[Docs] [txt|pdf] [draft-ietf-tcpm...] [Tracker] [Diff1] [Diff2]
Obsoleted by: 7414 INFORMATIONAL
Updated by: 6247
Network Working Group M. Duke
Request for Comments: 4614 Boeing Phantom Works
Category: Informational R. Braden
USC Information Sciences Institute
W. Eddy
Verizon Federal Network Systems
E. Blanton
Purdue University Computer Science
September 2006
A Roadmap for Transmission Control Protocol (TCP)
Specification Documents
Status of This Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2006).
Abstract
This document contains a "roadmap" to the Requests for Comments (RFC)
documents relating to the Internet's Transmission Control Protocol
(TCP). This roadmap provides a brief summary of the documents
defining TCP and various TCP extensions that have accumulated in the
RFC series. This serves as a guide and quick reference for both TCP
implementers and other parties who desire information contained in
the TCP-related RFCs.
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Table of Contents
1. Introduction ....................................................2
2. Basic Functionality .............................................4
3. Recommended Enhancements ........................................6
3.1. Congestion Control and Loss Recovery Extensions ............7
3.2. SACK-Based Loss Recovery and Congestion Control ............8
3.3. Dealing with Forged Segments ...............................9
4. Experimental Extensions ........................................10
5. Historic Extensions ............................................13
6. Support Documents ..............................................14
6.1. Foundational Works ........................................15
6.2. Difficult Network Environments ............................16
6.3. Implementation Advice .....................................19
6.4. Management Information Bases ..............................20
6.5. Tools and Tutorials .......................................22
6.6. Case Studies ..............................................22
7. Undocumented TCP Features ......................................23
8. Security Considerations ........................................24
9. Acknowledgments ................................................24
10. Informative References ........................................25
10.1. Basic Functionality ......................................25
10.2. Recommended Enhancements .................................25
10.3. Experimental Extensions ..................................26
10.4. Historic Extensions ......................................27
10.5. Support Documents ........................................28
10.6. Informative References Outside the RFC Series ............31
1. Introduction
A correct and efficient implementation of the Transmission Control
Protocol (TCP) is a critical part of the software of most Internet
hosts. As TCP has evolved over the years, many distinct documents
have become part of the accepted standard for TCP. At the same time,
a large number of more experimental modifications to TCP have also
been published in the RFC series, along with informational notes,
case studies, and other advice.
As an introduction to newcomers and an attempt to organize the
plethora of information for old hands, this document contains a
"roadmap" to the TCP-related RFCs. It provides a brief summary of
the RFC documents that define TCP. This should provide guidance to
implementers on the relevance and significance of the standards-track
extensions, informational notes, and best current practices that
relate to TCP.
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This document is not an update of RFC 1122 and is not a rigorous
standard for what needs to be implemented in TCP. This document is
merely an informational roadmap that captures, organizes, and
summarizes most of the RFC documents that a TCP implementer,
experimenter, or student should be aware of. Particular comments or
broad categorizations that this document makes about individual
mechanisms and behaviors are not to be taken as definitive, nor
should the content of this document alone influence implementation
decisions.
This roadmap includes a brief description of the contents of each
TCP-related RFC. In some cases, we simply supply the abstract or a
key summary sentence from the text as a terse description. In
addition, a letter code after an RFC number indicates its category in
the RFC series (see BCP 9 [RFC2026] for explanation of these
categories):
S - Standards Track (Proposed Standard, Draft Standard, or
Standard)
E - Experimental
B - Best Current Practice
I - Informational
Note that the category of an RFC does not necessarily reflect its
current relevance. For instance, RFC 2581 is nearly universally
deployed although it is only a Proposed Standard. Similarly, some
Informational RFCs contain significant technical proposals for
changing TCP.
This roadmap is divided into four main sections. Section 2 lists the
RFCs that describe absolutely required TCP behaviors for proper
functioning and interoperability. Further RFCs that describe
strongly encouraged, but non-essential, behaviors are listed in
Section 3. Experimental extensions that are not yet standard
practices, but that potentially could be in the future, are described
in Section 4.
The reader will probably notice that these three sections are broadly
equivalent to MUST/SHOULD/MAY specifications (per RFC 2119), and
although the authors support this intuition, this document is merely
descriptive; it does not represent a binding standards-track
position. Individual implementers still need to examine the
standards documents themselves to evaluate specific requirement
levels.
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A small number of older experimental extensions that have not been
widely implemented, deployed, and used are noted in Section 5. Many
other supporting documents that are relevant to the development,
implementation, and deployment of TCP are described in Section 6.
Within each section, RFCs are listed in the chronological order of
their publication dates.
A small number of fairly ubiquitous important implementation
practices that are not currently documented in the RFC series are
listed in Section 7.
2. Basic Functionality
A small number of documents compose the core specification of TCP.
These define the required basic functionalities of TCP's header
parsing, state machine, congestion control, and retransmission
timeout computation. These base specifications must be correctly
followed for interoperability.
RFC 793 S: "Transmission Control Protocol", STD 7 (September 1981)
This is the fundamental TCP specification document [RFC0793].
Written by Jon Postel as part of the Internet protocol suite's
core, it describes the TCP packet format, the TCP state machine
and event processing, and TCP's semantics for data transmission,
reliability, flow control, multiplexing, and acknowledgment.
Section 3.6 of RFC 793, describing TCP's handling of the IP
precedence and security compartment, is mostly irrelevant today.
RFC 2873 changed the IP precedence handling, and the security
compartment portion of the API is no longer implemented or used.
In addition, RFC 793 did not describe any congestion control
mechanism. Otherwise, however, the majority of this document
still accurately describes modern TCPs. RFC 793 is the last of a
series of developmental TCP specifications, starting in the
Internet Experimental Notes (IENs) and continuing in the RFC
series.
RFC 1122 S: "Requirements for Internet Hosts - Communication Layers"
(October 1989)
This document [RFC1122] updates and clarifies RFC 793, fixing some
specification bugs and oversights. It also explains some features
such as keep-alives and Karn's and Jacobson's RTO estimation
algorithms [KP87][Jac88][JK92]. ICMP interactions are mentioned,
and some tips are given for efficient implementation. RFC 1122 is
an Applicability Statement, listing the various features that
MUST, SHOULD, MAY, SHOULD NOT, and MUST NOT be present in
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standards-conforming TCP implementations. Unlike a purely
informational "roadmap", this Applicability Statement is a
standards document and gives formal rules for implementation.
RFC 2460 S: "Internet Protocol, Version 6 (IPv6) Specification
(December 1998)
This document [RFC2460] is of relevance to TCP because it defines
how the pseudo-header for TCP's checksum computation is derived
when 128-bit IPv6 addresses are used instead of 32-bit IPv4
addresses. Additionally, RFC 2675 describes TCP changes required
to support IPv6 jumbograms.
RFC 2581 S: "TCP Congestion Control" (April 1999)
Although RFC 793 did not contain any congestion control
mechanisms, today congestion control is a required component of
TCP implementations. This document [RFC2581] defines the current
versions of Van Jacobson's congestion avoidance and control
mechanisms for TCP, based on his 1988 SIGCOMM paper [Jac88]. RFC
2001 was a conceptual precursor that was obsoleted by RFC 2581.
