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/rfc5704.txt | 843 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 843 insertions(+) create mode 100644 doc/rfc/rfc5704.txt (limited to 'doc/rfc/rfc5704.txt') diff --git a/doc/rfc/rfc5704.txt b/doc/rfc/rfc5704.txt new file mode 100644 index 0000000..e0c413a --- /dev/null +++ b/doc/rfc/rfc5704.txt @@ -0,0 +1,843 @@ + + + + + + +Network Working Group S. Bryant, Ed. +Request for Comments: 5704 M. Morrow, Ed. +Category: Informational For the IAB + November 2009 + + + Uncoordinated Protocol Development Considered Harmful + +Abstract + + This document identifies problems that may result from the absence of + formal coordination and joint development on protocols of mutual + interest between standards development organizations (SDOs). Some of + these problems may cause significant harm to the Internet. The + document suggests that a robust procedure is required prevent this + from occurring in the future. The IAB has selected a number of case + studies, such as Transport MPLS (T-MPLS), as recent examples to + describe the hazard to the Internet architecture that results from + uncoordinated adaptation of a protocol. + + This experience has resulted in a considerable improvement in the + relationship between the IETF and the ITU-T. In particular, this was + achieved via the establishment of the "Joint working team on + MPLS-TP". In addition, the leadership of the two organizations + agreed to improve inter-organizational working practices so as to + avoid conflict in the future between ITU-T Recommendations and IETF + RFCs. + + Whilst we use ITU-T - IETF interactions in these case studies, the + scope of the document extends to all SDOs that have an overlapping + protocol interest with the IETF. + +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) 2009 IETF Trust and the persons identified as the + document authors. All rights reserved. + + This document is subject to BCP 78 and the IETF Trust's Legal + Provisions Relating to IETF Documents + (http://trustee.ietf.org/license-info) in effect on the date of + publication of this document. Please review these documents + carefully, as they describe your rights and restrictions with respect + + + +Bryant, et al. Informational [Page 1] + +RFC 5704 Uncoordinated Harmful November 2009 + + + to this document. Code Components extracted from this document must + include Simplified BSD License text as described in Section 4.e of + the Trust Legal Provisions and are provided without warranty as + described in the BSD License. + +Table of Contents + + 1. Introduction ....................................................2 + 2. Protocol Design Rules ...........................................3 + 2.1. Protocol Safety ............................................3 + 2.2. Importance of Invariants ...................................4 + 2.3. Importance of Correct Identification .......................4 + 2.4. The Role of the Design Authority ...........................4 + 2.5. Ships in the Night .........................................5 + 3. Examples of Miscoordination .....................................6 + 3.1. T-MPLS as a Case Study .....................................6 + 3.2. PPP over SONET/SDH (Synchronous Optical Network / + Synchronous Digital Hierarchy ..............................6 + 4. Managing Information Flow .......................................7 + 4.1. Managing Information Flow within an SDO ....................7 + 4.2. Managing Information Flow between SDOs .....................7 + 5. MPLS-TP as Best Practice ........................................7 + 6. IETF Change Process .............................................8 + 7. Security Considerations .........................................8 + 8. Acknowledgments .................................................8 + 9. IAB Members at the Time of This Writing .........................8 + 10. Emerging Issues ................................................9 + 11. Conclusion .....................................................9 + 12. Informative References .........................................9 + Appendix A. A Review of the T-MPLS Case ..........................12 + A.1. Multiple Definitions of Label 14 ..........................12 + A.2. Redefinition of TTL Semantics .............................13 + A.3. Reservation of Additional Labels ..........................13 + A.4. Redefinition of MPLS EXP Bits .............................14 + A.5. The Consequences for the Network Operators ................14 + A.6. The Consequences for the SDOs .............................15 + +1. Introduction + + The uncoordinated adaptation of a protocol, parameter, or code-point + by a standards development organization (SDO), either through the + allocation of a code-point without following the formal registration + procedures or by unilaterally modifying the semantics