quickly following a rate-limited interval.  This method is
   expected to benefit applications that send rate-limited traffic using
   TCP while also providing an appropriate response if congestion is
   experienced.

   This document also evaluates the Experimental specification of TCP
   Congestion Window Validation (CWV) defined in RFC 2861 and concludes
   that RFC 2861 sought to address important issues but failed to
   deliver a widely used solution.  This document therefore reclassifies
   the status of RFC 2861 from Experimental to Historic.  This document
   obsoletes RFC 2861.

Status of This Memo

   This document is not an Internet Standards Track specification; it is
   published for examination, experimental implementation, and
   evaluation.

   This document defines an Experimental Protocol for the Internet
   community.  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).  Not
   all documents approved by the IESG are a candidate for any level of
   Internet Standard; see 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/rfc7661.







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Copyright Notice

   Copyright (c) 2015 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.

Table of Contents

   1. Introduction ....................................................3
      1.1. Implementation of New CWV ..................................5
      1.2. Standards Status of This Document ..........................5
   2. Reviewing Experience with TCP-CWV ...............................5
   3. Terminology .....................................................7
   4. A New Congestion Window Validation Method .......................8
      4.1. Initialisation .............................................8
      4.2. Estimating the Validated Capacity Supported by a Path ......8
      4.3. Preserving cwnd during a Rate-Limited Period ..............10
      4.4. TCP Congestion Control during the Non-validated Phase .....11
           4.4.1. Response to Congestion in the Non-validated Phase ..12
           4.4.2. Sender Burst Control during the
                  Non-validated Phase ................................14
           4.4.3. Adjustment at the End of the Non-validated
                  Period (NVP) .......................................14
      4.5. Examples of Implementation ................................15
           4.5.1. Implementing the pipeACK Measurement ...............15
           4.5.2. Measurement of the NVP and pipeACK Samples .........16
           4.5.3. Implementing Detection of the cwnd-Limited
                  Condition ..........................................17
   5. Determining a Safe Period to Preserve cwnd .....................17
   6. Security Considerations ........................................18
   7. References .....................................................18
      7.1. Normative References ......................................18
      7.2. Informative References ....................................19
   Acknowledgments ...................................................21
   Authors' Addresses ................................................21







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1.  Introduction

   TCP is used for traffic with a range of application behaviours.  The
   TCP congestion window (cwnd) controls the maximum number of
   unacknowledged packets/bytes that a TCP flow may have in the network
   at any time, a value known as the FlightSize [RFC5681].  FlightSize
   is a measure of the volume of data that is unacknowledged at a
   specific time.  A bulk application will always have data available to
   transmit.  The rate at which it sends is therefore limited by the
   maximum permitted by the receiver advertised window and the sender
   congestion window (cwnd).  The FlightSize of a bulk flow increases
   with the cwnd and tracks the volume of data acknowledged in the last
   Round-Trip Time (RTT).

   In contrast, a rate-limited application will experience periods when
   the sender is either idle or unable to send at the maximum rate
   permitted by the cwnd.  In this case, the volume of data sent
   (FlightSize) can change significantly from one RTT to another and can
   be much less than the cwnd.  Hence, it is possible that the
   FlightSize could significantly exceed the recently used capacity.
   The update in this document targets the operation of TCP in such
   rate-limited cases.

   Standard TCP states that a TCP sender SHOULD set cwnd to no more than
   the Restart Window (RW) before beginning transmission if the TCP
   sender has not sent data in an interval exceeding the retransmission
   timeout, i.e., when an application becomes idle [RFC5681].  [RFC2861]
   notes that this TCP behaviour was not always observed in current
   implementations.  Experiments confirm this to still be the case (see
   [Bis08]).

   Congestion Window Validation (CWV) [RFC2861] introduced the term
   "application-limited period" for the time when the sender sends less
   than is allowed by the congestion or receiver windows.  [RFC2861]
   described a method that improved support for applications that vary
   their transmission rate, i.e., applications that either have (short)
   idle periods between transmissions or change the rate at which they
   send.  These applications are characterised by the TCP FlightSize
   often being less than the cwnd.  Many Internet applications exhibit
   this behaviour, including web browsing, HTTP-based adaptive
   streaming, applications that support query/response type protocols,
   network file sharing, and live video transmission.  Many such
   applications currently avoid using long-lived (persistent) TCP
   connections (e.g., servers that use HTTP/1.1 [RFC7230] typically
   support persistent HTTP connections but do not enable this by
   default).  Instead, such applications often either use a succession
   of short TCP transfers or use UDP.




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   Standard TCP does not impose additional restrictions on the growth of
   the congestion window when a TCP sender is unable to send at the
   maximum rate allowed by the cwnd.  In this case, the rate-limited
   sender may grow a cwnd far beyond that corresponding to the current
   transmit rate, resulting in a value that does not reflect current
   information about the state of the network path the flow is using.
   Use of such an invalid cwnd may result in reduced application
   performance and/or could significantly contribute to network
   congestion.

