Network Working Group R. Elz Request for Comments: 2182 University of Melbourne BCP: 16 R. Bush Category: Best Current Practice RGnet, Inc. S. Bradner Harvard University M. Patton Consultant July 1997
Selection and Operation of Secondary DNS Servers
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.
Abstract
The Domain Name System requires that multiple servers exist for every delegated domain (zone). This document discusses the selection of secondary servers for DNS zones. Both the physical and topological location of each server are material considerations when selecting secondary servers. The number of servers appropriate for a zone is also discussed, and some general secondary server maintenance issues considered.
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A number of problems in DNS operations today are attributable to poor choices of secondary servers for DNS zones. The geographic placement as well as the diversity of network connectivity exhibited by the set of DNS servers for a zone can increase the reliability of that zone as well as improve overall network performance and access characteristics. Other considerations in server choice can unexpectedly lower reliability or impose extra demands on the network.
This document discusses many of the issues that should be considered when selecting secondary servers for a zone. It offers guidance in how to best choose servers to serve a given zone.
Zone A part of the DNS tree, that is treated as a unit.
Forward Zone A zone containing data mapping names to host addresses, mail exchange targets, etc.
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Reverse Zone A zone containing data used to map addresses to names.
Server An implementation of the DNS protocols able to provide answers to queries. Answers may be from information known by the server, or information obtained from another server.
Authoritative Server A server that knows the content of a DNS zone from local knowledge, and thus can answer queries about that zone without needing to query other servers.
Listed Server An Authoritative Server for which there is an "NS" resource record (RR) in the zone.
Primary Server An authoritative server for which the zone information is locally configured. Sometimes known as a Master server.
Secondary Server An authoritative server that obtains information about a zone from a Primary Server via a zone transfer mechanism. Sometimes known as a Slave Server.
Stealth Server An authoritative server, usually secondary, which is not a Listed Server.
Resolver A client of the DNS which seeks information contained in a zone using the DNS protocols.
A major reason for having multiple servers for each zone is to allow information from the zone to be available widely and reliably to clients throughout the Internet, that is, throughout the world, even when one server is unavailable or unreachable.
Multiple servers also spread the name resolution load, and improve the overall efficiency of the system by placing servers nearer to the resolvers. Those purposes are not treated further here.
With multiple servers, usually one server will be the primary server, and others will be secondary servers. Note that while some unusual configurations use multiple primary servers, that can result in data inconsistencies, and is not advisable.
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The distinction between primary and secondary servers is relevant only to the servers for the zone concerned, to the rest of the DNS there are simply multiple servers. All are treated equally at first instance, even by the parent server that delegates the zone. Resolvers often measure the performance of the various servers, choose the "best", for some definition of best, and prefer that one for most queries. That is automatic, and not considered here.
The primary server holds the master copy of the zone file. That is, the server where the data is entered into the DNS from some source outside the DNS. Secondary servers obtain data for the zone using DNS protocol mechanisms to obtain the zone from the primary server.
When selecting secondary servers, attention should be given to the various likely failure modes. Servers should be placed so that it is likely that at least one server will be available to all significant parts of the Internet, for any likely failure.
Consequently, placing all servers at the local site, while easy to arrange, and easy to manage, is not a good policy. Should a single link fail, or there be a site, or perhaps even building, or room, power failure, such a configuration can lead to all servers being disconnected from the Internet.
Secondary servers must be placed at both topologically and geographically dispersed locations on the Internet, to minimise the likelihood of a single failure disabling all of them.
That is, secondary servers should be at geographically distant locations, so it is unlikely that events like power loss, etc, will disrupt all of them simultaneously. They should also be connected to the net via quite diverse paths. This means that the failure of any one link, or of routing within some segment of the network (such as a service provider) will not make all of the servers unreachable.
While it is unfortunately quite common, servers for a zone should certainly not all be placed on the same LAN segment in the same room of the same building - or any of those. Such a configuration almost defeats the requirement, and utility, of having multiple servers. The only redundancy usually provided in that configuration is for the case when one server is down, whereas there are many other possible failure modes, such as power failures, including lengthy ones, to consider.