A number of behaviors that together constitute what the community
refers to as "Reno TCP" are described in RFC 2581. The name
"Reno" comes from the Net/2 release of the 4.3 BSD operating
system. This is generally regarded as the least common
denominator among TCP flavors currently found running on Internet
hosts. Reno TCP includes the congestion control features of slow
start, congestion avoidance, fast retransmit, and fast recovery.
RFC 1122 mandates the implementation of a congestion control
mechanism, and RFC 2581 details the currently accepted mechanism.
RFC 2581 differs slightly from the other documents listed in this
section, as it does not affect the ability of two TCP endpoints to
communicate; however, congestion control remains a critical
component of any widely deployed TCP implementation and is
required for the avoidance of congestion collapse and to ensure
fairness among competing flows.
RFC 2873 S: "TCP Processing of the IPv4 Precedence Field" (June 2000)
This document [RFC2873] removes from the TCP specification all
processing of the precedence bits of the TOS byte of the IP
header. This resolves a conflict over the use of these bits
between RFC 793 and Differentiated Services [RFC2474].
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RFC 2988 S: "Computing TCP's Retransmission Timer" (November 2000)
Abstract: "This document defines the standard algorithm that
Transmission Control Protocol (TCP) senders are required to use to
compute and manage their retransmission timer. It expands on the
discussion in section 4.2.3.1 of RFC 1122 and upgrades the
requirement of supporting the algorithm from a SHOULD to a MUST."
[RFC2988]
3. Recommended Enhancements
This section describes recommended TCP modifications that improve
performance and security. RFCs 1323 and 3168 represent fundamental
changes to the protocol. RFC 1323, based on RFCs 1072 and 1185,
allows better utilization of high bandwidth-delay product paths by
providing some needed mechanisms for high-rate transfers. RFC 3168
describes a change to the Internet's architecture, whereby routers
signal end-hosts of growing congestion levels and can do so before
packet losses are forced. Section 3.1 lists improvements in the
congestion control and loss recovery mechanisms specified in RFC
2581. Section 3.2 describes further refinements that make use of
selective acknowledgments. Section 3.3 deals with the problem of
preventing forged segments.
RFC 1323 S: "TCP Extensions for High Performance" (May 1992)
This document [RFC1323] defines TCP extensions for window scaling,
timestamps, and protection against wrapped sequence numbers, for
efficient and safe operation over paths with large bandwidth-delay
products. These extensions are commonly found in currently used
systems; however, they may require manual tuning and
configuration. One issue in this specification that is still
under discussion concerns a modification to the algorithm for
estimating the mean RTT when timestamps are used.
RFC 2675 S: "IPv6 Jumbograms" (August 1999)
IPv6 supports longer datagrams than were allowed in IPv4. These
are known as Jumbograms, and use with TCP has necessitated changes
to the handling of TCP's MSS and Urgent fields (both 16 bits).
This document [RFC2675] explains those changes. Although it
describes changes to basic header semantics, these changes should
only affect the use of very large segments, such as IPv6
jumbograms, which are currently rarely used in the general
Internet. Supporting the behavior described in this document does
not affect interoperability with other TCP implementations when
IPv4 or non-jumbogram IPv6 is used. This document states that
jumbograms are to only be used when it can be guaranteed that all
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receiving nodes, including each router in the end-to-end path,
will support jumbograms. If even a single node that does not
support jumbograms is attached to a local network, then no host on
that network may use jumbograms. This explains why jumbogram use
has been rare, and why this document is considered a performance
optimization and not part of TCP over IPv6's basic functionality.
RFC 3168 S: "The Addition of Explicit Congestion Notification (ECN)
to IP" (September 2001)
This document [RFC3168] defines a means for end hosts to detect
congestion before congested routers are forced to discard packets.
Although congestion notification takes place at the IP level, ECN
requires support at the transport level (e.g., in TCP) to echo the
bits and adapt the sending rate. This document updates RFC 793 to
define two previously unused flag bits in the TCP header for ECN
support. RFC 3540 provides a supplementary (experimental) means
for more secure use of ECN, and RFC 2884 provides some sample
results from using ECN.
3.1. Congestion Control and Loss Recovery Extensions
Two of the most important aspects of TCP are its congestion control
and loss recovery features. TCP traditionally treats lost packets as
indicating congestion-related loss, and cannot distinguish between
congestion-related loss and loss due to transmission errors. Even
when ECN is in use, there is a rather intimate coupling between
congestion control and loss recovery mechanisms. There are several
extensions to both features, and more often than not, a particular
extension applies to both. In this sub-section, we group
enhancements to either congestion control, loss recovery, or both,
which can be performed unilaterally; that is, without negotiating
support between endpoints. In the next sub-section, we group the
extensions that specify or rely on the SACK option, which must be
negotiated bilaterally. TCP implementations should include the
enhancements from both sub-sections so that TCP senders can perform
well without regard to the feature sets of other hosts they connect
to. For example, if SACK use is not successfully negotiated, a host
should use the NewReno behavior as a fall back.
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RFC 3042 S: "Enhancing TCP's Loss Recovery Using Limited Transmit"
(January 2001)
Abstract: "This document proposes Limited Transmit, a new
Transmission Control Protocol (TCP) mechanism that can be used to
more effectively recover lost segments when a connection's
congestion window is small, or when a large number of segments are
lost in a single transmission window." [RFC3042] Tests from 2004
showed that Limited Transmit was deployed in roughly one third of
the web servers tested [MAF04].
RFC 3390 S: "Increasing TCP's Initial Window" (October 2002)
This document [RFC3390] updates RFC 2581 to permit an initial TCP
window of three or four segments during the slow-start phase,
depending on the segment size.
RFC 3782 S: "The NewReno Modification to TCP's Fast Recovery
Algorithm" (April 2004)
This document [RFC3782] specifies a modification to the standard
Reno fast recovery algorithm, whereby a TCP sender can use partial
acknowledgments to make inferences determining the next segment to
send in situations where SACK would be helpful but isn't
available. Although it is only a slight modification, the NewReno
behavior can make a significant difference in performance when
multiple segments are lost from a single window of data.
3.2. SACK-Based Loss Recovery and Congestion Control
The base TCP specification in RFC 793 provided only a simple
cumulative acknowledgment mechanism. However, a selective
acknowledgment (SACK) mechanism provides performance improvement in
the presence of multiple packet losses from the same flight, more
than outweighing the modest increase in complexity. A TCP should be
expected to implement SACK; however, SACK is a negotiated option and
is only used if support is advertised by both sides of a connection.
RFC 2018 S: "TCP Selective Acknowledgment Options" (October 1996)
This document [RFC2018] defines the basic selective acknowledgment
(SACK) mechanism for TCP.
RFC 2883 S: "An Extension to the Selective Acknowledgement (SACK)
Option for TCP" (July 2000)
This document [RFC2883] extends RFC 2018 to cover the case of
acknowledging duplicate segments.
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RFC 3517 S: "A Conservative Selective Acknowledgment (SACK)-based
Loss Recovery Algorithm for TCP" (April 2003)
This document [RFC3517] describes a relatively sophisticated
algorithm that a TCP sender can use for loss recovery when SACK
reports more than one segment lost from a single flight of data.