   [RFC2861] proposed a solution to these issues in an experimental
   method known as CWV.  CWV was intended to help reduce cases where TCP
   accumulated an invalid (inappropriately large) cwnd.  The use and
   drawbacks of using the CWV algorithm described in RFC 2861 with an
   application are discussed in Section 2.

   Section 3 defines relevant terminology.

   Section 4 specifies an alternative to CWV that seeks to address the
   same issues but does so in a way that is expected to mitigate the
   impact on an application that varies its sending rate.  The updated
   method applies to the rate-limited conditions (including both
   application-limited and idle senders).

   The goals of this update are:

   o  To not change the behaviour of a TCP sender that performs bulk
      transfers that fully use the cwnd.

   o  To provide a method that co-exists with standard TCP and other
      flows that use this updated method.

   o  To reduce transfer latency for applications that change their rate
      over short intervals of time.

   o  To avoid a TCP sender growing a large "non-validated" cwnd, when
      it has not recently sent using this cwnd.

   o  To remove the incentive for ad hoc application or network stack
      methods (such as "padding") solely to maintain a large cwnd for
      future transmission.

   o  To provide an incentive for the use of long-lived connections
      rather than a succession of short-lived flows, benefiting both the
      long-lived flows and other flows sharing capacity with these flows
      when congestion is encountered.





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   Section 5 describes the rationale for selecting the safe period to
   preserve the cwnd.

1.1.  Implementation of New CWV

   The method specified in Section 4 of this document is a sender-side-
   only change to the TCP congestion control behaviour of TCP.

   The method creates a new protocol state and requires a sender to
   determine when the cwnd is validated or non-validated to control the
   entry and exit from this state (see Section 4.3).  It defines how a
   TCP sender manages the growth of the cwnd using the set of rules
   defined in Section 4.

   Implementation of this specification requires an implementor to
   define a method to measure the available capacity using a set of
   pipeACK samples.  The details of this measurement are implementation-
   specific.  An example is provided in Section 4.5.1, but other methods
   are permitted.  A sender also needs to provide a method to determine
   when it becomes cwnd-limited.  Implementation of this may require
   consideration of other TCP methods (see Section 4.5.3).

   A sender is also recommended to provide a method that controls the
   maximum burst size (see Section 4.4.2).  However, implementors are
   allowed flexibility in how this method is implemented, and the choice
   of an appropriate method is expected to depend on the way in which
   the sender stack implements other TCP methods (such as TCP Segment
   Offload (TSO)).

1.2.  Standards Status of This Document

   The document obsoletes the methods described in [RFC2861].  It
   recommends a set of mechanisms, including the use of pacing during a
   non-validated period.  The updated mechanisms are intended to have a
   less aggressive congestion impact than would be exhibited by a
   standard TCP sender.

   The specification in this document is classified as "Experimental"
   pending experience with deployed implementations of the methods.

2.  Reviewing Experience with TCP-CWV

   [RFC2861] described a simple modification to the TCP congestion
   control algorithm that decayed the cwnd after the transition to a
   "sufficiently-long" idle period.  This used the slow-start threshold
   (ssthresh) to save information about the previous value of the
   congestion window.  The approach relaxed the standard TCP behaviour




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   for an idle session [RFC5681], which was intended to improve
   application performance.  CWV also modified the behaviour when a
   sender transmitted at a rate less than allowed by cwnd.

   [RFC2861] proposed two sets of responses: one after an "application-
   limited period" and one after an "idle period".  Although this
   distinction was argued, in practice, differentiating the two
   conditions was found problematic in actual networks (see, e.g.,
   [Bis10]).  While this offered predictable performance for long on-off
   periods (>>1 RTT) or slowly varying rate-based traffic, the
   performance could be unpredictable for variable-rate traffic and
   depended both upon whether an accurate RTT had been obtained and the
   pattern of application traffic relative to the measured RTT.

   Many applications can and often do vary their transmission over a
   wide range of rates.  Using [RFC2861], such applications often
   experienced varying performance, which made it hard for application
   developers to predict the TCP latency even when using a path with
   stable network characteristics.  We argue that an attempt to classify
   application behaviour as application-limited or idle is problematic
   and also inappropriate.  This document therefore explicitly avoids
   trying to differentiate these two cases, instead treating all rate-
   limited traffic uniformly.

   [RFC2861] has been implemented in some mainstream operating systems
   as the default behaviour [Bis08].  Analysis (e.g., [Bis10] and
   [Fai12]) has shown that a TCP sender using CWV is able to use
   available capacity on a shared path after an idle period.  This can
   benefit variable-rate applications, especially over long delay paths,
   when compared to the slow-start restart specified by standard TCP.
   However, CWV would only benefit an application if the idle period
   were less than several Retransmission Timeout (RTO) intervals
   [RFC6298], since the behaviour would otherwise be the same as for
   standard TCP, which resets the cwnd to the TCP Restart Window after
   this period.

