[Docs] [txt|pdf] [Tracker] [WG] [Email] [Diff1] [Diff2] [Nits]

Versions: 00 01 02 03

Internet Draft                                              Philip Hazel
draft-ietf-dnsop-dontpublish-unreachable-03.txt  University of Cambridge
Valid for six months                                       February 2002
Category: Best Current Practice

          IP Addresses that should never appear in the public DNS

      Copyright (C) The Internet Society (2002).  All Rights Reserved.

Status of this Memo

   This document is an Internet-Draft and is in full conformance with
   all provisions of Section 10 of RFC2026.

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF), its areas, and its working groups.  Note that
   other groups may also distribute working documents as Internet-

   Internet-Drafts are draft documents valid for a maximum of six months
   and may be updated, replaced, or obsoleted by other documents at any
   time.  It is inappropriate to use Internet-Drafts as reference
   material or to cite them other than as "work in progress."

   The list of current Internet-Drafts can be accessed at

   The list of Internet-Draft Shadow Directories can be accessed at


   This document specifies an Internet Best Current Practice for the
   Internet Community. It has two themes. Firstly, it reinforces the
   prohibition in [RFC 1918] about the appearance of private IP
   addresses in publicly visible DNS records, and extends the
   discussion to include IPv6 addresses.

   Secondly, the document discusses the problems that can be caused
   by the appearance of public addresses, or indirect references to
   them, when the service implied by the address or reference is
   inaccessible from the public Internet.

   Specifying a blanket prohibition in the second case is difficult
   because inaccessibility may arise from many causes, some possibly
   legitimate. Instead, the document points out some of the problems
   that can arise, and suggests that other means of achieving the
   desired effects should be used wherever possible.

1. Introduction

   The increasing use of firewalls, NAT boxes, and similar technology
   has resulted in the fragmentation of the Internet into regions whose
   boundaries do not allow general connectivity. There are two primary
   reasons for this:

   (1) The perceived shortage of IPv4 addresses has caused increasing
   use of private IPv4 network addresses such as on LANs. A
   number of such private address ranges are designated in [RFC 1918],
   and others may be also assigned by IANA.

[Note: For example, there's 169.254/16, which is mentioned in
draft-ietf-zeroconf-ipv4-linklocal-04.txt, but since that's still a
draft, I can't cite it.]

   IPv6 addresses are not in short supply, but the IPv6 architecture
   uses a scoped address model, in which non-global addresses have
   limited reachability and domains of uniqueness. For instance, site-
   local addresses are reachable only within a particular site.

   Hosts using private addresses that wish to communicate with the
   public Internet must do so via an address translation mechanism such
   as a NAT box. This allows a host with a private address to send
   packets to public Internet hosts, and to receive replies. However,
   unsolicited incoming packets cannot reach these hosts from outside
   their own private network.

   (2) Increasing security concerns have caused many sites to install
   firewalls or to implement restrictions in their boundary routers in
   order to lock out certain kinds of connection to their hosts, even
   when the hosts are using public Internet addresses, though in many
   cases firewalls also provide NAT functionality.

   Thus, there are two classes of host which some or all types of
   unexpected incoming packet from the public Internet cannot reach:
   those using truly private IPv4 or IPv6 addresses, and those using
   public addresses where access is blocked.

   A number of instances have been observed where IP addresses that are
   never accessible from the public Internet have nevertheless been
   inserted into resource records in the public DNS. This document seeks
   to prohibit such behaviour in the case of truly private addresses,
   and to discourage it in the case of public, but unreachable,

   Although this document is specifically concerned with the contents of
   the public DNS, the principle of not publishing private IP addresses
   is applicable to any other form of general publication.

   The keywords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   document are to be interpreted as described in [RFC 2119].

   The phrase "address record" means an A record or an AAAA record, or
   any other kind of name-to-address record that may come into use.

2. Private network addresses

   Examples of [RFC 1918] private host addresses are and In the case of IPv6, all link-local and site-local
   addresses are private.

