ArticlePDF Available

The NewReno Modification to TCP's Fast Recovery Algorithm

Authors:
Sally Floyd at University of California, Berkeley
Sally Floyd
Ta-Tanisha Henderson at University of Illinois Springfield
Ta-Tanisha Henderson
Andrei Gurtov at Linköping University
Andrei Gurtov
Download full-text PDF
Read full-text
Download citation

Abstract

RFC 2001 [RFC2001] documents the following four intertwined TCP congestion control algorithms: Slow Start, Congestion Avoidance, Fast Retransmit, and Fast Recovery. RFC 2581 [RFC2581] explicitly allows certain modifications of these algorithms, including modifications that use the TCP Selective Acknowledgement (SACK) option [MMFR96], and modifications that respond to "partial acknowledgments" (ACKs which cover new data, but not all the data outstanding when loss was detected) in the absence of SACK. This document describes a specific algorithm for responding to partial acknowledgments, referred to as NewReno. This response to partial acknowledgments was first proposed by Janey Hoe in [Hoe95]. 1. Introduction For the typical implementation of the TCP Fast Recovery algorithm described in [RFC2581] (first implemented in the 1990 BSD Reno release, and referred to as the Reno algorithm in [FF96]), the TCP data sender only retransmits a packet after a retransmit timeout has occurred, or afte...
Content uploaded by Andrei Gurtov
Author content
All content in this area was uploaded by Andrei Gurtov on Jan 23, 2015
Content may be subject to copyright.
Network Working Group S. Floyd
Request for Comments: 3782 ICSI
Obsoletes: 2582 T. Henderson
Category: Standards Track Boeing
A. Gurtov
TeliaSonera
April 2004
The NewReno Modification to TCP’s Fast Recovery Algorithm
Status of this Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2004). All Rights Reserved.
Abstract
The purpose of this document is to advance NewReno TCP’s Fast
Retransmit and Fast Recovery algorithms in RFC 2582 from Experimental
to Standards Track status.
The main change in this document relative to RFC 2582 is to specify
the Careful variant of NewReno’s Fast Retransmit and Fast Recovery
algorithms. The base algorithm described in RFC 2582 did not attempt
to avoid unnecessary multiple Fast Retransmits that can occur after a
timeout. However, RFC 2582 also defined "Careful" and "Less Careful"
variants that avoid these unnecessary Fast Retransmits, and
recommended the Careful variant. This document specifies the
previously-named "Careful" variant as the basic version of NewReno
TCP.
Floyd, et al. Standards Track [Page 1]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
1. Introduction
For the typical implementation of the TCP Fast Recovery algorithm
described in [RFC2581] (first implemented in the 1990 BSD Reno
release, and referred to as the Reno algorithm in [FF96]), the TCP
data sender only retransmits a packet after a retransmit timeout has
occurred, or after three duplicate acknowledgements have arrived
triggering the Fast Retransmit algorithm. A single retransmit
timeout might result in the retransmission of several data packets,
but each invocation of the Fast Retransmit algorithm in RFC 2581
leads to the retransmission of only a single data packet.
Problems can arise, therefore, when multiple packets are dropped from
a single window of data and the Fast Retransmit and Fast Recovery
algorithms are invoked. In this case, if the SACK option is
available, the TCP sender has the information to make intelligent
decisions about which packets to retransmit and which packets not to
retransmit during Fast Recovery. This document applies only for TCP
connections that are unable to use the TCP Selective Acknowledgement
(SACK) option, either because the option is not locally supported or
because the TCP peer did not indicate a willingness to use SACK.
In the absence of SACK, there is little information available to the
TCP sender in making retransmission decisions during Fast Recovery.
From the three duplicate acknowledgements, the sender infers a packet
loss, and retransmits the indicated packet. After this, the data
sender could receive additional duplicate acknowledgements, as the
data receiver acknowledges additional data packets that were already
in flight when the sender entered Fast Retransmit.
In the case of multiple packets dropped from a single window of data,
the first new information available to the sender comes when the
sender receives an acknowledgement for the retransmitted packet (that
is, the packet retransmitted when Fast Retransmit was first entered).
If there is a single packet drop and no reordering, then the
acknowledgement for this packet will acknowledge all of the packets
transmitted before Fast Retransmit was entered. However, if there
are multiple packet drops, then the acknowledgement for the
retransmitted packet will acknowledge some but not all of the packets
transmitted before the Fast Retransmit. We call this acknowledgement
a partial acknowledgment.
Along with several other suggestions, [Hoe95] suggested that during
Fast Recovery the TCP data sender responds to a partial
acknowledgment by inferring that the next in-sequence packet has been
lost, and retransmitting that packet. This document describes a
modification to the Fast Recovery algorithm in RFC 2581 that
incorporates a response to partial acknowledgements received during
Floyd, et al. Standards Track [Page 2]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
Fast Recovery. We call this modified Fast Recovery algorithm
NewReno, because it is a slight but significant variation of the
basic Reno algorithm in RFC 2581. This document does not discuss the
other suggestions in [Hoe95] and [Hoe96], such as a change to the
ssthresh parameter during Slow-Start, or the proposal to send a new
packet for every two duplicate acknowledgements during Fast Recovery.
The version of NewReno in this document also draws on other
discussions of NewReno in the literature [LM97, Hen98].
We do not claim that the NewReno version of Fast Recovery described
here is an optimal modification of Fast Recovery for responding to
partial acknowledgements, for TCP connections that are unable to use
SACK. Based on our experiences with the NewReno modification in the
NS simulator [NS] and with numerous implementations of NewReno, we
believe that this modification improves the performance of the Fast
Retransmit and Fast Recovery algorithms in a wide variety of
scenarios.
2. Terminology and Definitions
In this document, the key words "MUST", "MUST NOT", "REQUIRED",
"SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY",
and "OPTIONAL" are to be interpreted as described in BCP 14, RFC 2119
[RFC2119]. This RFC indicates requirement levels for compliant TCP
implementations implementing the NewReno Fast Retransmit and Fast
Recovery algorithms described in this document.
This document assumes that the reader is familiar with the terms
SENDER MAXIMUM SEGMENT SIZE (SMSS), CONGESTION WINDOW (cwnd), and
FLIGHT SIZE (FlightSize) defined in [RFC2581]. FLIGHT SIZE is
defined as in [RFC2581] as follows:
FLIGHT SIZE:
The amount of data that has been sent but not yet acknowledged.
3. The Fast Retransmit and Fast Recovery Algorithms in NewReno
The standard implementation of the Fast Retransmit and Fast Recovery
algorithms is given in [RFC2581]. This section specifies the basic
NewReno algorithm. Sections 4 through 6 describe some optional
variants, and the motivations behind them, that an implementor may
want to consider when tuning performance for certain network
scenarios. Sections 7 and 8 provide some guidance to implementors
based on experience with NewReno implementations.
The NewReno modification concerns the Fast Recovery procedure that
begins when three duplicate ACKs are received and ends when either a
retransmission timeout occurs or an ACK arrives that acknowledges all
Floyd, et al. Standards Track [Page 3]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
of the data up to and including the data that was outstanding when
the Fast Recovery procedure began.