   To enable better performance for variable-rate applications with TCP,
   some operating systems have chosen to support non-standard methods,
   or applications have resorted to "padding" streams by sending dummy
   data to maintain their sending rate when they have no data to
   transmit.  Although transmitting redundant data across a network path
   provides good evidence that the path can sustain data at the offered
   rate, padding also consumes network capacity and reduces the
   opportunity for congestion-free statistical multiplexing.  For
   variable-rate flows, the benefits of statistical multiplexing can be
   significant, and it is therefore a goal to find a viable alternative
   to padding streams.




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   Experience with [RFC2861] suggests that although the CWV method
   benefited the network in a rate-limited scenario (reducing the
   probability of network congestion), the behaviour was too
   conservative for many common rate-limited applications.  This
   mechanism did not therefore offer the desirable increase in
   application performance for rate-limited applications, and it is
   unclear whether applications actually use this mechanism in the
   general Internet.

   Therefore, it was concluded that CWV, as defined in [RFC2861], was
   often a poor solution for many rate-limited applications.  It had the
   correct motivation but the wrong approach to solving this problem.

3.  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 [RFC2119].

   The document assumes familiarity with the terminology of TCP
   congestion control [RFC5681].

   The following additional terminology is introduced in this document:

   o  cwnd-limited: A TCP flow that has sent the maximum number of
      segments permitted by the cwnd, where the application utilises the
      allowed sending rate (see Section 4.5.3).

   o  pipeACK sample: A measure of the volume of data acknowledged by
      the network within an RTT.

   o  pipeACK variable: A variable that measures the available capacity
      using the set of pipeACK samples (see Section 4.2).

   o  pipeACK Sampling Period: The maximum period that a measured
      pipeACK sample may influence the pipeACK variable.

   o  Non-validated phase: The phase where the cwnd reflects a previous
      measurement of the available path capacity.

   o  Non-validated period (NVP): The maximum period for which cwnd is
      preserved in the non-validated phase.

   o  Rate-limited: A TCP flow that does not consume more than one half
      of cwnd and hence operates in the non-validated phase.  This
      includes periods when an application is either idle or chooses to
      send at a rate less than the maximum permitted by the cwnd.




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   o  Validated phase: The phase where the cwnd reflects a current
      estimate of the available path capacity.

4.  A New Congestion Window Validation Method

   This section proposes an update to the TCP congestion control
   behaviour during a rate-limited interval.  This new method
   intentionally does not differentiate between times when the sender
   has become idle or chooses to send at a rate less than the maximum
   allowed by the cwnd.

   In the non-validated phase, the capacity used by an application can
   be less than that allowed by the TCP cwnd.  This update allows an
   application to preserve a recently used cwnd while in the non-
   validated phase and then to resume transmission at a previous rate
   without incurring the delay of slow-start.  However, if the TCP
   sender experiences congestion using the preserved cwnd, it is
   required to immediately reset the cwnd to an appropriate value
   specified by the method.  If a sender does not take advantage of the
   preserved cwnd within the non-validated period (NVP), the value of
   cwnd is reduced, ensuring the value better reflects the capacity that
   was recently actually used.

   It is expected that this update will satisfy the requirements of many
   rate-limited applications and at the same time provide an appropriate
   method for use in the Internet.  New CWV reduces this incentive for
   an application to send "padding" data simply to keep transport
   congestion state.

   The method is specified in the following subsections and is expected
   to encourage applications and TCP stacks to use standards-based
   congestion control methods.  It may also encourage the use of long-
   lived connections where this offers benefit (such as persistent
   HTTP).

4.1.  Initialisation

   A sender starts a TCP connection in the validated phase and
   initialises the pipeACK variable to the "undefined" value.  This
   value inhibits use of the value in cwnd calculations.

4.2.  Estimating the Validated Capacity Supported by a Path

   [RFC6675] defines "FlightSize", a variable that indicates the
   instantaneous amount of data that has been sent but not cumulatively
   acknowledged.  In this method, a new variable "pipeACK" is introduced
   to measure the acknowledged size of the network pipe.  This is used




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   to determine if the sender has validated the cwnd. pipeACK differs
   from FlightSize in that it is evaluated over a window of acknowledged
   data, rather than reflecting the amount of data outstanding.

   A sender determines a pipeACK sample by measuring the volume of data
   that was acknowledged by the network over the period of a measured
   Round-Trip Time (RTT).  Using the variables defined in [RFC6675], a
   value could be measured by caching the value of HighACK and, after
   one RTT, measuring the difference between the cached HighACK value
   and the current HighACK value.  A sender MAY count TCP DupACKs that
   acknowledge new data when collecting the pipeACK sample.  Other
   equivalent methods may be used.

   A sender is not required to continuously update the pipeACK variable
   after each received ACK but SHOULD perform a pipeACK sample at least
   once per RTT when it has sent unacknowledged segments.

