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Network Working Group P. Mockapetris | |
Request for Comments: 1034 ISI | |
Obsoletes: RFCs 882, 883, 973 November 1987 | |
DOMAIN NAMES - CONCEPTS AND FACILITIES | |
1. STATUS OF THIS MEMO | |
This RFC is an introduction to the Domain Name System (DNS), and omits | |
many details which can be found in a companion RFC, "Domain Names - | |
Implementation and Specification" [RFC-1035]. That RFC assumes that the | |
reader is familiar with the concepts discussed in this memo. | |
A subset of DNS functions and data types constitute an official | |
protocol. The official protocol includes standard queries and their | |
responses and most of the Internet class data formats (e.g., host | |
addresses). | |
However, the domain system is intentionally extensible. Researchers are | |
continuously proposing, implementing and experimenting with new data | |
types, query types, classes, functions, etc. Thus while the components | |
of the official protocol are expected to stay essentially unchanged and | |
operate as a production service, experimental behavior should always be | |
expected in extensions beyond the official protocol. Experimental or | |
obsolete features are clearly marked in these RFCs, and such information | |
should be used with caution. | |
The reader is especially cautioned not to depend on the values which | |
appear in examples to be current or complete, since their purpose is | |
primarily pedagogical. Distribution of this memo is unlimited. | |
2. INTRODUCTION | |
This RFC introduces domain style names, their use for Internet mail and | |
host address support, and the protocols and servers used to implement | |
domain name facilities. | |
2.1. The history of domain names | |
The impetus for the development of the domain system was growth in the | |
Internet: | |
- Host name to address mappings were maintained by the Network | |
Information Center (NIC) in a single file (HOSTS.TXT) which | |
was FTPed by all hosts [RFC-952, RFC-953]. The total network | |
Mockapetris [Page 1] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
bandwidth consumed in distributing a new version by this | |
scheme is proportional to the square of the number of hosts in | |
the network, and even when multiple levels of FTP are used, | |
the outgoing FTP load on the NIC host is considerable. | |
Explosive growth in the number of hosts didn't bode well for | |
the future. | |
- The network population was also changing in character. The | |
timeshared hosts that made up the original ARPANET were being | |
replaced with local networks of workstations. Local | |
organizations were administering their own names and | |
addresses, but had to wait for the NIC to change HOSTS.TXT to | |
make changes visible to the Internet at large. Organizations | |
also wanted some local structure on the name space. | |
- The applications on the Internet were getting more | |
sophisticated and creating a need for general purpose name | |
service. | |
The result was several ideas about name spaces and their management | |
[IEN-116, RFC-799, RFC-819, RFC-830]. The proposals varied, but a | |
common thread was the idea of a hierarchical name space, with the | |
hierarchy roughly corresponding to organizational structure, and names | |
using "." as the character to mark the boundary between hierarchy | |
levels. A design using a distributed database and generalized resources | |
was described in [RFC-882, RFC-883]. Based on experience with several | |
implementations, the system evolved into the scheme described in this | |
memo. | |
The terms "domain" or "domain name" are used in many contexts beyond the | |
DNS described here. Very often, the term domain name is used to refer | |
to a name with structure indicated by dots, but no relation to the DNS. | |
This is particularly true in mail addressing [Quarterman 86]. | |
2.2. DNS design goals | |
The design goals of the DNS influence its structure. They are: | |
- The primary goal is a consistent name space which will be used | |
for referring to resources. In order to avoid the problems | |
caused by ad hoc encodings, names should not be required to | |
contain network identifiers, addresses, routes, or similar | |
information as part of the name. | |
- The sheer size of the database and frequency of updates | |
suggest that it must be maintained in a distributed manner, | |
with local caching to improve performance. Approaches that | |
Mockapetris [Page 2] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
attempt to collect a consistent copy of the entire database | |
will become more and more expensive and difficult, and hence | |
should be avoided. The same principle holds for the structure | |
of the name space, and in particular mechanisms for creating | |
and deleting names; these should also be distributed. | |
- Where there tradeoffs between the cost of acquiring data, the | |
speed of updates, and the accuracy of caches, the source of | |
the data should control the tradeoff. | |
- The costs of implementing such a facility dictate that it be | |
generally useful, and not restricted to a single application. | |
We should be able to use names to retrieve host addresses, | |
mailbox data, and other as yet undetermined information. All | |
data associated with a name is tagged with a type, and queries | |
can be limited to a single type. | |
- Because we want the name space to be useful in dissimilar | |
networks and applications, we provide the ability to use the | |
same name space with different protocol families or | |
management. For example, host address formats differ between | |
protocols, though all protocols have the notion of address. | |
The DNS tags all data with a class as well as the type, so | |
that we can allow parallel use of different formats for data | |
of type address. | |
- We want name server transactions to be independent of the | |
communications system that carries them. Some systems may | |
wish to use datagrams for queries and responses, and only | |
establish virtual circuits for transactions that need the | |
reliability (e.g., database updates, long transactions); other | |
systems will use virtual circuits exclusively. | |
- The system should be useful across a wide spectrum of host | |
capabilities. Both personal computers and large timeshared | |
hosts should be able to use the system, though perhaps in | |
different ways. | |
2.3. Assumptions about usage | |
The organization of the domain system derives from some assumptions | |
about the needs and usage patterns of its user community and is designed | |
to avoid many of the the complicated problems found in general purpose | |
database systems. | |
The assumptions are: | |
- The size of the total database will initially be proportional | |
Mockapetris [Page 3] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
to the number of hosts using the system, but will eventually | |
grow to be proportional to the number of users on those hosts | |
as mailboxes and other information are added to the domain | |
system. | |
- Most of the data in the system will change very slowly (e.g., | |
mailbox bindings, host addresses), but that the system should | |
be able to deal with subsets that change more rapidly (on the | |
order of seconds or minutes). | |
- The administrative boundaries used to distribute | |
responsibility for the database will usually correspond to | |
organizations that have one or more hosts. Each organization | |
that has responsibility for a particular set of domains will | |
provide redundant name servers, either on the organization's | |
own hosts or other hosts that the organization arranges to | |
use. | |
- Clients of the domain system should be able to identify | |
trusted name servers they prefer to use before accepting | |
referrals to name servers outside of this "trusted" set. | |
- Access to information is more critical than instantaneous | |
updates or guarantees of consistency. Hence the update | |
process allows updates to percolate out through the users of | |
the domain system rather than guaranteeing that all copies are | |
simultaneously updated. When updates are unavailable due to | |
network or host failure, the usual course is to believe old | |
information while continuing efforts to update it. The | |
general model is that copies are distributed with timeouts for | |
refreshing. The distributor sets the timeout value and the | |
recipient of the distribution is responsible for performing | |
the refresh. In special situations, very short intervals can | |
be specified, or the owner can prohibit copies. | |
- In any system that has a distributed database, a particular | |
name server may be presented with a query that can only be | |
answered by some other server. The two general approaches to | |
dealing with this problem are "recursive", in which the first | |
server pursues the query for the client at another server, and | |
"iterative", in which the server refers the client to another | |
server and lets the client pursue the query. Both approaches | |
have advantages and disadvantages, but the iterative approach | |
is preferred for the datagram style of access. The domain | |
system requires implementation of the iterative approach, but | |
allows the recursive approach as an option. | |
Mockapetris [Page 4] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
The domain system assumes that all data originates in master files | |
scattered through the hosts that use the domain system. These master | |
files are updated by local system administrators. Master files are text | |
files that are read by a local name server, and hence become available | |
through the name servers to users of the domain system. The user | |
programs access name servers through standard programs called resolvers. | |
The standard format of master files allows them to be exchanged between | |
hosts (via FTP, mail, or some other mechanism); this facility is useful | |
when an organization wants a domain, but doesn't want to support a name | |
server. The organization can maintain the master files locally using a | |
text editor, transfer them to a foreign host which runs a name server, | |
and then arrange with the system administrator of the name server to get | |
the files loaded. | |
Each host's name servers and resolvers are configured by a local system | |
administrator [RFC-1033]. For a name server, this configuration data | |
includes the identity of local master files and instructions on which | |
non-local master files are to be loaded from foreign servers. The name | |
server uses the master files or copies to load its zones. For | |
resolvers, the configuration data identifies the name servers which | |
should be the primary sources of information. | |
The domain system defines procedures for accessing the data and for | |
referrals to other name servers. The domain system also defines | |
procedures for caching retrieved data and for periodic refreshing of | |
data defined by the system administrator. | |
The system administrators provide: | |
- The definition of zone boundaries. | |
- Master files of data. | |
- Updates to master files. | |
- Statements of the refresh policies desired. | |
The domain system provides: | |
- Standard formats for resource data. | |
- Standard methods for querying the database. | |
- Standard methods for name servers to refresh local data from | |
foreign name servers. | |
Mockapetris [Page 5] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
2.4. Elements of the DNS | |
The DNS has three major components: | |
- The DOMAIN NAME SPACE and RESOURCE RECORDS, which are | |
specifications for a tree structured name space and data | |
associated with the names. Conceptually, each node and leaf | |
of the domain name space tree names a set of information, and | |
query operations are attempts to extract specific types of | |
information from a particular set. A query names the domain | |
name of interest and describes the type of resource | |
information that is desired. For example, the Internet | |
uses some of its domain names to identify hosts; queries for | |
address resources return Internet host addresses. | |
- NAME SERVERS are server programs which hold information about | |
the domain tree's structure and set information. A name | |
server may cache structure or set information about any part | |
of the domain tree, but in general a particular name server | |
has complete information about a subset of the domain space, | |
and pointers to other name servers that can be used to lead to | |
information from any part of the domain tree. Name servers | |
know the parts of the domain tree for which they have complete | |
information; a name server is said to be an AUTHORITY for | |
these parts of the name space. Authoritative information is | |
organized into units called ZONEs, and these zones can be | |
automatically distributed to the name servers which provide | |
redundant service for the data in a zone. | |
- RESOLVERS are programs that extract information from name | |
servers in response to client requests. Resolvers must be | |
able to access at least one name server and use that name | |
server's information to answer a query directly, or pursue the | |
query using referrals to other name servers. A resolver will | |
typically be a system routine that is directly accessible to | |
user programs; hence no protocol is necessary between the | |
resolver and the user program. | |
These three components roughly correspond to the three layers or views | |
of the domain system: | |
- From the user's point of view, the domain system is accessed | |
through a simple procedure or OS call to a local resolver. | |
The domain space consists of a single tree and the user can | |
request information from any section of the tree. | |
- From the resolver's point of view, the domain system is | |