of the protocol + or intended use of the code-point itself, poses a risk of harm to the + Internet [RFC4775]. + + + + + + +Bryant, et al. Informational [Page 2] + +RFC 5704 Uncoordinated Harmful November 2009 + + + The purpose of this document is to describe the various problems that + may occur without formal coordination and joint development on + protocols of mutual interest between SDOs. Some of the problems that + arise may cause significant harm to the Internet. In particular, the + IAB considers it an essential principle of the protocol development + process that only one SDO maintains design authority for a given + protocol, with that SDO having ultimate authority over the allocation + of protocol parameter code-points and over defining the intended + semantics, interpretation, and actions associated with those code- + points. + + There is currently a joint IETF - ITU-T development effort underway, + known as the MPLS Transport Profile (MPLS-TP), which is progressing + rapidly to extend MPLS in a way that is consistent with the MPLS + architecture, and fully satisfies the requirements of the transport + network provider [LS26]. By way of a case study, we will refer to + the design and standardization process of the ITU-T protocol known as + Transport MPLS (T-MPLS). Development of T-MPLS was abandoned + [RFC5317] by ITU-T Study Group 15 due to inherent conflicts with the + IETF MPLS design and, in particular, with the Internet architecture. + These conflicts arose due to the lack of coordination with the IETF + as the design authority for MPLS. + + The goal of this document is to demonstrate the importance of a + coordinated approach to successful collaboration between SDOs, and to + explain a model for inter-SDO collaborative protocol development that + is being used successfully by the ITU-T and IETF. + +2. Protocol Design Rules + + This section describes a number of protocol design rules needed to + ensure the safe operation of a network. Whilst these rules will be + familiar to many protocol designers, the rules are restated here to + ensure that assumptions are clear and consistent. Differing + assumptions have been at the root of many miscoordinations and + miscommunications between SDOs in the past. + +2.1. Protocol Safety + + To understand the reasons why the IAB and IETF regard uncoordinated + use of code-points and/or protocol modification as posing a risk of + harm to the Internet, it is necessary to recap some important + principles of protocol design in large-scale networks such as the + Internet. Many end users and businesses have come to rely on the + Internet as part of their critical infrastructure, thus large-scale + networks, such as the Internet, represent significant economic value. + Any outage in a large-scale network due to a protocol failure will + therefore result in significant commercial and political damage. + + + +Bryant, et al. Informational [Page 3] + +RFC 5704 Uncoordinated Harmful November 2009 + + + When two incompatible protocols, or forms of the same protocol, are + deployed without coordination, there is a serious risk that this may + be catastrophic to the stability or security of the network. + + Furthermore, the scale and distributed nature of the Internet is such + that it may be difficult or impossible to rid the network of the + long-term consequences of the protocol incompatibility. Therefore, + the following issues are of critical importance. + +2.2. Importance of Invariants + + Invariants are core properties that are consistent across the network + and do not change over extremely long time-scales. Protocol + designers use such invariants as axioms in designing protocols. A + protocol often places an absolute reliance on an invariant to resolve + a design corner case. One example of an invariance in IP that was + inherited in the design of MPLS is the invariant that a time to live + (TTL) value is monotonically decreased and that a packet with TTL<=1 + will not be forwarded. This is a safety mechanism to mitigate the + damaging effects of packet-forwarding loops. Another example is the + way that MPLS applies special semantics to the reserved label set + (0..15) [RFC3032], and the notion that a Label Switched Router (LSR) + is free to allocate labels with a value of 16 or greater for its own + use. + +2.3. Importance of Correct Identification + + A special type of invariant is the allocation of a code-point. A + code-point may be used to identify a packet type or a component + within a packet. Without these identifiers, a packet is an opaque + sequence of bits. A packet parser operates by first identifying the + code-point and then using the semantics associated with that code- + point to interpret other components within the packet. Once a code- + point is defined, the interpretation of associated data and the + consequential actions become protocol