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Request for Comments number 4892

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RFC4892 Requirements for a Mechanism Identifying a Name Server Instance


RFC4892   Requirements for a Mechanism Identifying a Name Server Instance    S. Woolf, D. Conrad [ June 2007 ] (TXT = 17605 bytes)

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Network Working Group                                           S. Woolf
Request for Comments: 4892             Internet Systems Consortium, Inc.
Category: Informational                                        D. Conrad
                                                                   ICANN
                                                               June 2007


    Requirements for a Mechanism Identifying a Name Server Instance

Status of This Memo

   This memo provides information for the Internet community.  It does
   not specify an Internet standard of any kind.  Distribution of this
   memo is unlimited.

Copyright Notice

   Copyright (C) The IETF Trust (2007).

Abstract

   With the increased use of DNS anycast, load balancing, and other
   mechanisms allowing more than one DNS name server to share a single
   IP address, it is sometimes difficult to tell which of a pool of name
   servers has answered a particular query.  A standardized mechanism to
   determine the identity of a name server responding to a particular
   query would be useful, particularly as a diagnostic aid for
   administrators.  Existing ad hoc mechanisms for addressing this need
   have some shortcomings, not the least of which is the lack of prior
   analysis of exactly how such a mechanism should be designed and
   deployed.  This document describes the existing convention used in
   some widely deployed implementations of the DNS protocol, including
   advantages and disadvantages, and discusses some attributes of an
   improved mechanism.

1.  Introduction and Rationale

   Identifying which name server is responding to queries is often
   useful, particularly in attempting to diagnose name server
   difficulties.  This is most obviously useful for authoritative
   nameservers in the attempt to diagnose the source or prevalence of
   inaccurate data, but can also conceivably be useful for caching
   resolvers in similar and other situations.  Furthermore, the ability
   to identify which server is responding to a query has become more
   useful as DNS has become more critical to more Internet users, and as
   network and server deployment topologies have become more complex.





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   The conventional means for determining which of several possible
   servers is answering a query has traditionally been based on the use
   of the server's IP address as a unique identifier.  However, the
   modern Internet has seen the deployment of various load balancing,
   fault-tolerance, or attack-resistance schemes such as shared use of
   unicast IP addresses as documented in [RFC3258].  An unfortunate side
   effect of these schemes has been to make the use of IP addresses as
   identifiers associated with DNS (or any other) service somewhat
   problematic.  Specifically, multiple dedicated DNS queries may not go
   to the same server even though sent to the same IP address.  Non-DNS
   methods such as ICMP ping, TCP connections, or non-DNS UDP packets
   (such as those generated by tools like "traceroute"), etc., may well
   be even less certain to reach the same server as the one which
   receives the DNS queries.

   There is a well-known and frequently-used technique for determining
   an identity for a nameserver more specific than the possibly-non-
   unique "server that answered the query I sent to IP address A.B.C.D".
   The widespread use of the existing convention suggests a need for a
   documented, interoperable means of querying the identity of a
   nameserver that may be part of an anycast or load-balancing cluster.
   At the same time, however, it also has some drawbacks that argue
   against standardizing it as it's been practiced so far.

2.  Existing Conventions

   For some time, the commonly deployed Berkeley Internet Name Domain
   (BIND) implementation of the DNS protocol suite from the Internet
   Systems Consortium [BIND] has supported a way of identifying a
   particular server via the use of a standards-compliant, if somewhat
   unusual, DNS query.  Specifically, a query to a recent BIND server
   for a TXT resource record in class 3 (CHAOS) for the domain name
   "HOSTNAME.BIND." will return a string that can be configured by the
   name server administrator to provide a unique identifier for the
   responding server.  (The value defaults to the result of a
   gethostname() call).  This mechanism, which is an extension of the
   BIND convention of using CHAOS class TXT RR queries to sub-domains of
   the "BIND." domain for version information, has been copied by
   several name server vendors.

   A refinement to the BIND-based mechanism, which dropped the
   implementation-specific label, replaces "BIND." with "SERVER.".  Thus
   the query label to learn the unique name of a server may appear as
   "ID.SERVER.".

