Network Working Group M. Hamilton
Request for Comments: 2219 Loughborough University
BCP: 17 R. Wright
Category: Best Current Practice Lawrence Berkeley Laboratory
Use of DNS Aliases for Network Services
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.
It has become a common practice to use symbolic names (usually
CNAMEs) in the Domain Name Service (DNS - [RFC-1034, RFC-1035]) to
refer to network services such as anonymous FTP [RFC-959] servers,
Gopher [RFC-1436] servers, and most notably World-Wide Web HTTP
[RFC-1945] servers. This is desirable for a number of reasons. It
provides a way of moving services from one machine to another
transparently, and a mechanism by which people or agents may
programmatically discover that an organization runs, say, a World-
Wide Web server.
Although this approach has been almost universally adopted, there is
no standards document or similar specification for these commonly
used names. This document seeks to rectify this situation by
gathering together the extant 'folklore' on naming conventions, and
proposes a mechanism for accommodating new protocols.
It is important to note that these naming conventions do not provide
a complete long term solution to the problem of finding a particular
network service for a site. There are efforts in other IETF working
groups to address the long term solution to this problem, such as the
Server Location Resource Records (DNS SRV) [RFC-2052] work.
In order to locate the network services offered at a particular
Internet domain one is faced with the choice of selecting from a
growing number of centralized databases - typically Web or Usenet
News "wanderers", or attempting to infer the existence of network
services from whatever DNS information may be available. The former
approach is not practical in some cases, notably when the entity
seeking service information is a program.
Perhaps the most visible example of the latter approach at work is in
the case of World-Wide Web HTTP servers. It is common practice to
try prefixing the domain name of an organization with "http://www."
in order to reach its World-Wide Web site, e.g. taking "hivnet.fr"
and arriving at "http://www.hivnet.fr." Some popular World-Wide Web
browsers have gone so far as to provide automatic support for this
domain name expansion.
Ideally, the DNS or some complementary directory service would
provide a means for programs to determine automatically the network
services which are offered at a particular Internet domain, the
protocols which are used to deliver them, and other technical
information. Unfortunately, although much work has been done to
develop said directory service technologies and to define new types
of DNS resource record to provide this type of information, there is
no widely agreed upon or widely deployed solution to the problem -
except in a small number of cases.
The first case is where the DNS already provides a lookup capability
for the type of information being sought after. For example: Mail
Exchanger (MX) records specify how mail to a particular domain should
be routed [RFC-974], the Start of Authority (SOA) records make it
possible to determine who is responsible for a given domain, and Name
Server (NS) records indicate which hosts provide DNS name service for
a given domain.
The second case is where the DNS does not provide an appropriate
lookup capability, but there is some widely accepted convention for
finding this information. Some use has been made of Text (TXT)
[RFC-1035] records in this scenario, but in the vast majority of
cases a Canonical Name (CNAME) or Address (A) record pointer is used
to indicate the host or hosts which provide the service. This
document proposes a slight formalization of this well-known alias
It should be noted that the DNS provides a Well Known Services (WKS)
[RFC-1035] lookup capability, which makes it possible to determine
the network services offered at a given domain name. In practice
this is not widely used, perhaps because of the absence of a suitable
programming interface. Use of WKS for mail routing was deprecated in
the Host Requirements specification [RFC-1123] in favour of the MX
record, and in the long term it is conceivable that SRV records will
supersede both WKS and MX.
2. A generic framework
Our approach to dealing with aliases for protocols is
straightforward. We define a standard set of DNS aliases for the most
popular network services that currently exist (see the "Special
Cases" section below). For protocols that are not explicitly listed
in this document, the protocol specification must propose a name.
3. Special cases
archie archie [ARCHIE]
finger Finger [RFC-1288]
ftp File Transfer Protocol [RFC-959]
gopher Internet Gopher Protocol [RFC-1436]
ldap Lightweight Directory Access Protocol [RFC-1777]
mail SMTP mail [RFC-821]
news Usenet News via NNTP [RFC-977]
ntp Network Time Protocol [RFC-1305]
ph CCSO nameserver [PH]
pop Post Office Protocol [RFC-1939]
rwhois Referral WHOIS [RFC-1714]
wais Wide Area Information Server [RFC-1625]
whois NICNAME/WHOIS [RFC-954]
www World-Wide Web HTTP [RFC-1945]
4. (Ab)Use of the DNS as a directory service
The widespread use of these common aliases effectively means that it
is sometimes possible to "guess" the domain names associated with an
organization's network services, though this is becoming more
difficult as the number of organizations registered in the DNS
It should be understood by implementors that the existence of a DNS
entry such as
does not constitute a registration of a World-Wide Web service.