invariants. Subsequent + protocol development must adhere to those invariants. The semantics + for an allocated code-point must never change. If a future + enhancement requires different semantics, interpretation, or action, + then a new code-point must be obtained. + +2.4. The Role of the Design Authority + + A code-point such as an IEEE Ethertype is allocated to a design + authority such as the IETF. It is this design authority that + establishes how information identified by the code-point is to be + interpreted to associate appropriate invariants. Modification and + extension of a protocol requires great care. In particular, it is + necessary to understand the exact nature of the invariants and the + + + +Bryant, et al. Informational [Page 4] + +RFC 5704 Uncoordinated Harmful November 2009 + + + consequences of modification. Such understanding may not always be + possible when protocols are modified by organizations that don't have + the experience of the original designers or the design authority + expert pool. Furthermore, since there can only safely be a single + interpretation of the information identified by a code-point, there + must be a unique authority responsible for authorizing and + documenting the semantics of the information and consequential + protocol actions. + + In the case of IP and MPLS technologies, the design authority is the + IETF. The IETF has an internal process for evolving and maintaining + the protocols for which it is the design authority. The IETF also + has change processes in place [RFC4929] to work with other SDOs that + require enhancements to its protocols and architectures. Similarly, + the ITU-T has design authority for Recommendation E.164 [E.164] and + allocates the relevant code-points, even though the IETF has design + authority for the protocols ("ENUM") used to access E.164 numbers + through the Internet DNS [RFC3245]. + + It is a recommendation of this document that the IETF introduces + additional change mechanisms to encompass all of the technical areas + for which it has design authority. + +2.5. Ships in the Night + + It may be tempting for a designer to assert that the protocol + extensions it proposes are safe even though it breaks the invariants + of the original protocol because these protocol variants will operate + as ships in the night. That is, these protocol variants will never + simultaneously exist in the same network domain and will never need + to inter-work. This is a fundamentally unsound assumption for a + number of reasons. First, it is infeasible to ensure that the two + instances will never be interconnected under any circumstances. + Second, even if the operators that deploy the protocols apply + appropriate due diligence to ensure that the two instances do not + conflict, it is infeasible to ensure that such conflicting protocols + will not be interconnected under fault conditions. + + This assumption of ships in the night is particularly hazardous when + the instances of the protocol share the same identifying code-point. + This is because a system is unable to determine which variant of the + protocol it has received, and hence how to correctly interpret the + associated information or to determine what protocol actions may be + safely executed. + + + + + + + +Bryant, et al. Informational [Page 5] + +RFC 5704 Uncoordinated Harmful November 2009 + + +3. Examples of Miscoordination + + There are a variety of examples where lack of inter-SDO coordination + has led to the publication of flawed protocol designs. This section + describes a number of case studies that illustrate coordination + issues. + +3.1. T-MPLS as a Case Study + + A recent example where another SDO created a protocol based on + misunderstandings of IETF protocols is T-MPLS. T-MPLS was created in + ITU-T in an attempt to design a packet-transport method for + transport-oriented networks. This is an example of the success that + IETF protocols have enjoyed, and ITU-T's interest and selection of + MPLS is a compliment to the IETF work. Quite late in the ITU-T + design and specification cycle, there were a number of liaison + exchanges between the ITU-T and the IETF, where the IETF became + increasingly concerned about incompatibility of IETF MPLS procedures + and technologies with ITU-T T-MPLS [RFC5317]. Extensive discussions + took place regarding interpretation, definition, and + misunderstandings regarding aspects such as MPLS Label 14, MPLS swap + operation, TTL semantics, reservation of additional labels, and EXP + bits. If ITU-T had worked with IETF from the start in developing + T-MPLS, these problems could have been avoided. A detailed analysis + of the T-MPLS case is provided in Appendix A. + +3.2. PPP over SONET/SDH (Synchronous Optical Network / Synchronous + Digital Hierarchy) + + An example of where the IETF failed to coordinate with the ITU-T is + [RFC1619], which