   Packets cannot be routed to such addresses from the public Internet.
   [RFC 1918] explains this in section 3, from where this paragraph is

      Because private addresses have no global meaning, routing
      information about private networks shall not be propagated on
      inter-enterprise links, and packets with private source or
      destination addresses should not be forwarded across such links.
      Routers in networks not using private address space, especially
      those of Internet service providers, are expected to be
      configured to reject (filter out) routing information about
      private networks.

   Because the same private addresses are in use in many different
   organizations, they are ambiguous. The appearance of private
   addresses in the DNS could therefore lead to unpredictable and
   unwanted behaviour. Consider this set of entries:

      @       IN      MX  10  smtp
      smtp    IN      A
      smtp    IN      A

   The MX record resolves to two IP addresses, one of which is private
   and one of which is public. Zones set up in this way have been seen,
   and some administrators apparently believe this is useful, because
   it allows mail on their local network to be delivered straight to
   the internal server (the one with address However, this
   approach breaks down when a host on a foreign network that is also
   using the address attempts to send mail to the domain.

   In section 5 of [RFC 1918] there is a prohibition of the appearance
   of private addresses in publicly visible DNS records. It says:

      If an enterprise uses the private address space, or a mix of
      private and public address spaces, then DNS clients outside of
      the enterprise should not see addresses in the private address
      space used by the enterprise, since these addresses would be

   The wording "should not" is not a very strong prohibition,
   considering the interworking problems that ignoring it can cause.
   Therefore, this document makes a stronger statement:

   Public DNS zones MUST NOT contain [RFC 1918] addresses, IPv6 link-
   local or site-local addresses, or any other addresses designated
   by IANA as private, in any resource records where the context makes
   them appear to be globally-meaningful addresses.

3. Public network addresses that are inacessible

   The situation with public network addresses is more complicated
   because the Internet cannot in general be cleanly divided into
   "public" and "private" parts in this case. Examples of situations
   where the division is fuzzy are:

   (1) A host with a public address that is behind a firewall may be
   accessible for SSH sessions, but not for SMTP sessions. That is,
   the blocking may apply only to certain ports.

   (2) A host with a public address may make certain services available
   only to specific client hosts, for example, those in partner
   enterprises, or those in a specific geographic area.

   (3) A host might respond to incoming packets only if the client host
   is using IPsec.

   When a host is providing any service at all over the public Internet,
   a publicly visible address record is of course required to give
   access to that host.

   However, for some protocols and services, additional DNS records
   are defined that reference hosts' address records. These are the NS
   record for name servers, the MX record for SMTP, and the SRV record
   for other services. The existence of such indirect records advertises
   the availability of the relevant service.

   If these services are always inaccessible over the public Internet,
   it is bad practice to include the NS, MX or SRV records in public DNS
   zones, for the following reason:

   A host that tries to connect to an unreachable address (or port)
   may not receive an immediate rejection; in many cases the connection
   will fail only after a timeout expires. The wasted effort ties up
   resources on the calling host and the network, possibly for some
   considerable time (SMTP timeouts, for example, are of the order of
   minutes). It may also cause a gratuitous slowing down of the

   Furthermore, in the case of dial-up connections, ISDN, or other kinds
   of usage-based charged network connection, the wasted network
   resources may cost real money.

   Public DNS zones SHOULD NOT contain NS, MX or SRV records that point
   to hosts for which the relevant services are never accessible over the
   public Internet. In other words, if there is no host that is able to
   make use of the service using the public Internet, the service SHOULD
   NOT be publicly advertised.

4. Other kinds of IPv6 address

4.1 Anycast addresses

  Anycast addresses should be treated as global addresses with limited

4.2 Multicast addresses

  Scoped multicast addresses (multicast addresses with a 4 bit scope
  value less than 0x0e) MUST NOT be put into public DNS zones. Globally-
  scoped multicast addresses MAY be put into public DNS zones.

4.3 IPv4-mapped addresses

  IPv4-mapped addresses MUST NOT be put into public DNS zones, because
  their use is limited to an internal representation of IPv4 peers within
  the AF_INET6 socket API [RFC 2553].

