From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc4774.txt | 843 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 843 insertions(+) create mode 100644 doc/rfc/rfc4774.txt (limited to 'doc/rfc/rfc4774.txt') diff --git a/doc/rfc/rfc4774.txt b/doc/rfc/rfc4774.txt new file mode 100644 index 0000000..86d3b93 --- /dev/null +++ b/doc/rfc/rfc4774.txt @@ -0,0 +1,843 @@ + + + + + + +Network Working Group S. Floyd +Request for Comments: 4774 ICIR +BCP: 124 November 2006 +Category: Best Current Practice + + + Specifying Alternate Semantics for + the Explicit Congestion Notification (ECN) Field + +Status of This Memo + + This document specifies an Internet Best Current Practices for the + Internet Community, and requests discussion and suggestions for + improvements. Distribution of this memo is unlimited. + +Copyright Notice + + Copyright (C) The IETF Trust (2006). + +Abstract + + There have been a number of proposals for alternate semantics for the + Explicit Congestion Notification (ECN) field in the IP header RFC + 3168. This document discusses some of the issues in defining + alternate semantics for the ECN field, and specifies requirements for + a safe coexistence in an Internet that could include routers that do + not understand the defined alternate semantics. This document + evolved as a result of discussions with the authors of one recent + proposal for such alternate semantics. + + + + + + + + + + + + + + + + + + + + + + +Floyd Best Current Practice [Page 1] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + +Table of Contents + + 1. Introduction ....................................................2 + 2. An Overview of the Issues .......................................3 + 3. Signalling the Use of Alternate ECN Semantics ...................4 + 3.1. Using the Diffserv Field for Signalling ....................5 + 4. Issues of Incremental Deployment ................................6 + 4.1. Option 1: Unsafe for Deployment in the Internet ...........7 + 4.2. Option 2: Verification that Routers Understand the + Alternate ..................................................8 + 4.3. Option 3: Friendly Coexistence with Competing Traffic .....8 + 5. Evaluation of the Alternate ECN Semantics ......................10 + 5.1. Verification of Feedback from the Router ..................10 + 5.2. Coexistence with Competing Traffic ........................11 + 5.3. Proposals for Alternate ECN with Edge-to-Edge Semantics ...12 + 5.4. Encapsulated Packets ......................................12 + 5.5. A General Evaluation of the Alternate ECN Semantics .......12 + 6. Security Considerations ........................................12 + 7. Conclusions ....................................................13 + 8. Acknowledgements ...............................................13 + 9. Normative References ...........................................13 + 10. Informative References ........................................13 + +1. Introduction + + [RFC3168], a Proposed Standard document, defines the ECN field in the + IP header, and specifies the semantics for the codepoints for the ECN + field. However, end nodes could specify the use of alternate + semantics for the ECN field, e.g., using codepoints in the diffserv + field of the IP header. + + There have been a number of proposals in the IETF and in the research + community for alternate semantics for the ECN codepoint. One such + proposal, [BCF05], proposes alternate ECN semantics for real-time + inelastic traffic such as voice, video conferencing, and multimedia + streaming in DiffServ networks. In this proposal, the alternate ECN + semantics would provide information about two levels of congestion + experienced along the path [BCF05]. Another research proposal, + [XSSK05], proposes a low-complexity protocol, Variable-structure + congestion Control Protocol (VCP), that uses the two bits in the ECN + field to indicate low-load, high-load, and overload (congestion), + where transport protocols can increase more rapidly during the low- + load regime. Some of the proposals for alternate ECN semantics are + for when ECN is used in an edge-to-edge context between gateways at + the edge of a network region, e.g., for pre-congestion notification + for admissions control [BESFC06]. Other proposals for alternate ECN + semantics are listed on the ECN Web Page [ECN]. + + + + +Floyd Best Current Practice [Page 2] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + + The definition of multiple semantics for the ECN field could have + significant implications on both host and router implementations. + There is a huge base of installed hosts and routers in the Internet, + and in other IP networks, and updating these is an enormous and + potentially expensive undertaking. Some