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Network Working Group Alain Durand
INTERNET-DRAFT SUN Microsystems, inc.
October 25, 2002 Jun-ichiro itojun Hagino
Expires April 2002 IIJ Research Laboratory
Dave Thaler
Microsoft
Well known site local unicast addresses
to communicate with recursive DNS servers
<draft-ietf-ipv6-dns-discovery-07.txt>
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-
Drafts.
Internet Drafts are 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 a "work in progress".
To view the list Internet-Draft Shadow Directories, see
http://www.ietf.org/shadow.html.
Abstract
This documents specifies 3 well known addresses to configure stub
resolvers on IPv6 nodes to enable them to communicate with recursive
DNS server with minimum configuration in the network and without
running a discovery protocol on the end nodes. This method may be
used when no other information about the addresses of recursive DNS
servers is available. Implementation of stub resolvers using this as
default configuration must provide a way to override this.
Copyright notice
Copyright (C) The Internet Society (2002). All Rights Reserved.
1. Introduction
RFC 2462 [ADDRCONF] provides a way to autoconfigure nodes with one or
more IPv6 address and default routes.
However, for a node to be fully operational on a network, many other
parameters are needed, such as the address of a name server that
offer recursive service (a.k.a. recursive DNS server), mail relays,
web proxies, etc. Except for name resolution, all the other services
are usually described using names, not addresses, such as
smtp.myisp.net or webcache.myisp.net. For obvious bootstrapping
reasons, a node needs to be configured with the IP address (and not
the name) of a recursive DNS server. As IPv6 addresses look much
more complex than IPv4 ones, there is some incentive to make this
configuration as automatic and simple as possible.
Although it would be desirable to have all configuration parameters
configured/discovered automatically, it is common practice in IPv4
today to ask the user to do manual configuration for some of them by
entering server names in a configuration form. So, a solution that
will allow for automatic configuration of the recursive DNS server is
seen as an important step forward in the autoconfiguration story.
The intended usage scenario for this proposal is a home or enterprise
network where IPv6 nodes are plugged/unplugged with minimum
management and use local resources available on the network to
autoconfigure. This proposal is also useful in cellular networks
where all mobile devices are included within the same site.
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 [KEYWORDS].
2. Well known addresses vs discovery
Some of the discussions in the past around DNS server discovery have
been trying to characterize the solution space into stateless versus
stateful or server oriented versus severless. It is not absolutely
clear how much state if any needs to be kept to perform DNS server
discovery, and, although the semantic differences between a router
and a server are well understood from a conceptual perspective, the
current implementations tend to blur the picture. In another attempt
to characterize different approaches, one can look at how much
intelligence a client needs to have in order to use the service.
One avenue is to ask the IPv6 node to participate in a discovery
protocol, such as SLP or DHCP, learn the address of the server and
send packets to this server. Another one is to configure the IPv6
node with well known addresses and let the local routing system
forward packets to the right place. This document explores this
later avenue of configuration using well known addresses that does
not require participation of the end node in any discovery mechanism.
3. Reserved prefix and addresses
The mechanism described here is:
- intended for ongoing use and not not just for bootstrapping
- intended to populate a stub resolver's list of available
recursive servers only if that list is otherwise unpopulated
- providing reliability through redundancy using three unicast
addresses.
3.1 Stub resolver configuration
This memo reserved three well known IPv6 site local addresses.
In the absence of any other information about the addresses of
recursive DNS servers, IPv6 stub-resolvers MAY use any of those three
IPv6 addresses in their list of candidate recursive DNS servers.
3.2 Recursive DNS servers configuration
Within sites, one or more recursive DNS server SHOULD be configured
with any of those three addresses. It is RECOMMENDED that large sites
deploy 3 recursive DNS servers, one for each reserved address. Small
site could use only one recursive DNS server and assign the 3
addresses to it.
