From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc882.txt | 1798 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1798 insertions(+) create mode 100644 doc/rfc/rfc882.txt (limited to 'doc/rfc/rfc882.txt') diff --git a/doc/rfc/rfc882.txt b/doc/rfc/rfc882.txt new file mode 100644 index 0000000..9da22a9 --- /dev/null +++ b/doc/rfc/rfc882.txt @@ -0,0 +1,1798 @@ + +Network Working Group P. Mockapetris +Request for Comments: 882 ISI + November 1983 + + DOMAIN NAMES - CONCEPTS and FACILITIES + + +-----------------------------------------------------+ + | | + | This RFC introduces domain style names, their use | + | for ARPA Internet mail and host address support, | + | and the protocols and servers used to implement | + | domain name facilities. | + | | + | This memo describes the conceptual framework of the | + | domain system and some uses, but it omits many | + | uses, fields, and implementation details. A | + | complete specification of formats, timeouts, etc. | + | is presented in RFC 883, "Domain Names - | + | Implementation and Specification". That RFC | + | assumes that the reader is familiar with the | + | concepts discussed in this memo. | + | | + +-----------------------------------------------------+ + +INTRODUCTION + + The need for domain names + + As applications grow to span multiple hosts, then networks, and + finally internets, these applications must also span multiple + administrative boundaries and related methods of operation + (protocols, data formats, etc). The number of resources (for + example mailboxes), the number of locations for resources, and the + diversity of such an environment cause formidable problems when we + wish to create consistent methods for referencing particular + resources that are similar but scattered throughout the + environment. + + The ARPA Internet illustrates the size-related problems; it is a + large system and is likely to grow much larger. The need to have + a mapping between host names (e.g., USC-ISIF) and ARPA Internet + addresses (e.g., 10.2.0.52) is beginning to stress the existing + mechanisms. Currently hosts in the ARPA Internet are registered + with the Network Information Center (NIC) and listed in a global + table (available as the file HOSTS.TXT on the SRI-NIC + host) [1]. The size of this table, and especially the frequency + of updates to the table are near the limit of manageability. What + is needed is a distributed database that performs the same + function, and hence avoids the problems caused by a centralized + database. + + The problem for computer mail is more severe. While mail system + implementers long ago recognized the impossibility of centralizing + + +Mockapetris [Page 1] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + mailbox names, they have also created an increasingly large and + irregular set of methods for identifying the location of a + mailbox. Some of these methods involve the use of routes and + forwarding hosts as part of the mail destination address, and + consequently force the mail user to know multiple address formats, + the capabilities of various forwarders, and ad hoc tricks for + passing address specifications through intermediaries. + + These problems have common characteristics that suggest the nature + of any solution: + + The basic need is for 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 contain + 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 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. + + 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. + + Because we want the name space to be useful in dissimilar + networks, it is unlikely that all users of domain names will be + able to agree on the set of resources or resource information + that names will be used to retrieve. Hence names refer to a + set of resources, and queries contain resource identifiers. + The only standard types of information that we expect to see + throughout the name space is structuring information for the + name space itself, and resources that are described using + domain names and no nonstandard data. + + We also want the name server transactions to be independent of + the communications system that carries them. Some systems may + wish to use datagrams for simple 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. + + + + + +Mockapetris [Page 2] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + Elements of the solution + + The proposed solution has three major components: + + The DOMAIN NAME SPACE, which is a specification for a tree + structured name space. 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 ARPA Internet uses some of + its domain names to identify hosts; queries for address + resources return ARPA Internet host addresses. However, to + preserve the generality of the domain mechanism, domain names + are not required to have a one-to-one correspondence with host + names, host addresses, or any other type of information. + + 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; these parts are called ZONEs; a name server is an + AUTHORITY for these parts of the name space. + + RESOLVERS are programs that extract information from name + servers in response to user 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 simple procedure or OS calls to resolvers. 