composed of an unknown number of name servers. Each name | |
Mockapetris [Page 6] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
server has one or more pieces of the whole domain tree's data, | |
but the resolver views each of these databases as essentially | |
static. | |
- From a name server's point of view, the domain system consists | |
of separate sets of local information called zones. The name | |
server has local copies of some of the zones. The name server | |
must periodically refresh its zones from master copies in | |
local files or foreign name servers. The name server must | |
concurrently process queries that arrive from resolvers. | |
In the interests of performance, implementations may couple these | |
functions. For example, a resolver on the same machine as a name server | |
might share a database consisting of the the zones managed by the name | |
server and the cache managed by the resolver. | |
3. DOMAIN NAME SPACE and RESOURCE RECORDS | |
3.1. Name space specifications and terminology | |
The domain name space is a tree structure. Each node and leaf on the | |
tree corresponds to a resource set (which may be empty). The domain | |
system makes no distinctions between the uses of the interior nodes and | |
leaves, and this memo uses the term "node" to refer to both. | |
Each node has a label, which is zero to 63 octets in length. Brother | |
nodes may not have the same label, although the same label can be used | |
for nodes which are not brothers. One label is reserved, and that is | |
the null (i.e., zero length) label used for the root. | |
The domain name of a node is the list of the labels on the path from the | |
node to the root of the tree. By convention, the labels that compose a | |
domain name are printed or read left to right, from the most specific | |
(lowest, farthest from the root) to the least specific (highest, closest | |
to the root). | |
Internally, programs that manipulate domain names should represent them | |
as sequences of labels, where each label is a length octet followed by | |
an octet string. Because all domain names end at the root, which has a | |
null string for a label, these internal representations can use a length | |
byte of zero to terminate a domain name. | |
By convention, domain names can be stored with arbitrary case, but | |
domain name comparisons for all present domain functions are done in a | |
case-insensitive manner, assuming an ASCII character set, and a high | |
order zero bit. This means that you are free to create a node with | |
label "A" or a node with label "a", but not both as brothers; you could | |
refer to either using "a" or "A". When you receive a domain name or | |
Mockapetris [Page 7] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
label, you should preserve its case. The rationale for this choice is | |
that we may someday need to add full binary domain names for new | |
services; existing services would not be changed. | |
When a user needs to type a domain name, the length of each label is | |
omitted and the labels are separated by dots ("."). Since a complete | |
domain name ends with the root label, this leads to a printed form which | |
ends in a dot. We use this property to distinguish between: | |
- a character string which represents a complete domain name | |
(often called "absolute"). For example, "poneria.ISI.EDU." | |
- a character string that represents the starting labels of a | |
domain name which is incomplete, and should be completed by | |
local software using knowledge of the local domain (often | |
called "relative"). For example, "poneria" used in the | |
ISI.EDU domain. | |
Relative names are either taken relative to a well known origin, or to a | |
list of domains used as a search list. Relative names appear mostly at | |
the user interface, where their interpretation varies from | |
implementation to implementation, and in master files, where they are | |
relative to a single origin domain name. The most common interpretation | |
uses the root "." as either the single origin or as one of the members | |
of the search list, so a multi-label relative name is often one where | |
the trailing dot has been omitted to save typing. | |
To simplify implementations, the total number of octets that represent a | |
domain name (i.e., the sum of all label octets and label lengths) is | |
limited to 255. | |
A domain is identified by a domain name, and consists of that part of | |
the domain name space that is at or below the domain name which | |
specifies the domain. A domain is a subdomain of another domain if it | |
is contained within that domain. This relationship can be tested by | |
seeing if the subdomain's name ends with the containing domain's name. | |
For example, A.B.C.D is a subdomain of B.C.D, C.D, D, and " ". | |
3.2. Administrative guidelines on use | |
As a matter of policy, the DNS technical specifications do not mandate a | |
particular tree structure or rules for selecting labels; its goal is to | |
be as general as possible, so that it can be used to build arbitrary | |
applications. In particular, the system was designed so that the name | |
space did not have to be organized along the lines of network | |
boundaries, name servers, etc. The rationale for this is not that the | |
name space should have no implied semantics, but rather that the choice | |
of implied semantics should be left open to be used for the problem at | |
Mockapetris [Page 8] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
hand, and that different parts of the tree can have different implied | |
semantics. For example, the IN-ADDR.ARPA domain is organized and | |
distributed by network and host address because its role is to translate | |
from network or host numbers to names; NetBIOS domains [RFC-1001, RFC- | |
1002] are flat because that is appropriate for that application. | |
However, there are some guidelines that apply to the "normal" parts of | |
the name space used for hosts, mailboxes, etc., that will make the name | |
space more uniform, provide for growth, and minimize problems as | |
software is converted from the older host table. The political | |
decisions about the top levels of the tree originated in RFC-920. | |
Current policy for the top levels is discussed in [RFC-1032]. MILNET | |
conversion issues are covered in [RFC-1031]. | |
Lower domains which will eventually be broken into multiple zones should | |
provide branching at the top of the domain so that the eventual | |
decomposition can be done without renaming. Node labels which use | |
special characters, leading digits, etc., are likely to break older | |
software which depends on more restrictive choices. | |
3.3. Technical guidelines on use | |
Before the DNS can be used to hold naming information for some kind of | |
object, two needs must be met: | |
- A convention for mapping between object names and domain | |
names. This describes how information about an object is | |
accessed. | |
- RR types and data formats for describing the object. | |
These rules can be quite simple or fairly complex. Very often, the | |
designer must take into account existing formats and plan for upward | |
compatibility for existing usage. Multiple mappings or levels of | |
mapping may be required. | |
For hosts, the mapping depends on the existing syntax for host names | |
which is a subset of the usual text representation for domain names, | |
together with RR formats for describing host addresses, etc. Because we | |
need a reliable inverse mapping from address to host name, a special | |
mapping for addresses into the IN-ADDR.ARPA domain is also defined. | |
For mailboxes, the mapping is slightly more complex. The usual mail | |
address <local-part>@<mail-domain> is mapped into a domain name by | |
converting <local-part> into a single label (regardles of dots it | |
contains), converting <mail-domain> into a domain name using the usual | |
text format for domain names (dots denote label breaks), and | |
concatenating the two to form a single domain name. Thus the mailbox | |
Mockapetris [Page 9] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
[email protected] is represented as a domain name by | |
HOSTMASTER.SRI-NIC.ARPA. An appreciation for the reasons behind this | |
design also must take into account the scheme for mail exchanges [RFC- | |
974]. | |
The typical user is not concerned with defining these rules, but should | |
understand that they usually are the result of numerous compromises | |
between desires for upward compatibility with old usage, interactions | |
between different object definitions, and the inevitable urge to add new | |
features when defining the rules. The way the DNS is used to support | |
some object is often more crucial than the restrictions inherent in the | |
DNS. | |
3.4. Example name space | |
The following figure shows a part of the current domain name space, and | |
is used in many examples in this RFC. Note that the tree is a very | |
small subset of the actual name space. | |
| | |
| | |
+---------------------+------------------+ | |
| | | | |
MIL EDU ARPA | |
| | | | |
| | | | |
+-----+-----+ | +------+-----+-----+ | |
| | | | | | | | |
BRL NOSC DARPA | IN-ADDR SRI-NIC ACC | |
| | |
+--------+------------------+---------------+--------+ | |
| | | | | | |
UCI MIT | UDEL YALE | |
| ISI | |
| | | |
+---+---+ | | |
| | | | |
LCS ACHILLES +--+-----+-----+--------+ | |
| | | | | | | |
XX A C VAXA VENERA Mockapetris | |
In this example, the root domain has three immediate subdomains: MIL, | |
EDU, and ARPA. The LCS.MIT.EDU domain has one immediate subdomain named | |
XX.LCS.MIT.EDU. All of the leaves are also domains. | |
3.5. Preferred name syntax | |
The DNS specifications attempt to be as general as possible in the rules | |
Mockapetris [Page 10] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
for constructing domain names. The idea is that the name of any | |
existing object can be expressed as a domain name with minimal changes. | |
However, when assigning a domain name for an object, the prudent user | |
will select a name which satisfies both the rules of the domain system | |
and any existing rules for the object, whether these rules are published | |
or implied by existing programs. | |
For example, when naming a mail domain, the user should satisfy both the | |
rules of this memo and those in RFC-822. When creating a new host name, | |
the old rules for HOSTS.TXT should be followed. This avoids problems | |
when old software is converted to use domain names. | |
The following syntax will result in fewer problems with many | |
applications that use domain names (e.g., mail, TELNET). | |
<domain> ::= <subdomain> | " " | |
<subdomain> ::= <label> | <subdomain> "." <label> | |
<label> ::= <letter> [ [ <ldh-str> ] <let-dig> ] | |
<ldh-str> ::= <let-dig-hyp> | <let-dig-hyp> <ldh-str> | |
<let-dig-hyp> ::= <let-dig> | "-" | |
<let-dig> ::= <letter> | <digit> | |
<letter> ::= any one of the 52 alphabetic characters A through Z in | |
upper case and a through z in lower case | |
<digit> ::= any one of the ten digits 0 through 9 | |
Note that while upper and lower case letters are allowed in domain | |
names, no significance is attached to the case. That is, two names with | |
the same spelling but different case are to be treated as if identical. | |
The labels must follow the rules for ARPANET host names. They must | |
start with a letter, end with a letter or digit, and have as interior | |
characters only letters, digits, and hyphen. There are also some | |
restrictions on the length. Labels must be 63 characters or less. | |
For example, the following strings identify hosts in the Internet: | |
A.ISI.EDU XX.LCS.MIT.EDU SRI-NIC.ARPA | |
3.6. Resource Records | |
A domain name identifies a node. Each node has a set of resource | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
information, which may be empty. The set of resource information | |
associated with a particular name is composed of separate resource | |
records (RRs). The order of RRs in a set is not significant, and need | |
not be preserved by name servers, resolvers, or other parts of the DNS. | |
When we talk about a specific RR, we assume it has the following: | |
owner which is the domain name where the RR is found. | |
type which is an encoded 16 bit value that specifies the type | |
of the resource in this resource record. Types refer to | |
abstract resources. | |
This memo uses the following types: | |
A a host address | |
CNAME identifies the canonical name of an | |
alias | |
HINFO identifies the CPU and OS used by a host | |
MX identifies a mail exchange for the | |
domain. See [RFC-974 for details. | |
NS | |
the authoritative name server for the domain | |
PTR | |
a pointer to another part of the domain name space | |
SOA | |
identifies the start of a zone of authority] | |
class which is an encoded 16 bit value which identifies a | |
protocol family or instance of a protocol. | |
This memo uses the following classes: | |
IN the Internet system | |
CH the Chaos system | |
TTL which is the time to live of the RR. This field is a 32 | |
bit integer in units of seconds, an is primarily used by | |
resolvers when they cache RRs. The TTL describes how | |
long a RR can be cached before it should be discarded. | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
RDATA which is the type and sometimes class dependent data | |
which describes the resource: | |
A For the IN class, a 32 bit IP address | |
For the CH class, a domain name followed | |
by a 16 bit octal Chaos address. | |
CNAME a domain name. | |
MX a 16 bit preference value (lower is | |
better) followed by a host name willing | |
to act as a mail exchange for the owner | |
domain. | |
NS a host name. | |
PTR a domain name. | |
SOA several fields. | |
The owner name is often implicit, rather than forming an integral part | |
of the RR. For example, many name servers internally form tree or hash | |
