This is a purely informative rendering of an RFC that includes verified errata. This rendering may not be used as a reference.

The following 'Verified' errata have been incorporated in this document: EID 1900, EID 1901
Network Working Group                                       L. Dusseault
Request for Comments: 5657                          Messaging Architects
BCP: 9                                                         R. Sparks
Updates: 2026                                                    Tekelec
Category: Best Current Practice                           September 2009


         Guidance on Interoperation and Implementation Reports
                   for Advancement to Draft Standard

Abstract

   Advancing a protocol to Draft Standard requires documentation of the
   interoperation and implementation of the protocol.  Historic reports
   have varied widely in form and level of content and there is little
   guidance available to new report preparers.  This document updates
   the existing processes and provides more detail on what is
   appropriate in an interoperability and implementation report.

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 and License 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
   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. Content Requirements ............................................4
   3. Format ..........................................................5
   4. Feature Coverage ................................................6
   5. Special Cases ...................................................8
      5.1. Deployed Protocols .........................................8
      5.2. Undeployed Protocols .......................................8
      5.3. Schemas, Languages, and Formats ............................8
      5.4. Multiple Contributors, Multiple Implementation Reports .....9
      5.5. Test Suites ................................................9
      5.6. Optional Features, Extensibility Features .................10
   6. Examples .......................................................10
      6.1. Minimal Implementation Report .............................11
      6.2. Covering Exceptions .......................................11
   7. Security Considerations ........................................11
   8. References .....................................................12
      8.1. Normative References ......................................12
      8.2. Informative References ....................................12

1.  Introduction

   The Draft Standard level, and requirements for standards to meet it,
   are described in [RFC2026].  For Draft Standard, not only must two
   implementations interoperate, but also documentation (the report)
   must be provided to the IETF.  The entire paragraph covering this
   documentation reads:

      The Working Group chair is responsible for documenting the
      specific implementations which qualify the specification for Draft
      or Internet Standard status along with documentation about testing
      of the interoperation of these implementations.  The documentation
      must include information about the support of each of the
      individual options and features.  This documentation should be
      submitted to the Area Director with the protocol action request.
      (see Section 6)

   Moving documents along the standards track can be an important signal
   to the user and implementor communities, and the process of
   submitting a standard for advancement can help improve that standard
   or the quality of implementations that participate.  However, the
   barriers seem to be high for advancement to Draft Standard, or at the
   very least confusing.  This memo may help in guiding people through
   one part of advancing specifications to Draft Standard.  It also
   changes some of the requirements made in RFC 2026 in ways that are
   intended to maintain or improve the quality of reports while reducing
   the burden of creating them.

   Having and demonstrating sufficient interoperability is a gating
   requirement for advancing a protocol to Draft Standard.  Thus, the
   primary goal of an implementation report is to convince the IETF and
   the IESG that the protocol is ready for Draft Standard.  This goal
   can be met by summarizing the interoperability characteristics and by
   providing just enough detail to support that conclusion.  Side
   benefits may accrue to the community creating the report in the form
   of bugs found or fixed in tested implementations, documentation that
   can help future implementors, or ideas for other documents or future
   revisions of the protocol being tested.

   Different kinds of documentation are appropriate for widely deployed
   standards than for standards that are not yet deployed.  Different
   test approaches are appropriate for standards that are not typical
   protocols: languages, formats, schemas, etc.  This memo discusses how
   reports for these standards may vary in Section 5.

   Implementation should naturally focus on the final version of the
   RFC.  If there's any evidence that implementations are interoperating
   based on Internet-Drafts or earlier versions of the specification, or
   if interoperability was greatly aided by mailing list clarifications,
   this should be noted in the report.

   The level of detail in reports accepted in the past has varied
   widely.  An example of a submitted report that is not sufficient for
   demonstrating interoperability is (in its entirety): "A partial list
   of implementations include: Cray SGI Netstar IBM HP Network Systems
   Convex".  This report does not state how it is known that these
   implementations interoperate (was it through public lab testing?
   internal lab testing? deployment?).  Nor does it capture whether
   implementors are aware of, or were asked about, any features that
   proved to be problematic.  At a different extreme, reports have been
   submitted that contain a great amount of detail about the test
   methodology, but relatively little information about what worked and
   what failed to work.