existing devices might be + able to support the new ECN semantics with only a software upgrade + and without significant degradation in performance. Some other + equipment might be able to support the new semantics, but with a + degradation in performance -- which could range from trivial to + catastrophic. Some other deployed equipment might be able to support + the new ECN semantics only with a hardware upgrade, which, in some + cases, could be prohibitively expensive to deploy on a very wide + scale. For these reasons, it would be difficult and would take a + significant amount of time to universally deploy any new ECN + semantics. In particular, routers can be difficult to upgrade, since + small routers sometimes are not updated frequently, and large routers + commonly have specialized forwarding paths to facilitate high + performance. + + This document describes some of the technical issues that arise in + specifying alternate semantics for the ECN field, and gives + requirements for a safe coexistence in a world using the default ECN + semantics (or using no ECN at all). + +2. An Overview of the Issues + + In this section, we discuss some of the issues that arise if some of + the traffic in a network consists of alternate-ECN traffic (i.e., + traffic using alternate semantics for the ECN field). The issues + include the following: (1) how routers know which ECN semantics to + use with which packets; (2) incremental deployment in a network where + some routers use only the default ECN semantics or do not use ECN at + all; (3) coexistence of alternate-ECN traffic with competing traffic + on the path; and (4) a general evaluation of the alternate ECN + semantics. + + (1) The first issue concerns how routers know which ECN semantics to + use with which packets in the network: + + How does the connection indicate to the router that its packets + are using alternate ECN semantics? Is the specification of + alternate-ECN semantics robust and unambiguous? If not, is this + a problem? + + As an example, in most of the proposals for alternate ECN + semantics, a diffserv field is used to specify the use of + alternate ECN semantics. Do all routers that understand this + diffserv codepoint understand that it uses alternate ECN + + + +Floyd Best Current Practice [Page 3] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + + semantics, or not? Diffserv allows routers to re-mark DiffServ + Code Point (DSCP) values within the network; what is the effect + of this on the alternate ECN semantics? + + This is discussed in more detail in Section 3 below. + + (2) A second issue is that of incremental deployment in a network + where some routers only use the default ECN semantics, and other + routers might not use ECN at all. In this document, we use the + phrase "new routers" to refer to the routers that understand the + alternate ECN semantics, and "old routers" to refer to routers + that don't understand or aren't willing to use the alternate ECN + semantics. + + The possible existence of old routers raises the following + question: How does the possible presence of old routers affect + the performance of the alternate-ECN connections? + + (3) The possible existence of old routers also raises the question of + how the presence of old routers affects the coexistence of the + alternate-ECN traffic with competing traffic on the path. + + Issues (2) and (3) are discussed in Section 4 below. + + (4) A final issue is that of the general evaluation of the alternate + ECN semantics: + + How well does the alternate-ECN traffic perform, and how well + does it coexist with competing traffic on the path, in a "clean" + environment with new routers and with the unambiguous + specification of the use of alternate ECN semantics? + + These issues are discussed in Section 5. + +3. Signalling the Use of Alternate ECN Semantics + + This section discusses question (1) from Section 2: + + (1) How does the connection indicate to the router that its packets + are using alternate ECN semantics? Is the specification of + alternate ECN semantics robust and unambiguous? If not, is this + a problem? + + The assumption of this document is that when alternate semantics are + defined for the ECN field, a codepoint in the diffserv field is used + to signal the use of these alternate ECN semantics to the router. + That is, the end host sets the codepoint in the diffserv field to + indicate to routers that alternate semantics to the ECN field are + + + +Floyd Best Current Practice [Page 4] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + + being used. Routers that understand this diffserv codepoint would + know to use the alternate semantics for interpreting and setting the + ECN field. Old ECN-capable routers that do not understand this + diffserv codepoint would use the default ECN semantics in + interpreting and setting the ECN field. + + In general, the diffserv codepoints are used to signal the per-hop + behavior at router queues. One possibility would be to use one + diffserv codepoint to signal a per-hop behavior with the default ECN + semantics, and a separate diffserv codepoint to signal a similar + per-hop behavior with the alternate ECN semantics. Another + possibility would be to use a diffserv codepoint to signal the use of + best-effort per-hop queueing and scheduling behavior, but with + alternate ECN semantics. A detailed discussion of these issues is + beyond the scope of this document. + + We note that this discussion does not exclude the possibility of + using other methods, including out-of-band mechanisms, for signalling + the use of alternate semantics for the ECN field. The considerations + in the rest of this document apply regardless of the method used to + signal the use of alternate semantics for the ECN field. + +3.1. Using the Diffserv Field for Signalling + + We note that the default ECN semantics defined in RFC 3168 are the + current default semantics for the ECN field, regardless of the + contents of any other fields in the IP header. In particular, the + default ECN semantics apply for more than best-effort traffic with a + codepoint of '000000' for the diffserv field - the default ECN + semantics currently apply regardless of the contents of the diffserv + field. + + There are two ways to use the diffserv field to signal the use of + alternate ECN semantics. One way is to use an existing diffserv + codepoint, and to modify the current definition of that codepoint, + through approved IETF processes, to specify the use of alternate ECN + semantics with that codepoint. A second way is to define a new + diffserv codepoint, and to specify the use of alternate ECN semantics + with that codepoint. We note that the first of these two mechanisms + raises the possibility that some routers along the path will + understand the diffserv codepoint but will use the default ECN + semantics with this diffserv codepoint, or won't use ECN at all, and + that other routers will use the alternate ECN semantics with this + diffserv codepoint. + + + + + + + +Floyd Best Current Practice [Page 5] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + +4. Issues of Incremental Deployment + + This section discusses questions (2) and (3) posed in Section 2: + + (2) How does the possible presence of old routers affect the + performance of the alternate-ECN connections? + + (3) How does the possible presence of old routers affect the + coexistence of the alternate-ECN traffic with competing traffic + on the path? + + When alternate semantics are defined for the ECN field, it is + necessary to ensure that there are no problems caused by old routers + along the path that don't understand the alternate ECN semantics. + + One possible problem is that of poor performance for the alternate- + ECN traffic. Is it essential to the performance of the alternate-ECN + traffic that all routers along the path understand the alternate ECN + semantics? If not, what are the possible consequences, for the + alternate-ECN traffic itself, when some old routers along the path + don't understand the alternate ECN semantics? These issues have to + be answered in the context of each specific proposal for alternate + ECN semantics. + + A second specific problem is that of possible unfair competition with + other traffic along the path. If there is an old router along the + path that doesn't use ECN, that old router could drop packets from + the alternate-ECN traffic, and expect the alternate-ECN traffic to + reduce its sending rate as a result. Does the alternate-ECN traffic + respond to packet drops as an indication of congestion? + + |--------| + Alternate-ECN traffic ----> | | ---> CE-marked packet + | Old | + Non-ECN traffic ----------> | Router | ---> dropped packet + | | + RFC-3168 ECN traffic -----> | | ---> CE-marked packet + |--------| + + Figure 1: Alternate-ECN traffic, an old router, using RFC-3168 ECN, + that is congested and ready to drop or mark the arriving packet. + + Similarly, what if there is an old router along the path that + understands only the default ECN semantics from RFC 3168, as in + Figure 1 above? In times of congestion, the old default-ECN router + could see an alternate-ECN packet with one of the ECN-Capable + Transport (ECT) codepoints set in the ECN field in the IP header, as + defined in RFC 3168, and set the Congestion Experienced (CE) + + + +Floyd Best Current Practice [Page 6] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + + codepoint in the ECN field as an alternative to dropping the packet. + The router in this