structures for the name space, and chain RRs off nodes. The remaining | |
RR parts are the fixed header (type, class, TTL) which is consistent for | |
all RRs, and a variable part (RDATA) that fits the needs of the resource | |
being described. | |
The meaning of the TTL field is a time limit on how long an RR can be | |
kept in a cache. This limit does not apply to authoritative data in | |
zones; it is also timed out, but by the refreshing policies for the | |
zone. The TTL is assigned by the administrator for the zone where the | |
data originates. While short TTLs can be used to minimize caching, and | |
a zero TTL prohibits caching, the realities of Internet performance | |
suggest that these times should be on the order of days for the typical | |
host. If a change can be anticipated, the TTL can be reduced prior to | |
the change to minimize inconsistency during the change, and then | |
increased back to its former value following the change. | |
The data in the RDATA section of RRs is carried as a combination of | |
binary strings and domain names. The domain names are frequently used | |
as "pointers" to other data in the DNS. | |
3.6.1. Textual expression of RRs | |
RRs are represented in binary form in the packets of the DNS protocol, | |
and are usually represented in highly encoded form when stored in a name | |
server or resolver. In this memo, we adopt a style similar to that used | |
Mockapetris [Page 13] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
in master files in order to show the contents of RRs. In this format, | |
most RRs are shown on a single line, although continuation lines are | |
possible using parentheses. | |
The start of the line gives the owner of the RR. If a line begins with | |
a blank, then the owner is assumed to be the same as that of the | |
previous RR. Blank lines are often included for readability. | |
Following the owner, we list the TTL, type, and class of the RR. Class | |
and type use the mnemonics defined above, and TTL is an integer before | |
the type field. In order to avoid ambiguity in parsing, type and class | |
mnemonics are disjoint, TTLs are integers, and the type mnemonic is | |
always last. The IN class and TTL values are often omitted from examples | |
in the interests of clarity. | |
The resource data or RDATA section of the RR are given using knowledge | |
of the typical representation for the data. | |
For example, we might show the RRs carried in a message as: | |
ISI.EDU. MX 10 VENERA.ISI.EDU. | |
MX 10 VAXA.ISI.EDU. | |
VENERA.ISI.EDU. A 128.9.0.32 | |
A 10.1.0.52 | |
VAXA.ISI.EDU. A 10.2.0.27 | |
A 128.9.0.33 | |
The MX RRs have an RDATA section which consists of a 16 bit number | |
followed by a domain name. The address RRs use a standard IP address | |
format to contain a 32 bit internet address. | |
This example shows six RRs, with two RRs at each of three domain names. | |
Similarly we might see: | |
XX.LCS.MIT.EDU. IN A 10.0.0.44 | |
CH A MIT.EDU. 2420 | |
This example shows two addresses for XX.LCS.MIT.EDU, each of a different | |
class. | |
3.6.2. Aliases and canonical names | |
In existing systems, hosts and other resources often have several names | |
that identify the same resource. For example, the names C.ISI.EDU and | |
USC-ISIC.ARPA both identify the same host. Similarly, in the case of | |
mailboxes, many organizations provide many names that actually go to the | |
same mailbox; for example [email protected], [email protected], | |
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and [email protected] all go to the same mailbox (although the mechanism | |
behind this is somewhat complicated). | |
Most of these systems have a notion that one of the equivalent set of | |
names is the canonical or primary name and all others are aliases. | |
The domain system provides such a feature using the canonical name | |
(CNAME) RR. A CNAME RR identifies its owner name as an alias, and | |
specifies the corresponding canonical name in the RDATA section of the | |
RR. If a CNAME RR is present at a node, no other data should be | |
present; this ensures that the data for a canonical name and its aliases | |
cannot be different. This rule also insures that a cached CNAME can be | |
used without checking with an authoritative server for other RR types. | |
CNAME RRs cause special action in DNS software. When a name server | |
fails to find a desired RR in the resource set associated with the | |
domain name, it checks to see if the resource set consists of a CNAME | |
record with a matching class. If so, the name server includes the CNAME | |
record in the response and restarts the query at the domain name | |
specified in the data field of the CNAME record. The one exception to | |
this rule is that queries which match the CNAME type are not restarted. | |
For example, suppose a name server was processing a query with for USC- | |
ISIC.ARPA, asking for type A information, and had the following resource | |
records: | |
USC-ISIC.ARPA IN CNAME C.ISI.EDU | |
C.ISI.EDU IN A 10.0.0.52 | |
Both of these RRs would be returned in the response to the type A query, | |
while a type CNAME or * query should return just the CNAME. | |
Domain names in RRs which point at another name should always point at | |
the primary name and not the alias. This avoids extra indirections in | |
accessing information. For example, the address to name RR for the | |
above host should be: | |
52.0.0.10.IN-ADDR.ARPA IN PTR C.ISI.EDU | |
rather than pointing at USC-ISIC.ARPA. Of course, by the robustness | |
principle, domain software should not fail when presented with CNAME | |
chains or loops; CNAME chains should be followed and CNAME loops | |
signalled as an error. | |
3.7. Queries | |
Queries are messages which may be sent to a name server to provoke a | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
response. In the Internet, queries are carried in UDP datagrams or over | |
TCP connections. The response by the name server either answers the | |
question posed in the query, refers the requester to another set of name | |
servers, or signals some error condition. | |
In general, the user does not generate queries directly, but instead | |
makes a request to a resolver which in turn sends one or more queries to | |
name servers and deals with the error conditions and referrals that may | |
result. Of course, the possible questions which can be asked in a query | |
does shape the kind of service a resolver can provide. | |
DNS queries and responses are carried in a standard message format. The | |
message format has a header containing a number of fixed fields which | |
are always present, and four sections which carry query parameters and | |
RRs. | |
The most important field in the header is a four bit field called an | |
opcode which separates different queries. Of the possible 16 values, | |
one (standard query) is part of the official protocol, two (inverse | |
query and status query) are options, one (completion) is obsolete, and | |
the rest are unassigned. | |
The four sections are: | |
Question Carries the query name and other query parameters. | |
Answer Carries RRs which directly answer the query. | |
Authority Carries RRs which describe other authoritative servers. | |
May optionally carry the SOA RR for the authoritative | |
data in the answer section. | |
Additional Carries RRs which may be helpful in using the RRs in the | |
other sections. | |
Note that the content, but not the format, of these sections varies with | |
header opcode. | |
3.7.1. Standard queries | |
A standard query specifies a target domain name (QNAME), query type | |
(QTYPE), and query class (QCLASS) and asks for RRs which match. This | |
type of query makes up such a vast majority of DNS queries that we use | |
the term "query" to mean standard query unless otherwise specified. The | |
QTYPE and QCLASS fields are each 16 bits long, and are a superset of | |
defined types and classes. | |
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The QTYPE field may contain: | |
<any type> matches just that type. (e.g., A, PTR). | |
AXFR special zone transfer QTYPE. | |
MAILB matches all mail box related RRs (e.g. MB and MG). | |
* matches all RR types. | |
The QCLASS field may contain: | |
<any class> matches just that class (e.g., IN, CH). | |
* matches aLL RR classes. | |
Using the query domain name, QTYPE, and QCLASS, the name server looks | |
for matching RRs. In addition to relevant records, the name server may | |
return RRs that point toward a name server that has the desired | |
information or RRs that are expected to be useful in interpreting the | |
relevant RRs. For example, a name server that doesn't have the | |
requested information may know a name server that does; a name server | |
that returns a domain name in a relevant RR may also return the RR that | |
binds that domain name to an address. | |
For example, a mailer tying to send mail to [email protected] might | |
ask the resolver for mail information about ISI.EDU, resulting in a | |
query for QNAME=ISI.EDU, QTYPE=MX, QCLASS=IN. The response's answer | |
section would be: | |
ISI.EDU. MX 10 VENERA.ISI.EDU. | |
MX 10 VAXA.ISI.EDU. | |
while the additional section might be: | |
VAXA.ISI.EDU. A 10.2.0.27 | |
A 128.9.0.33 | |
VENERA.ISI.EDU. A 10.1.0.52 | |
A 128.9.0.32 | |
Because the server assumes that if the requester wants mail exchange | |
information, it will probably want the addresses of the mail exchanges | |
soon afterward. | |
Note that the QCLASS=* construct requires special interpretation | |
regarding authority. Since a particular name server may not know all of | |
the classes available in the domain system, it can never know if it is | |
authoritative for all classes. Hence responses to QCLASS=* queries can | |
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never be authoritative. | |
3.7.2. Inverse queries (Optional) | |
Name servers may also support inverse queries that map a particular | |
resource to a domain name or domain names that have that resource. For | |
example, while a standard query might map a domain name to a SOA RR, the | |
corresponding inverse query might map the SOA RR back to the domain | |
name. | |
Implementation of this service is optional in a name server, but all | |
name servers must at least be able to understand an inverse query | |
message and return a not-implemented error response. | |
The domain system cannot guarantee the completeness or uniqueness of | |
inverse queries because the domain system is organized by domain name | |
rather than by host address or any other resource type. Inverse queries | |
are primarily useful for debugging and database maintenance activities. | |
Inverse queries may not return the proper TTL, and do not indicate cases | |
where the identified RR is one of a set (for example, one address for a | |
host having multiple addresses). Therefore, the RRs returned in inverse | |
queries should never be cached. | |
Inverse queries are NOT an acceptable method for mapping host addresses | |
to host names; use the IN-ADDR.ARPA domain instead. | |
A detailed discussion of inverse queries is contained in [RFC-1035]. | |
3.8. Status queries (Experimental) | |
To be defined. | |
3.9. Completion queries (Obsolete) | |
The optional completion services described in RFCs 882 and 883 have been | |
deleted. Redesigned services may become available in the future, or the | |
opcodes may be reclaimed for other use. | |
4. NAME SERVERS | |
4.1. Introduction | |
Name servers are the repositories of information that make up the domain | |
database. The database is divided up into sections called zones, which | |
are distributed among the name servers. While name servers can have | |
several optional functions and sources of data, the essential task of a | |
name server is to answer queries using data in its zones. By design, | |
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name servers can answer queries in a simple manner; the response can | |
always be generated using only local data, and either contains the | |
answer to the question or a referral to other name servers "closer" to | |
the desired information. | |
A given zone will be available from several name servers to insure its | |
availability in spite of host or communication link failure. By | |
administrative fiat, we require every zone to be available on at least | |
two servers, and many zones have more redundancy than that. | |
A given name server will typically support one or more zones, but this | |
gives it authoritative information about only a small section of the | |
domain tree. It may also have some cached non-authoritative data about | |
other parts of the tree. The name server marks its responses to queries | |
so that the requester can tell whether the response comes from | |
authoritative data or not. | |
4.2. How the database is divided into zones | |
The domain database is partitioned in two ways: by class, and by "cuts" | |
made in the name space between nodes. | |
The class partition is simple. The database for any class is organized, | |
delegated, and maintained separately from all other classes. Since, by | |
convention, the name spaces are the same for all classes, the separate | |
classes can be thought of as an array of parallel namespace trees. Note | |
that the data attached to nodes will be different for these different | |
parallel classes. The most common reasons for creating a new class are | |
the necessity for a new data format for existing types or a desire for a | |
separately managed version of the existing name space. | |
Within a class, "cuts" in the name space can be made between any two | |
adjacent nodes. After all cuts are made, each group of connected name | |
space is a separate zone. The zone is said to be authoritative for all | |
names in the connected region. Note that the "cuts" in the name space | |