Although support for the exchange of SACK information is widely
implemented, not all implementations use an algorithm as
sophisticated as that described in RFC 3517.
3.3. Dealing with Forged Segments
By default, TCP lacks any cryptographic structures to differentiate
legitimate segments and those spoofed from malicious hosts. Spoofing
valid segments requires correctly guessing a number of fields. The
documents in this sub-section describe ways to make that guessing
harder, or to prevent it from being able to affect a connection
negatively.
The TCPM working group is currently in progress towards fully
understanding and defining mechanisms for preventing spoofing attacks
(including both spoofed TCP segments and ICMP datagrams). Some of
the solutions being considered rely on TCP modifications, whereas
others rely on security at lower layers (like IPsec) for protection.
RFC 1948 I: "Defending Against Sequence Number Attacks" (May 1996)
This document [RFC1948] describes the TCP vulnerability that
allows an attacker to send forged TCP packets, by guessing the
initial sequence number in the three-way handshake. Simple
defenses against exploitation are then described. Some variation
is implemented in most currently used operating systems.
RFC 2385 S: "Protection of BGP Sessions via the TCP MD5 Signature
Option" (August 1998)
From document: "This document describes current existing practice
for securing BGP against certain simple attacks. It is understood
to have security weaknesses against concerted attacks.
This memo describes a TCP extension to enhance security for BGP.
It defines a new TCP option for carrying an MD5 digest in a TCP
segment. This digest acts like a signature for that segment,
incorporating information known only to the connection end points.
Since BGP uses TCP as its transport, using this option in the way
described in this paper significantly reduces the danger from
certain security attacks on BGP." [RFC2385]
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TCP MD5 options are currently only used in very limited contexts,
primarily for defending BGP exchanges between routers. Some
deployment notes for those using TCP MD5 are found in the later
RFC 3562, "Key Management Considerations for the TCP MD5 Signature
Option" [RFC3562]. RFC 4278 deprecates the use of TCP MD5 outside
BGP [RFC4278].
4. Experimental Extensions
The RFCs in this section are still experimental, but they may become
proposed standards in the future. At least part of the reason that
they are still experimental is to gain more wide-scale experience
with them before a standards track decision is made. By their
publication as experimental RFCs, it is hoped that the community of
TCP researchers will analyze and test the contents of these RFCs.
Although experimentation is encouraged, there is not yet formal
consensus that these are fully logical and safe behaviors. Wide-
scale deployment of implementations that use these features should be
well thought-out in terms of consequences.
RFC 2140 I: "TCP Control Block Interdependence" (April 1997)
This document [RFC2140] suggests how TCP connections between the
same endpoints might share information, such as their congestion
control state. To some degree, this is done in practice by a few
operating systems; for example, Linux currently has a destination
cache. Although this RFC is technically informational, the
concepts it describes are in experimental use, so we include it in
this section.
A related proposal, the Congestion Manager, is specified in RFC
3124 [RFC3124]. The idea behind the Congestion Manager, moving
congestion control outside of individual TCP connections,
represents a modification to the core of TCP, which supports
sharing information among TCP connections as well. Although a
Proposed Standard, some pieces of the Congestion Manager support
architecture have not been specified yet, and it has not achieved
use or implementation beyond experimental stacks, so it is not
listed among the standard TCP enhancements in this roadmap.
RFC 2861 E: "TCP Congestion Window Validation" (June 2000)
This document [RFC2861] suggests reducing the congestion window
over time when no packets are flowing. This behavior is more
aggressive than that specified in RFC 2581, which says that a TCP
sender SHOULD set its congestion window to the initial window
after an idle period of an RTO or greater.
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RFC 3465 E: "TCP Congestion Control with Appropriate Byte Counting
(ABC)" (February 2003)
This document [RFC3465] suggests that congestion control use the
number of bytes acknowledged instead of the number of
acknowledgments received. This has been implemented in Linux.
The ABC mechanism behaves differently from the standard method
when there is not a one-to-one relationship between data segments
and acknowledgments. ABC still operates within the accepted
guidelines, but is more robust to delayed ACKs and ACK-division
[SCWA99][RFC3449].
RFC 3522 E: "The Eifel Detection Algorithm for TCP" (April 2003)
The Eifel detection algorithm [RFC3522] allows a TCP sender to
detect a posteriori whether it has entered loss recovery
unnecessarily.
RFC 3540 E: "Robust Explicit Congestion Notification (ECN) signaling
with Nonces" (June 2003)
This document [RFC3540] suggests a modified ECN to address
security concerns and updates RFC 3168.
RFC 3649 E: "HighSpeed TCP for Large Congestion Windows" (December
2003)
This document [RFC3649] suggests a modification to TCP's steady-
state behavior to use very large windows efficiently.
RFC 3708 E: "Using TCP Duplicate Selective Acknowledgement (DSACKs)
and Stream Control Transmission Protocol (SCTP) Duplicate
Transmission Sequence Numbers (TSNs) to Detect Spurious
Retransmissions" (February 2004)
Abstract: "TCP and Stream Control Transmission Protocol (SCTP)
provide notification of duplicate segment receipt through
Duplicate Selective Acknowledgement (DSACKs) and Duplicate
Transmission Sequence Number (TSN) notification, respectively.
This document presents conservative methods of using this
information to identify unnecessary retransmissions for various
applications." [RFC3708]
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RFC 3742 E: "Limited Slow-Start for TCP with Large Congestion
Windows" (March 2004)
This document [RFC3742] describes a more conservative slow-start
behavior to prevent massive packet losses when a connection uses a
very large window.
RFC 4015 S: "The Eifel Response Algorithm for TCP" (February 2005)
This document [RFC4015] describes the response portion of the
Eifel algorithm, which can be used in conjunction with one of
several methods of detecting when loss recovery has been
spuriously entered, such as the Eifel detection algorithm in RFC
3522, the algorithm in RFC 3708, or F-RTO in RFC 4138.
Abstract: "Based on an appropriate detection algorithm, the Eifel
response algorithm provides a way for a TCP sender to respond to a
detected spurious timeout. It adapts the retransmission timer to
avoid further spurious timeouts, and can avoid - depending on the
detection algorithm - the often unnecessary go-back-N retransmits
that would otherwise be sent. In addition, the Eifel response
algorithm restores the congestion control state in such a way that
packet bursts are avoided."
RFC 4015 is itself a Proposed Standard. The consensus of the TCPM
working group was to place it in this section of the roadmap
document due to three factors.
1. RFC 4015 operates on the output of a detection algorithm, for
which there is currently no available mechanism on the
standards track.
2. The working group was not aware of any wide deployment and use
of RFC 4015.
3. The consensus of the working group, after a discussion of the
known Intellectual Property Rights claims on the techniques
described in RFC 4015, identified this section of the roadmap
as an appropriate location.
RFC 4138 E: "Forward RTO-Recovery (F-RTO): An Algorithm for Detecting
Spurious Retransmission Timeouts with TCP and the Stream Control
Transmission Protocol" (August 2005)
The F-RTO detection algorithm [RFC4138] provides another option
for inferring spurious retransmission timeouts. Unlike some
similar detection methods, F-RTO does not rely on the use of any
TCP options.