There is no requirement that the domain name resolve to an IP address
or addresses. There is no requirement that a host be listening for
HTTP connections, or if it is, that the HTTP server be running on
port 80. Finally, even if all of these things are true, there can be
no guarantee that the World-Wide Web server will be prepared to honor
requests from arbitrary clients.
Having said this, the aliases do provide useful "hints" about the
services offered. We propose that they be taken in this spirit.
The conventions described in this document are, essentially, only
useful when the organization's domain name can be determined - e.g.
from some external database. A number of groups, including the IETF,
have been working on ways of finding domain names given a set of
information such as organization name, location, and business type.
It is hoped that one or more of these will eventually make it
possible to augment the basic lookup service which the DNS provides
with a more generalized search and retrieval capability.
5. DNS server configuration
In the short term, whilst directory service technology and further
types of DNS resource record are being developed, domain name
administrators are encouraged to use these common names for the
network services they run. They will make it easier for outsiders to
find information about your organization, and also make it easier for
you to move services from one machine to another.
There are two conventional approaches to creating these DNS entries.
One is to add a single CNAME record to your DNS server's
ph.hivnet.fr. IN CNAME baby.hivnet.fr.
Note that in this scenario no information about ph.hivnet.fr should
exist in the DNS other than the CNAME record. For example,
ph.hivnet.fr could not contain a MX record.
An alternative approach would be to create an A record for each of
the IP addresses associated with ph.hivnet.fr, e.g.
ph.hivnet.fr. IN A 22.214.171.124
It isn't a simple matter of recommending CNAMEs over A records. Each
site has it's own set of requirements that may make one approach
better than the other. RFC 1912 [RFC-1912] discusses some of the
configuration issues involved in using CNAMEs.
Recent DNS server implementations provide a "round-robin" feature
which causes the host's IP addresses to be returned in a different
order each time the address is looked up.
Network clients are starting to appear which, when they encounter a
host with multiple addresses, use heuristics to determine the address
to contact - e.g. picking the one which has the shortest round-trip-
time. Thus, if a server is mirrored (replicated) at a number of
locations, it may be desirable to list the IP addresses of the mirror
servers as A records of the primary server. This is only likely to
be appropriate if the mirror servers are exact copies of the original
6. Limitations of this approach
Some services require that a client have more information than the
server's domain name. For example, an LDAP client needs to know a
starting search base within the Directory Information Tree in order
to have a meaningful dialogue with the server. This document does
not attempt to address this problem.
7. CCSO service name
There are currently at least three different aliases in common use
for the CCSO nameserver - e.g. "ph", "cso" and "ns". It would appear
to be in everyone's interest to narrow the choice of alias down to a
single name. "ns" would seem to be the best choice since it is the
most commonly used name. However, "ns" is also being used by DNS to
point to the DNS server. In fact, the most prevalent use of "ns" is
to name DNS servers. For this reason, we suggest the use of "ph" as
the best name to use for CCSO nameservers.
Sites with existing CCSO servers using some of these aliases may find
it desirable to use all three. This increases the likelihood of the
service being found.
As noted earlier, implementations should be resilient in the event
that the name does not point to the expected service.
8. Security Considerations
The DNS is open to many kinds of "spoofing" attacks, and it cannot be
guaranteed that the result returned by a DNS lookup is indeed the
genuine information. Spoofing may take the form of denial of
service, such as directing of the client to a non-existent address,
or a passive attack such as an intruder's server which masquerades as
the legitimate one.
Work is ongoing to remedy this situation insofar as the DNS is
concerned [RFC-2065]. In the meantime it should be noted that
stronger authentication mechanisms such as public key cryptography
with large key sizes are a pre-requisite if the DNS is being used in
any sensitive situations. Examples of these would be on-line
financial transactions, and any situation where privacy is a concern
- such as the querying of medical records over the network. Strong
encryption of the network traffic may also be advisable, to protect
against TCP connection "hijacking" and packet sniffing.
The service names listed in this document provide a sensible set of
defaults which may be used as an aid in determining the hosts which
offer particular services for a given domain name.
This document has noted some exceptions which are either inherently
unsuitable for this treatment, or already have a substantial
installed base using alternative aliases.