may be in different places for different classes, the name servers may | |
be different, etc. | |
These rules mean that every zone has at least one node, and hence domain | |
name, for which it is authoritative, and all of the nodes in a | |
particular zone are connected. Given, the tree structure, every zone | |
has a highest node which is closer to the root than any other node in | |
the zone. The name of this node is often used to identify the zone. | |
It would be possible, though not particularly useful, to partition the | |
name space so that each domain name was in a separate zone or so that | |
all nodes were in a single zone. Instead, the database is partitioned | |
at points where a particular organization wants to take over control of | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
a subtree. Once an organization controls its own zone it can | |
unilaterally change the data in the zone, grow new tree sections | |
connected to the zone, delete existing nodes, or delegate new subzones | |
under its zone. | |
If the organization has substructure, it may want to make further | |
internal partitions to achieve nested delegations of name space control. | |
In some cases, such divisions are made purely to make database | |
maintenance more convenient. | |
4.2.1. Technical considerations | |
The data that describes a zone has four major parts: | |
- Authoritative data for all nodes within the zone. | |
- Data that defines the top node of the zone (can be thought of | |
as part of the authoritative data). | |
- Data that describes delegated subzones, i.e., cuts around the | |
bottom of the zone. | |
- Data that allows access to name servers for subzones | |
(sometimes called "glue" data). | |
All of this data is expressed in the form of RRs, so a zone can be | |
completely described in terms of a set of RRs. Whole zones can be | |
transferred between name servers by transferring the RRs, either carried | |
in a series of messages or by FTPing a master file which is a textual | |
representation. | |
The authoritative data for a zone is simply all of the RRs attached to | |
all of the nodes from the top node of the zone down to leaf nodes or | |
nodes above cuts around the bottom edge of the zone. | |
Though logically part of the authoritative data, the RRs that describe | |
the top node of the zone are especially important to the zone's | |
management. These RRs are of two types: name server RRs that list, one | |
per RR, all of the servers for the zone, and a single SOA RR that | |
describes zone management parameters. | |
The RRs that describe cuts around the bottom of the zone are NS RRs that | |
name the servers for the subzones. Since the cuts are between nodes, | |
these RRs are NOT part of the authoritative data of the zone, and should | |
be exactly the same as the corresponding RRs in the top node of the | |
subzone. Since name servers are always associated with zone boundaries, | |
NS RRs are only found at nodes which are the top node of some zone. In | |
the data that makes up a zone, NS RRs are found at the top node of the | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
zone (and are authoritative) and at cuts around the bottom of the zone | |
(where they are not authoritative), but never in between. | |
One of the goals of the zone structure is that any zone have all the | |
data required to set up communications with the name servers for any | |
subzones. That is, parent zones have all the information needed to | |
access servers for their children zones. The NS RRs that name the | |
servers for subzones are often not enough for this task since they name | |
the servers, but do not give their addresses. In particular, if the | |
name of the name server is itself in the subzone, we could be faced with | |
the situation where the NS RRs tell us that in order to learn a name | |
server's address, we should contact the server using the address we wish | |
to learn. To fix this problem, a zone contains "glue" RRs which are not | |
part of the authoritative data, and are address RRs for the servers. | |
These RRs are only necessary if the name server's name is "below" the | |
cut, and are only used as part of a referral response. | |
4.2.2. Administrative considerations | |
When some organization wants to control its own domain, the first step | |
is to identify the proper parent zone, and get the parent zone's owners | |
to agree to the delegation of control. While there are no particular | |
technical constraints dealing with where in the tree this can be done, | |
there are some administrative groupings discussed in [RFC-1032] which | |
deal with top level organization, and middle level zones are free to | |
create their own rules. For example, one university might choose to use | |
a single zone, while another might choose to organize by subzones | |
dedicated to individual departments or schools. [RFC-1033] catalogs | |
available DNS software an discusses administration procedures. | |
Once the proper name for the new subzone is selected, the new owners | |
should be required to demonstrate redundant name server support. Note | |
that there is no requirement that the servers for a zone reside in a | |
host which has a name in that domain. In many cases, a zone will be | |
more accessible to the internet at large if its servers are widely | |
distributed rather than being within the physical facilities controlled | |
by the same organization that manages the zone. For example, in the | |
current DNS, one of the name servers for the United Kingdom, or UK | |
domain, is found in the US. This allows US hosts to get UK data without | |
using limited transatlantic bandwidth. | |
As the last installation step, the delegation NS RRs and glue RRs | |
necessary to make the delegation effective should be added to the parent | |
zone. The administrators of both zones should insure that the NS and | |
glue RRs which mark both sides of the cut are consistent and remain so. | |
4.3. Name server internals | |
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4.3.1. Queries and responses | |
The principal activity of name servers is to answer standard queries. | |
Both the query and its response are carried in a standard message format | |
which is described in [RFC-1035]. The query contains a QTYPE, QCLASS, | |
and QNAME, which describe the types and classes of desired information | |
and the name of interest. | |
The way that the name server answers the query depends upon whether it | |
is operating in recursive mode or not: | |
- The simplest mode for the server is non-recursive, since it | |
can answer queries using only local information: the response | |
contains an error, the answer, or a referral to some other | |
server "closer" to the answer. All name servers must | |
implement non-recursive queries. | |
- The simplest mode for the client is recursive, since in this | |
mode the name server acts in the role of a resolver and | |
returns either an error or the answer, but never referrals. | |
This service is optional in a name server, and the name server | |
may also choose to restrict the clients which can use | |
recursive mode. | |
Recursive service is helpful in several situations: | |
- a relatively simple requester that lacks the ability to use | |
anything other than a direct answer to the question. | |
- a request that needs to cross protocol or other boundaries and | |
can be sent to a server which can act as intermediary. | |
- a network where we want to concentrate the cache rather than | |
having a separate cache for each client. | |
Non-recursive service is appropriate if the requester is capable of | |
pursuing referrals and interested in information which will aid future | |
requests. | |
The use of recursive mode is limited to cases where both the client and | |
the name server agree to its use. The agreement is negotiated through | |
the use of two bits in query and response messages: | |
- The recursion available, or RA bit, is set or cleared by a | |
name server in all responses. The bit is true if the name | |
server is willing to provide recursive service for the client, | |
regardless of whether the client requested recursive service. | |
That is, RA signals availability rather than use. | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
- Queries contain a bit called recursion desired or RD. This | |
bit specifies specifies whether the requester wants recursive | |
service for this query. Clients may request recursive service | |
from any name server, though they should depend upon receiving | |
it only from servers which have previously sent an RA, or | |
servers which have agreed to provide service through private | |
agreement or some other means outside of the DNS protocol. | |
The recursive mode occurs when a query with RD set arrives at a server | |
which is willing to provide recursive service; the client can verify | |
that recursive mode was used by checking that both RA and RD are set in | |
the reply. Note that the name server should never perform recursive | |
service unless asked via RD, since this interferes with trouble shooting | |
of name servers and their databases. | |
If recursive service is requested and available, the recursive response | |
to a query will be one of the following: | |
- The answer to the query, possibly preface by one or more CNAME | |
RRs that specify aliases encountered on the way to an answer. | |
- A name error indicating that the name does not exist. This | |
may include CNAME RRs that indicate that the original query | |
name was an alias for a name which does not exist. | |
- A temporary error indication. | |
If recursive service is not requested or is not available, the non- | |
recursive response will be one of the following: | |
- An authoritative name error indicating that the name does not | |
exist. | |
- A temporary error indication. | |
- Some combination of: | |
RRs that answer the question, together with an indication | |
whether the data comes from a zone or is cached. | |
A referral to name servers which have zones which are closer | |
ancestors to the name than the server sending the reply. | |
- RRs that the name server thinks will prove useful to the | |
requester. | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
4.3.2. Algorithm | |
The actual algorithm used by the name server will depend on the local OS | |
and data structures used to store RRs. The following algorithm assumes | |
that the RRs are organized in several tree structures, one for each | |
zone, and another for the cache: | |
1. Set or clear the value of recursion available in the response | |
depending on whether the name server is willing to provide | |
recursive service. If recursive service is available and | |
requested via the RD bit in the query, go to step 5, | |
otherwise step 2. | |
2. Search the available zones for the zone which is the nearest | |
ancestor to QNAME. If such a zone is found, go to step 3, | |
otherwise step 4. | |
3. Start matching down, label by label, in the zone. The | |
matching process can terminate several ways: | |
a. If the whole of QNAME is matched, we have found the | |
node. | |
If the data at the node is a CNAME, and QTYPE doesn't | |
match CNAME, copy the CNAME RR into the answer section | |
of the response, change QNAME to the canonical name in | |
the CNAME RR, and go back to step 1. | |
Otherwise, copy all RRs which match QTYPE into the | |
answer section and go to step 6. | |
b. If a match would take us out of the authoritative data, | |
we have a referral. This happens when we encounter a | |
node with NS RRs marking cuts along the bottom of a | |
zone. | |
Copy the NS RRs for the subzone into the authority | |
section of the reply. Put whatever addresses are | |
available into the additional section, using glue RRs | |
if the addresses are not available from authoritative | |
data or the cache. Go to step 4. | |
c. If at some label, a match is impossible (i.e., the | |
corresponding label does not exist), look to see if a | |
the "*" label exists. | |
If the "*" label does not exist, check whether the name | |
we are looking for is the original QNAME in the query | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
or a name we have followed due to a CNAME. If the name | |
is original, set an authoritative name error in the | |
response and exit. Otherwise just exit. | |
If the "*" label does exist, match RRs at that node | |
against QTYPE. If any match, copy them into the answer | |
section, but set the owner of the RR to be QNAME, and | |
not the node with the "*" label. Go to step 6. | |
4. Start matching down in the cache. If QNAME is found in the | |
cache, copy all RRs attached to it that match QTYPE into the | |
answer section. If there was no delegation from | |
authoritative data, look for the best one from the cache, and | |
put it in the authority section. Go to step 6. | |
5. Using the local resolver or a copy of its algorithm (see | |
resolver section of this memo) to answer the query. Store | |
the results, including any intermediate CNAMEs, in the answer | |
section of the response. | |
6. Using local data only, attempt to add other RRs which may be | |
useful to the additional section of the query. Exit. | |
4.3.3. Wildcards | |
In the previous algorithm, special treatment was given to RRs with owner | |
names starting with the label "*". Such RRs are called wildcards. | |
Wildcard RRs can be thought of as instructions for synthesizing RRs. | |
When the appropriate conditions are met, the name server creates RRs | |
with an owner name equal to the query name and contents taken from the | |
wildcard RRs. | |
This facility is most often used to create a zone which will be used to | |
forward mail from the Internet to some other mail system. The general | |
idea is that any name in that zone which is presented to server in a | |
query will be assumed to exist, with certain properties, unless explicit | |