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5. Historic Extensions
The RFCs listed here define extensions that have thus far failed to
arouse substantial interest from implementers, or that were found to
be defective for general use.
RFC 1106 "TCP Big Window and NAK Options" (June 1989): found
defective
This RFC [RFC1106] defined an alternative to the Window Scale
option for using large windows and described the "negative
acknowledgement" or NAK option. There is a comparison of NAK and
SACK methods, and early discussion of TCP over satellite issues.
RFC 1110 explains some problems with the approaches described in
RFC 1106. The options described in this document have not been
adopted by the larger community, although NAKs are used in the
SCPS-TP adaptation of TCP for satellite and spacecraft use,
developed by the Consultative Committee for Space Data Systems
(CCSDS).
RFC 1110 "A Problem with the TCP Big Window Option" (August 1989):
deprecates RFC 1106
Abstract: "The TCP Big Window option discussed in RFC 1106 will
not work properly in an Internet environment which has both a high
bandwidth * delay product and the possibility of disordering and
duplicating packets. In such networks, the window size must not
be increased without a similar increase in the sequence number
space. Therefore, a different approach to big windows should be
taken in the Internet." [RFC1110]
RFC 1146 E "TCP Alternate Checksum Options" (March 1990): lack of
interest
This document [RFC1146] defined more robust TCP checksums than the
16-bit ones-complement in use today. A typographical error in RFC
1145 is fixed in RFC 1146; otherwise, the documents are the same.
RFC 1263 "TCP Extensions Considered Harmful" (October 1991) - lack of
interest
This document [RFC1263] argues against "backwards compatible" TCP
extensions. Specifically mentioned are several TCP enhancements
that have been successful, including timestamps, window scaling,
PAWS, and SACK. RFC 1263 presents an alternative approach called
"protocol evolution", whereby several evolutionary versions of TCP
would exist on hosts. These distinct TCP versions would represent
upgrades to each other and could be header-incompatible.
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Interoperability would be provided by having a virtualization
layer select the right TCP version for a particular connection.
This idea did not catch on with the community, although the type
of extensions RFC 1263 specifically targeted as harmful did become
popular.
RFC 1379 I "Extending TCP for Transactions -- Concepts" (November
1992): found defective
See RFC 1644.
RFC 1644 E "T/TCP -- TCP Extensions for Transactions Functional
Specification" (July 1994): found defective
The inventors of TCP believed that cached connection state could
have been used to eliminate TCP's 3-way handshake, to support
two-packet request/response exchanges. RFCs 1379 [RFC1379] and
1644 [RFC1644] show that this is far from simple. Furthermore,
T/TCP floundered on the ease of denial-of-service attacks that can
result. One idea pioneered by T/TCP lives on in RFC 2140, in the
sharing of state across connections.
RFC 1693 E "An Extension to TCP: Partial Order Service" (November
1994): lack of interest
This document [RFC1693] defines a TCP extension for applications
that do not care about the order in which application-layer
objects are received. Examples are multimedia and database
applications. In practice, these applications either accept the
possible performance loss because of TCP's strict ordering or use
more specialized transport protocols.
6. Support Documents
This section contains several classes of documents that do not
necessarily define current protocol behaviors, but that are
nevertheless of interest to TCP implementers. Section 6.1 describes
several foundational RFCs that give modern readers a better
understanding of the principles underlying TCP's behaviors and
development over the years. The documents listed in Section 6.2
provide advice on using TCP in various types of network situations
that pose challenges above those of typical wired links. Some
implementation notes can be found in Section 6.3. The TCP Management
Information Bases are described in Section 6.4. RFCs that describe
tools for testing and debugging TCP implementations or that contain
high-level tutorials on the protocol are listed Section 6.5, and
Section 6.6 lists a number of case studies that have explored TCP
performance.
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6.1. Foundational Works
The documents listed in this section contain information that is
largely duplicated by the standards documents previously discussed.
However, some of them contain a greater depth of problem statement
explanation or other context. Particularly, RFCs 813 - 817 (known as
the "Dave Clark Five") describe some early problems and solutions
(RFC 815 only describes the reassembly of IP fragments and is not
included in this TCP roadmap).
RFC 813: "Window and Acknowledgement Strategy in TCP" (July 1982)
This document [RFC0813] contains an early discussion of Silly
Window Syndrome and its avoidance and motivates and describes the
use of delayed acknowledgments.
RFC 814: "Name, Addresses, Ports, and Routes" (July 1982)
Suggestions and guidance for the design of tables and algorithms
to keep track of various identifiers within a TCP/IP
implementation are provided by this document [RFC0814].
RFC 816: "Fault Isolation and Recovery" (July 1982)
In this document [RFC0816], TCP's response to indications of
network error conditions such as timeouts or received ICMP
messages is discussed.
RFC 817: "Modularity and Efficiency in Protocol Implementation" (July
1982)
This document [RFC0817] contains implementation suggestions that
are general and not TCP specific. However, they have been used to
develop TCP implementations and to describe some performance
implications of the interactions between various layers in the
Internet stack.
RFC 872: "TCP-ON-A-LAN" (September 1982)
Conclusion: "The sometimes-expressed fear that using TCP on a
local net is a bad idea is unfounded." [RFC0872]
RFC 896: "Congestion Control in IP/TCP Internetworks" (January 1984)
This document [RFC0896] contains some early experiences with
congestion collapse and some initial thoughts on how to avoid it
using congestion control in TCP.
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RFC 964: "Some Problems with the Specification of the Military
Standard Transmission Control Protocol" (November 1985)
This document [RFC0964] points out several specification bugs in
the US Military's MIL-STD-1778 document, which was intended as a
successor to RFC 793. This serves to remind us of the difficulty
in specification writing (even when we work from existing
documents!).
RFC 1072: "TCP Extensions for Long-Delay Paths" (October 1988)
This document [RFC1072] contains early explanations of the
mechanisms that were later described by RFCs 1323 and 2018, which
obsolete it.
RFC 1185: "TCP Extension for High-Speed Paths" (October 1990)
This document [RFC1185] builds on RFC 1072 to describe more
advanced strategies for dealing with sequence number wrapping and
detecting duplicates from earlier connections. This document was
obsoleted by RFC 1323.
RFC 2914 B: "Congestion Control Principles" (September 2000)
This document [RFC2914] motivates the use of end-to-end congestion
control for preventing congestion collapse and providing fairness
to TCP.
6.2. Difficult Network Environments
As the internetworking field has explored wireless, satellite,
cellular telephone, and other kinds of link-layer technologies, a
large body of work has built up on enhancing TCP performance for such
links. The RFCs listed in this section describe some of these more
challenging network environments and how TCP interacts with them.
RFC 2488 B: "Enhancing TCP Over Satellite Channels using Standard
Mechanisms" (January 1999)
From abstract: "While TCP works over satellite channels there are
several IETF standardized mechanisms that enable TCP to more
effectively utilize the available capacity of the network path.
This document outlines some of these TCP mitigations. At this
time, all mitigations discussed in this document are IETF
standards track mechanisms (or are compliant with IETF
standards)." [RFC2488]
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RFC 2757 I: "Long Thin Networks" (January 2000)
Several methods of improving TCP performance over long thin
networks, such as geosynchronous satellite links, are discussed in
this document [RFC2757]. A particular set of TCP options is
developed that should work well in such environments and be safe
to use in the global Internet. The implications of such
environments have been further discussed in RFC 3150 and RFC 3155,
and these documents should be preferred where there is overlap
between them and RFC 2757.