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 + server has one or more pieces of the whole domain tree's data, + + + +Mockapetris [Page 3] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + 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 using + the local zones. + + In the interests of performance, these layers blur a bit. For + example, resolvers on the same machine as a name server may share + a database and may also introduce foreign information for use in + later queries. This cached information is treated differently + from the authoritative data in zones. + + Database model + + 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 + 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 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 + + +Mockapetris [Page 4] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + updates or guarantees of consistency. Hence the update process + allows updates to percolate out though 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. + + Some users will wish to access the database via datagrams; + others will prefer virtual circuits. The domain system is + designed so that simple queries and responses can use either + style, although refreshing operations need the reliability of + virtual circuits. The same overall message format is used for + all communication. The domain system does not assume any + special properties of the communications system, and hence + could be used with any datagram or virtual circuit protocol. + + 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. The optional + recursive style is discussed in [14], and omitted from further + discussion in this memo. + + 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 to users of the domain system. A standard + format for these files is given in [14]. + + The standard format allows these files 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. + + +Mockapetris [Page 5] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + Each host's name servers and resolvers are configured by a local + system administrator. 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 + +DOMAIN NAME SPACE + + 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). Each + node and leaf has an associated label. Labels are NOT guaranteed + to be unique, with the exception of the root node, which has a + null label. The domain name of a node or leaf is the path from + the root of the tree to the node or leaf. By convention, the + labels that compose a domain name are read left to right, from the + most specific (lowest) to the least specific (highest). + + Internally, programs that manipulate domain names 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 + + +Mockapetris [Page 6] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + representations can use a length byte of zero to terminate a + domain name. When domain names are printed, labels in a path are + separated by dots ("."). The root label and its associated dot + are omitted from printed domain names, but the root can be named + by a null domain name (" " in this memo). + + To simplify implementations, the total number of octets that + represent label octets and label lengths is limited to 255. Thus + a printed domain name can be up to 254 characters. + + A special label is defined that matches any other label. This + label is the asterisk or "*". An asterisk matches a single label. + Thus *.ARPA matches FOO.ARPA, but does not match FOO.BAR.ARPA. + The asterisk is mainly used to create default resource records at + the boundary between protocol families, and requires prudence in + its use. + + 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 has the containing + domain's name as the right part of its name. For example, A.B.C.D + is a subdomain of B.C.D, C.D, D, and " ". + + This tree structure is intended to parallel the administrative + organization and delegation of authority. Potentially, each node + or leaf on the tree can create new subdomains ad infinitum. In + practice, this delegation can be limited by the administrator of + the name servers that manage the domain space and resource data. + + The following figure shows an example of a domain name space. + + | + +------------------+------------------+ + | | | + COLORS FLAVORS TRUTH + | | + +-----+-----+ | + | | | NATURAL + RED BLUE GREEN | + | + +---------------+---------------+ + | | | + CHOCOLATE VANILLA STRAWBERRY + + In this example, the root domain has three immediate subdomains: + COLORS, FLAVORS, and TRUTH. The FLAVORS domain has one immediate + subdomain named NATURAL.FLAVORS. All of the leaves are also + + +Mockapetris [Page 7] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + domains. This domain tree has the names " "(the root), COLORS, + RED.COLORS, BLUE.COLORS, GREEN.COLORS, FLAVORS, NATURAL.FLAVORS, + CHOCOLATE.NATURAL.FLAVORS, VANILLA.NATURAL.FLAVORS, + STRAWBERRY.NATURAL.FLAVORS, and TRUTH. If we wished to add a new + domain of ARTIFICIAL under FLAVORS, FLAVORS would typically be the + administrative entity that would decide; if we wished to create + CHIP and MOCHA names under CHOCOLATE, CHOCOLATE.NATURAL.FLAVORS + would typically be the appropriate administrative entity. + + Resource set information + + A domain name identifies a set of resource information. The set + of resource information associated with a particular name is + composed of separate resource records (RRs). + + Each