3.3 Rationale for the choice of three addresses
Three was chosen based on common practice in many places in the
industry. While it's true that if the first one fails, that it's
unlikely the second one will succeed (due to there really being no
DNS server at all), using multiple addresses is important so that
when ones do exist, the host can fail over to a second server more
quickly than routing converges. Three servers is a compromise between
extra reliability and increased complexity (maintaining additional
servers, having multiple entries in the routing system, additional
delays before the stub resolver returns an error,...).
Another reason to have multiple addresses is to avoid the need to use
of anycast addresses to achieve reliability through redundancy. On
top of the classic problems (TCP sessions, ICMP messages,...) using
an anycast address would hide the real locations of the recursive DNS
servers to the stub resolver, prohibiting it to keep track of which
servers are performing correctly. For this particular matter, using
well known addresses is no different than configuring the stub
resolver with regular addresses taken from the local site.
3.4 Implementation considerations
Stub resolver implementation MAY be configured by default using those
addresses. However, implementing only the mechanism described in this
memo may end up causing some interoperability problems when operating
in networks where no recursive DNS server is configured with any of
the well known addresses. Thus, stub resolvers MUST implement
mechanisms for overriding this default, for example: manual
configuration, L2 mechanisms and/or DHCPv6.
4. Routing
A solution to enable the stub resolvers to reach the recursive DNS
servers is to inject host routes in the local routing system.
Examples of methods for injecting host routes and a brief discussion
of their fate sharing properties are presented here:
a) Manual injection of routes by a router on the same subnet.
If the node running the recursive DNS server goes down, the router
may or may not be notified and keep announcing the route.
b) Running a routing protocol on the same node running the DNS
resolver.
If the process running the recursive DNS server dies, the routing
protocol may or may not be notified and keep announcing the route.
c) Running a routing protocol within the same process running the
recursive DNS server.
If the recursive DNS server and the routing protocol run in
separated threads, similar concerns as above are true.
d) Developing an "announcement" protocol that the recursive DNS
server could use to advertize the host route to the nearby router.
Details of such a protocol are out of scope of this document, but
something similar to [MLD] is possible. However, the three first
mechanisms should cover most cases.
An alternate solution is to configure a link with the well known
prefix and position the three recursive DNS servers on that link.
The advantage of this method is that host routes are not necessary ,
the well known prefix is advertised to the routing system by the
routers on the link. However, in the event of a problem on the
physical link, all resolvers will become unreachable.
IANA considerations for this prefix are covered in Section 6.
5. Site local versus global scope considerations
The rationales for having a site local prefix are:
-a) Using a site local prefix will ensure that the traffic to the
recursive DNS servers stays local to the site. This will prevent
the DNS requests from accidentally leaking out of the site.
However, the local resolver can implement a policy to forward DNS
resolution of non-local addresses to an external DNS resolver.
-b) Reverse DNS resolution of site local addresses is only
meaningful within the site. Thus, making sure that such queries
are first sent to a recursive DNS server located within the site
perimeter increase their likelihood of success.
6. Examples of use
This section presents example scenarios showing how the mechanism
described in this memo can co-exist with other techniques, namely
manual configuration and DHCPv6 discovery.
Note: those examples are just there to illustrate some usage
scenarios and in no way do they suggest any recommended practices.
6.1 Simple case, general purpose recursive DNS server
This example shows the case of a network that manages one recursive
DNS server and a large number of nodes running DNS stub resolvers.
The recursive DNS server is performing (and caching) all the
recursive queries on behalf of the stub resolvers. The recursive DNS
server is configured with an IPv6 address taken from the prefix
delegated to the site and with the 3 well known addresses defined in
this memo. The stub resolvers are either configured with the "real"
IPv6 address of the recursive DNS server or with the well known site
local unicast addresses defined in this memo.