RFC 2760 I: "Ongoing TCP Research Related to Satellites" (February
2000)
This document [RFC2760] discusses the advantages and disadvantages
of several different experimental means of improving TCP
performance over long-delay or error-prone paths. These include
T/TCP, larger initial windows, byte counting, delayed
acknowledgments, slow start thresholds, NewReno and SACK-based
loss recovery, FACK [MM96], ECN, various corruption-detection
mechanisms, congestion avoidance changes for fairness, use of
multiple parallel flows, pacing, header compression, state
sharing, and ACK congestion control, filtering, and
reconstruction. Although RFC 2488 looks at standard extensions,
this document focuses on more experimental means of performance
enhancement.
RFC 3135 I: "Performance Enhancing Proxies Intended to Mitigate
Link-Related Degradations" (June 2001)
From abstract: "This document is a survey of Performance Enhancing
Proxies (PEPs) often employed to improve degraded TCP performance
caused by characteristics of specific link environments, for
example, in satellite, wireless WAN, and wireless LAN
environments. Different types of Performance Enhancing Proxies
are described as well as the mechanisms used to improve
performance." [RFC3135]
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RFC 3150 B: "End-to-end Performance Implications of Slow Links" (July
2001)
From abstract: "This document makes performance-related
recommendations for users of network paths that traverse "very low
bit-rate" links....This recommendation may be useful in any
network where hosts can saturate available bandwidth, but the
design space for this recommendation explicitly includes
connections that traverse 56 Kb/second modem links or 4.8 Kb/
second wireless access links - both of which are widely deployed."
[RFC3150]
RFC 3155 B: "End-to-end Performance Implications of Links with
Errors" (August 2001)
From abstract: "This document discusses the specific TCP
mechanisms that are problematic in environments with high
uncorrected error rates, and discusses what can be done to
mitigate the problems without introducing intermediate devices
into the connection." [RFC3155]
RFC 3366 "Advice to link designers on link Automatic Repeat reQuest
(ARQ)" (August 2002)
From abstract: "This document provides advice to the designers of
digital communication equipment and link-layer protocols employing
link-layer Automatic Repeat reQuest (ARQ) techniques. This
document presumes that the designers wish to support Internet
protocols, but may be unfamiliar with the architecture of the
Internet and with the implications of their design choices for the
performance and efficiency of Internet traffic carried over their
links." [RFC3366]
RFC 3449 B: "TCP Performance Implications of Network Path Asymmetry"
(December 2002)
From abstract: "This document describes TCP performance problems
that arise because of asymmetric effects. These problems arise in
several access networks, including bandwidth-asymmetric networks
and packet radio subnetworks, for different underlying reasons.
However, the end result on TCP performance is the same in both
cases: performance often degrades significantly because of
imperfection and variability in the ACK feedback from the receiver
to the sender.
The document details several mitigations to these effects, which
have either been proposed or evaluated in the literature, or are
currently deployed in networks." [RFC3449]
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RFC 3481 B: "TCP over Second (2.5G) and Third (3G) Generation
Wireless Networks" (February 2003)
From abstract: "This document describes a profile for optimizing
TCP to adapt so that it handles paths including second (2.5G) and
third (3G) generation wireless networks." [RFC3481]
RFC 3819 B: "Advice for Internet Subnetwork Designers" (July 2004)
This document [RFC3819] describes how TCP performance can be
negatively affected by some particular lower-layer behaviors and
provides guidance in designing lower-layer networks and protocols
to be amicable to TCP.
6.3. Implementation Advice
RFC 879: "The TCP Maximum Segment Size and Related Topics" (November
1983)
Abstract: "This memo discusses the TCP Maximum Segment Size Option
and related topics. The purposes is to clarify some aspects of
TCP and its interaction with IP. This memo is a clarification to
the TCP specification, and contains information that may be
considered as 'advice to implementers'." [RFC0879]
RFC 1071: "Computing the Internet Checksum" (September 1988)
This document [RFC1071] lists a number of implementation
techniques for efficiently computing the Internet checksum (used
by TCP).
RFC 1624 I: "Computation of the Internet Checksum via Incremental
Update" (May 1994)
Incrementally updating the Internet checksum is useful to routers
in updating IP checksums. Some middleboxes that alter TCP headers
may also be able to update the TCP checksum incrementally. This
document [RFC1624] expands upon the explanation of the incremental
update procedure in RFC 1071.
RFC 1936 I: "Implementing the Internet Checksum in Hardware" (April
1996)
This document [RFC1936] describes the motivation for implementing
the Internet checksum in hardware, rather than in software, and
provides an implementation example.
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RFC 2525 I: "Known TCP Implementation Problems" (March 1999)
From abstract: "This memo catalogs a number of known TCP
implementation problems. The goal in doing so is to improve
conditions in the existing Internet by enhancing the quality of
current TCP/IP implementations." [RFC2525]
RFC 2923 I: "TCP Problems with Path MTU Discovery" (September 2000)
From abstract: "This memo catalogs several known Transmission
Control Protocol (TCP) implementation problems dealing with Path
Maximum Transmission Unit Discovery (PMTUD), including the long-
standing black hole problem, stretch acknowlegements (ACKs) due to
confusion between Maximum Segment Size (MSS) and segment size, and
MSS advertisement based on PMTU." [RFC2923]
RFC 3360 B: "Inappropriate TCP Resets Considered Harmful" (August
2002)
This document [RFC3360] is a plea that firewall vendors not send
gratuitous TCP RST (Reset) packets when unassigned TCP header bits
are used. This practice prevents desirable extension and
evolution of the protocol and thus is potentially harmful to the
future of the Internet.
RFC 3493 I: "Basic Socket Interface Extensions for IPv6" (February
2003)
This document [RFC3493] describes the de facto standard sockets
API for programming with TCP. This API is implemented nearly
ubiquitously in modern operating systems and programming
languages.
6.4. Management Information Bases
The first MIB module defined for use with Simple Network Management
Protocol (SNMP) (in RFC 1066 and its update, RFC 1156) was a single
monolithic MIB module, called MIB-I. This evolved over time to be
MIB-II (RFC 1213). It then became apparent that having a single
monolithic MIB module was not scalable, given the number and breadth
of MIB data definitions that needed to be included. Thus, additional
MIB modules were defined, and those parts of MIB-II that needed to
evolve were split off. Eventually, the remaining parts of MIB-II
were also split off, the TCP-specific part being documented in RFC
2012.
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RFC 2012 was obsoleted by RFC 4022, which is the primary TCP MIB
document today. MIB-I, defined in RFC 1156, has been obsoleted by
the MIB-II specification in RFC 1213. For current TCP implementers,
RFC 4022 should be supported.
RFC 1066: "Management Information Base for Network Management of
TCP/IP-based Internets" (August 1988)
This document [RFC1066] was the description of the TCP MIB. It
was obsoleted by RFC 1156.
RFC 1156 S: "Management Information Base for Network Management of
TCP/IP-based Internets" (May 1990)
This document [RFC1156] describes the required MIB fields for TCP
implementations, with minor corrections and no technical changes
from RFC 1066, which it obsoletes. This is the standards track
document for MIB-I.