   The pipeACK variable MAY consider multiple pipeACK samples over the
   pipeACK Sampling Period.  The value of the pipeACK variable MUST NOT
   exceed the maximum (highest value) within the pipeACK Sampling
   Period.  This specification defines the pipeACK Sampling Period as
   Max(3*RTT, 1 second).  This period enables a sender to compensate for
   large fluctuations in the sending rate, where there may be pauses in
   transmission, and allows the pipeACK variable to reflect the largest
   recently measured pipeACK sample.

   When no measurements are available (e.g., a sender that has just
   started transmission or immediately after loss recovery), the pipeACK
   variable is set to the "undefined value".  This value is used to
   inhibit entering the non-validated phase until the first new
   measurement of a pipeACK sample.  (Section 4.5 provides examples of
   implementation.)

   The pipeACK variable MUST NOT be updated during TCP Fast Recovery.
   That is, the sender stops collecting pipeACK samples during loss
   recovery.  The method RECOMMENDS enabling the TCP SACK option
   [RFC2018] and RECOMMENDS the method defined in [RFC6675] to recover
   missing segments.  This allows the sender to more accurately
   determine the number of missing bytes during the loss recovery phase,
   and using this method will result in a more appropriate cwnd
   following loss.

   Note: The use of pipeACK rather than FlightSize can change the
   behaviour of a TCP flow when a sender does not always have data
   available to send.  One example arises when there is a pause in
   transmission after sending a sequence of many packets, and the sender
   experiences loss at or near the end of its transmission sequence.  In
   this case, the TCP flow may have used a significant amount of



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   capacity just prior to the loss (which would be reflected in the
   volume of data acknowledged, recorded in the pipeACK variable), but
   at the actual time of loss, the number of unacknowledged packets in
   flight (at the end of the sequence) may be small, i.e., there is a
   small FlightSize.  After loss recovery, the sender resets its
   congestion control state.

   [Fai12] explored the benefits of different responses to congestion
   for application-limited streams.  If the response is based only on
   the Loss FlightSize, the sender would assign a small cwnd and
   ssthresh, based only on the volume of data sent after the loss.  When
   the sender next starts to transmit, it can incur many RTTs of delay
   in slow-start before it reacquires its previous rate.  When the
   pipeACK value is also used to calculate the cwnd and ssthresh (as
   specified in Section 4.4.1), the sender can use a value that also
   reflects the recently used capacity before the loss.  This prevents a
   variable-rate application from being unduly penalised.  When the
   sender resumes, it starts at one-half its previous rate, similar to
   the behaviour of a bulk TCP flow [Hos15].  To ensure an appropriate
   reaction to ongoing congestion, this method requires that the pipeACK
   variable is reset after it is used in this way.

4.3.  Preserving cwnd during a Rate-Limited Period

   The updated method creates a new TCP sender phase that captures
   whether the cwnd reflects a validated or non-validated value.  The
   phases are defined as:

   o  Validated phase: pipeACK >=(1/2)*cwnd, or pipeACK is undefined
      (i.e., at the start or directly after loss recovery).  This is the
      normal phase, where cwnd is expected to be an approximate
      indication of the capacity currently available along the network
      path, and the standard methods are used to increase cwnd
      (currently, the standard methods are described in [RFC5681]).

   o  Non-validated phase: pipeACK <(1/2)*cwnd.  This is the phase where
      the cwnd has a value based on a previous measurement of the
      available capacity, and the usage of this capacity has not been
      validated in the pipeACK Sampling Period, that is, when it is not
      known whether the cwnd reflects the currently available capacity
      along the network path.  The mechanisms to be used in this phase
      seek to determine a safe value for cwnd and an appropriate
      reaction to congestion.

   Note: A threshold is needed to determine whether a sender is in the
   validated or non-validated phase.  A standard TCP sender in slow-
   start is permitted to double its FlightSize from one RTT to the next.
   This motivated the choice of a threshold value of 1/2.  This



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   threshold ensures a sender does not further increase the cwnd as long
   as the FlightSize is less than (1/2*cwnd).  Furthermore, a sender
   with a FlightSize less than (1/2*cwnd) may, in the next RTT, be
   permitted by the cwnd to send at a rate that more than doubles the
   FlightSize; hence, this case needs to be regarded as non-validated,
   and a sender therefore needs to employ additional mechanisms while in
   this phase.

4.4.  TCP Congestion Control during the Non-validated Phase

   A TCP sender implementing this specification MUST enter the non-
   validated phase when the pipeACK is less than (1/2)*cwnd.  (The note
   at the end of Section 4.4.1 describes why pipeACK<=(1/2)*cwnd is
   expected to be a safe value.)

   A TCP sender that enters the non-validated phase preserves the cwnd
   (i.e., the cwnd only increases after a sender fully uses the cwnd in
   this phase; otherwise, the cwnd neither grows nor reduces).  The
   phase is concluded when the sender transmits sufficient data so that
   pipeACK > (1/2)*cwnd (i.e., the sender is no longer rate-limited) or
   when the sender receives an indication of congestion.