   This memo is intended to clarify what an implementation report should
   contain and to suggest a reasonable form for most implementation
   reports.  It is not intended to rule out good ideas.  For example,
   this memo can't take into account all process variations such as
   documents going to Draft Standard twice, nor can it consider all
   types of standards.  Whenever the situation varies significantly from
   what's described here, the IESG uses judgement in determining whether
   an implementation report meets the goals above.

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in BCP 14 [RFC2119].

2.  Content Requirements

   The implementation report MUST identify the author of the report, who
   is responsible for characterizing the interoperability quality of the
   protocol.  The report MAY identify other contributors (testers, those
   who answered surveys, or those who contributed information) to share
   credit or blame.  The report MAY provide a list of report reviewers
   who corroborate the characterization of interoperability quality, or
   name an active working group (WG) that reviewed the report.

   Some of the requirements of RFC 2026 are relaxed with this update:

   o  The report MAY name exactly which implementations were tested.  A
      requirement to name implementations was implied by the description
      of the responsibility for "documenting the specific
      implementations" in RFC 2026.  However, note that usually
      identifying implementations will help meet the goals of
      implementation reports.  If a subset of implementations was tested
      or surveyed, it would also help to explain how that subset was
      chosen or self-selected.  See also the note on implementation
      independence below.

   o  The report author MAY choose an appropriate level of detail to
      document feature interoperability, rather than document each
      individual feature.  See note on granularity of features below.

   o  A contributor other than a WG chair MAY submit an implementation
      report to an Area Director (AD).

   o  Optional features that are not implemented, but are important and
      do not harm interoperability, MAY, exceptionally and with approval
      of the IESG, be left in a protocol at Draft Standard.  See
      Section 5.6 for documentation requirements and an example of where
      this is needed.

   Note: Independence of implementations is mentioned in the RFC 2026
         requirements for Draft Standard status.  Independent
         implementations should be written by different people at
         different organizations using different code and protocol
         libraries.  If it's necessary to relax this definition, it can
         be relaxed as long as there is evidence to show that success is
         due more to the quality of the protocol than to out-of-band
         understandings or common code.  If there are only two
         implementations of an undeployed protocol, the report SHOULD
         identify the implementations and their "genealogy" (which
         libraries were used or where the codebase came from).  If there
         are many more implementations, or the protocol is in broad
         deployment, it is not necessary to call out which two of the

         implementations demonstrated interoperability of each given
         feature -- a reader may conclude that at least some of the
         implementations of that feature are independent.

   Note: The granularity of features described in a specification is
         necessarily very detailed.  In contrast, the granularity of an
         implementation report need not be as detailed.  A report need
         not list every "MAY", "SHOULD", and "MUST" in a complete matrix
         across implementations.  A more effective approach might be to
         characterize the interoperability quality and testing approach,
         then call out any known problems in either testing or
         interoperability.

3.  Format

   The format of implementation and interoperability reports MUST be
   ASCII text with line breaks for readability.  As with Internet-
   Drafts, no 8-bit characters are currently allowed.  It is acceptable,
   but not necessary, for a report to be formatted as an Internet-Draft.

   Here is a simple outline that an implementation report MAY follow in
   part or in full:

   Title:  Titles of implementation reports are strongly RECOMMENDED to
      contain one or more RFC number for consistent lookup in a simple
      archive.  In addition, the name or a common mnemonic of the
      standard should be in the title.  An example might look like
      "Implementation Report for the Example Name of Some Protocol
      (ENSP) RFC XXXX".

   Author:  Identify the author of the report.

   Summary:  Attest that the standard meets the requirements for Draft
      Standard and name who is attesting it.  Describe how many
      implementations were tested or surveyed.  Quickly characterize the
      deployment level and where the standard can be found in
      deployment.  Call out, and if possible, briefly describe any
      notably difficult or poorly interoperable features and explain why
      these still meet the requirement.  Assert any derivative
      conclusions: if a high-level system is tested and shown to work,
      then we may conclude that the normative requirements of that
      system (all sub-system or lower-layer protocols, to the extent
      that a range of features is used) have also been shown to work.