RFC 1213 S: "Management Information Base for Network Management of
TCP/IP-based Internets: MIB-II" (March 1991)
This document [RFC1213] describes the second version of the MIB in
a monolithic form. RFC 2012 updates this document by splitting
out the TCP-specific portions.
RFC 2012 S: "SNMPv2 Management Information Base for the Transmission
Control Protocol using SMIv2" (November 1996)
This document [RFC2012] defined the TCP MIB, in an update to RFC
1213. It is now obsoleted by RFC 4022.
RFC 2452 S: "IP Version 6 Management Information Base for the
Transmission Control Protocol" (December 1998)
This document [RFC2452] augments RFC 2012 by adding an IPv6-
specific connection table. The rest of 2012 holds for any IP
version. RFC 2012 is now obsoleted by RFC 4022.
Although it is a standards track document, RFC 2452 is considered
a historic mistake by the MIB community, as it is based on the
idea of parallel IPv4 and IPv6 structures. Although IPv6 requires
new structures, the community has decided to define a single
generic structure for both IPv4 and IPv6. This will aid in
definition, implementation, and transition between IPv4 and IPv6.
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RFC 4022 S: "Management Information Base for the Transmission Control
Protocol (TCP)" (March 2005)
This document [RFC4022] obsoletes RFC 2012 and RFC 2452 and
specifies the current standard for the TCP MIB that should be
deployed.
6.5. Tools and Tutorials
RFC 1180 I: "TCP/IP Tutorial" (January 1991)
This document [RFC1180] is an extremely brief overview of the
TCP/IP protocol suite as a whole. It gives some explanation as to
how and where TCP fits in.
RFC 1470 I: "FYI on a Network Management Tool Catalog: Tools for
Monitoring and Debugging TCP/IP Internets and Interconnected Devices"
(June 1993)
A few of the tools that this document [RFC1470] describes are
still maintained and in use today; for example, ttcp and tcpdump.
However, many of the tools described do not relate specifically to
TCP and are no longer used or easily available.
RFC 2398 I: "Some Testing Tools for TCP Implementors" (August 1998)
This document [RFC2398] describes a number of TCP packet
generation and analysis tools. Although some of these tools are
no longer readily available or widely used, for the most part they
are still relevant and usable.
6.6. Case Studies
RFC 1337 I: "TIME-WAIT Assassination Hazards in TCP" (May 1992)
This document [RFC1337] points out a problem with acting on
received reset segments while one is in the TIME-WAIT state. The
main recommendation is that hosts in TIME-WAIT ignore resets.
This recommendation might not currently be widely implemented.
RFC 2415 I: "Simulation Studies of Increased Initial TCP Window Size"
(September 1998)
This document [RFC2415] presents results of some simulations using
TCP initial windows greater than 1 segment. The analysis
indicates that user-perceived performance can be improved by
increasing the initial window to 3 segments.
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RFC 2416 I: "When TCP Starts Up With Four Packets Into Only Three
Buffers" (September 1998)
This document [RFC2416] uses simulation results to clear up some
concerns about using an initial window of 4 segments when the
network path has less provisioning.
RFC 2884 I: "Performance Evaluation of Explicit Congestion
Notification (ECN) in IP Networks" (July 2000)
This document [RFC2884] describes experimental results that show
some improvements to the performance of both short- and long-lived
connections due to ECN.
7. Undocumented TCP Features
There are a few important implementation tactics for the TCP that
have not yet been described in any RFC. Although this roadmap is
primarily concerned with mapping the TCP RFCs, this section is
included because an implementer needs to be aware of these important
issues.
SYN Cookies
A mechanism known as "SYN cookies" is widely used to thwart TCP
SYN flooding attacks, in which an attacker sends a flood of SYNs
to a victim but fails to complete the 3-way handshake. The result
is exhaustion of resources at the server. The SYN cookie
mechanism allows the server to return a cleverly chosen initial
sequence number that has all the required state for the secure
completion of the handshake. Then the server can avoid saving
connection state during the 3-way handshake and thus survive a SYN
flooding attack.
A web search for "SYN cookies" will reveal a number of useful
descriptions of this mechanism, although there is currently no RFC
on the matter.
Header Prediction
Header prediction is a trick to speed up the processing of
segments. Van Jacobson and Mike Karels developed the technique in
the late 1980s. The basic idea is that some processing time can
be saved when most of a segment's fields can be predicted from
previous segments. A good description of this was sent to the
TCP-IP mailing list by Van Jacobson on March 9, 1988:
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Quite a bit of the speedup comes from an algorithm that we
('we' refers to collaborator Mike Karels and myself) are
calling "header prediction". The idea is that if you're in the
middle of a bulk data transfer and have just seen a packet, you
know what the next packet is going to look like: It will look
just like the current packet with either the sequence number or
ack number updated (depending on whether you're the sender or
receiver). Combining this with the "Use hints" epigram from
Butler Lampson's classic "Epigrams for System Designers", you
start to think of the tcp state (rcv.nxt, snd.una, etc.) as
"hints" about what the next packet should look like.
If you arrange those "hints" so they match the layout of a tcp
packet header, it takes a single 14-byte compare to see if your
prediction is correct (3 longword compares to pick up the send
& ack sequence numbers, header length, flags and window, plus a
short compare on the length). If the prediction is correct,
there's a single test on the length to see if you're the sender
or receiver followed by the appropriate processing. E.g., if
the length is non-zero (you're the receiver), checksum and
append the data to the socket buffer then wake any process
that's sleeping on the buffer. Update rcv.nxt by the length of
this packet (this updates your "prediction" of the next
packet). Check if you can handle another packet the same size
as the current one. If not, set one of the unused flag bits in
your header prediction to guarantee that the prediction will
fail on the next packet and force you to go through full
protocol processing. Otherwise, you're done with this packet.
So, the *total* tcp protocol processing, exclusive of
checksumming, is on the order of 6 compares and an add.
8. Security Considerations
This document introduces no new security considerations. Each RFC
listed in this document attempts to address the security
considerations of the specification it contains.
9. Acknowledgments
This document grew out of a discussion on the end2end-interest
mailing list, the public list of the End-to-End Research Group of the
IRTF, and continued development under the IETF's TCP Maintenance and
Minor Extensions (TCPM) working group. We thank Joe Touch, Reiner
Ludwig, Pekka Savola, Gorry Fairhurst, and Sally Floyd for their
contributions, in particular. The chairs of the TCPM working group,
Mark Allman and Ted Faber, have been instrumental in the development
of this document. Keith McCloghrie provided some useful notes and
clarification on the various MIB-related RFCs.
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10. Informative References
10.1. Basic Functionality
[RFC0793] Postel, J., "Transmission Control Protocol", STD 7, RFC
793, September 1981.
[RFC1122] Braden, R., "Requirements for Internet Hosts -
Communication Layers", STD 3, RFC 1122, October 1989.
[RFC2026] Bradner, S., "The Internet Standards Process -- Revision
3", BCP 9, RFC 2026, October 1996.
[RFC2460] Deering, S. and R. Hinden, "Internet Protocol, Version 6
(IPv6) Specification", RFC 2460, December 1998.