defined PPP over SONET. In the text dealing with + the SONET/SDH Synchronous Payload Envelope (SPE), the document + erroneously stated that "no scrambling is needed during insertion + into the SPE." It was later determined by SONET experts operating in + the ITU-T and in ANSI that this error arose due to an incomplete + understanding of the SONET scrambler. By not using a scrambler, the + protocol was attempting to transport non-transparent data over SONET. + This resulted in lost or misinterpreted data in the Packet over SONET + (PoS) network. This impacted routing, signaling, and end-user data + traffic. Details of this work are described in [PPPoSONET]. This + problem would have been prevented if the IETF had worked with ITU-T + and ANSI in initially developing [RFC1619] . The problem was + resolved by working jointly with ITU-T and ANSI experts to publish + [RFC2615], which mandated the use of scrambling. + + Note that [RFC1619] was developed four years before the IETF and + ITU-T agreed on formal procedures for cooperation, as documented in + [RFC2436] (which was later obsoleted by [RFC3356]). + + + +Bryant, et al. Informational [Page 6] + +RFC 5704 Uncoordinated Harmful November 2009 + + +4. Managing Information Flow + + This section recommends that intra- and inter-SDO information flows + require careful management in order to prevent the accidental + extension of protocols without complete coordination of the work with + the relevant design authority. + +4.1. Managing Information Flow within an SDO + + One cannot assume that an SDO is completely familiar with the + internal structure, information exchange, or internal processes of + another SDO. Hence, the initial contact point and the subgroup with + which a long-term working relationship is formed has a duty to ensure + that the work is fully notified and coordinated to all relevant + parties within the SDO. + +4.2. Managing Information Flow between SDOs + + A recommendation is that, as part of their document-approval process, + SDOs should confirm that all protocol parameters, code-points, TLV + identifiers, etc., have been authorized by the appropriate design + authority (e.g., IANA, IETF, etc. in this case) and that SDO approval + from the design authority has been obtained prior to publishing + protocol extensions. This confirmation should be an integral part of + the approval or consent process as verifying that the normative + references are qualified. + +5. MPLS-TP as Best Practice + + In order to bridge the gap between the two organizations, the IETF + and the ITU-T established a joint working team (JWT) to assess + whether it was possible to enhance existing MPLS standards to provide + a best-in-class solution for transport networks. The outcome of this + investigation is reported in [RFC5317]. + + The JWT proposed a design that was acceptable to both SDOs. This has + led to the creation of the MPLS-TP project. This is a joint project + in which the ITU-T experts work with the IETF on protocol-development + tasks, and IETF members work within the ITU-T to understand + requirements and to assist in the creation of ITU-T recommendations + that describe MPLS-TP in which the technical definition is provided + through normative references to IETF RFCs. + + Although the JWT approach allowed the IETF and the ITU-T to agree on + a method of resolving the T-MPLS problem, this approach had a + significant resource cost. The JWT required considerable protocol- + design expertise and IETF management time to agree on a suitable + technical solution. A lightweight process, starting with close + + + +Bryant, et al. Informational [Page 7] + +RFC 5704 Uncoordinated Harmful November 2009 + + + coordination during the requirements phase and continuing during the + development phase, would likely reduce the resources needed to an + acceptable level in the future. + +6. IETF Change Process + + There is an MPLS-change-process [RFC4929] . However, the IETF has + not yet defined a change process that is applicable to all of its + work areas. The problems described in this document indicate that + the IETF needs to develop a universal change process. The MPLS- + change-process would seem to be a suitable starting point. + +7. Security Considerations + + The uncoordinated development of protocols poses a risk of harm to + the Internet and must not be permitted. The enhancement or + modification of a protocol can increase attack surfaces considerably + and may therefore compromise the security or stability of the + Internet. The IETF has a review process that combines cross-area + review with specialist security review by experts familiar with the + development and deployment context of the Internet protocol suite. + In particular, because of the Internet infrastructure's reliance on + the IP and MPLS protocol suites, this security review process must be + exercised with considerable diligence. Failure to apply this review + process exposes the Internet to increased risk along both security + and stability vectors. + +8. Acknowledgments + + The authors wish to acknowledge Loa Andersson for his contribution to + this work. + +9. IAB Members at the Time of This Writing + + Marcelo Bagnulo + Gonzalo Camarillo + Stuart Cheshire + Vijay Gill + Russ Housley + John Klensin + Olaf Kolkman + Gregory Lebovitz + Andrew Malis + Danny McPherson + David Oran + Jon Peterson + Dave Thaler + + + + +Bryant, et al. Informational [Page 8] + +RFC 5704 Uncoordinated Harmful November 2009 + + +10. Emerging Issues + + Although we have used T-MPLS as a case study, there are other ongoing + ITU-T projects and core IETF specifications that could be the subject + of either improved coordination or new conflicts, depending on + whether or not the principles outlined in this document are adhered + to by the IETF and ITU. Two current examples are [Y.2015] and + [Q.Flowsig]. New areas with potential for cooperation or conflict + are emerging from the work of ITU-T SG13 Question 7, "IPv6" -- for + example: [Y.ipv6split] and [Y.ipv6migration]. + + Improved coordination, of course, is not limited to the relationship + between IETF and ITU-T. This issue is present between a set of SDOs. + The IETF - ITU-T relationship has simply been used because there is a + recent example where a potential disaster was, through much hard + work, not only prevented but turned into a net gain for all. + +11. Conclusion + + It is important that all SDOs developing standards that affect the + operation of the Internet learn the lessons that arise from cases + cited in this document. Uncoordinated parallel work between SDOs + creates significant problems with potentially damaging operation + impact to those that deploy and use the Internet. Both inter- and + intra-SDO information flow needs to be well managed to ensure that + all impacted parties are aware of work items. Finally, the IETF + needs to develop a universal change process that encompasses all of + its work areas. + +12. Informative References + + [E.164] ITU-T, "ITU Recommendation E.164: The international + public telecommunication numbering plan", + February 2005. + + [LS26] ITU-T Study Group 15, "Cooperation Between IETF and + ITU-T on the Development of MPLS-TP", Geneva, + December 2008, . + + [PPPoSONET] Manchester, J., et al., "PPP over SONET/SDH", Work in + Progress, October 1997. + + [Q.Flowsig] ITU-T Study Group 11, Question 5, "Signalling protocols + and procedures relating to flow state aware access QoS + control in an NGN", Draft Recommendation. + + + + + +Bryant, et al. Informational [Page 9] + +RFC 5704 Uncoordinated Harmful November 2009 + + + [RFC1393] Malkin, G., "Traceroute Using an IP Option", RFC 1393, + January 1993. + + [RFC1619] Simpson, W., "PPP over SONET/SDH", RFC 1619, May 1994. + + [RFC2436] Brett, R., Bradner, S., and G. Parsons, "Collaboration + between ISOC/IETF and ITU-T", RFC 2436, October 1998. + + [RFC2615] Malis, A. and W. Simpson, "PPP over SONET/SDH", + RFC 2615, June 1999. + + [RFC3031] Rosen, E., Viswanathan, A., and R. Callon, + "Multiprotocol Label Switching Architecture", RFC 3031, + January 2001. + + [RFC3032] Rosen, E., Tappan, D., Fedorkow, G., Rekhter, Y., + Farinacci, D., Li, T., and A. Conta, "MPLS Label Stack + Encoding", RFC 3032, January 2001. + + [RFC3245] Klensin, J. and IAB, "The History and Context of + Telephone Number Mapping (ENUM) Operational Decisions: + Informational Documents Contributed to ITU-T Study + Group 2 (SG2)", RFC 3245, March 2002. + + [RFC3270] Le Faucheur, F., Wu, L., Davie, B., Davari, S., + Vaananen, P., Krishnan, R., Cheval, P., and J. + Heinanen, "Multi-Protocol Label Switching (MPLS) + Support of Differentiated Services", RFC 3270, + May 2002. + + [RFC3356] Fishman, G. and S. Bradner, "Internet Engineering Task + Force and International Telecommunication Union - + Telecommunications Standardization Sector Collaboration + Guidelines", RFC 3356, August 2002. + + [RFC3429] Ohta, H., "Assignment of the 'OAM Alert Label' for + Multiprotocol Label Switching Architecture (MPLS) + Operation and Maintenance (OAM) Functions", RFC 3429, + November 2002. + + [RFC4379] Kompella, K. and G. Swallow, "Detecting Multi-Protocol + Label Switched (MPLS) Data Plane Failures", RFC 4379, + February 2006. + + [RFC4775] Bradner, S., Carpenter, B., and T. Narten, "Procedures + for Protocol Extensions and Variations", BCP 125, + RFC 4775, December 2006. + + + + +Bryant, et al. Informational [Page 10] + +RFC 5704 Uncoordinated Harmful November 2009 + + + [RFC4929] Andersson, L. and A. Farrel, "Change Process for + Multiprotocol Label Switching (MPLS) and Generalized + MPLS (GMPLS) Protocols and Procedures", BCP 129, + RFC 4929, June 2007. + + [RFC5129] Davie, B., Briscoe, B., and J. Tay, "Explicit + Congestion Marking in MPLS", RFC 5129, January 2008. + + [RFC5317] Bryant, S. and L. Andersson, "Joint Working Team (JWT) + Report on MPLS Architectural Considerations for a + Transport Profile", RFC 5317, February 2009. + + [RFC5462] Andersson, L. and R. Asati, "Multiprotocol Label + Switching (MPLS) Label Stack Entry: "EXP" Field Renamed + to "Traffic Class" Field", RFC 5462, February 2009. + + [RFC5654] Niven-Jenkins, B., Brungard, D., Betts, M., Sprecher, + N., and S. Ueno, "Requirements of an MPLS Transport + Profile", RFC 5654, September 2009. + + [Y.1711-2002] ITU-T Study Group 13, "ITU-T Recommendation Y.1711: OAM + mechanism for MPLS networks", November 2002. + + [Y.1711-2004] ITU-T Study Group 13, "ITU-T Recommendation Y.1711: OAM + mechanism for MPLS networks", February 2004. + + [Y.1711am1] ITU-T Study Group 13, "ITU-T Recommendation Y.1711 + Amendment 1: New Function Type Codes", October 2005. + + [Y.1711cor1] ITU-T Study Group 13, "ITU-T Recommendation Y.1711 + (2004) corrigendum 1", February 2005. + + [Y.2015] ITU-T Study Group 13, Question 5, "General Requirements + for ID/Locator Separation in NGN". + + [Y.ipv6migration] + ITU-T, "ITU draft Y.ipv6migration: Roadmap for IPv6 + migration from NGN operators perspective", 2009. + + [Y.ipv6split] ITU-T, "ITU draft Y.ipv6split: Framework of ID/LOC + separation in IPv6-based NGN", 2009. + + + + + + + + + + +Bryant, et al. Informational [Page 11] + +RFC 5704 Uncoordinated Harmful November 2009 + + +Appendix A. A Review of the T-MPLS Case + + T-MPLS was created in ITU-T in an attempt to design an MPLS-based + packet-transport method for transport-oriented networks. This + appendix describes the technical issues that the IETF identified with + the T-MPLS documents and their consequences. + +A.1. Multiple Definitions of Label 14 + + To appreciate why the use of MPLS Reserved Label 14 by the T-MPLS + protocol represented a safety concern to the Internet, it is + important to understand the current standards that use MPLS Reserved + Label 14. + + The governing standard on the use of MPLS Reserved Label 14 is + [RFC3429], "Assignment of the 'OAM Alert Label' for Multiprotocol + Label Switching Architecture (MPLS) Operation and Maintenance (OAM) + Functions". + + Label 14 is assigned to a specific protocol, namely, ITU-T + Recommendation [Y.1711-2002]. + + ITU-T Recommendation [Y.1711-2002] has been superseded by newer + versions, specifically: [Y.1711-2004], [Y.1711cor1], and [Y.1711am1]. + + All three documents are currently in force as ITU-T Recommendations. + + The problem is that the changes made to Y.1711 were never reflected + in an update to RFC 3429, which only defines the protocol as + specified by the now superseded 2002 Recommendation. So for example, + MPLS equipment responding to an MPLS packet containing Label 14 would + expect to see the 2002 version of the Y.1711 [Y.1711-2002] protocol + and would not recognize any of the new function codes specified in + Y.1711 Amendment 1. This problem arises because Y.1711 does not have + a version field, and RFC 3429 offers no other method to disambiguate + non-interoperable versions of Y.1711. Having a version number in the + protocol permits an implementer to codify non-interoperability. + Furthermore, the IETF as the authority over Label 14 semantics has + the final say over maintaining the interoperability of the protocol + employing that code-point, unless the IETF explicitly delegates such + authority. + + With regard to T-MPLS, there was a lack of coordination between the + ITU-T and the IETF over the redefinition of the semantics of MPLS + Label 14, which resulted in protocol definitions that conflicted with + the IETF MPLS architecture. + + + + + +Bryant, et al. Informational [Page 12] + +RFC 5704 Uncoordinated Harmful November 2009 + + + The MPLS architecture [RFC3031], defines a swap operation as an + atomic function that replaces the top label in an MPLS label stack + with another label, which provides context for the next hop LSR. + However, the ITU-T Recommendations that specified the new OAM + functions defined by Label 14 redefined the label-swap operation as a + POP, followed by a PUSH, thereby causing all LSRs to inspect the + label stack for the presence of Label 14 at each hop. This proposed + new behaviour conflicts with the IETF definition of a swap operation. + + The behaviour proposed in these specifications would have had major + consequences for deployed hardware designs. The outcome would have + been that the equipments built according to the two different + specifications would have been incompatible. It is important that + the atomic procedure defined in [RFC3031] is kept unchanged. + +A.2. Redefinition of TTL Semantics + + The standard method of delivering an OAM message to an entity on a + Label Switched Path (LSP), such that the OAM message shares its fate + with the data