case would expect the alternate-ECN connection to + respond, in terms of congestion control, as it would if the packet + has been dropped. If the alternate-ECN traffic fails to respond + appropriately to the CE codepoint being set by an old router, this + could increase the aggregate traffic arriving at the old router, + resulting in an increase in the packet-marking and packet-dropping + rates at that router, further resulting in the alternate-ECN traffic + crowding out the other traffic competing for bandwidth on that link. + + Basically, there are three possibilities for avoiding scenarios where + the presence of old routers along the path results in the alternate- + ECN traffic competing unfairly with other traffic along the path: + + Option 1: Alternate-ECN traffic is clearly understood as unsafe for + deployment in the global Internet; or + + Option 2: All alternate-ECN traffic deploys some mechanism for + verifying that all routers on the path understand and agree to use + the alternate ECN semantics for this traffic; or + + Option 3: The alternate ECN semantics are defined in such a way as + to ensure the fair and peaceful coexistence of the alternate-ECN + traffic with best-effort and other traffic, even in environments that + include old routers that do not understand the alternate ECN + semantics. + + Each of these alternatives is explored in more detail below. + +4.1. Option 1: Unsafe for Deployment in the Internet + + The first option specified above is for the alternate-ECN traffic to + be clearly understood as only suitable for enclosed environments, and + as unsafe for deployment in the global Internet. Specifically, this + would mean that it would be unsafe for packets using the alternate + ECN semantics to be unleashed in the global Internet. This + restriction would prevent the alternate-ECN traffic from traversing + an old router outside of the enclosed environment that didn't + understand the alternate semantics. This document doesn't comment on + whether a mechanism would be required to ensure that the alternate + ECN semantics would not be let loose on the global Internet. This + document also doesn't comment on the chances that this scenario would + be considered acceptable for standardization by the IETF community. + + + + + + + + +Floyd Best Current Practice [Page 7] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + +4.2. Option 2: Verification that Routers Understand the Alternate + Semantics + + The second option specified above is for the alternate-ECN traffic to + include a mechanism for ensuring that all routers along the path + understand and agree to the use of the alternate ECN semantics for + this traffic. As an example, such a mechanism could consist of a + field in an IP option that all routers along the path decrement if + they agree to use the alternate ECN semantics with this traffic. (A + similar mechanism is proposed for Quick-Start, for verifying that all + of the routers along the path understand the Quick-Start IP Option + [QuickStart].) Using such a mechanism, a sender could have + reasonable assurance that the packets that are sent specifying the + use of alternate ECN semantics only traverse routers that, in fact, + understand and agree to use these alternate semantics for these + packets. Note, however, that most existing routers are optimized for + IP packets with no options, or with only some very well-known and + simple IP options. Thus, the definition and use of any new IP option + may have a serious detrimental effect on the performance of many + existing IP routers. + + Such a mechanism should be robust in the presence of paths with + multi-path routing, and in the presence of routing or configuration + changes along the path while the connection is in use. In + particular, if this option is used, connections could include some + form of monitoring for changes in path behavior and/or periodic + monitoring that all routers along the path continue to understand the + alternate ECN semantics. + +4.3. Option 3: Friendly Coexistence with Competing Traffic + + The third option specified above is for the alternate ECN semantics + to be defined so that traffic using the alternate semantics would + coexist safely in the Internet on a path with one or more old routers + that use only the default ECN semantics. In this scenario, a + connection sending alternate-ECN traffic would have to respond + appropriately to a CE packet (a packet with the ECN codepoint "11") + received at the receiver, using a conformant congestion control + response. Hopefully, the connection sending alternate-ECN traffic + would also respond appropriately to a dropped packet, which could be + a congestion indication from a router that doesn't use ECN. + + RFC 3168 defines the