   (For reference, the other well-known name used by recent versions of
   BIND within the CHAOS class "BIND." domain is "VERSION.BIND.".  A
   query for a CHAOS TXT RR for this name will return an



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   administratively defined string which defaults to the software
   version of the server responding.  This is, however, not generally
   implemented by other vendors.)

2.1.  Advantages

   There are several valuable attributes to this mechanism, which
   account for its usefulness.

   1.  The "HOSTNAME.BIND." or "ID.SERVER." query response mechanism is
       within the DNS protocol itself.  An identification mechanism that
       relies on the DNS protocol is more likely to be successful
       (although not guaranteed) in going to the same system as a
       "normal" DNS query.

   2.  Since the identity information is requested and returned within
       the DNS protocol, it doesn't require allowing any other query
       mechanism to the server, such as holes in firewalls for
       otherwise-unallowed ICMP Echo requests.  Thus it is likely to
       reach the same server over a path subject to the same routing,
       resource, and security policy as the query, without any special
       exceptions to site security policy.

   3.  It is simple to configure.  An administrator can easily turn on
       this feature and control the results of the relevant query.

   4.  It allows the administrator complete control of what information
       is given out in the response, minimizing passive leakage of
       implementation or configuration details.  Such details are often
       considered sensitive by infrastructure operators.

2.2.  Disadvantages

   At the same time, there are some serious drawbacks to the CHAOS/TXT
   query mechanism that argue against standardizing it as it currently
   operates.

   1.  It requires an additional query to correlate between the answer
       to a DNS query under normal conditions and the supposed identity
       of the server receiving the query.  There are a number of
       situations in which this simply isn't reliable.

   2.  It reserves an entire class in the DNS (CHAOS) for what amounts
       to one zone.  While CHAOS class is defined in [RFC1034] and
       [RFC1035], it's not clear that supporting it solely for this
       purpose is a good use of the namespace or of implementation
       effort.




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   3.  The initial and still common form, using "BIND.", is
       implementation specific.  BIND is one DNS implementation.  At the
       time of this writing, it is probably most prevalent for
       authoritative servers.  This does not justify standardizing on
       its ad hoc solution to a problem shared across many operators and
       implementors.  Meanwhile, the aforementioned refinement changes
       the query label but preserves the ad hoc CHAOS/TXT mechanism.

   4.  There is no convention or shared understanding of what
       information an answer to such a query for a server identity could
       or should contain, including a possible encoding or
       authentication mechanism.

   5.  Hypothetically, since DNSSEC has been defined to cover all DNS
       classes, the TXT RRs returned in response to the "ID.SERVER."
       query could be signed, which has the advantages described in
       [RFC4033].  However, since DNSSEC deployment for the CHAOS class
       is neither existent nor foreseeable, and since the "ID.SERVER."
       TXT RR is expected to be unique per server, this would be
       impossible in practice.

   The first of the listed disadvantages may be technically the most
   serious.  It argues for an attempt to design a good answer to the
   problem, "I need to know what nameserver is answering my queries",
   not simply a convenient one.

3.  Characteristics of an Implementation Neutral Convention

   The discussion above of advantages and disadvantages to the
   "HOSTNAME.BIND." mechanism suggest some requirements for a better
   solution to the server identification problem.  These are summarized
   here as guidelines for any effort to provide appropriate protocol
   extensions:

   1.  The mechanism adopted must be in-band for the DNS protocol.  That
       is, it needs to allow the query for the server's identifying
       information to be part of a normal, operational query.  It should
       also permit a separate, dedicated query for the server's
       identifying information.  But it should preserve the ability of
       the CHAOS/TXT query-based mechanism to work through firewalls and
       in other situations where only DNS can be relied upon to reach
       the server of interest.

   2.  The new mechanism should not require dedicated namespaces or
       other reserved values outside of the existing protocol mechanisms
       for these, i.e., the OPT pseudo-RR.  In particular, it should not
       propagate the existing drawback of requiring support for a CLASS




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       and top level domain in the authoritative server (or the querying
       tool) to be useful.