   After a fixed period of time (the non-validated period (NVP)), the
   sender adjusts the cwnd (Section 4.4.3).  The NVP SHOULD NOT exceed
   five minutes.  Section 5 discusses the rationale for choosing a safe
   value for this period.

   The behaviour in the non-validated phase is specified as:

   o  A sender determines whether to increase the cwnd based upon
      whether it is cwnd-limited (see Section 4.5.3):

      *  A sender that is cwnd-limited MAY use the standard TCP method
         to increase cwnd (i.e., the standard method permits a TCP
         sender that fully utilises the cwnd to increase the cwnd each
         time it receives an ACK).

      *  A sender that is not cwnd-limited MUST NOT increase the cwnd
         when ACK packets are received in this phase (i.e., needs to
         avoid growing the cwnd when it has not recently sent using the
         current size of cwnd).

   o  If the sender receives an indication of congestion while in the
      non-validated phase (i.e., detects loss), the sender MUST exit the
      non-validated phase (reducing the cwnd as defined in
      Section 4.4.1).





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   o  If the Retransmission Timeout (RTO) expires while in the non-
      validated phase, the sender MUST exit the non-validated phase.  It
      then resumes using the standard TCP RTO mechanism [RFC5681].

   o  A sender with a pipeACK variable greater than (1/2)*cwnd SHOULD
      enter the validated phase.  (A rate-limited sender will not
      normally be impacted by whether it is in a validated or non-
      validated phase, since it will normally not increase FlightSize to
      use the entire cwnd.  However, a change to the validated phase
      will release the sender from constraints on the growth of cwnd and
      result in using the standard congestion response.)

   The cwnd-limited behaviour may be triggered during a transient
   condition that occurs when a sender is in the non-validated phase and
   receives an ACK that acknowledges received data, the cwnd was fully
   utilised, and more data is awaiting transmission than may be sent
   with the current cwnd.  The sender MAY then use the standard method
   to increase the cwnd.  (Note that if the sender succeeds in sending
   these new segments, the updated cwnd and pipeACK variables will
   eventually result in a transition to the validated phase.)

4.4.1.  Response to Congestion in the Non-validated Phase

   Reception of congestion feedback while in the non-validated phase is
   interpreted as an indication that it was inappropriate for the sender
   to use the preserved cwnd.  The sender is therefore required to
   quickly reduce the rate to avoid further congestion.  Since the cwnd
   does not have a validated value, a new cwnd value needs to be
   selected based on the utilised rate.

   A sender that detects a packet drop MUST record the current
   FlightSize in the variable LossFlightSize and MUST calculate a safe
   cwnd for loss recovery using the method below:

           cwnd = (Max(pipeACK,LossFlightSize))/2.

   The pipeACK value is not updated during loss recovery (see
   Section 4.2).  If there is a valid pipeACK value, the new cwnd is
   adjusted to reflect that a non-validated cwnd may be larger than the
   actual FlightSize or recently used FlightSize (recorded in pipeACK).
   The updated cwnd therefore prevents overshoot by a sender,
   significantly increasing its transmission rate during the recovery
   period.

   At the end of the recovery phase, the TCP sender MUST reset the cwnd
   using the method below:

           cwnd = (Max(pipeACK,LossFlightSize) - R)/2.



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   Where R is the volume of data that was successfully retransmitted
   during the recovery phase.  This corresponds to segments
   retransmitted and considered lost by the pipe estimation algorithm at
   the end of recovery.  It does not include the additional cost of
   multiple retransmission of the same data.  The loss of segments
   indicates that the path capacity was exceeded by at least R; hence,
   the calculated cwnd is reduced by at least R before the window is
   halved.

   The calculated cwnd value MUST NOT be reduced below 1 TCP Maximum
   Segment Size (MSS).

   After completing the loss recovery phase, the sender MUST
   re-initialise the pipeACK variable to the "undefined" value.  This
   ensures that standard TCP methods are used immediately after
   completing loss recovery until a new pipeACK value can be determined.

   The ssthresh is adjusted using the standard TCP method (Step 6 in
   Section 3.2 of RFC 5681 assigns the ssthresh a value equal to cwnd at
   the end of the loss recovery).

   Note: The adjustment by reducing cwnd by the volume of data not sent
   (R) follows the method proposed for Jump Start [Liu07].  The
   inclusion of the term R makes the adjustment more conservative than
   standard TCP.  This is required, since a sender in the non-validated
   phase is allowed a rate higher than a standard TCP sender would have
   achieved in the last RTT (i.e., to have more than doubled the number
   of segments in flight relative to what was sent in the previous RTT).
   The additional reduction after congestion is beneficial when the
   LossFlightSize has significantly overshot the available path
   capacity, incurring significant loss (e.g., following a change of
   path characteristics or when additional traffic has taken a larger
   share of the network bottleneck during a period when the sender
   transmits less).

   Note: The pipeACK value is only valid during a non-validated phase;
   therefore, this does not exceed cwnd/2.  If LossFlightSize and R were
   small, then this can result in the final cwnd after loss recovery
   being at most one-quarter of the cwnd on detection of congestion.
   This reduction is conservative, and pipeACK is then reset to
   undefined; hence, cwnd updates after a congestion event do not depend
   upon the pipeACK history before congestion was detected.