The NewReno algorithm specified in this document differs from the
implementation in [RFC2581] in the introduction of the variable
"recover" in step 1, in the response to a partial or new
acknowledgement in step 5, and in modifications to step 1 and the
addition of step 6 for avoiding multiple Fast Retransmits caused by
the retransmission of packets already received by the receiver.
The algorithm specified in this document uses a variable "recover",
whose initial value is the initial send sequence number.
1) Three duplicate ACKs:
When the third duplicate ACK is received and the sender is not
already in the Fast Recovery procedure, check to see if the
Cumulative Acknowledgement field covers more than "recover". If
so, go to Step 1A. Otherwise, go to Step 1B.
1A) Invoking Fast Retransmit:
If so, then set ssthresh to no more than the value given in
equation 1 below. (This is equation 3 from [RFC2581]).
ssthresh = max (FlightSize / 2, 2*SMSS) (1)
In addition, record the highest sequence number transmitted in
the variable "recover", and go to Step 2.
1B) Not invoking Fast Retransmit:
Do not enter the Fast Retransmit and Fast Recovery procedure. In
particular, do not change ssthresh, do not go to Step 2 to
retransmit the "lost" segment, and do not execute Step 3 upon
subsequent duplicate ACKs.
2) Entering Fast Retransmit:
Retransmit the lost segment and set cwnd to ssthresh plus 3*SMSS.
This artificially "inflates" the congestion window by the number
of segments (three) that have left the network and the receiver
has buffered.
3) Fast Recovery:
For each additional duplicate ACK received while in Fast
Recovery, increment cwnd by SMSS. This artificially inflates the
congestion window in order to reflect the additional segment that
has left the network.
Floyd, et al. Standards Track [Page 4]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
4) Fast Recovery, continued:
Transmit a segment, if allowed by the new value of cwnd and the
receiver’s advertised window.
5) When an ACK arrives that acknowledges new data, this ACK could be
the acknowledgment elicited by the retransmission from step 2, or
elicited by a later retransmission.
Full acknowledgements:
If this ACK acknowledges all of the data up to and including
"recover", then the ACK acknowledges all the intermediate
segments sent between the original transmission of the lost
segment and the receipt of the third duplicate ACK. Set cwnd to
either (1) min (ssthresh, FlightSize + SMSS) or (2) ssthresh,
where ssthresh is the value set in step 1; this is termed
"deflating" the window. (We note that "FlightSize" in step 1
referred to the amount of data outstanding in step 1, when Fast
Recovery was entered, while "FlightSize" in step 5 refers to the
amount of data outstanding in step 5, when Fast Recovery is
exited.) If the second option is selected, the implementation is
encouraged to take measures to avoid a possible burst of data, in
case the amount of data outstanding in the network is much less
than the new congestion window allows. A simple mechanism is to
limit the number of data packets that can be sent in response to
a single acknowledgement; this is known as "maxburst_" in the NS
simulator. Exit the Fast Recovery procedure.
Partial acknowledgements:
If this ACK does *not* acknowledge all of the data up to and
including "recover", then this is a partial ACK. In this case,
retransmit the first unacknowledged segment. Deflate the
congestion window by the amount of new data acknowledged by the
cumulative acknowledgement field. If the partial ACK
acknowledges at least one SMSS of new data, then add back SMSS
bytes to the congestion window. As in Step 3, this artificially
inflates the congestion window in order to reflect the additional
segment that has left the network. Send a new segment if
permitted by the new value of cwnd. This "partial window
deflation" attempts to ensure that, when Fast Recovery eventually
ends, approximately ssthresh amount of data will be outstanding
in the network. Do not exit the Fast Recovery procedure (i.e.,
if any duplicate ACKs subsequently arrive, execute Steps 3 and 4
above).
For the first partial ACK that arrives during Fast Recovery, also
reset the retransmit timer. Timer management is discussed in
more detail in Section 4.
Floyd, et al. Standards Track [Page 5]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
6) Retransmit timeouts:
After a retransmit timeout, record the highest sequence number
transmitted in the variable "recover" and exit the Fast Recovery
procedure if applicable.
Step 1 specifies a check that the Cumulative Acknowledgement field
covers more than "recover". Because the acknowledgement field
contains the sequence number that the sender next expects to receive,
the acknowledgement "ack_number" covers more than "recover" when:
ack_number - 1 > recover;
i.e., at least one byte more of data is acknowledged beyond the
highest byte that was outstanding when Fast Retransmit was last
entered.
Note that in Step 5, the congestion window is deflated after a
partial acknowledgement is received. The congestion window was
likely to have been inflated considerably when the partial
acknowledgement was received. In addition, depending on the original
pattern of packet losses, the partial acknowledgement might
acknowledge nearly a window of data. In this case, if the congestion
window was not deflated, the data sender might be able to send nearly
a window of data back-to-back.
This document does not specify the sender’s response to duplicate
ACKs when the Fast Retransmit/Fast Recovery algorithm is not invoked.
This is addressed in other documents, such as those describing the
Limited Transmit procedure [RFC3042]. This document also does not
address issues of adjusting the duplicate acknowledgement threshold,
but assumes the threshold specified in the IETF standards; the
current standard is RFC 2581, which specifies a threshold of three
duplicate acknowledgements.
As a final note, we would observe that in the absence of the SACK
option, the data sender is working from limited information. When
the issue of recovery from multiple dropped packets from a single
window of data is of particular importance, the best alternative
would be to use the SACK option.
4. Resetting the Retransmit Timer in Response to Partial
Acknowledgements
One possible variant to the response to partial acknowledgements
specified in Section 3 concerns when to reset the retransmit timer
after a partial acknowledgement. The algorithm in Section 3, Step 5,
resets the retransmit timer only after the first partial ACK. In
this case, if a large number of packets were dropped from a window of
Floyd, et al. Standards Track [Page 6]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
data, the TCP data sender’s retransmit timer will ultimately expire,
and the TCP data sender will invoke Slow-Start. (This is illustrated
on page 12 of [F98].) We call this the Impatient variant of NewReno.
We note that the Impatient variant in Section 3 doesn’t follow the
recommended algorithm in RFC 2988 of restarting the retransmit timer
after every packet transmission or retransmission [RFC2988, Step
5.1].
In contrast, the NewReno simulations in [FF96] illustrate the
algorithm described above with the modification that the retransmit
timer is reset after each partial acknowledgement. We call this the
Slow-but-Steady variant of NewReno. In this case, for a window with
a large number of packet drops, the TCP data sender retransmits at
most one packet per roundtrip time. (This behavior is illustrated in
the New-Reno TCP simulation of Figure 5 in [FF96], and on page 11 of
[F98]).
When N packets have been dropped from a window of data for a large
value of N, the Slow-but-Steady variant can remain in Fast Recovery
for N round-trip times, retransmitting one more dropped packet each
round-trip time; for these scenarios, the Impatient variant gives a
faster recovery and better performance. The tests "ns test-suite-
newreno.tcl impatient1" and "ns test-suite-newreno.tcl slow1" in the
NS simulator illustrate such a scenario, where the Impatient variant
performs better than the Slow-but-Steady variant. The Impatient
variant can be particularly important for TCP connections with large
congestion windows, as illustrated by the tests "ns test-suite-
newreno.tcl impatient4" and "ns test-suite-newreno.tcl slow4" in the
NS simulator.