   Methodology:  Describe how the information in the report was
      obtained.  This should be no longer than the summary.

   Exceptions:  This section might read "Every feature was implemented,
      tested, and widely interoperable without exception and without
      question".  If that statement is not true, then this section
      should cover whether any features were thought to be problematic.
      Problematic features need not disqualify a protocol from Draft
      Standard, but this section should explain why they do not (e.g.,
      optional, untestable, trace, or extension features).  See the
      example in Section 6.2.

   Detail sections:  Any other justifying or background information can
      be included here.  In particular, any information that would have
      made the summary or methodology sections more than a few
      paragraphs long may be created as a detail section and referenced.

      In this section, it would be good to discuss how the various
      considerations sections played out.  Were the security
      considerations accurate and dealt with appropriately in
      implementations?  Was real internationalization experience found
      among the tested implementations?  Did the implementations have
      any common monitoring or management functionality (although note
      that documenting the interoperability of a management standard
      might be separate from documenting the interoperability of the
      protocol itself)?  Did the IANA registries or registrations, if
      any, work as intended?

   Appendix sections:  It's not necessary to archive test material such
      as test suites, test documents, questionnaire text, or
      questionnaire responses.  However, if it's easy to preserve this
      information, appendix sections allow readers to skip over it if
      they are not interested.  Preserving detailed test information can
      help people doing similar or follow-on implementation reports, and
      can also help new implementors.

4.  Feature Coverage

   What constitutes a "feature" for the purposes of an interoperability
   report has been frequently debated.  Good judgement is required in
   finding a level of detail that adequately demonstrates coverage of
   the requirements.  Statements made at too high a level will result in
   a document that can't be verified and hasn't adequately challenged
   that the testing accidentally missed an important failure to
   interoperate.  On the other hand, statements at too fine a level
   result in an exponentially exploding matrix of requirement
   interaction that overburdens the testers and report writers.  The
   important information in the resulting report would likely be hard to
   find in the sea of detail, making it difficult to evaluate whether
   the important points of interoperability have been addressed.

   The best interoperability reports will organize statements of
   interoperability at a level of detail just sufficient to convince the
   reader that testing has covered the full set of requirements and in
   particular that the testing was sufficient to uncover any places
   where interoperability does not exist.  Reports similar to that for
   RTP/RTCP (an excerpt appears below) are more useful than an
   exhaustive checklist of every normative statement in the
   specification.

         10. Interoperable exchange of receiver report packets.

             o  PASS: Many implementations, tested UCL rat with vat,
                      Cisco IP/TV with vat/vic.

         11. Interoperable exchange of receiver report packets when
             not receiving data (ie:   the empty receiver report
             which has to be sent first in each compound RTCP packet
             when no-participants are transmitting data).

             o  PASS: Many implementations, tested UCL rat with vat,
                      Cisco IP/TV with vat/vic.

          ...

           8. Interoperable transport of RTP via TCP using the
              encapsulation defined in the audio/video profile

              o  FAIL: no known implementations. This has been
                       removed from the audio/video profile.


                               Excerpts from
      http://www.ietf.org/iesg/implementation/report-avt-rtp-rtcp.txt

   Consensus can be a good tool to help determine the appropriate level
   for such feature descriptions.  A working group can make a strong
   statement by documenting its consensus that a report sufficiently
   covers a specification and that interoperability has been
   demonstrated.

5.  Special Cases

5.1.  Deployed Protocols

   When a protocol is deployed, results obtained from laboratory testing
   are not as useful to the IETF as learning what is actually working in
   deployment.  To this end, it may be more informative to survey
   implementors or operators.  A questionnaire or interview can elicit
   information from a wider number of sources.  As long as it is known
   that independent implementations can work in deployment, it is more
   useful to discover what problems exist, rather than gather long and
   detailed checklists of features and options.