evidence exists to the contrary. Note that the use of the term zone | |
here, instead of domain, is intentional; such defaults do not propagate | |
across zone boundaries, although a subzone may choose to achieve that | |
appearance by setting up similar defaults. | |
The contents of the wildcard RRs follows the usual rules and formats for | |
RRs. The wildcards in the zone have an owner name that controls the | |
query names they will match. The owner name of the wildcard RRs is of | |
the form "*.<anydomain>", where <anydomain> is any domain name. | |
<anydomain> should not contain other * labels, and should be in the | |
authoritative data of the zone. The wildcards potentially apply to | |
descendants of <anydomain>, but not to <anydomain> itself. Another way | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
to look at this is that the "*" label always matches at least one whole | |
label and sometimes more, but always whole labels. | |
Wildcard RRs do not apply: | |
- When the query is in another zone. That is, delegation cancels | |
the wildcard defaults. | |
- When the query name or a name between the wildcard domain and | |
the query name is know to exist. For example, if a wildcard | |
RR has an owner name of "*.X", and the zone also contains RRs | |
attached to B.X, the wildcards would apply to queries for name | |
Z.X (presuming there is no explicit information for Z.X), but | |
not to B.X, A.B.X, or X. | |
A * label appearing in a query name has no special effect, but can be | |
used to test for wildcards in an authoritative zone; such a query is the | |
only way to get a response containing RRs with an owner name with * in | |
it. The result of such a query should not be cached. | |
Note that the contents of the wildcard RRs are not modified when used to | |
synthesize RRs. | |
To illustrate the use of wildcard RRs, suppose a large company with a | |
large, non-IP/TCP, network wanted to create a mail gateway. If the | |
company was called X.COM, and IP/TCP capable gateway machine was called | |
A.X.COM, the following RRs might be entered into the COM zone: | |
X.COM MX 10 A.X.COM | |
*.X.COM MX 10 A.X.COM | |
A.X.COM A 1.2.3.4 | |
A.X.COM MX 10 A.X.COM | |
*.A.X.COM MX 10 A.X.COM | |
This would cause any MX query for any domain name ending in X.COM to | |
return an MX RR pointing at A.X.COM. Two wildcard RRs are required | |
since the effect of the wildcard at *.X.COM is inhibited in the A.X.COM | |
subtree by the explicit data for A.X.COM. Note also that the explicit | |
MX data at X.COM and A.X.COM is required, and that none of the RRs above | |
would match a query name of XX.COM. | |
4.3.4. Negative response caching (Optional) | |
The DNS provides an optional service which allows name servers to | |
distribute, and resolvers to cache, negative results with TTLs. For | |
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RFC 1034 Domain Concepts and Facilities November 1987 | |
example, a name server can distribute a TTL along with a name error | |
indication, and a resolver receiving such information is allowed to | |
assume that the name does not exist during the TTL period without | |
consulting authoritative data. Similarly, a resolver can make a query | |
with a QTYPE which matches multiple types, and cache the fact that some | |
of the types are not present. | |
This feature can be particularly important in a system which implements | |
naming shorthands that use search lists beacuse a popular shorthand, | |
which happens to require a suffix toward the end of the search list, | |
will generate multiple name errors whenever it is used. | |
The method is that a name server may add an SOA RR to the additional | |
section of a response when that response is authoritative. The SOA must | |
be that of the zone which was the source of the authoritative data in | |
the answer section, or name error if applicable. The MINIMUM field of | |
the SOA controls the length of time that the negative result may be | |
cached. | |
Note that in some circumstances, the answer section may contain multiple | |
owner names. In this case, the SOA mechanism should only be used for | |
the data which matches QNAME, which is the only authoritative data in | |
this section. | |
Name servers and resolvers should never attempt to add SOAs to the | |
additional section of a non-authoritative response, or attempt to infer | |
results which are not directly stated in an authoritative response. | |
There are several reasons for this, including: cached information isn't | |
usually enough to match up RRs and their zone names, SOA RRs may be | |
cached due to direct SOA queries, and name servers are not required to | |
output the SOAs in the authority section. | |
This feature is optional, although a refined version is expected to | |
become part of the standard protocol in the future. Name servers are | |
not required to add the SOA RRs in all authoritative responses, nor are | |
resolvers required to cache negative results. Both are recommended. | |
All resolvers and recursive name servers are required to at least be | |
able to ignore the SOA RR when it is present in a response. | |
Some experiments have also been proposed which will use this feature. | |
The idea is that if cached data is known to come from a particular zone, | |
and if an authoritative copy of the zone's SOA is obtained, and if the | |
zone's SERIAL has not changed since the data was cached, then the TTL of | |
the cached data can be reset to the zone MINIMUM value if it is smaller. | |
This usage is mentioned for planning purposes only, and is not | |
recommended as yet. | |
Mockapetris [Page 27] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
4.3.5. Zone maintenance and transfers | |
Part of the job of a zone administrator is to maintain the zones at all | |
of the name servers which are authoritative for the zone. When the | |
inevitable changes are made, they must be distributed to all of the name | |
servers. While this distribution can be accomplished using FTP or some | |
other ad hoc procedure, the preferred method is the zone transfer part | |
of the DNS protocol. | |
The general model of automatic zone transfer or refreshing is that one | |
of the name servers is the master or primary for the zone. Changes are | |
coordinated at the primary, typically by editing a master file for the | |
zone. After editing, the administrator signals the master server to | |
load the new zone. The other non-master or secondary servers for the | |
zone periodically check for changes (at a selectable interval) and | |
obtain new zone copies when changes have been made. | |
To detect changes, secondaries just check the SERIAL field of the SOA | |
for the zone. In addition to whatever other changes are made, the | |
SERIAL field in the SOA of the zone is always advanced whenever any | |
change is made to the zone. The advancing can be a simple increment, or | |
could be based on the write date and time of the master file, etc. The | |
purpose is to make it possible to determine which of two copies of a | |
zone is more recent by comparing serial numbers. Serial number advances | |
and comparisons use sequence space arithmetic, so there is a theoretic | |
limit on how fast a zone can be updated, basically that old copies must | |
die out before the serial number covers half of its 32 bit range. In | |
practice, the only concern is that the compare operation deals properly | |
with comparisons around the boundary between the most positive and most | |
negative 32 bit numbers. | |
The periodic polling of the secondary servers is controlled by | |
parameters in the SOA RR for the zone, which set the minimum acceptable | |
polling intervals. The parameters are called REFRESH, RETRY, and | |
EXPIRE. Whenever a new zone is loaded in a secondary, the secondary | |
waits REFRESH seconds before checking with the primary for a new serial. | |
If this check cannot be completed, new checks are started every RETRY | |
seconds. The check is a simple query to the primary for the SOA RR of | |
the zone. If the serial field in the secondary's zone copy is equal to | |
the serial returned by the primary, then no changes have occurred, and | |
the REFRESH interval wait is restarted. If the secondary finds it | |
impossible to perform a serial check for the EXPIRE interval, it must | |
assume that its copy of the zone is obsolete an discard it. | |
When the poll shows that the zone has changed, then the secondary server | |
must request a zone transfer via an AXFR request for the zone. The AXFR | |
may cause an error, such as refused, but normally is answered by a | |
sequence of response messages. The first and last messages must contain | |
Mockapetris [Page 28] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
the data for the top authoritative node of the zone. Intermediate | |
messages carry all of the other RRs from the zone, including both | |
authoritative and non-authoritative RRs. The stream of messages allows | |
the secondary to construct a copy of the zone. Because accuracy is | |
essential, TCP or some other reliable protocol must be used for AXFR | |
requests. | |
Each secondary server is required to perform the following operations | |
against the master, but may also optionally perform these operations | |
against other secondary servers. This strategy can improve the transfer | |
process when the primary is unavailable due to host downtime or network | |
problems, or when a secondary server has better network access to an | |
"intermediate" secondary than to the primary. | |
5. RESOLVERS | |
5.1. Introduction | |
Resolvers are programs that interface user programs to domain name | |
servers. In the simplest case, a resolver receives a request from a | |
user program (e.g., mail programs, TELNET, FTP) in the form of a | |
subroutine call, system call etc., and returns the desired information | |
in a form compatible with the local host's data formats. | |
The resolver is located on the same machine as the program that requests | |
the resolver's services, but it may need to consult name servers on | |
other hosts. Because a resolver may need to consult several name | |
servers, or may have the requested information in a local cache, the | |
amount of time that a resolver will take to complete can vary quite a | |
bit, from milliseconds to several seconds. | |
A very important goal of the resolver is to eliminate network delay and | |
name server load from most requests by answering them from its cache of | |
prior results. It follows that caches which are shared by multiple | |
processes, users, machines, etc., are more efficient than non-shared | |
caches. | |
5.2. Client-resolver interface | |
5.2.1. Typical functions | |
The client interface to the resolver is influenced by the local host's | |
conventions, but the typical resolver-client interface has three | |
functions: | |
1. Host name to host address translation. | |
This function is often defined to mimic a previous HOSTS.TXT | |
Mockapetris [Page 29] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
based function. Given a character string, the caller wants | |
one or more 32 bit IP addresses. Under the DNS, it | |
translates into a request for type A RRs. Since the DNS does | |
not preserve the order of RRs, this function may choose to | |
sort the returned addresses or select the "best" address if | |
the service returns only one choice to the client. Note that | |
a multiple address return is recommended, but a single | |
address may be the only way to emulate prior HOSTS.TXT | |
services. | |
2. Host address to host name translation | |
This function will often follow the form of previous | |
functions. Given a 32 bit IP address, the caller wants a | |
character string. The octets of the IP address are reversed, | |
used as name components, and suffixed with "IN-ADDR.ARPA". A | |
type PTR query is used to get the RR with the primary name of | |
the host. For example, a request for the host name | |
corresponding to IP address 1.2.3.4 looks for PTR RRs for | |
domain name "4.3.2.1.IN-ADDR.ARPA". | |
3. General lookup function | |
This function retrieves arbitrary information from the DNS, | |
and has no counterpart in previous systems. The caller | |
supplies a QNAME, QTYPE, and QCLASS, and wants all of the | |
matching RRs. This function will often use the DNS format | |
for all RR data instead of the local host's, and returns all | |
RR content (e.g., TTL) instead of a processed form with local | |
quoting conventions. | |
When the resolver performs the indicated function, it usually has one of | |
the following results to pass back to the client: | |
- One or more RRs giving the requested data. | |
In this case the resolver returns the answer in the | |
appropriate format. | |
- A name error (NE). | |
This happens when the referenced name does not exist. For | |
example, a user may have mistyped a host name. | |
- A data not found error. | |
This happens when the referenced name exists, but data of the | |
appropriate type does not. For example, a host address | |
Mockapetris [Page 30] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
function applied to a mailbox name would return this error | |
since the name exists, but no address RR is present. | |
It is important to note that the functions for translating between host | |
names and addresses may combine the "name error" and "data not found" | |
error conditions into a single type of error return, but the general | |
function should not. One reason for this is that applications may ask | |
first for one type of information about a name followed by a second | |
request to the same name for some other type of information; if the two | |
errors are combined, then useless queries may slow the application. | |
5.2.2. Aliases | |
While attempting to resolve a particular request, the resolver may find | |
that the name in question is an alias. For example, the resolver might | |