One can also construct scenarios where the Slow-but-Steady variant
gives better performance than the Impatient variant. As an example,
this occurs when only a small number of packets are dropped, the RTO
is sufficiently small that the retransmit timer expires, and
performance would have been better without a retransmit timeout. The
tests "ns test-suite-newreno.tcl impatient2" and "ns test-suite-
newreno.tcl slow2" in the NS simulator illustrate such a scenario.
The Slow-but-Steady variant can also achieve higher goodput than the
Impatient variant, by avoiding unnecessary retransmissions. This
could be of special interest for cellular links, where every
transmission costs battery power and money. The tests "ns test-
suite-newreno.tcl impatient3" and "ns test-suite-newreno.tcl slow3"
in the NS simulator illustrate such a scenario. The Slow-but-Steady
variant can also be more robust to delay variation in the network,
where a delay spike might force the Impatient variant into a timeout
and go-back-N recovery.
Floyd, et al. Standards Track [Page 7]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
Neither of the two variants discussed above are optimal. Our
recommendation is for the Impatient variant, as specified in Section
3 of this document, because of the poor performance of the Slow-but-
Steady variant for TCP connections with large congestion windows.
One possibility for a more optimal algorithm would be one that
recovered from multiple packet drops as quickly as does slow-start,
while resetting the retransmit timers after each partial
acknowledgement, as described in the section below. We note,
however, that there is a limitation to the potential performance in
this case in the absence of the SACK option.
5. Retransmissions after a Partial Acknowledgement
One possible variant to the response to partial acknowledgements
specified in Section 3 would be to retransmit more than one packet
after each partial acknowledgement, and to reset the retransmit timer
after each retransmission. The algorithm specified in Section 3
retransmits a single packet after each partial acknowledgement. This
is the most conservative alternative, in that it is the least likely
to result in an unnecessarily-retransmitted packet. A variant that
would recover faster from a window with many packet drops would be to
effectively Slow-Start, retransmitting two packets after each partial
acknowledgement. Such an approach would take less than N roundtrip
times to recover from N losses [Hoe96]. However, in the absence of
SACK, recovering as quickly as slow-start introduces the likelihood
of unnecessarily retransmitting packets, and this could significantly
complicate the recovery mechanisms.
We note that the response to partial acknowledgements specified in
Section 3 of this document and in RFC 2582 differs from the response
in [FF96], even though both approaches only retransmit one packet in
response to a partial acknowledgement. Step 5 of Section 3 specifies
that the TCP sender responds to a partial ACK by deflating the
congestion window by the amount of new data acknowledged, adding back
SMSS bytes if the partial ACK acknowledges at least SMSS bytes of new
data, and sending a new segment if permitted by the new value of
cwnd. Thus, only one previously-sent packet is retransmitted in
response to each partial acknowledgement, but additional new packets
might be transmitted as well, depending on the amount of new data
acknowledged by the partial acknowledgement. In contrast, the
variant of NewReno illustrated in [FF96] simply set the congestion
window to ssthresh when a partial acknowledgement was received. The
approach in [FF96] is more conservative, and does not attempt to
accurately track the actual number of outstanding packets after a
partial acknowledgement is received. While either of these
approaches gives acceptable performance, the variant specified in
Section 3 recovers more smoothly when multiple packets are dropped
Floyd, et al. Standards Track [Page 8]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
from a window of data. (The [FF96] behavior can be seen in the NS
simulator by setting the variable "partial_window_deflation_" for
"Agent/TCP/Newreno" to 0; the behavior specified in Section 3 is
achieved by setting "partial_window_deflation_" to 1.)
6. Avoiding Multiple Fast Retransmits
This section describes the motivation for the sender’s state variable
"recover", and discusses possible heuristics for distinguishing
between a retransmitted packet that was dropped, and three duplicate
acknowledgements from the unnecessary retransmission of three
packets.
In the absence of the SACK option or timestamps, a duplicate
acknowledgement carries no information to identify the data packet or
packets at the TCP data receiver that triggered that duplicate
acknowledgement. In this case, the TCP data sender is unable to
distinguish between a duplicate acknowledgement that results from a
lost or delayed data packet, and a duplicate acknowledgement that
results from the sender’s unnecessary retransmission of a data packet
that had already been received at the TCP data receiver. Because of
this, with the Retransmit and Fast Recovery algorithms in Reno TCP,
multiple segment losses from a single window of data can sometimes
result in unnecessary multiple Fast Retransmits (and multiple
reductions of the congestion window) [F94].
With the Fast Retransmit and Fast Recovery algorithms in Reno TCP,
the performance problems caused by multiple Fast Retransmits are
relatively minor compared to the potential problems with Tahoe TCP,
which does not implement Fast Recovery. Nevertheless, unnecessary
Fast Retransmits can occur with Reno TCP unless some explicit
mechanism is added to avoid this, such as the use of the "recover"
variable. (This modification is called "bugfix" in [F98], and is
illustrated on pages 7 and 9 of that document. Unnecessary Fast
Retransmits for Reno without "bugfix" is illustrated on page 6 of
[F98].)
Section 3 of [RFC2582] defined a default variant of NewReno TCP that
did not use the variable "recover", and did not check if duplicate
ACKs cover the variable "recover" before invoking Fast Retransmit.
With this default variant from RFC 2582, the problem of multiple Fast
Retransmits from a single window of data can occur after a Retransmit
Timeout (as in page 8 of [F98]) or in scenarios with reordering (as
in the validation test "./test-all-newreno newreno5_noBF" in
directory "tcl/test" of the NS simulator. This gives performance
similar to that on page 8 of [F03].) RFC 2582 also defined Careful
and Less Careful variants of the NewReno algorithm, and recommended
the Careful variant.
Floyd, et al. Standards Track [Page 9]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
The algorithm specified in Section 3 of this document corresponds to
the Careful variant of NewReno TCP from RFC 2582, and eliminates the
problem of multiple Fast Retransmits. This algorithm uses the
variable "recover", whose initial value is the initial send sequence
number. After each retransmit timeout, the highest sequence number
transmitted so far is recorded in the variable "recover".
If, after a retransmit timeout, the TCP data sender retransmits three
consecutive packets that have already been received by the data
receiver, then the TCP data sender will receive three duplicate
acknowledgements that do not cover more than "recover". In this
case, the duplicate acknowledgements are not an indication of a new
instance of congestion. They are simply an indication that the
sender has unnecessarily retransmitted at least three packets.
However, when a retransmitted packet is itself dropped, the sender
can also receive three duplicate acknowledgements that do not cover
more than "recover". In this case, the sender would have been better
off if it had initiated Fast Retransmit. For a TCP that implements
the algorithm specified in Section 3 of this document, the sender
does not infer a packet drop from duplicate acknowledgements in this
scenario. As always, the retransmit timer is the backup mechanism
for inferring packet loss in this case.