default ECN semantics as follows: + + "Upon the receipt by an ECN-Capable transport of a single CE packet, + the congestion control algorithms followed at the end-systems MUST be + essentially the same as the congestion control response to a *single* + dropped packet. For example, for ECN-Capable TCP the source TCP is + + + +Floyd Best Current Practice [Page 8] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + + required to halve its congestion window for any window of data + containing either a packet drop or an ECN indication." + + The only conformant congestion control mechanisms currently + standardized in the IETF are TCP [RFC2581] and protocols using TCP- + like congestion control (e.g., SCTP [RFC2960], DCCP with CCID-2 + ([RFC4340], [RFC4341])), and TCP-Friendly Rate Control (TFRC) + [RFC3448], and protocols with TFRC-like congestion control (e.g., + DCCP using CCID-3 [RFC4342]). TCP uses Additive-Increase + Multiplicative-Decrease congestion control, and responds to the loss + or ECN-marking of a single packet by halving its congestion window. + In contrast, the equation-based congestion control mechanism in TFRC + estimates the loss event rate over some period of time, and uses a + sending rate that would be comparable, in packets per round-trip- + time, to that of a TCP connection experiencing the same loss event + rate. + + So what are the requirements for alternate-ECN traffic to compete + appropriately with other traffic on a path through an old router that + doesn't understand the alternate ECN semantics (and therefore might + be using the default ECN semantics)? The first and second + requirements below concern compatibility between traffic using + alternate ECN semantics and routers using default ECN semantics. + + The first requirement for compatibility with routers using default + ECN is that if a packet is marked with the ECN codepoint "11" in the + network, this marking is not changed on the packet's way to the + receiver (unless the packet is dropped before it reaches the + receiver). This requirement is necessary to ensure that congestion + indications from a default-ECN router make it to the transport + receiver. + + A second requirement for compatibility with routers using default ECN + is that the end-nodes respond to packets that are marked with the ECN + codepoint "11" in a way that is friendly to flows using IETF- + conformant congestion control. This requirement is needed because + the "11"-marked packets might have come from a congested router that + understands only the default ECN semantics, and that expects that + end-nodes will respond appropriately to CE packets. This requirement + would ensure that the traffic using the alternate semantics does not + `bully' competing traffic that it might encounter along the path, and + that it does not drive up congestion on the shared link + inappropriately. + + Additional requirements concern compatibility between traffic using + default ECN semantics and routers using alternate ECN semantics. + This situation could occur if a diffserv codepoint using default ECN + semantics is redefined to use alternate ECN semantics, and traffic + + + +Floyd Best Current Practice [Page 9] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + + from an "old" source traverses a "new" router. If the router "knows" + that a packet is from a sender using alternate semantics (e.g., + because the packet is using a certain diffserv codepoint, and all + packets with that diffserv codepoint use alternate semantics for the + ECN field), then the requirements below are not necessary, and the + rules for the alternate semantics apply. + + A requirement for compatibility with end-nodes using default ECN is + that if a packet that *could* be using default semantics is marked + with the ECN codepoint "00", this marking must not be changed to + "01", "10", or "11" in the network. This prevents the packet from + being represented incorrectly to a default-ECN router downstream as + ECN-Capable. Similarly, if a packet that *could* be using default + semantics is marked with the ECN codepoint "01", then this codepoint + should not be changed to "10" in the network (and a "10" codepoint + should not be changed to "01"). This requirement is necessary to + avoid interference with the transport protocol's use of the ECN nonce + [RFC3540]. + + As discussed earlier, the current conformant congestion control + responses to a dropped or default-ECN-marked packet consist of TCP + and TCP-like congestion control, and of TFRC (TCP-Friendly Rate + Control). Another possible response considered in RFC 3714, but not + standardized in a standards-track document, is that of simply + terminating an alternate-ECN connection for a period of time if the + long-term sending rate is