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An argument is occasionally made that there is no need for the domain name servers for a domain to be accessible if the hosts in the domain are unreachable. This argument is fallacious.
+ Clients react differently to inability to resolve than inability to connect, and reactions to the former are not always as desirable. + If the zone is resolvable yet the particular name is not, then a client can discard the transaction rather than retrying and creating undesirable load on the network. + While positive DNS results are usually cached, the lack of a result is not cached. Thus, unnecessary inability to resolve creates an undesirable load on the net. + All names in the zone may not resolve to addresses within the detached network. This becomes more likely over time. Thus a basic assumption of the myth often becomes untrue.
It is important that there be nameservers able to be queried, available always, for all forward zones.
Another class of problems is caused by listing servers that cannot be reached from large parts of the network. This could be listing the name of a machine that is completely isolated behind a firewall, or just a secondary address on a dual homed machine which is not accessible from outside. The names of servers listed in NS records should resolve to addresses which are reachable from the region to which the NS records are being returned. Including addresses which most of the network cannot reach does not add any reliability, and causes several problems, which may, in the end, lower the reliability of the zone.
First, the only way the resolvers can determine that these addresses are, in fact, unreachable, is to try them. They then need to wait on a lack of response timeout (or occasionally an ICMP error response) to know that the address cannot be used. Further, even that is generally indistinguishable from a simple packet loss, so the sequence must be repeated, several times, to give any real evidence of an unreachable server. All of this probing and timeout may take sufficiently long that the original client program or user will decide that no answer is available, leading to an apparent failure of the zone. Additionally, the whole thing needs to be repeated from time to time to distinguish a permanently unreachable server from a temporarily unreachable one.
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And finally, all these steps will potentially need to be done by resolvers all over the network. This will increase the traffic, and probably the load on the filters at whatever firewall is blocking this access. All of this additional load does no more than effectively lower the reliability of the service.
A similar problem occurs with DNS servers located in parts of the net that are often disconnected from the Internet as a whole. For example, those which connect via an intermittent connection that is often down. Such servers should usually be treated as if they were behind a firewall, and unreachable to the network at any time.
Similar problems occur when a Network Address Translator (NAT) [RFC1631] exists between a resolver and server. Despite what [RFC1631] suggests, NATs in practice do not translate addresses embedded in packets, only those in the headers. As [RFC1631] suggests, this is somewhat of a problem for the DNS. This can sometimes be overcome if the NAT is accompanied by, or replaced with, an Application Layer Gateway (ALG). Such a device would understand the DNS protocol and translate all the addresses as appropriate as packets pass through. Even with such a device, it is likely to be better in any of these cases to adopt the solution described in the following section.
To avoid these problems, NS records for a zone returned in any response should list only servers that the resolver requesting the information, is likely to be able to reach. Some resolvers are simultaneously servers performing lookups on behalf of other resolvers. The NS records returned should be reachable not only by the resolver that requested the information, but any other resolver that may be forwarded the information. All the addresses of all the servers returned must be reachable. As the addresses of each server form a Resource Record Set [RFC2181], all must be returned (or none), thus it is not acceptable to elide addresses of servers that are unreachable, or to return them with a low TTL (while returning others with a higher TTL).
In particular, when some servers are behind a firewall, intermittent connection, or NAT, which disallows, or has problems with, DNS queries or responses, their names, or addresses, should not be returned to clients outside the firewall. Similarly, servers outside the firewall should not be made known to clients inside it, if the
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clients would be unable to query those servers. Implementing this usually requires dual DNS setups, one for internal use, the other for external use. Such a setup often solves other problems with environments like this.
When a server is at a firewall boundary, reachable from both sides, but using different addresses, that server should be given two names, each name associated with appropriate A records, such that each appears to be reachable only on the appropriate side of the firewall. This should then be treated just like two servers, one on each side of the firewall. A server implemented in an ALG will usually be such a case. Special care will need to be taken to allow such a server to return the correct responses to clients on each side. That is, return only information about hosts reachable from that side and the correct IP address(es) for the host when viewed from that side.