There are several heuristics, based on timestamps or on the amount of
advancement of the cumulative acknowledgement field, that allow the
sender to distinguish, in some cases, between three duplicate
acknowledgements following a retransmitted packet that was dropped,
and three duplicate acknowledgements from the unnecessary
retransmission of three packets [Gur03, GF04]. The TCP sender MAY
use such a heuristic to decide to invoke a Fast Retransmit in some
cases, even when the three duplicate acknowledgements do not cover
more than "recover".
For example, when three duplicate acknowledgements are caused by the
unnecessary retransmission of three packets, this is likely to be
accompanied by the cumulative acknowledgement field advancing by at
least four segments. Similarly, a heuristic based on timestamps uses
the fact that when there is a hole in the sequence space, the
timestamp echoed in the duplicate acknowledgement is the timestamp of
the most recent data packet that advanced the cumulative
acknowledgement field [RFC1323]. If timestamps are used, and the
sender stores the timestamp of the last acknowledged segment, then
the timestamp echoed by duplicate acknowledgements can be used to
distinguish between a retransmitted packet that was dropped and three
duplicate acknowledgements from the unnecessary retransmission of
three packets. The heuristics are illustrated in the NS simulator in
the validation test "./test-all-newreno".
Floyd, et al. Standards Track [Page 10]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
6.1. ACK Heuristic
If the ACK-based heuristic is used, then following the advancement of
the cumulative acknowledgement field, the sender stores the value of
the previous cumulative acknowledgement as prev_highest_ack, and
stores the latest cumulative ACK as highest_ack. In addition, the
following step is performed if Step 1 in Section 3 fails, before
proceeding to Step 1B.
1*) If the Cumulative Acknowledgement field didn’t cover more than
"recover", check to see if the congestion window is greater than
SMSS bytes and the difference between highest_ack and
prev_highest_ack is at most 4*SMSS bytes. If true, duplicate
ACKs indicate a lost segment (proceed to Step 1A in Section 3).
Otherwise, duplicate ACKs likely result from unnecessary
retransmissions (proceed to Step 1B in Section 3).
The congestion window check serves to protect against fast retransmit
immediately after a retransmit timeout, similar to the
"exitFastRetrans_" variable in NS. Examples of applying the ACK
heuristic are in validation tests "./test-all-newreno
newreno_rto_loss_ack" and "./test-all-newreno newreno_rto_dup_ack" in
directory "tcl/test" of the NS simulator.
If several ACKs are lost, the sender can see a jump in the cumulative
ACK of more than three segments, and the heuristic can fail. A
validation test for this scenario is "./test-all-newreno
newreno_rto_loss_ackf". RFC 2581 recommends that a receiver should
send duplicate ACKs for every out-of-order data packet, such as a
data packet received during Fast Recovery. The ACK heuristic is more
likely to fail if the receiver does not follow this advice, because
then a smaller number of ACK losses are needed to produce a
sufficient jump in the cumulative ACK.
6.2. Timestamp Heuristic
If this heuristic is used, the sender stores the timestamp of the
last acknowledged segment. In addition, the second paragraph of step
1 in Section 3 is replaced as follows:
1**) If the Cumulative Acknowledgement field didn’t cover more than
"recover", check to see if the echoed timestamp in the last
non-duplicate acknowledgment equals the stored timestamp. If
true, duplicate ACKs indicate a lost segment (proceed to Step 1A
in Section 3). Otherwise, duplicate ACKs likely result from
unnecessary retransmissions (proceed to Step 1B in Section 3).
Floyd, et al. Standards Track [Page 11]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
Examples of applying the timestamp heuristic are in validation tests
"./test-all-newreno newreno_rto_loss_tsh" and "./test-all-newreno
newreno_rto_dup_tsh". The timestamp heuristic works correctly, both
when the receiver echoes timestamps as specified by [RFC1323], and by
its revision attempts. However, if the receiver arbitrarily echoes
timestamps, the heuristic can fail. The heuristic can also fail if a
timeout was spurious and returning ACKs are not from retransmitted
segments. This can be prevented by detection algorithms such as
[RFC3522].
7. Implementation Issues for the Data Receiver
[RFC2581] specifies that "Out-of-order data segments SHOULD be
acknowledged immediately, in order to accelerate loss recovery."
Neal Cardwell has noted that some data receivers do not send an
immediate acknowledgement when they send a partial acknowledgment,
but instead wait first for their delayed acknowledgement timer to
expire [C98]. As [C98] notes, this severely limits the potential
benefit of NewReno by delaying the receipt of the partial
acknowledgement at the data sender. Echoing RFC 2581, our
recommendation is that the data receiver send an immediate
acknowledgement for an out-of-order segment, even when that out-of-
order segment fills a hole in the buffer.
8. Implementation Issues for the Data Sender
In Section 3, Step 5 above, it is noted that implementations should
take measures to avoid a possible burst of data when leaving Fast
Recovery, in case the amount of new data that the sender is eligible
to send due to the new value of the congestion window is large. This
can arise during NewReno when ACKs are lost or treated as pure window
updates, thereby causing the sender to underestimate the number of
new segments that can be sent during the recovery procedure.
Specifically, bursts can occur when the FlightSize is much less than
the new congestion window when exiting from Fast Recovery. One
simple mechanism to avoid a burst of data when leaving Fast Recovery
is to limit the number of data packets that can be sent in response
to a single acknowledgment. (This is known as "maxburst_" in the ns
simulator.) Other possible mechanisms for avoiding bursts include
rate-based pacing, or setting the slow-start threshold to the
resultant congestion window and then resetting the congestion window
to FlightSize. A recommendation on the general mechanism to avoid
excessively bursty sending patterns is outside the scope of this
document.
An implementation may want to use a separate flag to record whether
or not it is presently in the Fast Recovery procedure. The use of
the value of the duplicate acknowledgment counter for this purpose is
Floyd, et al. Standards Track [Page 12]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
not reliable because it can be reset upon window updates and out-of-
order acknowledgments.
When not in Fast Recovery, the value of the state variable "recover"
should be pulled along with the value of the state variable for
acknowledgments (typically, "snd_una") so that, when large amounts of
data have been sent and acked, the sequence space does not wrap and
falsely indicate that Fast Recovery should not be entered (Section 3,
step 1, last paragraph).
It is important for the sender to respond correctly to duplicate ACKs
received when the sender is no longer in Fast Recovery (e.g., because
of a Retransmit Timeout). The Limited Transmit procedure [RFC3042]
describes possible responses to the first and second duplicate
acknowledgements. When three or more duplicate acknowledgements are
received, the Cumulative Acknowledgement field doesn’t cover more
than "recover", and a new Fast Recovery is not invoked, it is
important that the sender not execute the Fast Recovery steps (3) and
(4) in Section 3. Otherwise, the sender could end up in a chain of
spurious timeouts. We mention this only because several NewReno
implementations had this bug, including the implementation in the NS
simulator. (This bug in the NS simulator was fixed in July 2003,
with the variable "exitFastRetrans_".)