Thanks to Jeff Allen, Tom Gillman, Renato Iannella, Thomas
Lenggenhager, Bill Manning, Andy Powell, Sri Sataluri, Patrik
Faltstrom, Paul Vixie and Greg Woods for their comments on draft
versions of this document.
This work was supported by UK Electronic Libraries Programme (eLib)
grant 12/39/01, the European Commission's Telematics for Research
Programme grant RE 1004, and U. S. Department of Energy Contract
Request For Comments (RFC) documents are available from
<URL:ftp://ftp.internic.net/rfc> and numerous mirror sites.
[ARCHIE] A. Emtage, P. Deutsch. "archie - An Electronic
Directory Service for the Internet", Winter Usenix
Conference Proceedings 1992. Pages 93-110.
[PH] R. Hedberg, S. Dorner, P. Pomes. "The CCSO
Nameserver (Ph) Architecture", Work in Progress.
[RFC-768] Postel, J., "User Datagram Protocol", STD 6, RFC 768,
[RFC-793] Postel, J., "Transmission Control Protocol", STD 7,
RFC 793, September 1981.
[RFC-821] Postel, J., "Simple Mail Transfer Protocol", STD 10,
RFC 821, August 1982.
[RFC-954] Harrenstien, K., Stahl, M., and E. Feinler,
"NICNAME/WHOIS", RFC 954, October 1985.
[RFC-959] Postel, J., and J.K. Reynolds, "File Transfer
Protocol", STD 9, RFC 959, October 1985.
[RFC-974] Partridge, C., "Mail routing and the domain
System", STD 14, RFC 974, January 1986.
[RFC-977] Kantor, B., and P. Lapsley, "Network News Transfer
Protocol", RFC 977, February 1986.
[RFC-1034] Mockapetris, P., "Domain names - concepts and
facilities", STD 13, RFC 1034, November 1987.
[RFC-1035] Mockapetris, P., "Domain names - implementation
and specification", STD 13, RFC 1035, November 1987.
[RFC-1123] Braden, R., "Requirements for Internet hosts -
application and support", STD 3, RFC 1123, October 1989.
[RFC-1288] Zimmerman, D., "The Finger User Information
Protocol", RFC 1288, December 1992.
[RFC-1305] Mills, D., "Network Time Protocol (Version 3)
Specification, Implementation", RFC 1305, March 1992.
[RFC-1436] Anklesaria, F., McCahill, M., Lindner, P., Johnson, D.,
Torrey, D., and B. Albert, "The Internet Gopher Protocol
(a distributed document search and retrieval protocol)",
RFC 1436, March 1993.
[RFC-1590] Postel, J., "Media Type Registration Procedure",
RFC 1590, March 1994.
[RFC-1625] St. Pierre, M., Fullton, J., Gamiel, K., Goldman, J.,
Kahle, B., Kunze, J., Morris, H., and F. Schiettecatte,
"WAIS over Z39.50-1988", RFC 1625, June 1994.
[RFC-1700] Reynolds, J.K., and J. Postel, "ASSIGNED NUMBERS",
STD 2, RFC 1700, October 1994.
[RFC-1714] Williamson, S., and M. Kosters, "Referral Whois
Protocol (RWhois)", RFC 1714, November 1994.
[RFC-1777] Yeong, W., Howes, T., and S. Kille, "Lightweight
Directory Access Protocol", RFC 1777, March 1995.
[RFC-1912] Barr, D., "Common DNS Operational and Configuration
Errors", RFC 1912, Feburary 1996.
[RFC-1939] Myers, J., and M. Rose, "Post Office Protocol - Version
3", STD 53, RFC 1939, May 1996.
[RFC-1945] Berners-Lee, T., Fielding, R., and H. Nielsen,
"Hypertext Transfer Protocol -- HTTP/1.0", RFC 1945, May
[RFC-2052] Gulbrandsen, A., and P. Vixie, "A DNS RR for specifying
the location of services (DNS SRV)", RFC 2052, October
[RFC-2065] Eastlake, D., and C. Kaufman, "Domain Name System
Security Extensions", RFC 2065, January 1997.
12. Authors' Addresses
Department of Computer Studies
Loughborough University of Technology
Leics. LE11 3TU, UK
Information & Computing Sciences Division
Lawrence Berkeley National Laboratory
1 Cyclotron Road, Berkeley
CA 94720, USA