[RFC2474] Nichols, K., Blake, S., Baker, F., and D. Black,
"Definition of the Differentiated Services Field (DS
Field) in the IPv4 and IPv6 Headers", RFC 2474, December
1998.
[RFC2581] Allman, M., Paxson, V., and W. Stevens, "TCP Congestion
Control", RFC 2581, April 1999.
[RFC2675] Borman, D., Deering, S., and R. Hinden, "IPv6 Jumbograms",
RFC 2675, August 1999.
[RFC2873] Xiao, X., Hannan, A., Paxson, V., and E. Crabbe, "TCP
Processing of the IPv4 Precedence Field", RFC 2873, June
2000.
[RFC2988] Paxson, V. and M. Allman, "Computing TCP's Retransmission
Timer", RFC 2988, November 2000.
10.2. Recommended Enhancements
[RFC1323] Jacobson, V., Braden, R., and D. Borman, "TCP Extensions
for High Performance", RFC 1323, May 1992.
[RFC1948] Bellovin, S., "Defending Against Sequence Number Attacks",
RFC 1948, May 1996.
[RFC2018] Mathis, M., Mahdavi, J., Floyd, S., and A. Romanow, "TCP
Selective Acknowledgment Options", RFC 2018, October 1996.
[RFC2385] Heffernan, A., "Protection of BGP Sessions via the TCP MD5
Signature Option", RFC 2385, August 1998.
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[RFC2883] Floyd, S., Mahdavi, J., Mathis, M., and M. Podolsky, "An
Extension to the Selective Acknowledgement (SACK) Option
for TCP", RFC 2883, July 2000.
[RFC3042] Allman, M., Balakrishnan, H., and S. Floyd, "Enhancing
TCP's Loss Recovery Using Limited Transmit", RFC 3042,
January 2001.
[RFC3168] Ramakrishnan, K., Floyd, S., and D. Black, "The Addition
of Explicit Congestion Notification (ECN) to IP", RFC
3168, September 2001.
[RFC3390] Allman, M., Floyd, S., and C. Partridge, "Increasing TCP's
Initial Window", RFC 3390, October 2002.
[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.
[RFC3562] Leech, M., "Key Management Considerations for the TCP MD5
Signature Option", RFC 3562, July 2003.
[RFC3782] Floyd, S., Henderson, T., and A. Gurtov, "The NewReno
Modification to TCP's Fast Recovery Algorithm", RFC 3782,
April 2004.
[RFC4015] Ludwig, R. and A. Gurtov, "The Eifel Response Algorithm
for TCP", RFC 4015, February 2005.
[RFC4278] Bellovin, S. and A. Zinin, "Standards Maturity Variance
Regarding the TCP MD5 Signature Option (RFC 2385) and the
BGP-4 Specification", RFC 4278, January 2006.
10.3. Experimental Extensions
[RFC2140] Touch, J., "TCP Control Block Interdependence", RFC 2140,
April 1997.
[RFC2861] Handley, M., Padhye, J., and S. Floyd, "TCP Congestion
Window Validation", RFC 2861, June 2000.
[RFC3124] Balakrishnan, H. and S. Seshan, "The Congestion Manager",
RFC 3124, June 2001.
[RFC3465] Allman, M., "TCP Congestion Control with Appropriate Byte
Counting (ABC)", RFC 3465, February 2003.
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[RFC3522] Ludwig, R. and M. Meyer, "The Eifel Detection Algorithm
for TCP", RFC 3522, April 2003.
[RFC3540] Spring, N., Wetherall, D., and D. Ely, "Robust Explicit
Congestion Notification (ECN) Signaling with Nonces", RFC
3540, June 2003.
[RFC3649] Floyd, S., "HighSpeed TCP for Large Congestion Windows",
RFC 3649, December 2003.
[RFC3708] Blanton, E. and M. Allman, "Using TCP Duplicate Selective
Acknowledgement (DSACKs) and Stream Control Transmission
Protocol (SCTP) Duplicate Transmission Sequence Numbers
(TSNs) to Detect Spurious Retransmissions", RFC 3708,
February 2004.
[RFC3742] Floyd, S., "Limited Slow-Start for TCP with Large
Congestion Windows", RFC 3742, March 2004.
[RFC4138] Sarolahti, P. and M. Kojo, "Forward RTO-Recovery (F-RTO):
An Algorithm for Detecting Spurious Retransmission
Timeouts with TCP and the Stream Control Transmission
Protocol (SCTP)", RFC 4138, August 2005.
10.4. Historic Extensions
[RFC1106] Fox, R., "TCP big window and NAK options", RFC 1106, June
1989.
[RFC1110] McKenzie, A., "Problem with the TCP big window option",
RFC 1110, August 1989.
[RFC1146] Zweig, J. and C. Partridge, "TCP alternate checksum
options", RFC 1146, March 1990.
[RFC1263] O'Malley, S. and L. Peterson, "TCP Extensions Considered
Harmful", RFC 1263, October 1991.
[RFC1379] Braden, R., "Extending TCP for Transactions -- Concepts",
RFC 1379, November 1992.
[RFC1644] Braden, R., "T/TCP -- TCP Extensions for Transactions
Functional Specification", RFC 1644, July 1994.
[RFC1693] Connolly, T., Amer, P., and P. Conrad, "An Extension to
TCP : Partial Order Service", RFC 1693, November 1994.
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10.5. Support Documents
[RFC0813] Clark, D., "Window and Acknowledgement Strategy in TCP",
RFC 813, July 1982.
[RFC0814] Clark, D., "Name, addresses, ports, and routes", RFC 814,
July 1982.
[RFC0816] Clark, D., "Fault isolation and recovery", RFC 816, July
1982.
[RFC0817] Clark, D., "Modularity and efficiency in protocol
implementation", RFC 817, July 1982.
[RFC0872] Padlipsky, M., "TCP-on-a-LAN", RFC 872, September 1982.
[RFC0879] Postel, J., "TCP maximum segment size and related topics",
RFC 879, November 1983.
[RFC0896] Nagle, J., "Congestion control in IP/TCP internetworks",
RFC 896, January 1984.
[RFC0964] Sidhu, D. and T. Blumer, "Some problems with the
specification of the Military Standard Transmission
Control Protocol", RFC 964, November 1985.
[RFC1066] McCloghrie, K. and M. Rose, "Management Information Base
for Network Management of TCP/IP-based internets", RFC
1066, August 1988.
[RFC1071] Braden, R., Borman, D., and C. Partridge, "Computing the
Internet checksum", RFC 1071, September 1988.
[RFC1072] Jacobson, V. and R. Braden, "TCP extensions for long-delay
paths", RFC 1072, October 1988.
[RFC1156] McCloghrie, K. and M. Rose, "Management Information Base
for network management of TCP/IP-based internets", RFC
1156, May 1990.
[RFC1180] Socolofsky, T. and C. Kale, "TCP/IP tutorial", RFC 1180,
January 1991.
[RFC1185] Jacobson, V., Braden, B., and L. Zhang, "TCP Extension for
High-Speed Paths", RFC 1185, October 1990.
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[RFC1213] McCloghrie, K. and M. Rose, "Management Information Base
for Network Management of TCP/IP-based internets: MIB-II",
STD 17, RFC 1213, March 1991.