9. Simulations
Simulations with NewReno are illustrated with the validation test
"tcl/test/test-all-newreno" in the NS simulator. The command
"../../ns test-suite-newreno.tcl reno" shows a simulation with Reno
TCP, illustrating the data sender’s lack of response to a partial
acknowledgement. In contrast, the command "../../ns test-suite-
newreno.tcl newreno_B" shows a simulation with the same scenario
using the NewReno algorithms described in this paper.
10. Comparisons between Reno and NewReno TCP
As we stated in the introduction, we believe that the NewReno
modification described in this document improves the performance of
the Fast Retransmit and Fast Recovery algorithms of Reno TCP in a
wide variety of scenarios. This has been discussed in some depth in
[FF96], which illustrates Reno TCP’s poor performance when multiple
packets are dropped from a window of data and also illustrates
NewReno TCP’s good performance in that scenario.
We do, however, know of one scenario where Reno TCP gives better
performance than NewReno TCP, that we describe here for the sake of
completeness. Consider a scenario with no packet loss, but with
sufficient reordering so that the TCP sender receives three duplicate
Floyd, et al. Standards Track [Page 13]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
acknowledgements. This will trigger the Fast Retransmit and Fast
Recovery algorithms. With Reno TCP or with Sack TCP, this will
result in the unnecessary retransmission of a single packet, combined
with a halving of the congestion window (shown on pages 4 and 6 of
[F03]). With NewReno TCP, however, this reordering will also result
in the unnecessary retransmission of an entire window of data (shown
on page 5 of [F03]).
While Reno TCP performs better than NewReno TCP in the presence of
reordering, NewReno’s superior performance in the presence of
multiple packet drops generally outweighs its less optimal
performance in the presence of reordering. (Sack TCP is the
preferred solution, with good performance in both scenarios.) This
document recommends the Fast Retransmit and Fast Recovery algorithms
of NewReno TCP instead of those of Reno TCP for those TCP connections
that do not support SACK. We would also note that NewReno’s Fast
Retransmit and Fast Recovery mechanisms are widely deployed in TCP
implementations in the Internet today, as documented in [PF01]. For
example, tests of TCP implementations in several thousand web servers
in 2001 showed that for those TCP connections where the web browser
was not SACK-capable, more web servers used the Fast Retransmit and
Fast Recovery algorithms of NewReno than those of Reno or Tahoe TCP
[PF01].
11. Changes Relative to RFC 2582
The purpose of this document is to advance the NewReno’s Fast
Retransmit and Fast Recovery algorithms in RFC 2582 to Standards
Track.
The main change in this document relative to RFC 2582 is to specify
the Careful variant of NewReno’s Fast Retransmit and Fast Recovery
algorithms. The base algorithm described in RFC 2582 did not attempt
to avoid unnecessary multiple Fast Retransmits that can occur after a
timeout (described in more detail in the section above). However,
RFC 2582 also defined "Careful" and "Less Careful" variants that
avoid these unnecessary Fast Retransmits, and recommended the Careful
variant. This document specifies the previously-named "Careful"
variant as the basic version of NewReno. As described below, this
algorithm uses a variable "recover", whose initial value is the send
sequence number.
The algorithm specified in Section 3 checks whether the
acknowledgement field of a partial acknowledgement covers *more* than
"recover", as defined in Section 3. Another possible variant would
be to simply require that the acknowledgement field covers *more than
or equal to* "recover" before initiating another Fast Retransmit. We
called this the Less Careful variant in RFC 2582.
Floyd, et al. Standards Track [Page 14]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
There are two separate scenarios in which the TCP sender could
receive three duplicate acknowledgements acknowledging "recover" but
no more than "recover". One scenario would be that the data sender
transmitted four packets with sequence numbers higher than "recover",
that the first packet was dropped in the network, and the following
three packets triggered three duplicate acknowledgements
acknowledging "recover". The second scenario would be that the
sender unnecessarily retransmitted three packets below "recover", and
that these three packets triggered three duplicate acknowledgements
acknowledging "recover". In the absence of SACK, the TCP sender is
unable to distinguish between these two scenarios.
For the Careful variant of Fast Retransmit, the data sender would
have to wait for a retransmit timeout in the first scenario, but
would not have an unnecessary Fast Retransmit in the second scenario.
For the Less Careful variant to Fast Retransmit, the data sender
would Fast Retransmit as desired in the first scenario, and would
unnecessarily Fast Retransmit in the second scenario. This document
only specifies the Careful variant in Section 3. Unnecessary Fast
Retransmits with the Less Careful variant in scenarios with
reordering are illustrated in page 8 of [F03].
The document also specifies two heuristics that the TCP sender MAY
use to decide to invoke Fast Retransmit even when the three duplicate
acknowledgements do not cover more than "recover". These heuristics,
an ACK-based heuristic and a timestamp heuristic, are described in
Sections 6.1 and 6.2 respectively.
12. Conclusions
This document specifies the NewReno Fast Retransmit and Fast Recovery
algorithms for TCP. This NewReno modification to TCP can even be
important for TCP implementations that support the SACK option,
because the SACK option can only be used for TCP connections when
both TCP end-nodes support the SACK option. NewReno performs better
than Reno (RFC 2581) in a number of scenarios discussed herein.
A number of options to the basic algorithm presented in Section 3 are
also described. These include the handling of the retransmission
timer (Section 4), the response to partial acknowledgments (Section
5), and the value of the congestion window when leaving Fast Recovery
(section 3, step 5). Our belief is that the differences between
these variants of NewReno are small compared to the differences
between Reno and NewReno. That is, the important thing is to
implement NewReno instead of Reno, for a TCP connection without SACK;
it is less important exactly which of the variants of NewReno is
implemented.
Floyd, et al. Standards Track [Page 15]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
13. Security Considerations
RFC 2581 discusses general security considerations concerning TCP
congestion control. This document describes a specific algorithm
that conforms with the congestion control requirements of RFC 2581,
and so those considerations apply to this algorithm, too. There are
no known additional security concerns for this specific algorithm.
14. Acknowledgements
Many thanks to Anil Agarwal, Mark Allman, Armando Caro, Jeffrey Hsu,
Vern Paxson, Kacheong Poon, Keyur Shah, and Bernie Volz for detailed
feedback on this document or on its precursor, RFC 2582.
15. References
15.1. Normative References
[RFC2018] Mathis, M., Mahdavi, J., Floyd, S. and A. Romanow, "TCP
Selective Acknowledgement Options", RFC 2018, October 1996.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2581] Allman, M., Paxson, V. and W. Stevens, "TCP Congestion
Control", RFC 2581, April 1999.
[RFC2582] Floyd, S. and T. Henderson, "The NewReno Modification to
TCP’s Fast Recovery Algorithm", RFC 2582, April 1999.
[RFC2988] Paxson, V. and M. Allman, "Computing TCP’s Retransmission
Timer", RFC 2988, November 2000.
[RFC3042] Allman, M., Balakrishnan, H. and S. Floyd, "Enhancing TCP’s
Loss Recovery Using Limited Transmit", RFC 3042, January
2001.