traffic, is to use TTL expiry. The IETF's Internet + Protocol (IP) utilizes this mechanism for traceroute [RFC1393], as + does MPLS ping [RFC4379]. + + At one stage, the T-MPLS designers considered a multi-level OAM + design in which the OAM packet was steered to its target by a process + in which some nodes increased the TTL as they forwarded the OAM + packet to its next hop. TTL is a safety device in the IETF IP and + MPLS architecture that prevents a packet from continuously looping + under fault conditions. Thus, the proposed extension to support an + enhanced OAM mechanism violated an MPLS design invariant specifically + introduced to ensure safe operation of the Internet by preventing + persistent forwarding loops. + +A.3. Reservation of Additional Labels + + The IETF MPLS protocol uses a small number of reserved labels + [RFC3032] as a mechanism to provide additional context and to trigger + some special processing operations in the forwarder. All other + labels used for forwarding use semantics defined by the forwarding + equivalence class (FEC). In an early implementation of T-MPLS, the + designers determined that they needed some additional labels to alert + the forwarder that the packet needed special processing. Thus, a + conflict was thereby introduced between the behaviour of an IETF MPLS + LSR and LSRs that operate according to the specification in the ITU-T + Recommendation. Thus, some LSRs would attribute special semantics to + Labels 16..31, whilst other LSRs would perform normal forwarding on + them. + + + + +Bryant, et al. Informational [Page 13] + +RFC 5704 Uncoordinated Harmful November 2009 + + +A.4. Redefinition of MPLS EXP Bits + + The early MPLS documents defined the form of the MPLS label stack + entry [RFC3032]. This includes a three-bit field called the "EXP + field". The exact use of this field was not defined by these + documents, except to state that it was to be "reserved for + experimental use". + + Although the intended use of the EXP field was as a "Class of + Service" (CoS) field, it was not named a CoS field by these early + documents because the use of such a CoS field was not considered to + be sufficiently defined. Today, a number of standards documents + define its usage as a CoS field ([RFC3270], [RFC5129]), and hardware + is deployed that assumes this exclusive usage. + + The T-MPLS designers, unaware of the historic reason for the + "provisional" naming of this field, assumed that they were available + for any experimental use and re-purposed them to indicate the + maintenance-entity level (a hierarchical maintenance mechanism). + + The intended use of the EXP field was subsequently carried in + [RFC5462], which reinforces this use by formally changing the name to + Traffic Class (TC). + +A.5. The Consequences for the Network Operators + + Transport network operators need a way to realize the statistical + gain inherent in packet networking while retaining the familiar + operational structure of their SONET/SDH networks. T-MPLS was an + attempt to provide that functionality. However, creating an + incompatible variant of MPLS without tight coordination with IETF + created a number of problems for network operators. + + Firstly, those operators that deployed T-MPLS in production networks + will need to address the risk and complexity of transitioning their + network to MPLS-TP. Secondly, there has been a consequential delay + of the necessary enhancements to MPLS to meet their needs [RFC5654] + as the IETF and ITU-T executed a redevelopment of MPLS-based + transport network protocols. + + Fortunately, the two organizations are now working together to design + the necessary enhancements + + The resulting technology, MPLS-TP, brings significant benefits to + all. However, this has not been without cost. Had things continued, + we are not sure what would have happened -- at the least, the larger + + + + + +Bryant, et al. Informational [Page 14] + +RFC 5704 Uncoordinated Harmful November 2009 + + + MPLS community would have been denied the benefit of better OAM, and + the transport community would have been denied the many benefits of + an interoperable solution. + +A.6. The Consequences for the SDOs + + The process of resolution required considerable resources and + introduced a great deal of conflict between the IETF and the ITU-T, + much of which was exposed to public scrutiny, to the detriment of + both organizations. In particular, this conflict-resolution process + consumed the very resources required to develop an optimal + architecture for MPLS in transport networks. + +Authors' Addresses + + Stewart Bryant (editor) + + EMail: stbryant@cisco.com + + + Monique Morrow (editor) + + EMail: mmorrow@cisco.com + + + Internet Architecture Board + + EMail: iab@iab.org + + + + + + + + + + + + + + + + + + + + + + + +Bryant, et al. Informational [Page 15] + -- cgit v1.2.3