find that the name given for host name to address translation is an | |
alias when it finds the CNAME RR. If possible, the alias condition | |
should be signalled back from the resolver to the client. | |
In most cases a resolver simply restarts the query at the new name when | |
it encounters a CNAME. However, when performing the general function, | |
the resolver should not pursue aliases when the CNAME RR matches the | |
query type. This allows queries which ask whether an alias is present. | |
For example, if the query type is CNAME, the user is interested in the | |
CNAME RR itself, and not the RRs at the name it points to. | |
Several special conditions can occur with aliases. Multiple levels of | |
aliases should be avoided due to their lack of efficiency, but should | |
not be signalled as an error. Alias loops and aliases which point to | |
non-existent names should be caught and an error condition passed back | |
to the client. | |
5.2.3. Temporary failures | |
In a less than perfect world, all resolvers will occasionally be unable | |
to resolve a particular request. This condition can be caused by a | |
resolver which becomes separated from the rest of the network due to a | |
link failure or gateway problem, or less often by coincident failure or | |
unavailability of all servers for a particular domain. | |
It is essential that this sort of condition should not be signalled as a | |
name or data not present error to applications. This sort of behavior | |
is annoying to humans, and can wreak havoc when mail systems use the | |
DNS. | |
While in some cases it is possible to deal with such a temporary problem | |
by blocking the request indefinitely, this is usually not a good choice, | |
particularly when the client is a server process that could move on to | |
Mockapetris [Page 31] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
other tasks. The recommended solution is to always have temporary | |
failure as one of the possible results of a resolver function, even | |
though this may make emulation of existing HOSTS.TXT functions more | |
difficult. | |
5.3. Resolver internals | |
Every resolver implementation uses slightly different algorithms, and | |
typically spends much more logic dealing with errors of various sorts | |
than typical occurances. This section outlines a recommended basic | |
strategy for resolver operation, but leaves details to [RFC-1035]. | |
5.3.1. Stub resolvers | |
One option for implementing a resolver is to move the resolution | |
function out of the local machine and into a name server which supports | |
recursive queries. This can provide an easy method of providing domain | |
service in a PC which lacks the resources to perform the resolver | |
function, or can centralize the cache for a whole local network or | |
organization. | |
All that the remaining stub needs is a list of name server addresses | |
that will perform the recursive requests. This type of resolver | |
presumably needs the information in a configuration file, since it | |
probably lacks the sophistication to locate it in the domain database. | |
The user also needs to verify that the listed servers will perform the | |
recursive service; a name server is free to refuse to perform recursive | |
services for any or all clients. The user should consult the local | |
system administrator to find name servers willing to perform the | |
service. | |
This type of service suffers from some drawbacks. Since the recursive | |
requests may take an arbitrary amount of time to perform, the stub may | |
have difficulty optimizing retransmission intervals to deal with both | |
lost UDP packets and dead servers; the name server can be easily | |
overloaded by too zealous a stub if it interprets retransmissions as new | |
requests. Use of TCP may be an answer, but TCP may well place burdens | |
on the host's capabilities which are similar to those of a real | |
resolver. | |
5.3.2. Resources | |
In addition to its own resources, the resolver may also have shared | |
access to zones maintained by a local name server. This gives the | |
resolver the advantage of more rapid access, but the resolver must be | |
careful to never let cached information override zone data. In this | |
discussion the term "local information" is meant to mean the union of | |
the cache and such shared zones, with the understanding that | |
Mockapetris [Page 32] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
authoritative data is always used in preference to cached data when both | |
are present. | |
The following resolver algorithm assumes that all functions have been | |
converted to a general lookup function, and uses the following data | |
structures to represent the state of a request in progress in the | |
resolver: | |
SNAME the domain name we are searching for. | |
STYPE the QTYPE of the search request. | |
SCLASS the QCLASS of the search request. | |
SLIST a structure which describes the name servers and the | |
zone which the resolver is currently trying to query. | |
This structure keeps track of the resolver's current | |
best guess about which name servers hold the desired | |
information; it is updated when arriving information | |
changes the guess. This structure includes the | |
equivalent of a zone name, the known name servers for | |
the zone, the known addresses for the name servers, and | |
history information which can be used to suggest which | |
server is likely to be the best one to try next. The | |
zone name equivalent is a match count of the number of | |
labels from the root down which SNAME has in common with | |
the zone being queried; this is used as a measure of how | |
"close" the resolver is to SNAME. | |
SBELT a "safety belt" structure of the same form as SLIST, | |
which is initialized from a configuration file, and | |
lists servers which should be used when the resolver | |
doesn't have any local information to guide name server | |
selection. The match count will be -1 to indicate that | |
no labels are known to match. | |
CACHE A structure which stores the results from previous | |
responses. Since resolvers are responsible for | |
discarding old RRs whose TTL has expired, most | |
implementations convert the interval specified in | |
arriving RRs to some sort of absolute time when the RR | |
is stored in the cache. Instead of counting the TTLs | |
down individually, the resolver just ignores or discards | |
old RRs when it runs across them in the course of a | |
search, or discards them during periodic sweeps to | |
reclaim the memory consumed by old RRs. | |
Mockapetris [Page 33] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
5.3.3. Algorithm | |
The top level algorithm has four steps: | |
1. See if the answer is in local information, and if so return | |
it to the client. | |
2. Find the best servers to ask. | |
3. Send them queries until one returns a response. | |
4. Analyze the response, either: | |
a. if the response answers the question or contains a name | |
error, cache the data as well as returning it back to | |
the client. | |
b. if the response contains a better delegation to other | |
servers, cache the delegation information, and go to | |
step 2. | |
c. if the response shows a CNAME and that is not the | |
answer itself, cache the CNAME, change the SNAME to the | |
canonical name in the CNAME RR and go to step 1. | |
d. if the response shows a servers failure or other | |
bizarre contents, delete the server from the SLIST and | |
go back to step 3. | |
Step 1 searches the cache for the desired data. If the data is in the | |
cache, it is assumed to be good enough for normal use. Some resolvers | |
have an option at the user interface which will force the resolver to | |
ignore the cached data and consult with an authoritative server. This | |
is not recommended as the default. If the resolver has direct access to | |
a name server's zones, it should check to see if the desired data is | |
present in authoritative form, and if so, use the authoritative data in | |
preference to cached data. | |
Step 2 looks for a name server to ask for the required data. The | |
general strategy is to look for locally-available name server RRs, | |
starting at SNAME, then the parent domain name of SNAME, the | |
grandparent, and so on toward the root. Thus if SNAME were | |
Mockapetris.ISI.EDU, this step would look for NS RRs for | |
Mockapetris.ISI.EDU, then ISI.EDU, then EDU, and then . (the root). | |
These NS RRs list the names of hosts for a zone at or above SNAME. Copy | |
the names into SLIST. Set up their addresses using local data. It may | |
be the case that the addresses are not available. The resolver has many | |
choices here; the best is to start parallel resolver processes looking | |
Mockapetris [Page 34] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
for the addresses while continuing onward with the addresses which are | |
available. Obviously, the design choices and options are complicated | |
and a function of the local host's capabilities. The recommended | |
priorities for the resolver designer are: | |
1. Bound the amount of work (packets sent, parallel processes | |
started) so that a request can't get into an infinite loop or | |
start off a chain reaction of requests or queries with other | |
implementations EVEN IF SOMEONE HAS INCORRECTLY CONFIGURED | |
SOME DATA. | |
2. Get back an answer if at all possible. | |
3. Avoid unnecessary transmissions. | |
4. Get the answer as quickly as possible. | |
If the search for NS RRs fails, then the resolver initializes SLIST from | |
the safety belt SBELT. The basic idea is that when the resolver has no | |
idea what servers to ask, it should use information from a configuration | |
file that lists several servers which are expected to be helpful. | |
Although there are special situations, the usual choice is two of the | |
root servers and two of the servers for the host's domain. The reason | |
for two of each is for redundancy. The root servers will provide | |
eventual access to all of the domain space. The two local servers will | |
allow the resolver to continue to resolve local names if the local | |
network becomes isolated from the internet due to gateway or link | |
failure. | |
In addition to the names and addresses of the servers, the SLIST data | |
structure can be sorted to use the best servers first, and to insure | |
that all addresses of all servers are used in a round-robin manner. The | |
sorting can be a simple function of preferring addresses on the local | |
network over others, or may involve statistics from past events, such as | |
previous response times and batting averages. | |
Step 3 sends out queries until a response is received. The strategy is | |
to cycle around all of the addresses for all of the servers with a | |
timeout between each transmission. In practice it is important to use | |
all addresses of a multihomed host, and too aggressive a retransmission | |
policy actually slows response when used by multiple resolvers | |
contending for the same name server and even occasionally for a single | |
resolver. SLIST typically contains data values to control the timeouts | |
and keep track of previous transmissions. | |
Step 4 involves analyzing responses. The resolver should be highly | |
paranoid in its parsing of responses. It should also check that the | |
response matches the query it sent using the ID field in the response. | |
Mockapetris [Page 35] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
The ideal answer is one from a server authoritative for the query which | |
either gives the required data or a name error. The data is passed back | |
to the user and entered in the cache for future use if its TTL is | |
greater than zero. | |
If the response shows a delegation, the resolver should check to see | |
that the delegation is "closer" to the answer than the servers in SLIST | |
are. This can be done by comparing the match count in SLIST with that | |
computed from SNAME and the NS RRs in the delegation. If not, the reply | |
is bogus and should be ignored. If the delegation is valid the NS | |
delegation RRs and any address RRs for the servers should be cached. | |
The name servers are entered in the SLIST, and the search is restarted. | |
If the response contains a CNAME, the search is restarted at the CNAME | |
unless the response has the data for the canonical name or if the CNAME | |
is the answer itself. | |
Details and implementation hints can be found in [RFC-1035]. | |
6. A SCENARIO | |
In our sample domain space, suppose we wanted separate administrative | |
control for the root, MIL, EDU, MIT.EDU and ISI.EDU zones. We might | |
allocate name servers as follows: | |
|(C.ISI.EDU,SRI-NIC.ARPA | |
| A.ISI.EDU) | |
+---------------------+------------------+ | |
| | | | |
MIL EDU ARPA | |
|(SRI-NIC.ARPA, |(SRI-NIC.ARPA, | | |
| A.ISI.EDU | C.ISI.EDU) | | |
+-----+-----+ | +------+-----+-----+ | |
| | | | | | | | |
BRL NOSC DARPA | IN-ADDR SRI-NIC ACC | |
| | |
+--------+------------------+---------------+--------+ | |
| | | | | | |
UCI MIT | UDEL YALE | |
|(XX.LCS.MIT.EDU, ISI | |
|ACHILLES.MIT.EDU) |(VAXA.ISI.EDU,VENERA.ISI.EDU, | |
+---+---+ | A.ISI.EDU) | |
| | | | |
LCS ACHILLES +--+-----+-----+--------+ | |
| | | | | | | |
XX A C VAXA VENERA Mockapetris | |
Mockapetris [Page 36] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
In this example, the authoritative name server is shown in parentheses | |
at the point in the domain tree at which is assumes control. | |
Thus the root name servers are on C.ISI.EDU, SRI-NIC.ARPA, and | |
A.ISI.EDU. The MIL domain is served by SRI-NIC.ARPA and A.ISI.EDU. The | |
EDU domain is served by SRI-NIC.ARPA. and C.ISI.EDU. Note that servers | |
may have zones which are contiguous or disjoint. In this scenario, | |
C.ISI.EDU has contiguous zones at the root and EDU domains. A.ISI.EDU | |