15.2. Informative References
[C98] Cardwell, N., "delayed ACKs for retransmitted packets:
ouch!". November 1998, Email to the tcpimpl mailing list,
Message-ID "Pine.LNX.4.02A.9811021421340.26785-
100000@sake.cs.washington.edu", archived at "http://tcp-
impl.lerc.nasa.gov/tcp-impl".
Floyd, et al. Standards Track [Page 16]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
[F98] Floyd, S., Revisions to RFC 2001, "Presentation to the
TCPIMPL Working Group", August 1998. URLs
"ftp://ftp.ee.lbl.gov/talks/sf-tcpimpl-aug98.ps" and
"ftp://ftp.ee.lbl.gov/talks/sf-tcpimpl-aug98.pdf".
[F03] Floyd, S., "Moving NewReno from Experimental to Proposed
Standard? Presentation to the TSVWG Working Group", March
2003. URLs "http://www.icir.org/floyd/talks/newreno-
Mar03.ps" and "http://www.icir.org/floyd/talks/newreno-
Mar03.pdf".
[FF96] Fall, K. and S. Floyd, "Simulation-based Comparisons of
Tahoe, Reno and SACK TCP", Computer Communication Review,
July 1996. URL "ftp://ftp.ee.lbl.gov/papers/sacks.ps.Z".
[F94] Floyd, S., "TCP and Successive Fast Retransmits", Technical
report, October 1994. URL
"ftp://ftp.ee.lbl.gov/papers/fastretrans.ps".
[GF04] Gurtov, A. and S. Floyd, "Resolving Acknowledgment
Ambiguity in non-SACK TCP", Next Generation Teletraffic and
Wired/Wireless Advanced Networking (NEW2AN’04), February
2004. URL "http://www.cs.helsinki.fi/u/gurtov/papers/
heuristics.html".
[Gur03] Gurtov, A., "[Tsvwg] resolving the problem of unnecessary
fast retransmits in go-back-N", email to the tsvwg mailing
list, message ID <3F25B467.9020609@cs.helsinki.fi>, July
28, 2003. URL "http://www1.ietf.org/mail-archive/working-
groups/tsvwg/current/msg04334.html".
[Hen98] Henderson, T., Re: NewReno and the 2001 Revision. September
1998. Email to the tcpimpl mailing list, Message ID
"Pine.BSI.3.95.980923224136.26134A-
100000@raptor.CS.Berkeley.EDU", archived at "http://tcp-
impl.lerc.nasa.gov/tcp-impl".
[Hoe95] Hoe, J., "Startup Dynamics of TCP’s Congestion Control and
Avoidance Schemes", Master’s Thesis, MIT, 1995.
[Hoe96] Hoe, J., "Improving the Start-up Behavior of a Congestion
Control Scheme for TCP", ACM SIGCOMM, August 1996. URL
"http://www.acm.org/sigcomm/sigcomm96/program.html".
[LM97] Lin, D. and R. Morris, "Dynamics of Random Early
Detection", SIGCOMM 97, September 1997. URL
"http://www.acm.org/sigcomm/sigcomm97/program.html".
Floyd, et al. Standards Track [Page 17]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
[NS] The Network Simulator (NS). URL
"http://www.isi.edu/nsnam/ns/".
[PF01] Padhye, J. and S. Floyd, "Identifying the TCP Behavior of
Web Servers", June 2001, SIGCOMM 2001.
[RFC1323] Jacobson, V., Braden, R. and D. Borman, "TCP Extensions for
High Performance", RFC 1323, May 1992.
[RFC3517] Blanton, E., Allman, M., Fall, K. and L. Wang, "A
Conservative Selective Acknowledgment (SACK)-based Loss
Recovery Algorithm for TCP", RFC 3517, April 2003.
[RFC3522] Ludwig, R. and M. Meyer, "The Eifel Detection Algorithm for
TCP", RFC 3522, April 2003.
Authors’ Addresses
Sally Floyd
International Computer Science Institute
Phone: +1 (510) 666-2989
EMail: floyd@acm.org
URL: http://www.icir.org/floyd/
Tom Henderson
The Boeing Company
EMail: thomas.r.henderson@boeing.com
Andrei Gurtov
TeliaSonera
EMail: andrei.gurtov@teliasonera.com
Floyd, et al. Standards Track [Page 18]
RFC 3782 NewReno Modification to Fast Recovery Algorithm April 2004
Full Copyright Statement
Copyright (C) The Internet Society (2004). This document is subject
to the rights, licenses and restrictions contained in BCP 78, and
except as set forth therein, the authors retain all their rights.
This document and the information contained herein are provided on an
"AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE
REPRESENTS OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE
INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF
THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
Intellectual Property
The IETF takes no position regarding the validity or scope of any
Intellectual Property Rights or other rights that might be claimed
to pertain to the implementation or use of the technology
described in this document or the extent to which any license
under such rights might or might not be available; nor does it
represent that it has made any independent effort to identify any
such rights. Information on the procedures with respect to
rights in RFC documents can be found in BCP 78 and BCP 79.
Copies of IPR disclosures made to the IETF Secretariat and any
assurances of licenses to be made available, or the result of an
attempt made to obtain a general license or permission for the use
of such proprietary rights by implementers or users of this
specification can be obtained from the IETF on-line IPR repository
at http://www.ietf.org/ipr.
The IETF invites any interested party to bring to its attention
any copyrights, patents or patent applications, or other
proprietary rights that may cover technology that may be required
to implement this standard. Please address the information to the
IETF at ietf-ipr@ietf.org.
Acknowledgement
Funding for the RFC Editor function is currently provided by the
Internet Society.
Floyd, et al. Standards Track [Page 19]
... Existing algorithms are oblivious to the influence by the rates of change or dynamics of various parameters. For example, loss-based algorithms, such as TcpNewReno (NewReno) [3]- [5] and TcpCubic (Cubic) [6], [7], increases the throughput until there is packet loss, after which it reduces the throughput abruptly. They do not consider the rate of change of the throughput over time as a factor in congestion control. ...
... A TCP congestion control algorithm developed for high speed networks [6]. It uses cubic increase function instead of linear increase function used bt Reno and NewReno [3], [5]. TcpQtOptimal (QtOptimal) TCP congestion control algorithm developed in this article, based on queueing theory and optimal control. ...
... Qt stands for queueing theory and Optimal refers to optimal control. TcpReno (Reno), TcpNewReno (NewReno) TcpReno is one of earliest Loss-Based TCP congestion control algorithms based on Jacobson's mechanism [3]- [5]. TcpNewReno [5] is the modification of TcpReno. ...
View
... Unlike other network solutions, IP networks require a generic connection to the network, only, utilizing its dynamic routing capabilities as a transport basis. Despite continuous efforts to improve QoS [17], a disadvantage of IP networks is the lack of control over the transmission quality. For time-sensitive transmissions, UDP/RTP protocols may be used. ...