higher than would be that of a TCP + connection experiencing the same packet dropping or marking rates + [RFC3714]. We note that the use of such a congestion control + response to CE-marked packets would require specification of time + constants for measuring the loss rates and for stopping transmission, + and would require a consideration of issues of packet size. + +5. Evaluation of the Alternate ECN Semantics + + This section discusses question (4) posed in Section 2: + + (4) How well does the alternate-ECN traffic perform, and how well + does it coexist with competing traffic on the path, in a "clean" + environment with new routers and with the unambiguous + specification of the use of alternate ECN semantics? + +5.1. Verification of Feedback from the Router + + One issue in evaluating the alternate ECN semantics concerns + mechanisms to discourage lying from the transport receiver to the + transport sender. In many cases, the sender is a server that has an + interest in using the alternate ECN semantics correctly, while the + + + + +Floyd Best Current Practice [Page 10] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + + receiver has more incentive to lie about the congestion experienced + along the path. + + In the default ECN semantics, two of the four ECN codepoints are used + for ECN-Capable(0) and ECN-Capable(1). The use of two codepoints for + ECN-Capable, instead of one, permits the data sender to verify the + receiver's reports that packets were actually received unmarked at + the receiver. In particular, the sender can specify that the + receiver report to the sender whether each unmarked packet was + received ECN-Capable(0) or ECN-Capable(1), as discussed in RFC 3540 + [RFC3540]. This use of ECN-Capable(0) and ECN-Capable(1) is + independent of the semantics of the other ECN codepoints, and could + be used, if desired, with alternate semantics for the other + codepoints. + + If alternate semantics for the ECN codepoint don't include the use of + two separate codepoints to indicate ECN-Capable, then the connections + using those semantics have lost the ability to verify that the data + receiver is accurately reporting the received ECN codepoint to the + data sender. In this case, it might be necessary for the alternate- + ECN framework to include alternate mechanisms for ensuring that the + data receiver is reporting feedback appropriately to the sender. As + one possibility, policers could be used in routers to ensure that end + nodes are responding appropriately to marked packets. + +5.2. Coexistence with Competing Traffic + + A second general issue concerns the coexistence of alternate-ECN + traffic with competing traffic along the path, in a clean environment + where all routers understand and are willing to use the alternate ECN + semantics for the traffic that specifies its use. + + If the traffic using the alternate ECN semantics is best-effort + traffic, then it is subject to the general requirement of fair + competition with TCP and other traffic along the path [RFC2914]. + + If the traffic using the alternate ECN semantics is diffserv traffic, + then the requirements are governed by the overall guidelines for that + class of diffserv traffic. It is beyond the scope of this document + to specify the requirements, if any, for the coexistence of diffserv + traffic with other traffic on the link; this should be addressed in + the specification of the diffserv codepoint itself. + + + + + + + + + +Floyd Best Current Practice [Page 11] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + +5.3. Proposals for Alternate ECN with Edge-to-Edge Semantics + + RFC 3168 specifies the use of the default ECN semantics by an end- + to-end transport protocol, with the requirement that "upon the + receipt by an ECN-Capable transport of a single CE packet, the + congestion control algorithms followed at the end-systems MUST be + essentially the same as the congestion control response to a *single* + dropped packet" ([RFC3168], Section 5). In contrast, some of the + proposals for alternate ECN semantics are for ECN used in an edge- + to-edge context between gateways at the edge of a network region, + e.g., [BESFC06]. + + When alternate ECN is defined with edge-to-edge semantics, this + definition needs to ensure that the edge-to-edge semantics do not + conflict with a connection using other ECN semantics end-to-end. One + way to avoid conflict would be for the edge-to-edge ECN proposal to + include some mechanism to ensure that the edge-to-edge ECN is not + used for connections that are using other ECN semantics (standard or + otherwise) end-to-end. Alternately, the edge-to-edge semantics could + be defined so that they do not conflict with a connection using other + ECN semantics