4.4 IPv4-compatible addresses

  IPv4-compatible addresses MUST NOT be put into public DNS zones.
  Although there might be a case for doing so in order to indicate
  that the node is willing to accept auto-tunnelled packets [RFC 2893],
  it is not clear that this transition mechanism will be widely used.
  It is therefore preferable to keep the DNS operationally "clean" by
  not allowing them.

5. Loopback addresses

   The loopback addresses ( for IPv4 and ::1 for IPv6) are
   another form of private address. There has been a practice of including
   them in DNS zones for two entirely different reasons.

5.1 The name "localhost"

   Some hostmasters include records of this type in their zones:

     localhost.some.domain.example.  A

   The reason for doing this is so that other hosts in the domain
   that use the DNS for all their name resolution can make use of the
   unqualified name "localhost". This works because DNS resolvers
   normally add the local enclosing domain to unqualified names.

   DNS zones MAY make use of this technique for the name "localhost"
   only, if it is required in their environment, but SHOULD avoid it
   if possible. See section 6.1 below for an alternative technique.

5.2 DNS "black lists"

   There is an  increasingly popular practice of creating "black
   lists" of misbehaving hosts (for example, open mail relays) in
   the DNS. The first of these was the "Realtime Blackhole List"
   (RBL). Such lists make use of address values in the
   network in DNS address records to give information about listed
   hosts (which are looked up via their inverted IP addresses).

   Such records are in specific "black list" domains, and are well
   understood not to be invitations to attempt connections to the
   addresses they publish. In other words, the values that appear
   in these records do not appear in a context where they are
   interpreted as IP addresses.

   DNS zones MAY continue to make use of this technique.

5.3 Other uses of loopback networks

   Apart from the exceptions mentioned in 5.1 and 5.2 above, the
   loopback addresses MUST NOT appear in address records in the public
   DNS, unless it is clear from the context that the value is not to be
   interpreted as an IP address.

5.4 References to loopback addresses

   When address records that contain loopback addresses do exist,
   DNS zones MUST NOT contain indirect records (NS, MX or SRV) that
   reference them.

6. Alternative techniques

6.1 Handling "localhost"

   Instead of including "localhost" within every domain for which a name
   server is authoritative, [RFC 1912] recommends setting up "localhost."
   as a top-level domain in each name server. [RFC 2606] reserves the
   name "localhost." for this purpose.

6.2 Splitting DNS zones

   A site that is using private addresses may well want to use DNS
   lookups for address resolution on its hosts. The lazy way approach is
   simply to put the data into the public DNS zone, as in the example
   shown in section 2 above. Because this can cause problems for
   external hosts, this MUST NOT be done.

   One approach that is commonly taken is to run a so-called "split
   DNS". Two different authoritative servers are created: one containing
   all the zone data is accessible only from within the private network.
   External DNS queries are directed to the second server, which
   contains a filtered version of the zone, without the private

6.3 SMTP servers behind firewalls

   The complication of a split DNS is not normally needed if it is only
   SMTP traffic that is being blocked to a public address on a host
   behind a firewall. Setting up MX records like this:

     plc.example.   MX   5   mail.plc.example.
                    MX  10   public.plc.example.

   where both hosts have public IP addresses, but the first is blocked
   at the firewall, SHOULD NOT be done. Only the publicly accessible
   host should be used:

     plc.example.   MX  10   public.plc.example.

   If a split DNS is in use, the host public.plc.example can use the
   internal version to route the mail onwards. However, most MTAs have
   configuration facilities to allow for explicit routing of mail, without
   the need to use a DNS lookup.

6.4 Specification of no SMTP service

   MX records that point to host names whose address records specify the
   loopback address have been seen in the DNS. This seems to be a
   misguided attempt to specify "no SMTP service for this domain" more
   positively than just refusing connections to the SMTP port. (A refused
   connection is treated as a temporary error, because it might be the
   result of a system rebooting, for example.)

   If such a facility is required, it SHOULD instead be done by
   arranging for the hosts in question to return

     554 No SMTP service here

   to all SMTP connections.

7. Security Considerations

   This document is not known to create new security issues in the DNS,
   mail agents, etc. In some sense, it may reduce security exposure by
   insisting that a site's inappropriate internal data not be exposed.