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4.4.2.  Sender Burst Control during the Non-validated Phase

   TCP congestion control allows a sender to accumulate a cwnd that
   would allow it to send a burst of segments with a total size up to
   the difference between the FlightSize and cwnd.  Such bursts can
   impact other flows that share a network bottleneck and/or may induce
   congestion when buffering is limited.

   Various methods have been proposed to control the sender burstiness
   [Hug01] [All05].  For example, TCP can limit the number of new
   segments it sends per received ACK.  This is effective when a flow of
   ACKs is received but cannot be used to control a sender that has not
   sent appreciable data in the previous RTT [All05].

   This document recommends using a method to avoid line-rate bursts
   after an idle or rate-limited interval when there is less reliable
   information about the capacity of the network path.  A TCP sender in
   the non-validated phase SHOULD control the maximum burst size, e.g.,
   using a rate-based pacing algorithm in which a sender paces out the
   cwnd over its estimate of the RTT, or some other method, to prevent
   many segments being transmitted contiguously at line-rate.  The most
   appropriate method(s) to implement pacing depend on the design of the
   TCP/IP stack, speed of interface, and whether hardware support (such
   as TSO) is used.  This document does not recommend any specific
   method.

4.4.3.  Adjustment at the End of the Non-validated Period (NVP)

   An application that remains in the non-validated phase for a period
   greater than the NVP is required to adjust its congestion control
   state.  If the sender exits the non-validated phase after this
   period, it MUST update the ssthresh:

         ssthresh = max(ssthresh, 3*cwnd/4).

   (This adjustment of ssthresh ensures that the sender records that it
   has safely sustained the present rate.  The change is beneficial to
   rate-limited flows that encounter occasional congestion and could
   otherwise suffer an unwanted additional delay in recovering the
   sending rate.)

   The sender MUST then update cwnd to be not greater than:

            cwnd = max((1/2)*cwnd, IW).

   Where IW is the appropriate TCP initial window used by the TCP sender
   (see, e.g., [RFC5681]).




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   Note: These cwnd and ssthresh adjustments cause the sender to enter
   slow-start (since ssthresh > cwnd).  This adjustment ensures that the
   sender responds conservatively after remaining in the non-validated
   phase for more than the non-validated period.  In this case, it
   reduces the cwnd by a factor of two from the preserved value.  This
   adjustment is helpful when flows accumulate but do not use a large
   cwnd; this adjustment seeks to mitigate the impact when these flows
   later resume transmission.  This could, for instance, mitigate the
   impact if multiple high-rate application flows were to become idle
   over an extended period of time and then were simultaneously awakened
   by an external event.

4.5.  Examples of Implementation

   This section provides informative examples of implementation methods.
   Implementations may choose to use other methods that comply with the
   normative requirements.

4.5.1.  Implementing the pipeACK Measurement

   A pipeACK sample may be measured once each RTT.  This reduces the
   sender processing burden for calculating after each acknowledgment
   and also reduces storage requirements at the sender.

   Since application behaviour can be bursty using CWV, it may be
   desirable to implement a maximum filter to accumulate the measured
   values so that the pipeACK variable records the largest pipeACK
   sample within the pipeACK Sampling Period.  One simple way to
   implement this is to divide the pipeACK Sampling Period into several
   (e.g., five) equal-length measurement periods.  The sender then
   records the start time for each measurement period and the highest
   measured pipeACK sample.  At the end of the measurement period, any
   measurement(s) that is older than the pipeACK Sampling Period is
   discarded.  The pipeACK variable is then assigned the largest of the
   set of the highest measured values.
















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   pipeACK sample (Bytes)
   ^
   |   +----------+----------+           +----------+---......
   |   | Sample A | Sample B | No        | Sample C | Sample D
   |   |          |          | Sample    |          |
   |   | |\ 5     |          |           |          |
   |   | | |      |          |           |  /\ 4    |
   |   | | |      |  |\ 3    |           |  | \     |
   |   | | \      | |  \---  |           |  /  \    |   /| 2
   |   |/   \------|       - |           | /    \------/ \...
   +//-+----------+---------\+----/ /----+/---------+-------------> Time

    <------------------------------------------------|
                        Sampling Period          Current Time

              Figure 1: Example of Measuring pipeACK Samples

   Figure 1 shows an example of how measurement samples may be
   collected.  At the time represented by the figure, new samples are
   being accumulated into sample D.  Three previous samples also fall
   within the pipeACK Sampling Period: A, B, and C.  There was also a
   period of inactivity between samples B and C during which no
   measurements were taken (because no new data segments were
   acknowledged).  The current value of the pipeACK variable will be 5,
   the maximum across all samples.  During this period, the pipeACK
   samples may be regarded as zero and hence do not contribute to the
   calculated pipeACK value.