Servers in this environment often need special provision to give them access to the root servers. Often this is accomplished via "fake root" configurations. In such a case the servers should be kept well isolated from the rest of the DNS, lest their unusual configuration pollute others.
The DNS specification and domain name registration rules require at least two servers for every zone. That is, usually, the primary and one secondary. While two, carefully placed, are often sufficient, occasions where two are insufficient are frequent enough that we advise the use of more than two listed servers. Various problems can cause a server to be unavailable for extended periods - during such a period, a zone with only two listed servers is actually running with just one. Since any server may occasionally be unavailable, for all kinds of reasons, this zone is likely, at times, to have no functional servers at all.
On the other hand, having large numbers of servers adds little benefit, while adding costs. At the simplest, more servers cause packets to be larger, so requiring more bandwidth. This may seem, and realistically is, trivial. However there is a limit to the size of a DNS packet, and causing that limit to be reached has more serious performance implications. It is wise to stay well clear of it. More servers also increase the likelihood that one server will be misconfigured, or malfunction, without being detected.
It is recommended that three servers be provided for most organisation level zones, with at least one which must be well removed from the others. For zones where even higher reliability is required, four, or even five, servers may be desirable. Two, or
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occasionally three of five, would be at the local site, with the others not geographically or topologically close to the site, or each other.
Reverse zones, that is, sub-domains of .IN-ADDR.ARPA, tend to be less crucial, and less servers, less distributed, will often suffice. This is because address to name translations are typically needed only when packets are being received from the address in question, and only by resolvers at or near the destination of the packets. This gives some assurances that servers located at or near the packet source, for example, on the the same network, will be reachable from the resolvers that need to perform the lookups. Thus some of the failure modes that need to be considered when planning servers for forward zones may be less relevant when reverse zones are being planned.
Servers which are authoritative for the zone, but not listed in NS records (also known as "stealth" servers) are not included in the count of servers.
It can often be useful for all servers at a site to be authoritative (secondary), but only one or two be listed servers, the rest being unlisted servers for all local zones, that is, to be stealth servers.
This allows those servers to provide answers to local queries directly, without needing to consult another server. If it were necessary to consult another server, it would usually be necessary for the root servers to be consulted, in order to follow the delegation tree - that the zone is local would not be known. This would mean that some local queries may not be able to be answered if external communications were disrupted.
Listing all such servers in NS records, if more than one or two, would cause the rest of the Internet to spend unnecessary effort attempting to contact all servers at the site when the whole site is inaccessible due to link or routing failures.
Operating a secondary server is usually an almost automatic task. Once established, the server generally runs itself, based upon the actions of the primary server. Because of this, large numbers of organisations are willing to provide a secondary server, if requested. The best approach is usually to find an organisation of similar size, and agree to swap secondary zones - each organisation agrees to provide a server to act as a secondary server for the other
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organisation's zones. Note that there is no loss of confidential data here, the data set exchanged would be available publically whatever the servers are.
Secondary servers use the serial number in the SOA record of the zone to determine when it is necessary to update their local copy of the zone. Serial numbers are basically just 32 bit unsigned integers that wrap around from the biggest possible value to zero again. See [RFC1982] for a more rigorous definition of the serial number.
The serial number must be incremented every time a change, or group of changes, is made to the zone on the primary server. This informs secondary servers they need update their copies of the zone. Note that it is not possible to decrement a serial number, increments are the only defined modification.
Occasionally due to editing errors, or other factors, it may be necessary to cause a serial number to become smaller. Never simply decrease the serial number. Secondary servers will ignore that change, and further, will ignore any later increments until the earlier large value is exceeded.
Instead, given that serial numbers wrap from large to small, in absolute terms, increment the serial number, several times, until it has reached the value desired. At each step, wait until all secondary servers have updated to the new value before proceeding.