has contiguous zones at the root and MIL domains, but also has a non- | |
contiguous zone at ISI.EDU. | |
6.1. C.ISI.EDU name server | |
C.ISI.EDU is a name server for the root, MIL, and EDU domains of the IN | |
class, and would have zones for these domains. The zone data for the | |
root domain might be: | |
. IN SOA SRI-NIC.ARPA. HOSTMASTER.SRI-NIC.ARPA. ( | |
870611 ;serial | |
1800 ;refresh every 30 min | |
300 ;retry every 5 min | |
604800 ;expire after a week | |
86400) ;minimum of a day | |
NS A.ISI.EDU. | |
NS C.ISI.EDU. | |
NS SRI-NIC.ARPA. | |
MIL. 86400 NS SRI-NIC.ARPA. | |
86400 NS A.ISI.EDU. | |
EDU. 86400 NS SRI-NIC.ARPA. | |
86400 NS C.ISI.EDU. | |
SRI-NIC.ARPA. A 26.0.0.73 | |
A 10.0.0.51 | |
MX 0 SRI-NIC.ARPA. | |
HINFO DEC-2060 TOPS20 | |
ACC.ARPA. A 26.6.0.65 | |
HINFO PDP-11/70 UNIX | |
MX 10 ACC.ARPA. | |
USC-ISIC.ARPA. CNAME C.ISI.EDU. | |
73.0.0.26.IN-ADDR.ARPA. PTR SRI-NIC.ARPA. | |
65.0.6.26.IN-ADDR.ARPA. PTR ACC.ARPA. | |
51.0.0.10.IN-ADDR.ARPA. PTR SRI-NIC.ARPA. | |
52.0.0.10.IN-ADDR.ARPA. PTR C.ISI.EDU. | |
Mockapetris [Page 37] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
103.0.3.26.IN-ADDR.ARPA. PTR A.ISI.EDU. | |
A.ISI.EDU. 86400 A 26.3.0.103 | |
C.ISI.EDU. 86400 A 10.0.0.52 | |
This data is represented as it would be in a master file. Most RRs are | |
single line entries; the sole exception here is the SOA RR, which uses | |
"(" to start a multi-line RR and ")" to show the end of a multi-line RR. | |
Since the class of all RRs in a zone must be the same, only the first RR | |
in a zone need specify the class. When a name server loads a zone, it | |
forces the TTL of all authoritative RRs to be at least the MINIMUM field | |
of the SOA, here 86400 seconds, or one day. The NS RRs marking | |
delegation of the MIL and EDU domains, together with the glue RRs for | |
the servers host addresses, are not part of the authoritative data in | |
the zone, and hence have explicit TTLs. | |
Four RRs are attached to the root node: the SOA which describes the root | |
zone and the 3 NS RRs which list the name servers for the root. The | |
data in the SOA RR describes the management of the zone. The zone data | |
is maintained on host SRI-NIC.ARPA, and the responsible party for the | |
zone is [email protected]. A key item in the SOA is the 86400 | |
second minimum TTL, which means that all authoritative data in the zone | |
has at least that TTL, although higher values may be explicitly | |
specified. | |
The NS RRs for the MIL and EDU domains mark the boundary between the | |
root zone and the MIL and EDU zones. Note that in this example, the | |
lower zones happen to be supported by name servers which also support | |
the root zone. | |
The master file for the EDU zone might be stated relative to the origin | |
EDU. The zone data for the EDU domain might be: | |
EDU. IN SOA SRI-NIC.ARPA. HOSTMASTER.SRI-NIC.ARPA. ( | |
870729 ;serial | |
1800 ;refresh every 30 minutes | |
300 ;retry every 5 minutes | |
604800 ;expire after a week | |
86400 ;minimum of a day | |
) | |
NS SRI-NIC.ARPA. | |
NS C.ISI.EDU. | |
UCI 172800 NS ICS.UCI | |
172800 NS ROME.UCI | |
ICS.UCI 172800 A 192.5.19.1 | |
ROME.UCI 172800 A 192.5.19.31 | |
Mockapetris [Page 38] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
ISI 172800 NS VAXA.ISI | |
172800 NS A.ISI | |
172800 NS VENERA.ISI.EDU. | |
VAXA.ISI 172800 A 10.2.0.27 | |
172800 A 128.9.0.33 | |
VENERA.ISI.EDU. 172800 A 10.1.0.52 | |
172800 A 128.9.0.32 | |
A.ISI 172800 A 26.3.0.103 | |
UDEL.EDU. 172800 NS LOUIE.UDEL.EDU. | |
172800 NS UMN-REI-UC.ARPA. | |
LOUIE.UDEL.EDU. 172800 A 10.0.0.96 | |
172800 A 192.5.39.3 | |
YALE.EDU. 172800 NS YALE.ARPA. | |
YALE.EDU. 172800 NS YALE-BULLDOG.ARPA. | |
MIT.EDU. 43200 NS XX.LCS.MIT.EDU. | |
43200 NS ACHILLES.MIT.EDU. | |
XX.LCS.MIT.EDU. 43200 A 10.0.0.44 | |
ACHILLES.MIT.EDU. 43200 A 18.72.0.8 | |
Note the use of relative names here. The owner name for the ISI.EDU. is | |
stated using a relative name, as are two of the name server RR contents. | |
Relative and absolute domain names may be freely intermixed in a master | |
6.2. Example standard queries | |
The following queries and responses illustrate name server behavior. | |
Unless otherwise noted, the queries do not have recursion desired (RD) | |
in the header. Note that the answers to non-recursive queries do depend | |
on the server being asked, but do not depend on the identity of the | |
requester. | |
Mockapetris [Page 39] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
6.2.1. QNAME=SRI-NIC.ARPA, QTYPE=A | |
The query would look like: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY | | |
+---------------------------------------------------+ | |
Question | QNAME=SRI-NIC.ARPA., QCLASS=IN, QTYPE=A | | |
+---------------------------------------------------+ | |
Answer | <empty> | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
The response from C.ISI.EDU would be: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA | | |
+---------------------------------------------------+ | |
Question | QNAME=SRI-NIC.ARPA., QCLASS=IN, QTYPE=A | | |
+---------------------------------------------------+ | |
Answer | SRI-NIC.ARPA. 86400 IN A 26.0.0.73 | | |
| 86400 IN A 10.0.0.51 | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
The header of the response looks like the header of the query, except | |
that the RESPONSE bit is set, indicating that this message is a | |
response, not a query, and the Authoritative Answer (AA) bit is set | |
indicating that the address RRs in the answer section are from | |
authoritative data. The question section of the response matches the | |
question section of the query. | |
Mockapetris [Page 40] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
If the same query was sent to some other server which was not | |
authoritative for SRI-NIC.ARPA, the response might be: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY,RESPONSE | | |
+---------------------------------------------------+ | |
Question | QNAME=SRI-NIC.ARPA., QCLASS=IN, QTYPE=A | | |
+---------------------------------------------------+ | |
Answer | SRI-NIC.ARPA. 1777 IN A 10.0.0.51 | | |
| 1777 IN A 26.0.0.73 | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
This response is different from the previous one in two ways: the header | |
does not have AA set, and the TTLs are different. The inference is that | |
the data did not come from a zone, but from a cache. The difference | |
between the authoritative TTL and the TTL here is due to aging of the | |
data in a cache. The difference in ordering of the RRs in the answer | |
section is not significant. | |
6.2.2. QNAME=SRI-NIC.ARPA, QTYPE=* | |
A query similar to the previous one, but using a QTYPE of *, would | |
receive the following response from C.ISI.EDU: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA | | |
+---------------------------------------------------+ | |
Question | QNAME=SRI-NIC.ARPA., QCLASS=IN, QTYPE=* | | |
+---------------------------------------------------+ | |
Answer | SRI-NIC.ARPA. 86400 IN A 26.0.0.73 | | |
| A 10.0.0.51 | | |
| MX 0 SRI-NIC.ARPA. | | |
| HINFO DEC-2060 TOPS20 | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
Mockapetris [Page 41] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
If a similar query was directed to two name servers which are not | |
authoritative for SRI-NIC.ARPA, the responses might be: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE | | |
+---------------------------------------------------+ | |
Question | QNAME=SRI-NIC.ARPA., QCLASS=IN, QTYPE=* | | |
+---------------------------------------------------+ | |
Answer | SRI-NIC.ARPA. 12345 IN A 26.0.0.73 | | |
| A 10.0.0.51 | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
and | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE | | |
+---------------------------------------------------+ | |
Question | QNAME=SRI-NIC.ARPA., QCLASS=IN, QTYPE=* | | |
+---------------------------------------------------+ | |
Answer | SRI-NIC.ARPA. 1290 IN HINFO DEC-2060 TOPS20 | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
Neither of these answers have AA set, so neither response comes from | |
authoritative data. The different contents and different TTLs suggest | |
that the two servers cached data at different times, and that the first | |
server cached the response to a QTYPE=A query and the second cached the | |
response to a HINFO query. | |
Mockapetris [Page 42] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
6.2.3. QNAME=SRI-NIC.ARPA, QTYPE=MX | |
This type of query might be result from a mailer trying to look up | |
routing information for the mail destination [email protected]. | |
The response from C.ISI.EDU would be: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA | | |
+---------------------------------------------------+ | |
Question | QNAME=SRI-NIC.ARPA., QCLASS=IN, QTYPE=MX | | |
+---------------------------------------------------+ | |
Answer | SRI-NIC.ARPA. 86400 IN MX 0 SRI-NIC.ARPA.| | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | SRI-NIC.ARPA. 86400 IN A 26.0.0.73 | | |
| A 10.0.0.51 | | |
+---------------------------------------------------+ | |
This response contains the MX RR in the answer section of the response. | |
The additional section contains the address RRs because the name server | |
at C.ISI.EDU guesses that the requester will need the addresses in order | |
to properly use the information carried by the MX. | |
6.2.4. QNAME=SRI-NIC.ARPA, QTYPE=NS | |
C.ISI.EDU would reply to this query with: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA | | |
+---------------------------------------------------+ | |
Question | QNAME=SRI-NIC.ARPA., QCLASS=IN, QTYPE=NS | | |
+---------------------------------------------------+ | |
Answer | <empty> | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
The only difference between the response and the query is the AA and | |
RESPONSE bits in the header. The interpretation of this response is | |
that the server is authoritative for the name, and the name exists, but | |
no RRs of type NS are present there. | |
6.2.5. QNAME=SIR-NIC.ARPA, QTYPE=A | |
If a user mistyped a host name, we might see this type of query. | |
Mockapetris [Page 43] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
C.ISI.EDU would answer it with: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA, RCODE=NE | | |
+---------------------------------------------------+ | |
Question | QNAME=SIR-NIC.ARPA., QCLASS=IN, QTYPE=A | | |
+---------------------------------------------------+ | |
Answer | <empty> | | |
+---------------------------------------------------+ | |
Authority | . SOA SRI-NIC.ARPA. HOSTMASTER.SRI-NIC.ARPA. | | |
| 870611 1800 300 604800 86400 | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
This response states that the name does not exist. This condition is | |
signalled in the response code (RCODE) section of the header. | |
The SOA RR in the authority section is the optional negative caching | |
information which allows the resolver using this response to assume that | |
the name will not exist for the SOA MINIMUM (86400) seconds. | |
6.2.6. QNAME=BRL.MIL, QTYPE=A | |
If this query is sent to C.ISI.EDU, the reply would be: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE | | |
+---------------------------------------------------+ | |
Question | QNAME=BRL.MIL, QCLASS=IN, QTYPE=A | | |
+---------------------------------------------------+ | |
Answer | <empty> | | |
+---------------------------------------------------+ | |
Authority | MIL. 86400 IN NS SRI-NIC.ARPA. | | |
| 86400 NS A.ISI.EDU. | | |
+---------------------------------------------------+ | |
Additional | A.ISI.EDU. A 26.3.0.103 | | |
| SRI-NIC.ARPA. A 26.0.0.73 | | |
| A 10.0.0.51 | | |
+---------------------------------------------------+ | |
This response has an empty answer section, but is not authoritative, so | |
it is a referral. The name server on C.ISI.EDU, realizing that it is | |
not authoritative for the MIL domain, has referred the requester to | |
servers on A.ISI.EDU and SRI-NIC.ARPA, which it knows are authoritative | |
for the MIL domain. | |
Mockapetris [Page 44] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
6.2.7. QNAME=USC-ISIC.ARPA, QTYPE=A | |
The response to this query from A.ISI.EDU would be: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA | | |
+---------------------------------------------------+ | |
Question | QNAME=USC-ISIC.ARPA., QCLASS=IN, QTYPE=A | | |
+---------------------------------------------------+ | |
Answer | USC-ISIC.ARPA. 86400 IN CNAME C.ISI.EDU. | | |
| C.ISI.EDU. 86400 IN A 10.0.0.52 | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
Note that the AA bit in the header guarantees that the data matching | |
QNAME is authoritative, but does not say anything about whether the data | |
for C.ISI.EDU is authoritative. This complete reply is possible because | |
A.ISI.EDU happens to be authoritative for both the ARPA domain where | |
USC-ISIC.ARPA is found and the ISI.EDU domain where C.ISI.EDU data is | |
found. | |
If the same query was sent to C.ISI.EDU, its response might be the same | |
as shown above if it had its own address in its cache, but might also | |
be: | |
Mockapetris [Page 45] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA | | |
+---------------------------------------------------+ | |
Question | QNAME=USC-ISIC.ARPA., QCLASS=IN, QTYPE=A | | |
+---------------------------------------------------+ | |
Answer | USC-ISIC.ARPA. 86400 IN CNAME C.ISI.EDU. | | |
+---------------------------------------------------+ | |
Authority | ISI.EDU. 172800 IN NS VAXA.ISI.EDU. | | |
| NS A.ISI.EDU. | | |
| NS VENERA.ISI.EDU. | | |
+---------------------------------------------------+ | |
Additional | VAXA.ISI.EDU. 172800 A 10.2.0.27 | | |
| 172800 A 128.9.0.33 | | |
| VENERA.ISI.EDU. 172800 A 10.1.0.52 | | |
| 172800 A 128.9.0.32 | | |
| A.ISI.EDU. 172800 A 26.3.0.103 | | |
+---------------------------------------------------+ | |