[RFC1337] Braden, R., "TIME-WAIT Assassination Hazards in TCP", RFC
1337, May 1992.
[RFC1470] Enger, R. and J. Reynolds, "FYI on a Network Management
Tool Catalog: Tools for Monitoring and Debugging TCP/IP
Internets and Interconnected Devices", FYI 2, RFC 1470,
June 1993.
[RFC1624] Rijsinghani, A., "Computation of the Internet Checksum via
Incremental Update", RFC 1624, May 1994.
[RFC1936] Touch, J. and B. Parham, "Implementing the Internet
Checksum in Hardware", RFC 1936, April 1996.
[RFC2012] McCloghrie, K., "SNMPv2 Management Information Base for
the Transmission Control Protocol using SMIv2", RFC 2012,
November 1996.
[RFC2398] Parker, S. and C. Schmechel, "Some Testing Tools for TCP
Implementors", RFC 2398, August 1998.
[RFC2415] Poduri, K. and K. Nichols, "Simulation Studies of
Increased Initial TCP Window Size", RFC 2415, September
1998.
[RFC2416] Shepard, T. and C. Partridge, "When TCP Starts Up With
Four Packets Into Only Three Buffers", RFC 2416, September
1998.
[RFC2452] Daniele, M., "IP Version 6 Management Information Base for
the Transmission Control Protocol", RFC 2452, December
1998.
[RFC2488] Allman, M., Glover, D., and L. Sanchez, "Enhancing TCP
Over Satellite Channels using Standard Mechanisms", BCP
28, RFC 2488, January 1999.
[RFC2525] Paxson, V., Allman, M., Dawson, S., Fenner, W., Griner,
J., Heavens, I., Lahey, K., Semke, J., and B. Volz, "Known
TCP Implementation Problems", RFC 2525, March 1999.
[RFC2757] Montenegro, G., Dawkins, S., Kojo, M., Magret, V., and N.
Vaidya, "Long Thin Networks", RFC 2757, January 2000.
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[RFC2760] Allman, M., Dawkins, S., Glover, D., Griner, J., Tran, D.,
Henderson, T., Heidemann, J., Touch, J., Kruse, H.,
Ostermann, S., Scott, K., and J. Semke, "Ongoing TCP
Research Related to Satellites", RFC 2760, February 2000.
[RFC2884] Hadi Salim, J. and U. Ahmed, "Performance Evaluation of
Explicit Congestion Notification (ECN) in IP Networks",
RFC 2884, July 2000.
[RFC2914] Floyd, S., "Congestion Control Principles", BCP 41, RFC
2914, September 2000.
[RFC2923] Lahey, K., "TCP Problems with Path MTU Discovery", RFC
2923, September 2000.
[RFC3135] Border, J., Kojo, M., Griner, J., Montenegro, G., and Z.
Shelby, "Performance Enhancing Proxies Intended to
Mitigate Link-Related Degradations", RFC 3135, June 2001.
[RFC3150] Dawkins, S., Montenegro, G., Kojo, M., and V. Magret,
"End-to-end Performance Implications of Slow Links", BCP
48, RFC 3150, July 2001.
[RFC3155] Dawkins, S., Montenegro, G., Kojo, M., Magret, V., and N.
Vaidya, "End-to-end Performance Implications of Links with
Errors", BCP 50, RFC 3155, August 2001.
[RFC3360] Floyd, S., "Inappropriate TCP Resets Considered Harmful",
BCP 60, RFC 3360, August 2002.
[RFC3366] Fairhurst, G. and L. Wood, "Advice to link designers on
link Automatic Repeat reQuest (ARQ)", BCP 62, RFC 3366,
August 2002.
[RFC3449] Balakrishnan, H., Padmanabhan, V., Fairhurst, G., and M.
Sooriyabandara, "TCP Performance Implications of Network
Path Asymmetry", BCP 69, RFC 3449, December 2002.
[RFC3481] Inamura, H., Montenegro, G., Ludwig, R., Gurtov, A., and
F. Khafizov, "TCP over Second (2.5G) and Third (3G)
Generation Wireless Networks", BCP 71, RFC 3481, February
2003.
[RFC3493] Gilligan, R., Thomson, S., Bound, J., McCann, J., and W.
Stevens, "Basic Socket Interface Extensions for IPv6", RFC
3493, February 2003.
Duke, et al. Informational [Page 30]
RFC 4614 TCP Roadmap September 2006
[RFC3819] Karn, P., Bormann, C., Fairhurst, G., Grossman, D.,
Ludwig, R., Mahdavi, J., Montenegro, G., Touch, J., and L.
Wood, "Advice for Internet Subnetwork Designers", BCP 89,
RFC 3819, July 2004.
[RFC4022] Raghunarayan, R., "Management Information Base for the
Transmission Control Protocol (TCP)", RFC 4022, March
2005.
10.6. Informative References Outside the RFC Series
[JK92] Jacobson, V. and M. Karels, "Congestion Avoidance and
Control", This paper is a revised version of [Jac88], that
includes an additional appendix. This paper has not been
traditionally published, but is currently available at
ftp://ftp.ee.lbl.gov/papers/congavoid.ps.Z. 1992.
[Jac88] Jacobson, V., "Congestion Avoidance and Control", ACM
SIGCOMM 1988 Proceedings, in ACM Computer Communication
Review, 18 (4), pp. 314-329, August 1988.
[KP87] Karn, P. and C. Partridge, "Round Trip Time Estimation",
ACM SIGCOMM 1987 Proceedings, in ACM Computer
Communication Review, 17 (5), pp. 2-7, August 1987
[MAF04] Medina, A., Allman, M., and S. Floyd, "Measuring the
Evolution of Transport Protocols in the Internet", ACM
Computer Communication Review, 35 (2), April 2005.
[MM96] Mathis, M. and J. Mahdavi, "Forward Acknowledgement:
Refining TCP Congestion Control", ACM SIGCOMM 1996
Proceedings, in ACM Computer Communication Review 26 (4),
pp. 281-292, October 1996.
[SCWA99] Savage, S., Cardwell, N., Wetherall, D., and T. Anderson,
"TCP Congestion Control with a Misbehaving Receiver", ACM
Computer Communication Review, 29 (5), pp. 71-78, October
1999.
Duke, et al. Informational [Page 31]
RFC 4614 TCP Roadmap September 2006
Authors' Addresses
Martin H. Duke
The Boeing Company
PO Box 3707, MC 7L-49
Seattle, WA 98124-2207
Phone: 425-373-2852
EMail: martin.duke@boeing.com
Robert Braden
USC Information Sciences Institute
Marina del Rey, CA 90292-6695
Phone: 310-448-9173
EMail: braden@isi.edu
Wesley M. Eddy
Verizon Federal Network Systems
21000 Brookpark Rd, MS 54-5
Cleveland, OH 44135
Phone: 216-433-6682
EMail: weddy@grc.nasa.gov
Ethan Blanton
Purdue University Computer Science
250 N. University St.
West Lafayette, IN 47907
EMail: eblanton@cs.purdue.edu
Duke, et al. Informational [Page 32]
RFC 4614 TCP Roadmap September 2006
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Duke, et al. Informational [Page 33]
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