For example, assume that the serial number of a zone was 10, but has accidentally been set to 1000, and it is desired to set it back to 11. Do not simply change the value from 1000 to 11. A secondary server that has seen the 1000 value (and in practice, there is always at least one) will ignore this change, and continue to use the version of the zone with serial number 1000, until the primary server's serial number exceeds that value. This may be a long time - in fact, the secondary often expires its copy of the zone before the zone is ever updated again.
Instead, for this example, set the primary's serial number to 2000000000, and wait for the secondary servers to update to that zone. The value 2000000000 is chosen as a value a lot bigger than the current value, but less that 2^31 bigger (2^31 is 2147483648). This is then an increment of the serial number [RFC1982].
Next, after all servers needing updating have the zone with that serial number, the serial number can be set to 4000000000. 4000000000 is 2000000000 more than 2000000000 (fairly clearly), and
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is thus another increment (the value added is less than 2^31).
Once this copy of the zone file exists at all servers, the serial number can simply be set to 11. In serial number arithmetic, a change from 4000000000 to 11 is an increment. Serial numbers wrap at 2^32 (4294967296), so 11 is identical to 4294967307 (4294967296 + 11). 4294967307 is just 294967307 greater than 4000000000, and 294967307 is well under 2^31, this is therefore an increment.
When following this procedure, it is essential to verify that all relevant servers have been updated at each step, never assume anything. Failing to do this can result in a worse mess than existed before the attempted correction. Also beware that it is the relationship between the values of the various serial numbers that is important, not the absolute values. The values used above are correct for that one example only.
It is possible in essentially all cases to correct the serial number in two steps by being more aggressive in the choices of the serial numbers. This however causes the numbers used to be less "nice", and requires considerably more care.
Also, note that not all nameserver implementations correctly implement serial number operations. With such servers as secondaries there is typically no way to cause the serial number to become smaller, other than contacting the administrator of the server and requesting that all existing data for the zone be purged. Then that the secondary be loaded again from the primary, as if for the first time.
It remains safe to carry out the above procedure, as the malfunctioning servers will need manual attention in any case. After the sequence of serial number changes described above, conforming secondary servers will have been reset. Then when the primary server has the correct (desired) serial number, contact the remaining secondary servers and request their understanding of the correct serial number be manually corrected. Perhaps also suggest that they upgrade their software to a standards conforming implementation.
A server which does not implement this algorithm is defective, and may be detected as follows. At some stage, usually when the absolute integral value of the serial number becomes smaller, a server with this particular defect will ignore the change. Servers with this type of defect can be detected by waiting for at least the time specified in the SOA refresh field and then sending a query for the SOA. Servers with this defect will still have the old serial number. We are not aware of other means to detect this defect.
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Security Considerations
It is not believed that anything in this document adds to any security issues that may exist with the DNS, nor does it do anything to lessen them.
Administrators should be aware, however, that compromise of a server for a domain can, in some situations, compromise the security of hosts in the domain. Care should be taken in choosing secondary servers so that this threat is minimised.
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
[RFC1631] Egevang, K., Francis, P., "The IP Network Address Translator (NAT)", RFC 1631, May 1994
[RFC1982] Elz, R., Bush, R., "Serial Number Arithmetic", RFC 1982, August 1996.
[RFC2181] Elz, R., Bush, R., "Clarifications to the DNS specification", RFC 2181, July 1997.
Acknowledgements
Brian Carpenter and Yakov Rekhter suggested mentioning NATs and ALGs as a companion to the firewall text. Dave Crocker suggested explicitly exploding the myth.
Authors' Addresses
Robert Elz Computer Science University of Melbourne Parkville, Vic, 3052 Australia.
EMail: kre@munnari.OZ.AU
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Randy Bush RGnet, Inc. 5147 Crystal Springs Drive NE Bainbridge Island, Washington, 98110 United States.
EMail: randy@psg.com
Scott Bradner Harvard University 1350 Mass Ave Cambridge, MA, 02138 United States.
EMail: sob@harvard.edu
Michael A. Patton 33 Blanchard Road Cambridge, MA, 02138 United States.