5.2.  Undeployed Protocols

   It is appropriate to provide finer-grained detail in reports for
   protocols that do not yet have a wealth of experience gained through
   deployment.  In particular, some complicated, flexible or powerful
   features might show interoperability problems when testers start to
   probe outside the core use cases.  RFC 2026 requires "sufficient
   successful operational experience" before progressing a standard to
   Draft, and notes that:

      Draft Standard may still require additional or more widespread
      field experience, since it is possible for implementations based
      on Draft Standard specifications to demonstrate unforeseen
      behavior when subjected to large-scale use in production
      environments.

   When possible, reports for protocols without much deployment
   experience should anticipate common operational considerations.  For
   example, it would be appropriate to put additional emphasis on
   overload or congestion management features the protocol may have.

5.3.  Schemas, Languages, and Formats

   Standards that are not on-the-wire protocols may be special cases for
   implementation reports.  The IESG SHOULD use judgement in what kind
   of implementation information is acceptable for these kinds of
   standards.  ABNF (RFC 4234) is an example of a language for which an
   implementation report was filed: it is interoperable in that
   protocols are specified using ABNF and these protocols can be
   successfully implemented and syntax verified.  Implementations of
   ABNF include the RFCs that use it as well as ABNF checking software.
   Management Information Base (MIB, [RFC3410]) modules are sometimes
   documented in implementation reports, and examples of that can be
   found in the archive of implementation reports.

   The interoperability reporting requirements for some classes of
   documents may be discussed in separate documents.  See [METRICSTEST]
   for example.

5.4.  Multiple Contributors, Multiple Implementation Reports

   If it's easiest to divide up the work of implementation reports by
   implementation, the result -- multiple implementation reports -- MAY
   be submitted to the sponsoring Area Director one-by-one.  Each report
   might cover one implementation, including:

      identification of the implementation;

      an affirmation that the implementation works in testing (or
      better, in deployment);

      whether any features are known to interoperate poorly with other
      implementations;

      which optional or required features are not implemented (note that
      there are no protocol police to punish this disclosure, we should
      instead thank implementors who point out unimplemented or
      unimplementable features especially if they can explain why); and

      who is submitting this report for this implementation.

   These SHOULD be collated into one document for archiving under one
   title, but can be concatenated trivially even if the result has
   several summary sections or introductions.

5.5.  Test Suites

   Some automated tests, such as automated test clients, do not test
   interoperability directly.  When specialized test implementations are
   necessary, tests can at least be constructed from real-world protocol
   or document examples.  For example:

   -  ABNF [RFC4234] itself was tested by combining real-world examples
      -- uses of ABNF found in well-known RFCs -- and feeding those
      real-world examples into ABNF checkers.  As the well-known RFCs
      were themselves interoperable and in broad deployment, this served
      as both a deployment proof and an interoperability proof.
           [RFC4234] progressed from Proposed Standard to Draft Standard and 
     then has been obsoleted by the Full Standard [RFC5234].
EID 1900 (Verified) is as follows:

Section: 5.5

Original Text:

|     [RFC4234] progressed from Proposed Standard through Draft Standard
|     to Standard and is obsoleted by [RFC5234].

Corrected Text:

|     [RFC4234] progressed from Proposed Standard to Draft Standard and
|     then has been obsoleted by the Full Standard [RFC5234].
Notes:
Clear description of historical timeline.
- Atom [RFC4287] clients might be tested by finding that they consistently display the information in a test Atom feed, constructed from real-world examples that cover all the required and optional features. - MIB modules can be tested with generic MIB browsers, to confirm that different implementations return the same values for objects under similar conditions. As a counter-example, the automated WWW Distributed Authoring and Versioning (WebDAV) test client Litmus (http://www.webdav.org/neon/litmus/) is of limited use in demonstrating interoperability for WebDAV because it tests completeness of server implementations and simple test cases. It does not test real-world use or whether any real WebDAV clients implement a feature properly or at all. 5.6. Optional Features, Extensibility Features Optional features need not be shown to be implemented everywhere. However, they do need to be implemented somewhere, and more than one independent implementation is required. If an optional feature does not meet this requirement, the implementation report must say so and explain why the feature must be kept anyway versus being evidence of a poor-quality standard. Extensibility points and versioning features are particularly likely to need this kind of treatment. When a protocol version 1 is released, the protocol version field itself is likely to be unused. Before any other versions exist, it can't really be demonstrated that this particular field or option is implemented. 6. Examples Some good, extremely brief, examples of implementation reports can be found in the archives: http://www.ietf.org/iesg/implementation/report-ppp-lcp-ext.html http://www.ietf.org/iesg/implementation/report-otp.html In some cases, perfectly good implementation reports are longer than necessary, but may preserve helpful information: http://www.ietf.org/iesg/implementation/report-rfc2329.txt http://www.ietf.org/iesg/implementation/report-rfc4234.txt 6.1. Minimal Implementation Report A large number of SMTP implementations support SMTP pipelining, including: (1) Innosoft's PMDF and Sun's SIMS. (2) ISODE/ MessagingDirect's PP. (3) ISOCOR's nPlex. (4) software.com's post.office. (5) Zmailer. (6) Smail. (7) The SMTP server in Windows 2000. SMTP pipelining has been widely deployed in these and other implementations for some time, and there have been no reported interoperability problems. This implementation report can also be found at http://www.ietf.org//iesg/implementation/report-smtp-pipelining.txt but the entire report is already reproduced above. Since SMTP pipelining had no interoperability problems, the implementation report was able to provide all the key information in a very terse format. The reader can infer from the different vendors and platforms that the codebases must, by and in large, be independent. This implementation report would only be slightly improved by a positive affirmation that there have been probes or investigations asking about interoperability problems rather than merely a lack of problem reports, and by stating who provided this summary report. 6.2. Covering Exceptions
EID 1901 (Verified) is as follows:

Section: 6.2

Original Text:

[[ second paragraph of Section 6.2 ]]

      VRFY and EXPN commands are often not implemented or are disabled.
      This does not pose an interoperability problem for SMTP because
|     EXPN is an optional features and its support is never relied on.
      [...]                     ^^


Corrected Text:

      VRFY and EXPN commands are often not implemented or are disabled.
      This does not pose an interoperability problem for SMTP because
|     EXPN is an optional feature and its support is never relied on.
      [...]                     ^
Notes:
Correct typo.
The RFC2821bis (SMTP) implementation survey asked implementors what features were not implemented. The VRFY and EXPN commands showed up frequently in the responses as not implemented or disabled. That implementation report might have followed the advice in this document, had it already existed, by justifying the interoperability of those features up front or in an "exceptions" section if the outline defined in this memo were used: VRFY and EXPN commands are often not implemented or are disabled. This does not pose an interoperability problem for SMTP because EXPN is an optional features and its support is never relied on. VRFY is required, but in practice it is not relied on because servers can legitimately reply with a non-response. These commands should remain in the standard because they are sometimes used by administrators within a domain under controlled circumstances (e.g. authenticated query from within the domain). Thus, the occasional utility argues for keeping these features, while the lack of problems for end-users means that the interoperability of SMTP in real use is not in the least degraded. 7. Security Considerations This memo introduces no new security considerations. 8. References 8.1. Normative References [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. 8.2. Informative References [METRICSTEST] Bradner, S. and V. Paxson, "Advancement of metrics specifications on the IETF Standards Track", Work in Progress, July 2007. [RFC2026] Bradner, S., "The Internet Standards Process -- Revision 3", BCP 9, RFC 2026, October 1996. [RFC3410] Case, J., Mundy, R., Partain, D., and B. Stewart, "Introduction and Applicability Statements for Internet-Standard Management Framework", RFC 3410, December 2002. [RFC4234] Crocker, D., Ed. and P. Overell, "Augmented BNF for Syntax Specifications: ABNF", RFC 4234, October 2005. [RFC4287] Nottingham, M., Ed. and R. Sayre, Ed., "The Atom Syndication Format", RFC 4287, December 2005. [RFC5234] Crocker, D. and P. Overell, "Augmented BNF for Syntax Specifications: ABNF", STD 68, RFC 5234, January 2008. Authors' Addresses Lisa Dusseault Messaging Architects EMail: lisa.dusseault@gmail.com Robert Sparks Tekelec 17210 Campbell Road Suite 250 Dallas, Texas 75254-4203 USA EMail: RjS@nostrum.com