   3.  Support for the identification functionality should be easy to
       implement and easy to enable.  It must be easy to disable and
       should lend itself to access controls on who can query for it.

   4.  It should be possible to return a unique identifier for a server
       without requiring the exposure of information that may be non-
       public and considered sensitive by the operator, such as a
       hostname or unicast IP address maintained for administrative
       purposes.

   5.  It should be possible to authenticate the received data by some
       mechanism analogous to those provided by DNSSEC.  In this
       context, the need could be met by including encryption options in
       the specification of a new mechanism.

   6.  The identification mechanism should not be implementation-
       specific.

4.  IANA Considerations

   This document proposes no specific IANA action.  Protocol extensions,
   if any, to meet the requirements described are out of scope for this
   document.  A proposed extension, specified and adopted by normal IETF
   process, is described in [NSID], including relevant IANA action.

5.  Security Considerations

   Providing identifying information as to which server is responding to
   a particular query from a particular location in the Internet can be
   seen as information leakage and thus a security risk.  This motivates
   the suggestion above that a new mechanism for server identification
   allow the administrator to disable the functionality altogether or
   partially restrict availability of the data.  It also suggests that
   the server identification data should not be readily correlated with
   a hostname or unicast IP address that may be considered private to
   the nameserver operator's management infrastructure.

   Propagation of protocol or service meta-data can sometimes expose the
   application to denial of service or other attack.  As the DNS is a
   critically important infrastructure service for the production
   Internet, extra care needs to be taken against this risk for
   designers, implementors, and operators of a new mechanism for server
   identification.





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   Both authentication and confidentiality of server identification data
   are potentially of interest to administrators -- that is, operators
   may wish to make such data available and reliable to themselves and
   their chosen associates only.  This constraint would imply both an
   ability to authenticate it to themselves and to keep it private from
   arbitrary other parties, which leads to characteristics 4 and 5 of an
   improved solution.

6.  Acknowledgements

   The technique for host identification documented here was initially
   implemented by Paul Vixie of the Internet Software Consortium in the
   Berkeley Internet Name Daemon package.  Comments and questions on
   earlier versions were provided by Bob Halley, Brian Wellington,
   Andreas Gustafsson, Ted Hardie, Chris Yarnell, Randy Bush, and
   members of the ICANN Root Server System Advisory Committee.  The
   newest version takes a significantly different direction from
   previous versions, owing to discussion among contributors to the
   DNSOP working group and others, particularly Olafur Gudmundsson, Ed
   Lewis, Bill Manning, Sam Weiler, and Rob Austein.

7.  References

7.1.  Normative References

   [RFC1034]  Mockapetris, P., "Domain Names - Concepts and Facilities",
              STD 13, RFC 1034, November 1987.

   [RFC1035]  Mockapetris, P., "Domain Names - Implementation and
              Specification", STD 13, RFC 1035, November 1987.

   [RFC3258]  Hardie, T., "Distributing Authoritative Name Servers via
              Shared Unicast Addresses", RFC 3258, April 2002.

7.2.  Informative References

   [BIND]     ISC, "BIND 9 Configuration Reference".

   [NSID]     Austein, R., "DNS Name Server Identifier Option (NSID)",
              Work in Progress, June 2006.

   [RFC4033]  Arends, R., Austein, R., Larson, M., Massey, D., and S.
              Rose, "DNS Security Introduction and Requirements", RFC
              4033, March 2005.







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Authors' Addresses

   Suzanne Woolf
   Internet Systems Consortium, Inc.
   950 Charter Street
   Redwood City, CA  94063
   US

   Phone: +1 650 423-1333
   EMail: woolf@isc.org
   URI:   http://www.isc.org/


   David Conrad
   ICANN
   4676 Admiralty Way
   Marina del Rey, CA  90292
   US

   Phone: +1 310 823 9358
   EMail: david.conrad@icann.org
   URI:   http://www.iana.org/





























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Full Copyright Statement

   Copyright (C) The IETF Trust (2007).

   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.

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   The IETF invites any interested party to bring to its attention any
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Acknowledgement

   Funding for the RFC Editor function is currently provided by the
   Internet Society.







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