--------------------------------------------
| |
| --------------------- |
| |DNS stub resolver | |
| |configured with the| |
| |"real" address of | |
| |the recursive DNS | |
| |server | |
| --------------------- |
| ----------- | |
| |recursive| | |
| |DNS |<---------- |
| |server |<---------------- |
| ----------- | |
| ---------------------- |
| |DNS stub resolver | |
| |configured with 3 | |
| |well known addresses| |
| ---------------------- |
| |
--------------------------------------------
(The recursive DNS server is configured to listen both on
its IPv6 address and on the well known address)
6.2 Three recursive DNS servers
This is a similar example as above, except that three recursive DNS
resolvers are configured instead of just one.
-------------------------------------------
| |
| --------------------- |
| |DNS stub resolver | |
| |configured with the| |
| |"real" address of | |
| |the recursive DNS | |
| |server | |
| --------------------- |
| | |
| ----------- | |
| |recursive| | |
| |DNS |<---------| |
| |server 1 |<---------|------ |
| ----------- | | |
| | | |
| ----------- | | |
| |recursive| | | |
| |DNS |<---------| | |
| |server 2 |<---------|-----| |
| ----------- | | |
| | | |
| ----------- | | |
| |recursive| | | |
| |DNS |<---------- | |
| |server 3 |<---------------| |
| ----------- | |
| ---------------------- |
| |DNS stub resolver | |
| |configured with 3 | |
| |well known addresses| |
| ---------------------- |
| |
-------------------------------------------
(The recursive DNS server is configured to listen both on
its IPv6 address and on the well known address)
6.3 DNS forwarder
A drawback of the choice of site local scope for the reserved
addresses for recursive DNS server is that, in the case of a
home/small office network connected to an ISP, DNS traffic cannot be
sent directly to the ISP recursive DNS server without having the ISP
and all its customers share the same definition of site.
In this scenario, the home/small office network is connected to the
ISP router (PE) via an edge router (CPE).
-------------
/ |
-------- ----- / |
|ISP PE| |CPE| / Customer |
| |===========| |====< site |
| | | | \ |
-------- ----- \ |
\ |
-------------
The customer router CPE could be configured on its internal interface
with one of the reserved site local addresses and listen for DNS
queries. It would be configured to use one (or several) of the well
known site local unicast addresses within the ISP's site to send its
own queries to. It would act as a DNS forwarder, forwarding queries
received on its internal interface to the ISP's recursive DNS server.
-------------
/ |
---------- -------------- / |
|ISP | | CPE| / Customer |
|DNS |===========| DNS|====< site |
|server | <------|---forwarder|-----\---- |
---------- -------------- \ |
\ |
-------------
In this configuration, the CPE is acting as a multi-sited router.
6.4 DNS forwarder with DHCPv6 interactions
In this variant scenario, DHCPv6 is be used between the PE and CPE to
do prefix delegation [DELEG] and recursive DNS server discovery.
-------------
/ |
-------- -------------- / |
|ISP | |customer CPE| / Customer |
|DHCPv6|===========| DHCPv6|====< site |
|server| <------|------client| \ |
-------- -------------- \ |
\ |
-------------
This example will show how DHCPv6 and well known site local unicast
addresses cooperate to enable the internal nodes to access DNS.
The customer router CPE is configured on its internal interface with
one of the reserved site local addresses and listen for DNS queries.
It would act as a DNS forwarder, as in 5.2, forwarding those queries
to the recursive DNS server pointed out by the ISP in the DHCPv6
exchange.
-------------
/ |
---------- -------------- / |
|ISP | |customer CPE| / Customer |
|DNS |===========| DNS|====< site |
|resolver| <------|---forwarder|-----\---- |
---------- -------------- \ |
\ |
-------------
The same CPE router could also implement a local DHCPv6 server and
advertizes itself as DNS forwarder.
-------------
/ |
-------- -------------- / Customer |
|ISP PE| |customer CPE| / site |
| |===========|DHCPv6 |====< |
| | |server------|-----\---> |
-------- -------------- \ |
\ |
-------------
Within the site:
a) DHCPv6 aware clients use DHCPv6 to obtain the address of the
DNS forwarder...