... Various phenomena, outside the control of communicating agent, such as interference from other users and appliances, aggravate the system uncertainty and limit the available range of services. In order to address these problems, it has been proposed to simultaneously engage multiple transmission channels using different physical interfaces [17,18,19], thus mitigating the impact of uncertainty. However, early attempts to materialize this idea failed [20], until a new version of the TCP protocol tailored for multi-interface traffic -Multipath TCP (MPTCP) was proposed [21,22]. ...
... On the SPTCP level: Reno and BBR. The legacy Reno algorithm [17] linearly increases the transfer speed and reduces it multiplicatively when packet loss is detected. ...
View
... In this case, Reno and New Reno have the same behavior in the second round. [6,7] The source first receives 21 duplicate ACK's , each with a sequence number requesting Packet 1. The first three ACK's trigger the fast retransmit of Packet 1 and cause the window to drop to 12. ...
... It is not deflated, since only one new packet is acknowledged. With the successful retransmission of packet 24, the window is cut back to 12 again [6,7]. ...
A Survey on Performance Analysis of TCP Variants in IEEE 802.11 Based Ad-Hoc Networks
Article
  • Aug 2011
In order to allow programmers to follow conventional techniques while creating applications that uses an internet, software in the internet must provide the same semantics as a conventional computer system, it means it must guarantee reliable communication. Transport protocol provides reliability, which is fundamental for all the applications. The transmission Control protocol (TCP) is the transport level protocol that provides a completely reliable connection-oriented, full duplex stream transport service that allows two application programs to form a connection, send data in either direction, and then terminate the connection. This paper reviews existing work done in this area
View
... This main practical goal led to an enormous number of heuristic AIMD algorithms for Internet CC (e.g. [18,25,29,30,47]), and even today, the default CC algorithm in most platforms is still an AIMD algorithm that had the same intrinsic objective during the design (TCP Cubic [25]). The throughput-oriented nature of CC designs was a practical and acceptable assumption mainly due to the throughput-oriented nature of the dominant applications at the time. ...
... The non-exhausting list of schemes consists of 22 different Internet CC algorithms. These algorithms include 14 available TCP schemes in Linux Kernel named Cubic [25], Vegas [12], YeAH [11], BBRv2 [16], NewReno [29], Illinois [36], Westwood [17], Veno [23], HighSpeed [22], CDG [27], HTCP [35], BIC [47], C2TCP [6], and Hybla [14], 5 recent ML-Based CC schemes named Orca [8], Indigo [48], Aurora [31], PCC Vivace [21], and DeepCC [9], and 3 other CC schemes named Copa [10], LEDBAT [42], and Sprout [46]. ...
Internet Congestion Control Benchmarking
Preprint
Full-text available
  • Jul 2023
How do we assess a new Internet congestion control (CC) design? How do we compare it with other existing schemes? Under what scenarios and using what network parameters? These are just a handful of simple questions coming up every time a new CC design is going to be evaluated. Interestingly, the number of specific answers to these questions can be as large as the number of CC designers. In this work, we aim to highlight that the network congestion control, as a hot and active research topic, requires a crystal clear set(s) of \textit{CC Benchmarks} to form a common ground for quantitatively comparing and unambiguously assessing the strengths and weaknesses of a design with respect to the existing ones. As a first step toward that goal, we introduce general benchmarks that can capture the different performance of the existing Internet CC schemes. Using these benchmarks, we rank the Internet CC algorithms and illustrate that there is still lots of room for more innovations and improvements in this topic.
View
... QUIC has demonstrated potential in lowering latency and enhancing throughput in challenging scenarios [15]. However, its congestion control algorithm [16] is similar to TCP NewReno's [17], rendering it unsuitable for the UDP environment explored in this work. Another possibility is the mechanism employed by WebRTC, which utilizes the real-time transport protocol (RTP) over UDP. ...
A Reinforcement Learning Congestion Control Algorithm for Smart Grid Networks
Article
Full-text available
  • Jan 2024
Modern electrical systems are evolving with data communication networks, ushering in upgraded electrical infrastructures and enabling bidirectional communication between utility grids and consumers. The selection of communication technologies is crucial, where wireless communications have emerged as one of the main benefactor technologies due to its cost-effectiveness, scalability, and ease of deployment. Ensuring the streamlined transmission of diverse applications between residential users and utility control centers is crucial for the effective data delivery in smart grids. This paper proposes a congestion control mechanism tailored to smart grid applications using unreliable transport protocols such as UDP, which, unlike TCP, lacks inherent congestion control, presenting a significant challenge to the performance of the network. In this article, we have exploited a reinforcement learning (RL) algorithm and a deep Q -neural network (DQN), to manage congestion control under a UDP environment. In this particular instance, the DQN model learns on its own from interactions with the environment without the need to generate a dataset, rendering it apt for intricate and dynamic scenarios within smart grid communications. Our evaluation covers two scenarios: (i) a grid-like configuration, and (ii) urban scenarios considering the deployment of smart meters in the cities of Montreal, Berlin and Beijing. These evaluations provide a comprehensive examination of the proposed DQN-based congestion control approach under different conditions, showing its effectiveness and adaptability. Conducting a comprehensive performance assessment in both scenarios leads to improvements in metrics such as packet delivery ratio, network throughput, fairness between different traffic sources, packet network transit time, and QoS provision.
View
... There are many congestion window control algorithms [14]. The TCP NewReno [15] algorithm is the most widely used in Internet transmissions. Random packet deletion provided by AQM allows avoiding socalled global synchronisation effect, which involves slowing down transmission by multiple TCP transmitters at the same time in case of losses caused by exceeding maximum queue size in nodes. ...
View
... As the time passes and if there are no errors during data transmission (which is indicated by the received stream of acknowledgements), the aforementioned sliding window size is systematically increased (linearly only) and reaction to congestion in the network is fast; this congestion avoidance is carried out by drastic limitation of window size and intensity of segment sending (loss of data segment is interpreted as symptom of congestion, this is indicated by duplicate acknowledgements received by the sender). The variants of controlling the flow and congestion in TCP protocol, such as Tahoe and Reno [28] (shown in Fig.1), or TCP-NewReno [29], or e.g. CUBIC [30] use different control mechanisms to manage behaviour of "slow start" and "fast drop" type (of the window size); they may also utilize different signals for data flow control, basing for instance on RTT time measurements (data transfer end-to-end), delay times in packet transmission or jitter (delay variability), time intervals between packets. ...
The Need for New Transport Protocols on the INTERNET
Article
Full-text available
  • Sep 2023
TThe TCP/IP protocol suite is widely used in IP networks, regardless of diverse environments and usage scenarios. Due to the fact of being the basic concept of organizing the work of the Internet, it is the subject of interest and constant analysis of operators, users, network researchers, and designers. The Internet is a "living" organism in which new needs appear all the time. This is particularly important due to the emerging new application requirements - at the highest level of network architecture, and at the same time, completely new ways of transmitting messages related to new technologies and reception techniques, allowing for parallelization of messages transfer and lossless switching/handover between several interfaces. The paper highlights the expectations and requirements related, in particular, to new "multi-object" applications, as well as the limitations resulting from the high inertia observed on the side of the IP network transport infrastructure. Taking into account both the limitations and the formulated requirements, the selected end-to-end transport protocols have been characterized. More attention was paid to two protocols implementing multi-stream transfers, namely SCTP and QUIC.