   After one further measurement period, Sample A will be discarded,
   since it then is older than the pipeACK Sampling Period, and the
   pipeACK variable will be recalculated.  Its value will be the larger
   of Sample C or the final value accumulated in Sample D.

4.5.2.  Measurement of the NVP and pipeACK Samples

   The mechanism requires a number of measurements of time.  These
   measurements could be implemented using protocol timers but do not
   necessarily require a new timer to be implemented.  Avoiding the use
   of dedicated timers can save operating system resources, especially
   when there may be large numbers of TCP flows.

   The NVP could be measured by recording a timestamp when the sender
   enters the non-validated phase.  Each time a sender transmits a new
   segment, this timestamp can be used to determine if the NVP has
   expired.  If the measured period exceeds the NVP, the sender can then
   take into account how many units of the NVP have passed and make one
   reduction (defined in Section 4.4.3) for each NVP.




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   Similarly, the time measurements for collecting pipeACK samples and
   determining the pipeACK Sampling Period could be derived by using a
   timestamp to record when each sample was measured and using this to
   calculate how much time has passed when each new ACK is received.

4.5.3.  Implementing Detection of the cwnd-Limited Condition

   A sender needs to implement a method that detects the cwnd-limited
   condition (see Section 4.4).  This detects a condition where a sender
   in the non-validated phase receives an ACK, but the size of cwnd
   prevents sending more new data.

   In simple terms, this condition is true only when the FlightSize of a
   TCP sender is equal to or larger than the current cwnd.  However, an
   implementation also needs to consider constraints on the way in which
   the cwnd variable can be used; for instance, implementations need to
   support other TCP methods such as the Nagle Algorithm and TCP Segment
   Offload (TSO) that also use cwnd to control transmission.  These
   other methods can result in a sender becoming cwnd-limited when the
   cwnd is nearly, rather than completely, equal to the FlightSize.

5.  Determining a Safe Period to Preserve cwnd

   This section documents the rationale for selecting the maximum period
   that cwnd may be preserved, known as the NVP.

   Limiting the period that cwnd may be preserved avoids undesirable
   side effects that would result if the cwnd were to be kept
   unnecessarily high for an arbitrarily long period, which was a part
   of the problem that CWV originally attempted to address.  The period
   a sender may safely preserve the cwnd is a function of the period
   that a network path is expected to sustain the capacity reflected by
   cwnd.  There is no ideal choice for this time.

   A period of five minutes was chosen for this NVP.  This is a
   compromise that was larger than the idle intervals of common
   applications but not sufficiently larger than the period for which
   the capacity of an Internet path may commonly be regarded as stable.
   The capacity of wired networks is usually relatively stable for
   periods of several minutes, and that load stability increases with
   the capacity.  This suggests that cwnd may be preserved for at least
   a few minutes.

   There are cases where the TCP throughput exhibits significant
   variability over a time less than five minutes.  Examples could
   include wireless topologies, where TCP rate variations may fluctuate
   on the order of a few seconds as a consequence of medium access
   protocol instabilities.  Mobility changes may also impact TCP



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   performance over short time scales.  Senders that observe such rapid
   changes in the path characteristic may also experience increased
   congestion with the new method; however, such variation would likely
   also impact TCP's behaviour when supporting interactive and bulk
   applications.

   Routing algorithms may change the network path that is used by a
   transport.  Although a change of path can in turn disrupt the RTT
   measurement and may result in a change of the capacity available to a
   TCP connection, we assume these path changes do not usually occur
   frequently (compared to a time frame of a few minutes).

   The value of five minutes is therefore expected to be sufficient for
   most current applications.  Simulation studies (e.g., [Bis11]) also
   suggest that for many practical applications, the performance using
   this value will not be significantly different from that observed
   using a non-standard method that does not reset the cwnd after idle.

   Finally, other TCP sender mechanisms have used a five-minute timer,
   and there could be simplifications in some implementations by reusing
   the same interval.  TCP defines a default user timeout of five
   minutes [RFC793], which is how long transmitted data may remain
   unacknowledged before a connection is forcefully closed.

6.  Security Considerations

   General security considerations concerning TCP congestion control are
   discussed in [RFC5681].  This document describes an algorithm that
   updates one aspect of the congestion control procedures, so the
   considerations described in [RFC5681] also apply to this algorithm.

7.  References

7.1.  Normative References

   [RFC793]   Postel, J., "Transmission Control Protocol", STD 7,
              RFC 793, DOI 10.17487/RFC0793, September 1981,
              <http://www.rfc-editor.org/info/rfc793>.

   [RFC2018]  Mathis, M., Mahdavi, J., Floyd, S., and A. Romanow, "TCP
              Selective Acknowledgment Options", RFC 2018,
              DOI 10.17487/RFC2018, October 1996,
              <http://www.rfc-editor.org/info/rfc2018>.

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119,
              DOI 10.17487/RFC2119, March 1997,
              <http://www.rfc-editor.org/info/rfc2119>.