end-to-end. + +5.4. Encapsulated Packets + + RFC 3168 has an extensive discussion of the interactions between ECN + and IP tunnels, including IPsec and IP in IP. Proposals for + alternate ECN semantics might interact with IP tunnels differently + than default ECN. As a result, proposals for alternate ECN semantics + must explicitly consider the issue of interactions with IP tunnels. + +5.5. A General Evaluation of the Alternate ECN Semantics + + A third general issue concerns the evaluation of the general merits + of the proposed alternate ECN semantics. Again, it would be beyond + the scope of this document to specify requirements for the general + evaluation of alternate ECN semantics. + +6. Security Considerations + + This document doesn't propose any new mechanisms for the Internet + protocol, and therefore doesn't introduce any new security + considerations. + + + + + + + + + +Floyd Best Current Practice [Page 12] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + +7. Conclusions + + This document has discussed some of the issues to be considered in + the specification of alternate semantics for the ECN field in the IP + header. + + Specifications of alternate ECN semantics must clearly state how they + address the issues raised in this document, particularly the issues + discussed in Section 2. In addition, specifications for alternate + ECN semantics must meet the requirements in Section 5.2 for + coexistence with competing traffic. + +8. Acknowledgements + + This document is based in part on conversations with Jozef Babiarz, + Kwok Ho Chan, and Victor Firoiu on their proposal for an alternate + use of the ECN field in DiffServ environments. Many thanks to + Francois Le Faucheur for feedback recommending that the document + include a section at the beginning discussing the potential issues + that need to be addressed. Thanks also to Mark Allman, Fred Baker, + David Black, Gorry Fairhurst, and to members of the TSVWG working + group for feedback on these issues. + +9. Normative References + + [RFC3168] Ramakrishnan, K., Floyd, S., and D. Black, "The Addition + of Explicit Congestion Notification (ECN) to IP", RFC + 3168, September 2001. + +10. Informative References + + [BCF05] Babiarz, J., Chan, K., and V. Firoiu, "Congestion + Notification Process for Real-Time Traffic", Work in + Progress, July 2005. + + [BESFC06] Briscoe, B., et al., "An edge-to-edge Deployment Model + for Pre-Congestion Notification: Admission Control over + a DiffServ Region", Work in Progress, June 2006. + + [ECN] ECN Web Page, URL . + + [QuickStart] S. Floyd, M. Allman, A. Jain, and P. Sarolahti, "Quick- + Start for TCP and IP", Work in Progress, October 2006. + + [RFC2581] Allman, M., Paxson, V., and W. Stevens, "TCP Congestion + Control", RFC 2581, April 1999. + + + + + +Floyd Best Current Practice [Page 13] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + + [RFC2914] Floyd, S., "Congestion Control Principles", BCP 41, RFC + 2914, September 2000. + + [RFC2960] Stewart, R., Xie, Q., Morneault, K., Sharp, C., + Schwarzbauer, H., Taylor, T., Rytina, I., Kalla, M., + Zhang, L., and V. Paxson, "Stream Control Transmission + Protocol", RFC 2960, October 2000. + + [RFC3448] Handley, M., Floyd, S., Padhye, J., and J. Widmer, "TCP + Friendly Rate Control (TFRC): Protocol Specification", + RFC 3448, January 2003. + + [RFC3540] Spring, N., Wetherall, D., and D. Ely, "Robust Explicit + Congestion Notification (ECN) Signaling with Nonces", + RFC 3540, June 2003. + + [RFC3714] Floyd, S. and J. Kempf, "IAB Concerns Regarding + Congestion Control for Voice Traffic in the Internet", + RFC 3714, March 2004. + + [RFC4340] Kohler, E., Handley, M., and S. Floyd, "Datagram + Congestion Control Protocol (DCCP)", RFC 4340, March + 2006. + + [RFC4341] Floyd, S. and E. Kohler, "Profile for Datagram + Congestion Control Protocol (DCCP) Congestion Control ID + 2: TCP-like Congestion Control", RFC 4341, March 2006. + + [RFC4342] Floyd, S., Kohler, E., and J. Padhye, "Profile for + Datagram Congestion Control Protocol (DCCP) Congestion + Control ID 3: TCP-Friendly Rate Control (TFRC)", RFC + 4342, March 2006. + + [XSSK05] Y. Xia, L. Subramanian, I. Stoica, and S. Kalyanaraman, + One More Bit Is Enough, SIGCOMM 2005, September 2005. + +Author's Address + + Sally Floyd + ICIR (ICSI Center for Internet Research) + + Phone: +1 (510) 666-2989 + EMail: floyd@icir.org + URL: http://www.icir.org/floyd/ + + + + + + + +Floyd Best Current Practice [Page 14] + +RFC 4774 Alternate Semantics for the ECN Field November 2006 + + +Full Copyright Statement + + Copyright (C) The IETF Trust (2006). + + 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, THE IETF TRUST, + 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 Best Current Practice [Page 15] + -- cgit v1.2.3