View
... Delay-based protocols aim to minimize queuing by adjusting their sending rate based on queuing delay [10,25,28], or delay-gradients [1,6,24]. Buffer-filling algorithms [26,29,30] send as much traffic as possible until loss or congestion is detected. Some approaches like Nimbus [31] switch between delay-based and buffer-filling modes to improve fairness against competing traffic while maintaining high utilization. ...
Vidaptive: Efficient and Responsive Rate Control for Real-Time Video on Variable Networks
Preprint
Full-text available
  • Sep 2023
Real-time video streaming relies on rate control mechanisms to adapt video bitrate to network capacity while maintaining high utilization and low delay. However, the current video rate controllers, such as Google Congestion Control (GCC) in WebRTC, are very slow to respond to network changes, leading to link under-utilization and latency spikes. While recent delay-based congestion control algorithms promise high efficiency and rapid adaptation to variable conditions, low-latency video applications have been unable to adopt these schemes due to the intertwined relationship between video encoders and rate control in current systems. This paper introduces Vidaptive, a new rate control mechanism designed for low-latency video applications. Vidaptive decouples packet transmission decisions from encoder output, injecting "dummy" padding traffic as needed to treat video streams akin to backlogged flows controlled by a delay-based congestion controller. Vidaptive then adapts the frame rate, resolution, and target bitrate of the encoder to align the video bitrate with the congestion controller's sending rate. Our evaluations atop WebRTC show that, across a set of cellular traces, Vidaptive achieves ∼2× higher video bitrate and 1.6 dB higher PSNR, and it reduces 95 th-percentile frame latency by 2.7s with a slight increase in median frame latency.
View
... The second challenge in classical forward-path congestion control loops is the dependency of the reaction time of the sender node on the downstream path from the bottleneck to the receiver. Considering a network where multiple flows with different RTTs share one bottleneck, current congestion control approaches lead to unfair bottleneck capacity distribution among these flows [20]- [23]. Hence, although the flows may experience congestion simultaneously, the time of arrival of the congestion notification at the respective sources varies and hence they react with different delays to the congestion leading to throughput unfairness with sources having a smaller RTT receiving more bandwidth. ...
View
View
View
Simulation-based comparisons of Tahoe, Reno and SACK TCP
Article
Full-text available
  • Dec 1995
  • COMPUT COMMUN REV
This paper uses simulations to explore the benefits of adding selective acknowledgments (SACK) and selective repeat to TCP. We compare Tahoe and Reno TCP, the two most common reference implementations for TCP, with two modified versions of Reno TCP. The first version is New-Reno TCP, a modified version of TCP without SACK that avoids some of Reno TCP's performance problems when multiple packets are dropped from a window of data. The second version is SACK TCP, a conservative extension of Reno TCP modified to use the SACK option being proposed in the Internet Engineering Task Force (IETF). We describe the congestion control algorithms in our simulated implementation of SACK TCP and show that while selective acknowledgments are not required to solve Reno TCP's performance problems when multiple packets are dropped, the absence of selective acknowledgments does impose limits to TCP's ultimate performance. In particular, we show that without selective acknowledgments, TCP implementations are constrained to either retransmit at most one dropped packet per round-trip time, or to retransmit packets that might have already been successfully delivered. 1
View
TCP and Successive Fast Retransmits
Article
Full-text available
  • May 1995
won't go through the details, but Figure 2 shows the pathological behavior that can result from multiple Fast Retransmits in one roundtrip time. This work was supported by the Director, Office of Energy Research, Scientific Computing Staff, of the U.S. Department of Energy under Contract No. DE-AC03-76SF00098. This problem is somewhat more difficult to duplicate in simulations with Reno implementations. With Reno implementations, the source essentially assumes that only one packet has been dropped, retransmits that dropped packet, and instead of waiting for the ACK to be received, continues transmitted new packets. For multiple packet drops in one roundtrip time, the Reno source often has to wait for a retransmit timer to recover (given the absence of Selective ACKs). And in some circumstances with Reno, the ability to have multiple Fast Retransmits in a single roundtrip time can avoid the wait for a retransmit timer timeout, in the absence of Selective ACKs.
View
View
View
Computing TCP's Retransmission Timer
Article
  • Jan 2000
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.
View
View
Dynamics of Random Early Detection
Article
  • Dec 1999
  • COMPUT COMMUN REV
In this paper we evaluate the effectiveness of Random Early Detection (RED) over traffic types categorized as nonadaptive, fragile and robust, according to their responses to congestion. We point out that RED allows unfair bandwidth sharing when a mixture of the three traffic types shares a link. This unfairness is caused by the fact that at any given time RED imposes the same loss rate on all flows, regardless of their bandwidths. We propose Flow Random Early Drop (FRED), a modified version of RED. FRED uses per-active-flow accounting to impose on each flow a loss rate that depends on the flow's buffer use. We show that FRED provides better protection than RED for adaptive (fragile and robust) flows. In addition, FRED is able to isolate non-adaptive greedy traffic more effectively. Finally, we present a "two-packet-buffer" gateway mechanism to support a large number of flows without incurring additional queueing delays inside the network. These improvements are demonstrated by simulation of TCP and UDP traffic.
View
Improving the Start-up Behavior of a Congestion Control Scheme for TCP
Article
  • Nov 1999
  • COMPUT COMMUN REV
Based on experiments conducted in a network simulator and over real networks, this paper proposes changes to the congestion control scheme in current TCP implementations to improve its behavior during the start-up period of a TCP connection. The scheme, which includes Slow-start, Fast Retransmit, and Fast Recovery algorithms, uses acknowledgments from a receiver to dynamically calculate reasonable operating values for a sender's TCP parameters governing when and how much a sender can pump into the network. During the startup period, because a TCP sender starts with default parameters, it often ends up sending too many packets and too fast, leading to multiple losses of packets from the same window. This paper shows that recovery from losses during this start-up period is often unnecessarily time-consuming. In particular, using the current Fast Retransmit algorithm, when multiple packets in the same window are lost, only one of the packet losses may be recovered by each Fast Retransmi...
View
TCP Selective Acknowledgement OptionsKey words for use in RFCs to Indicate Requirement LevelsThe NewReno Modification to TCP's Fast Recovery Algorithm
  • Jan 1996
  • M Normative References [ Rfc2018 ] Mathis
  • J Mahdavi
  • S Floyd
  • A Bradner
  • S Allman
  • M Paxson
  • W Stevens Floyd
  • T Henderson
Normative References [RFC2018] Mathis, M., Mahdavi, J., Floyd, S. and A. Romanow, "TCP Selective Acknowledgement Options", RFC 2018, October 1996. [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC2581] Allman, M., Paxson, V. and W. Stevens, "TCP Congestion Control", RFC 2581, April 1999. [RFC2582] Floyd, S. and T. Henderson, "The NewReno Modification to TCP's Fast Recovery Algorithm", RFC 2582, April 1999. [RFC2988] Paxson, V. and M. Allman, "Computing TCP's Retransmission Timer", RFC 2988, November 2000.