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   [RFC2861]  Handley, M., Padhye, J., and S. Floyd, "TCP Congestion
              Window Validation", RFC 2861, DOI 10.17487/RFC2861, June
              2000, <http://www.rfc-editor.org/info/rfc2861>.

   [RFC5681]  Allman, M., Paxson, V., and E. Blanton, "TCP Congestion
              Control", RFC 5681, DOI 10.17487/RFC5681, September 2009,
              <http://www.rfc-editor.org/info/rfc5681>.

   [RFC6298]  Paxson, V., Allman, M., Chu, J., and M. Sargent,
              "Computing TCP's Retransmission Timer", RFC 6298,
              DOI 10.17487/RFC6298, June 2011,
              <http://www.rfc-editor.org/info/rfc6298>.

   [RFC6675]  Blanton, E., Allman, M., Wang, L., Jarvinen, I., Kojo, M.,
              and Y. Nishida, "A Conservative Loss Recovery Algorithm
              Based on Selective Acknowledgment (SACK) for TCP",
              RFC 6675, DOI 10.17487/RFC6675, August 2012,
              <http://www.rfc-editor.org/info/rfc6675>.

7.2.  Informative References

   [All05]    Allman, M. and E. Blanton, "Notes on Burst Mitigation for
              Transport Protocols", ACM SIGCOMM Computer Communication
              Review, Volume 35, Issue 2, DOI 10.1145/1064413.1064419,
              April 2005.

   [Bis08]    Biswas, I. and G. Fairhurst, "A Practical Evaluation of
              Congestion Window Validation Behaviour", 9th Annual
              Postgraduate Symposium in the Convergence of
              Telecommunications, Networking and Broadcasting
              (PGNet), Liverpool, UK, 2008.

   [Bis10]    Biswas, I., Sathiaseelan, A., Secchi, R., and G.
              Fairhurst, "Analysing TCP for Bursty Traffic", Int'l J. of
              Communications, Network and System Sciences,
              DOI 10.4236/ijcns.2010.37078, July 2010.

   [Bis11]    Biswas, I., "Internet Congestion Control for Variable-Rate
              TCP Traffic", PhD Thesis, School of Engineering,
              University of Aberdeen, 2011.

   [Fai12]    Sathiaseelan, A., Secchi, R., Fairhurst, G., and I.
              Biswas, "Enhancing TCP Performance to support Variable-
              Rate Traffic", 2nd Capacity Sharing Workshop, ACM
              CoNEXT, Nice, France, December 2012.






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   [Hos15]    Hossain, Z., "A Study of Mechanisms to Support Variable-
              Rate Internet Applications over a Multi-service Satellite
              Platform", PhD Thesis, School of Engineering, University
              of Aberdeen, January 2015.

   [Hug01]    Hughes, A., Touch, J., and J. Heidemann, "Issues in TCP
              Slow-Start Restart After Idle", Work in Progress,
              draft-hughes-restart-00, December 2001.

   [Liu07]    Liu, D., Allman, M., Jin, S., and L. Wang, "Congestion
              Control without a Startup Phase", 5th International
              Workshop on Protocols for Fast Long-Distance Networks
              (PFLDnet), Los Angeles, California, February 2007.

   [RFC7230]  Fielding, R., Ed. and J. Reschke, Ed., "Hypertext Transfer
              Protocol (HTTP/1.1): Message Syntax and Routing",
              RFC 7230, DOI 10.17487/RFC7230, June 2014,
              <http://www.rfc-editor.org/info/rfc7230>.

































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Acknowledgments

   This document was produced by the TCP Maintenance and Minor
   Extensions (tcpm) working group.

   The authors acknowledge the contributions of Dr. I. Biswas and Dr.
   Ziaul Hossain in supporting the evaluation of CWV and for their help
   in developing the mechanisms proposed in this document.  We also
   acknowledge comments received from the Internet Congestion Control
   Research Group, in particular Yuchung Cheng, Mirja Kuehlewind, Joe
   Touch, and Mark Allman.  This work was partly funded by the European
   Community under its Seventh Framework Programme through the Reducing
   Internet Transport Latency (RITE) project (ICT-317700).

Authors' Addresses

   Godred Fairhurst
   University of Aberdeen
   School of Engineering
   Fraser Noble Building
   Aberdeen, Scotland  AB24 3UE
   United Kingdom

   Email: gorry@erg.abdn.ac.uk
   URI:   http://www.erg.abdn.ac.uk


   Arjuna Sathiaseelan
   University of Aberdeen
   School of Engineering
   Fraser Noble Building
   Aberdeen, Scotland  AB24 3UE
   United Kingdom

   Email: arjuna@erg.abdn.ac.uk
   URI:   http://www.erg.abdn.ac.uk


   Raffaello Secchi
   University of Aberdeen
   School of Engineering
   Fraser Noble Building
   Aberdeen, Scotland  AB24 3UE
   United Kingdom

   Email: raffaello@erg.abdn.ac.uk
   URI:   http://www.erg.abdn.ac.uk




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  1. RFC 7661