8. IANA Considerations

   No IANA actions are required by this document.

9. Acknowledgements

   Randy Bush read an early draft of this document and suggested several

   Draft 01 has benefitted from comments made by Daniel Senie, John
   Schnizlein, Robert Elz, Bert Hubert, and Stuart Cheshire.

   Draft 02 has benefitted from comments made by David Keegel and Simon

   Draft 03 has benefitted from comments made by Jun-ichiro itojun
   Hagino, David Terrell, Erik Nordmark, Matt Larson, and Zefram.

10. Author's Address

   Philip Hazel
   University of Cambridge Computing Service
   New Museums Site, Pembroke Street
   Cambridge CB2 3QH, England

   Phone: + 44 1223 334714
   Email: ph10@cam.ac.uk

11. References

   [RFC 1912]  Barr, D. "Common DNS Operational and Configuration
               Errors", RFC 1912, February 1996.

   [RFC 1918]  Rekhter, Y. et al "Address allocation for Private
               Internets", BCP 5, RFC 1918, February 1996.

   [RFC 2119]  Bradner, S. "Key words for use in RFCs to Indicate
               Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC 2553]  Gilligan, S. et al "Basic Socket Interface Extensions
               for IPv6", RFC 2553, March 1999.

   [RFC 2606]  Eastlake, D. and Panitz, A. "Reserved Top Level DNS
               Names", BCP 32, RFC 2606, June 1999.

   [RFC 2893]  Gilligan, R. and Nordmark, E. "Transition Mechanisms
               for IPv6 Hosts and Routers", RFC 2893, August 2000.

12. Changes made during development of this document

   This section is provided for the convenients of those tracking the
   document. It will be removed from the final draft.

12.1 Changes made to the -00 version to create -01

   . While leaving the MUSTs in for truly private addresses, I've tried
   to be more "educational" about the case of public addresses that are
   inaccessible, and backed down to SHOULD in those cases.

   . I've pointed out the lack of a clear-cut public/private boundary,
   and tried to make the case for not advertising unavailable services
   without being so probititive in the wording. This includes using
   "never accessible" instead of "not accessible".

   . Changed "hostmaster" to "zone" in a couple of cases.

   . Included an example of bad MX practice with an [RFC 1918] address.

   . Noted that [RFC 1918] is not the only list of private addresses.

   . General tidying of the wording and rearrangement of the material.

   . The Post Office changed our postcode!

12.2 Changes made to the -01 version to create -02

   . Add NS to MX and SRV as another DNS record that advertises a service

   . Changed the address in an example to a genuine real address
   to make it quite clear what I mean.

   . Added "geographic area" as another example of a service restriction.

   . Suggested why people might want something other than "connection
   refused" from hosts that don't provide SMTP service.

   . Some other very minor rewording.

12.3 Changes made to the -02 version to create -03

   . Added more words about IPv6, with detail supplied by Jun-ichiro
   itojun Hagino about specific kinds of IPv6 address.

   . Added a references to RFCs 1912 and 2606 for the handling of
   "localhost" by setting it up as a TLD.

   . Generalized ideas such as "black hole lists" to talk about the
   context of interpretation of addresses.

   . Added a short statement about other (non-DNS) forms of publication.

Full Copyright Statement

   Copyright (C) The Internet Society (2002).  All Rights Reserved.

   This document and translations of it may be copied and furnished to
   others, and derivative works that comment on or otherwise explain it
   or assist in its implementation may be prepared, copied, published
   and distributed, in whole or in part, without restriction of any
   kind, provided that the above copyright notice and this paragraph are
   included on all such copies and derivative works.  However, this
   document itself may not be modified in any way, such as by removing
   the copyright notice or references to the Internet Society or other
   Internet organizations, except as needed for the purpose of
   developing Internet standards in which case the procedures for
   copyrights defined in the Internet Standards process must be
   followed, or as required to translate it into languages other than

   The limited permissions granted above are perpetual and will not be
   revoked by the Internet Society or its successors or assigns.

   This document and the information contained herein is provided on an


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

Html markup produced by rfcmarkup 1.123, available from https://tools.ietf.org/tools/rfcmarkup/