This reply contains an authoritative reply for the alias USC-ISIC.ARPA, | |
plus a referral to the name servers for ISI.EDU. This sort of reply | |
isn't very likely given that the query is for the host name of the name | |
server being asked, but would be common for other aliases. | |
6.2.8. QNAME=USC-ISIC.ARPA, QTYPE=CNAME | |
If this query is sent to either A.ISI.EDU or C.ISI.EDU, the reply would | |
be: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA | | |
+---------------------------------------------------+ | |
Question | QNAME=USC-ISIC.ARPA., QCLASS=IN, QTYPE=A | | |
+---------------------------------------------------+ | |
Answer | USC-ISIC.ARPA. 86400 IN CNAME C.ISI.EDU. | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
Because QTYPE=CNAME, the CNAME RR itself answers the query, and the name | |
server doesn't attempt to look up anything for C.ISI.EDU. (Except | |
possibly for the additional section.) | |
6.3. Example resolution | |
The following examples illustrate the operations a resolver must perform | |
for its client. We assume that the resolver is starting without a | |
Mockapetris [Page 46] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
cache, as might be the case after system boot. We further assume that | |
the system is not one of the hosts in the data and that the host is | |
located somewhere on net 26, and that its safety belt (SBELT) data | |
structure has the following information: | |
Match count = -1 | |
SRI-NIC.ARPA. 26.0.0.73 10.0.0.51 | |
A.ISI.EDU. 26.3.0.103 | |
This information specifies servers to try, their addresses, and a match | |
count of -1, which says that the servers aren't very close to the | |
target. Note that the -1 isn't supposed to be an accurate closeness | |
measure, just a value so that later stages of the algorithm will work. | |
The following examples illustrate the use of a cache, so each example | |
assumes that previous requests have completed. | |
6.3.1. Resolve MX for ISI.EDU. | |
Suppose the first request to the resolver comes from the local mailer, | |
which has mail for [email protected]. The mailer might then ask for type MX | |
RRs for the domain name ISI.EDU. | |
The resolver would look in its cache for MX RRs at ISI.EDU, but the | |
empty cache wouldn't be helpful. The resolver would recognize that it | |
needed to query foreign servers and try to determine the best servers to | |
query. This search would look for NS RRs for the domains ISI.EDU, EDU, | |
and the root. These searches of the cache would also fail. As a last | |
resort, the resolver would use the information from the SBELT, copying | |
it into its SLIST structure. | |
At this point the resolver would need to pick one of the three available | |
addresses to try. Given that the resolver is on net 26, it should | |
choose either 26.0.0.73 or 26.3.0.103 as its first choice. It would | |
then send off a query of the form: | |
Mockapetris [Page 47] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY | | |
+---------------------------------------------------+ | |
Question | QNAME=ISI.EDU., QCLASS=IN, QTYPE=MX | | |
+---------------------------------------------------+ | |
Answer | <empty> | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
The resolver would then wait for a response to its query or a timeout. | |
If the timeout occurs, it would try different servers, then different | |
addresses of the same servers, lastly retrying addresses already tried. | |
It might eventually receive a reply from SRI-NIC.ARPA: | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE | | |
+---------------------------------------------------+ | |
Question | QNAME=ISI.EDU., QCLASS=IN, QTYPE=MX | | |
+---------------------------------------------------+ | |
Answer | <empty> | | |
+---------------------------------------------------+ | |
Authority | ISI.EDU. 172800 IN NS VAXA.ISI.EDU. | | |
| NS A.ISI.EDU. | | |
| NS VENERA.ISI.EDU.| | |
+---------------------------------------------------+ | |
Additional | VAXA.ISI.EDU. 172800 A 10.2.0.27 | | |
| 172800 A 128.9.0.33 | | |
| VENERA.ISI.EDU. 172800 A 10.1.0.52 | | |
| 172800 A 128.9.0.32 | | |
| A.ISI.EDU. 172800 A 26.3.0.103 | | |
+---------------------------------------------------+ | |
The resolver would notice that the information in the response gave a | |
closer delegation to ISI.EDU than its existing SLIST (since it matches | |
three labels). The resolver would then cache the information in this | |
response and use it to set up a new SLIST: | |
Match count = 3 | |
A.ISI.EDU. 26.3.0.103 | |
VAXA.ISI.EDU. 10.2.0.27 128.9.0.33 | |
VENERA.ISI.EDU. 10.1.0.52 128.9.0.32 | |
A.ISI.EDU appears on this list as well as the previous one, but that is | |
purely coincidental. The resolver would again start transmitting and | |
waiting for responses. Eventually it would get an answer: | |
Mockapetris [Page 48] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA | | |
+---------------------------------------------------+ | |
Question | QNAME=ISI.EDU., QCLASS=IN, QTYPE=MX | | |
+---------------------------------------------------+ | |
Answer | ISI.EDU. MX 10 VENERA.ISI.EDU. | | |
| MX 20 VAXA.ISI.EDU. | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | VAXA.ISI.EDU. 172800 A 10.2.0.27 | | |
| 172800 A 128.9.0.33 | | |
| VENERA.ISI.EDU. 172800 A 10.1.0.52 | | |
| 172800 A 128.9.0.32 | | |
+---------------------------------------------------+ | |
The resolver would add this information to its cache, and return the MX | |
RRs to its client. | |
6.3.2. Get the host name for address 26.6.0.65 | |
The resolver would translate this into a request for PTR RRs for | |
65.0.6.26.IN-ADDR.ARPA. This information is not in the cache, so the | |
resolver would look for foreign servers to ask. No servers would match, | |
so it would use SBELT again. (Note that the servers for the ISI.EDU | |
domain are in the cache, but ISI.EDU is not an ancestor of | |
65.0.6.26.IN-ADDR.ARPA, so the SBELT is used.) | |
Since this request is within the authoritative data of both servers in | |
SBELT, eventually one would return: | |
Mockapetris [Page 49] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
+---------------------------------------------------+ | |
Header | OPCODE=SQUERY, RESPONSE, AA | | |
+---------------------------------------------------+ | |
Question | QNAME=65.0.6.26.IN-ADDR.ARPA.,QCLASS=IN,QTYPE=PTR | | |
+---------------------------------------------------+ | |
Answer | 65.0.6.26.IN-ADDR.ARPA. PTR ACC.ARPA. | | |
+---------------------------------------------------+ | |
Authority | <empty> | | |
+---------------------------------------------------+ | |
Additional | <empty> | | |
+---------------------------------------------------+ | |
6.3.3. Get the host address of poneria.ISI.EDU | |
This request would translate into a type A request for poneria.ISI.EDU. | |
The resolver would not find any cached data for this name, but would | |
find the NS RRs in the cache for ISI.EDU when it looks for foreign | |
servers to ask. Using this data, it would construct a SLIST of the | |
form: | |
Match count = 3 | |
A.ISI.EDU. 26.3.0.103 | |
VAXA.ISI.EDU. 10.2.0.27 128.9.0.33 | |
VENERA.ISI.EDU. 10.1.0.52 | |
A.ISI.EDU is listed first on the assumption that the resolver orders its | |
choices by preference, and A.ISI.EDU is on the same network. | |
One of these servers would answer the query. | |
7. REFERENCES and BIBLIOGRAPHY | |
[Dyer 87] Dyer, S., and F. Hsu, "Hesiod", Project Athena | |
Technical Plan - Name Service, April 1987, version 1.9. | |
Describes the fundamentals of the Hesiod name service. | |
[IEN-116] J. Postel, "Internet Name Server", IEN-116, | |
USC/Information Sciences Institute, August 1979. | |
A name service obsoleted by the Domain Name System, but | |
still in use. | |
Mockapetris [Page 50] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
[Quarterman 86] Quarterman, J., and J. Hoskins, "Notable Computer | |
Networks",Communications of the ACM, October 1986, | |
volume 29, number 10. | |
[RFC-742] K. Harrenstien, "NAME/FINGER", RFC-742, Network | |
Information Center, SRI International, December 1977. | |
[RFC-768] J. Postel, "User Datagram Protocol", RFC-768, | |
USC/Information Sciences Institute, August 1980. | |
[RFC-793] J. Postel, "Transmission Control Protocol", RFC-793, | |
USC/Information Sciences Institute, September 1981. | |
[RFC-799] D. Mills, "Internet Name Domains", RFC-799, COMSAT, | |
September 1981. | |
Suggests introduction of a hierarchy in place of a flat | |
name space for the Internet. | |
[RFC-805] J. Postel, "Computer Mail Meeting Notes", RFC-805, | |
USC/Information Sciences Institute, February 1982. | |
[RFC-810] E. Feinler, K. Harrenstien, Z. Su, and V. White, "DOD | |
Internet Host Table Specification", RFC-810, Network | |
Information Center, SRI International, March 1982. | |
Obsolete. See RFC-952. | |
[RFC-811] K. Harrenstien, V. White, and E. Feinler, "Hostnames | |
Server", RFC-811, Network Information Center, SRI | |
International, March 1982. | |
Obsolete. See RFC-953. | |
[RFC-812] K. Harrenstien, and V. White, "NICNAME/WHOIS", RFC-812, | |
Network Information Center, SRI International, March | |
1982. | |
[RFC-819] Z. Su, and J. Postel, "The Domain Naming Convention for | |
Internet User Applications", RFC-819, Network | |
Information Center, SRI International, August 1982. | |
Early thoughts on the design of the domain system. | |
Current implementation is completely different. | |
[RFC-821] J. Postel, "Simple Mail Transfer Protocol", RFC-821, | |
USC/Information Sciences Institute, August 1980. | |
Mockapetris [Page 51] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
[RFC-830] Z. Su, "A Distributed System for Internet Name Service", | |
RFC-830, Network Information Center, SRI International, | |
October 1982. | |
Early thoughts on the design of the domain system. | |
Current implementation is completely different. | |
[RFC-882] P. Mockapetris, "Domain names - Concepts and | |
Facilities," RFC-882, USC/Information Sciences | |
Institute, November 1983. | |
Superceeded by this memo. | |
[RFC-883] P. Mockapetris, "Domain names - Implementation and | |
Specification," RFC-883, USC/Information Sciences | |
Institute, November 1983. | |
Superceeded by this memo. | |
[RFC-920] J. Postel and J. Reynolds, "Domain Requirements", | |
RFC-920, USC/Information Sciences Institute | |
October 1984. | |
Explains the naming scheme for top level domains. | |
[RFC-952] K. Harrenstien, M. Stahl, E. Feinler, "DoD Internet Host | |
Table Specification", RFC-952, SRI, October 1985. | |
Specifies the format of HOSTS.TXT, the host/address | |
table replaced by the DNS. | |
[RFC-953] K. Harrenstien, M. Stahl, E. Feinler, "HOSTNAME Server", | |
RFC-953, SRI, October 1985. | |
This RFC contains the official specification of the | |
hostname server protocol, which is obsoleted by the DNS. | |
This TCP based protocol accesses information stored in | |
the RFC-952 format, and is used to obtain copies of the | |
host table. | |
[RFC-973] P. Mockapetris, "Domain System Changes and | |
Observations", RFC-973, USC/Information Sciences | |
Institute, January 1986. | |
Describes changes to RFC-882 and RFC-883 and reasons for | |
them. Now obsolete. | |
Mockapetris [Page 52] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
[RFC-974] C. Partridge, "Mail routing and the domain system", | |
RFC-974, CSNET CIC BBN Labs, January 1986. | |
Describes the transition from HOSTS.TXT based mail | |
addressing to the more powerful MX system used with the | |
domain system. | |
[RFC-1001] NetBIOS Working Group, "Protocol standard for a NetBIOS | |
service on a TCP/UDP transport: Concepts and Methods", | |
RFC-1001, March 1987. | |
This RFC and RFC-1002 are a preliminary design for | |
NETBIOS on top of TCP/IP which proposes to base NetBIOS | |
name service on top of the DNS. | |
[RFC-1002] NetBIOS Working Group, "Protocol standard for a NetBIOS | |
service on a TCP/UDP transport: Detailed | |
Specifications", RFC-1002, March 1987. | |
[RFC-1010] J. Reynolds and J. Postel, "Assigned Numbers", RFC-1010, | |
USC/Information Sciences Institute, May 1987 | |
Contains socket numbers and mnemonics for host names, | |
operating systems, etc. | |
[RFC-1031] W. Lazear, "MILNET Name Domain Transition", RFC-1031, | |
November 1987. | |
Describes a plan for converting the MILNET to the DNS. | |
[RFC-1032] M. K. Stahl, "Establishing a Domain - Guidelines for | |
Administrators", RFC-1032, November 1987. | |
Describes the registration policies used by the NIC to | |
administer the top level domains and delegate subzones. | |
[RFC-1033] M. K. Lottor, "Domain Administrators Operations Guide", | |
RFC-1033, November 1987. | |
A cookbook for domain administrators. | |
[Solomon 82] M. Solomon, L. Landweber, and D. Neuhengen, "The CSNET | |
Name Server", Computer Networks, vol 6, nr 3, July 1982. | |
Describes a name service for CSNET which is independent | |
from the DNS and DNS use in the CSNET. | |
Mockapetris [Page 53] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
Index | |
A 12 | |
Absolute names 8 | |
Aliases 14, 31 | |
Authority 6 | |
AXFR 17 | |
Case of characters 7 | |
CH 12 | |
CNAME 12, 13, 31 | |
Completion queries 18 | |
Domain name 6, 7 | |
Glue RRs 20 | |
HINFO 12 | |
IN 12 | |
Inverse queries 16 | |
Iterative 4 | |
Label 7 | |
Mailbox names 9 | |
MX 12 | |
Name error 27, 36 | |
Name servers 5, 17 | |
NE 30 | |
Negative caching 44 | |
NS 12 | |
Opcode 16 | |
PTR 12 | |
QCLASS 16 | |
QTYPE 16 | |
RDATA 13 | |
Recursive 4 | |
Recursive service 22 | |
Relative names 7 | |
Resolvers 6 | |
RR 12 | |
Mockapetris [Page 54] | |
RFC 1034 Domain Concepts and Facilities November 1987 | |
Safety belt 33 | |
Sections 16 | |
SOA 12 | |
Standard queries 22 | |
Status queries 18 | |
Stub resolvers 32 | |
TTL 12, 13 | |
Wildcards 25 | |
Zone transfers 28 | |
Zones 19 | |
Mockapetris [Page 55] | |
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