-------------
/ |
---------- -------------- / Customer |
|ISP | |customer CPE| / site |
|DNS |===========| DNS|====< |
|resolver| <------|---forwarder|-----\----DHCPv6 |
---------- -------------- \ client |
\ |
-------------
(The address of the DNS forwarder is acquired via DHCPv6.)
b) other nodes simply send their DNS request to the reserved site
local addresses.
-------------
/ |
---------- -------------- / customer |
|ISP | |customer CPE| / site |
|DNS |===========| DNS|====< |
|resolver| <------|---forwarder|-----\----non DHCPv6|
---------- -------------- \ node |
\ |
-------------
(Internal nodes use the reserved site local unicast address.)
A variant of this scenario is the CPE can decide to pass the global
address of the ISP recursive DNS server in the DHCPv6 exchange with
the internal nodes.
7. IANA considerations
The site local prefix fec0:0000:0000:ffff::/64 is to be reserved out
of the site local fec0::/10 prefix.
The unicast addresses fec0:000:0000:ffff::1, fec0:000:0000:ffff::2
and fec0:000:0000:ffff::3 are to be reserved for recursive DNS server
configuration.
All other addresses within the fec0:0000:0000:ffff::/64 are reserved
for future use and are expected to be assigned only with IESG
approval.
8. Security Considerations
Ensuring that queries reach a legitimate DNS server relies on the
security of the IPv6 routing infrastructure. The issues here are the
same as those for protecting basic IPv6 connectivity.
IPsec/IKE can be used as the well known addresses are used as unicast
addresses.
The payload can be protected using standard DNS security techniques.
If the client can preconfigure a well known private or public key
then TSIG [TSIG] can be used with the same packets presented for the
query. If this is not the case, then TSIG keys will have to be
negotiated using [TKEY]. After the client has the proper key then
the query can be performed.
The use of site local addresses instead of global addresses will
ensure the DNS queries issued by host using this mechanism will not
leak out of the site.
9. References
[KEYWORDS]
Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[ADDRCONF]
Thomson, S., and T. Narten, "IPv6 Stateless Address
Autoconfiguration", RFC 2462, December 1998.
[MLD]
Deering, S., Fenner, W., Haberman, B.,
"Multicast Listener Discovery (MLD) for IPv6",
RFC2710, October 1999.
[TSIG]
Vixie, P., Gudmundsson, O., Eastlake, D. and B. Wellington,
"Secret Key Transaction Authentication for DNS (TSIG)",
RFC2845, May 2000.
[TKEY]
D. Eastlake, "Secret Key Establishment for DNS (TKEY RR)",
RFC2930, September 2000.
[DHCPv6]
Bound, J., Carney, M., Perkins, C., Lemon, T., Volz, B. and
Droms, R. (ed.), "Dynamic host Configuration Protocol for IPv6
(DHCPv6)", draft-ietf-dhc-dhcpv6-27 (work in progress),
Februray 2002.
[DELEG]
Troan, O., Droms, R., "IPv6 Prefix Options for DHCPv6",
draft-troan-dhcpv6-opt-prefix-delegation-01.txt (work in progress),
February 2002.
10. Authors' Addresses
Alain Durand
SUN microsystems, inc.
17 Network Circle, UMPK 17-202
Menlo Park, CA 94025
Email: Alain.Durand@sun.com
Jun-ichiro itojun HAGINO
Research Laboratory, Internet Initiative Japan Inc.
Takebashi Yasuda Bldg.,
3-13 Kanda Nishiki-cho,
Chiyoda-ku, Tokyo 101-0054, JAPAN
Email: itojun@iijlab.net
Dave Thaler
Microsoft
One Microsoft Way
Redmond, CA 98052, USA
Email: dthaler@microsoft.com
11. Full Copyright Statement
Copyright (C) The Internet Society (2002). All Rights Reserved.
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