resource record has the following major components: + + The domain name which identifies resource set that holds this + record, and hence the "owner" of the information. For example, + a RR that specifies a host address has a domain name the + specifies the host having that address. Thus F.ISI.ARPA might + be the owner of a RR which specified an address field of + 10.2.0.52. Since name servers typically store their resource + information in tree structures paralleling the organization of + the domain space, this information can usually be stored + implicitly in the database; however it is always included in + each resource record carried in a message. + + Other information used to manage the RR, such as length fields, + timeouts, etc. This information is omitted in much of this + memo, but is discussed in [14]. + + A resource type field that specifies the type of the resource + in this resource record. Types refer to abstract resources + such as host addresses or mail delivery agents. The type field + is two octets long and uses an encoding that is standard + throughout the domain name system. + + A class field identifies the format of the resource data, such + as the ARPA Internet format (IN) or the Computer Science + Network format (CSNET), for certain RR types (such as address + data). Note that while the class may separate different + protocol families, networks, etc. it does not do so in all + cases. For example, the IN class uses 32 bit IP addresses + exclusively, but the CSNET class uses 32 bit IP addresses, X.25 + addresses, and phone numbers. Thus the class field should be + used as a guide for interpreting the resource data. The class + field is two octets long and uses an encoding that is standard + throughout the domain name system. + + +Mockapetris [Page 8] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + Resource data that describes the resource. The format of this + data can be determined given the type and class fields, but + always starts with a two octet length field that allows a name + server or resolver to determine the boundaries of the resource + data in any transaction, even if it cannot "understand" the + resource data itself. Thus name servers and resolvers can hold + and pass on records which they cannot interpret. The format of + the internal data is restricted only by the maximum length of + 65535 octets; for example the host address record might specify + a fixed 32 bit number for one class, and a variable length list + of addresses in another class. + + While the class field in effect partitions the resource data in + the domain name system into separate parallel sections according + to class, services can span class boundaries if they use + compatible resource data formats. For example, the domain name + system uses compatible formats for structure information, and the + mail data decouples mail agent identification from details of how + to contact the agent (e.g. host addresses). + + This memo uses the following types in its examples: + + A - the host address associated with the domain name + + MF - identifies a mail forwarder for the domain + + MD - identifies a mail destination for the domain + + NS - the authoritative name server for the domain + + SOA - identifies the start of a zone of authority + + CNAME - identifies the canonical name of an alias + + This memo uses the following classes in its examples: + + IN - the ARPA Internet system + + CS - the CSNET system + + The first type of resource record holds a host name to host + address binding. Its fields are: + + +--------+--------+--------+--------------//----------------------+ + | | A | | information | + +--------+--------+--------+--------------//----------------------+ + + + + + +Mockapetris [Page 9] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + The content of the class specific information varies according to + the value in the CLASS field; for the ARPA Internet, it is the 32 + bit ARPA Internet address of the host, for the CSNET it might be + the phone number of the host. For example, F.ISI.ARPA might have + two A records of the form: + + +----------+--------+--------+----------------------------+ + |F.ISI.ARPA| A | IN | 10.2.0.52 | + +----------+--------+--------+----------------------------+ + and + +----------+--------+--------+----------------------------+ + |F.ISI.ARPA| A | CS | 213-822-2112 | + +----------+--------+--------+----------------------------+ + + Note that the data formats for the A type are class dependent, and + the Internet address and phone number formats shown above are for + purposes of illustration only. The actual data formats are + specified in [14]. For example, CS class data for type A records + might actually be a list of Internet addresses, phone numbers and + TELENET addresses. + + The mail forwarder (MF) and mail delivery (MD) records have the + following format: + + +--------+--------+--------+----------------------------+ + | | MD/MF | | | + +--------+--------+--------+----------------------------+ + + The field is a domain name of the host that will + handle mail; note that this domain name may be completely + different from the domain name which names the resource record. + For example, F.ISI.ARPA might have two records of the form: + + +----------+--------+--------+----------------------------+ + |F.ISI.ARPA| MD | IN | F.ISI.ARPA | + +----------+--------+--------+----------------------------+ + and + +----------+--------+--------+----------------------------+ + |F.ISI.ARPA| MF | IN | B.ISI.ARPA | + +----------+--------+--------+----------------------------+ + + These records mean that mail for F.ISI.ARPA can either be + delivered to the host F.ISI.ARPA or forwarded to B.ISI.ARPA, which + will accept responsibility for its eventual delivery. In + principle, an additional name lookup is required to map the domain + name of the host to the appropriate address, in practice this + information is usually returned in the response to the mail query. + + The SOA and NS types of resource records are used to define limits + + +Mockapetris [Page 10] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + of authority. The domain name given by the owner field of a SOA + record is the start of a zone; the domain name given by the owner + field of a NS record identifies a point in the name space where + authority has been delegated, and hence marks the zone boundary. + Except in the case where a name server delegates authority to + itself, the SOA identifies the top limit of authority, and NS + records define the first name outside of a zone. These resource + records have a standard format for all of the name space: + + +----------+--------+--------+-----------------------------+ + | | SOA | | | + +----------+--------+--------+-----------------------------+ + + +----------+--------+--------+-----------------------------+ + | | NS | | | + +----------+--------+--------+-----------------------------+ + + The SOA record marks the start of a zone when it is present in a + database; the NS record both marks the end of a zone started by an + SOA (if a higher SOA is present) and also points to a name server + that has a copy of the zone specified by the in the SOA record specifies the original + source of the information in the zone and other information used + by name servers to organize their activities. SOA records are + never cached (otherwise they would create false zones); they can + only be created in special name server maintenance operations. + + The NS record says that a name server which is authoritative for + records of the given CLASS can be found at . + + Queries + + Queries to a name server must include a domain name which + identifies the target resource set (QNAME), and the type and class + of desired resource records. The type and class fields in a query + can include any of the corresponding type and class fields that + are defined for resource records; in addition, the query type + (QTYPE) and query class (QCLASS) fields may contain special values + that match more than one of the corresponding fields in RRs. + + For example, the QTYPE field may contain: + + MAILA - matches all mail agent RRs (e.g. MD and MF). + + * - matches any RR type. + + + + +Mockapetris [Page 11] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + The QCLASS field may contain: + + * - matches any RR class. + + 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. + + Note that the QCLASS=* construct requires special interpretation + regarding authority. Since a 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 never be authoritative. + + Example space + + For purposes of exposition, the following name space is used for + the remainder of this memo: + + | + +------------------+------------------+ + | | | + DDN ARPA CSNET + | | | + +-----+-----+ | +-----+-----+ + | | | | | | + JCS ARMY NAVY | UDEL UCI + | + +--------+---------------+---------------+--------+ + | | | | | + DTI MIT ISI UDEL NBS + | | + +---+---+ +---+---+ + | | | | | + DMS AI A B F + + + + + + + + + + + +Mockapetris [Page 12] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + +NAME SERVERS + + Introduction + + Name servers store a distributed database consisting of the + structure of the domain name space, the resource sets associated + with domain names, and other information used to coordinate + actions between name servers. + + In general, a name server will be an authority for all or part of + a particular domain. The region covered by this authority is + called a zone. Name servers may be responsible for no + authoritative data, and hence have no zones, or may have several + zones. When a name server has multiple zones, the zones may have + no common borders or zones may be contiguous. + + While administrators should not construct overlapping zones, and + name servers must defend against overlapping zones, overlapping is + regarded as a non-fatal flaw in the database. Hence the measures + taken to protect against it are omitted for the remainder of this + memo. A detailed discussion can be found in [14]. + + When presented with a query for a domain name over which it has + authority, a name server returns the desired resource information + or an indication that the query refers to a domain name or + resource that does not exist. If a name server is presented with + a query for a domain name that is not within its authority, it may + have the desired information, but it will also return a response + that points toward an authoritative name server. If a name server + is not an authority for a query, it can never return a negative + response. + + There is no requirement that a name server for a domain reside in + a host which has a name in the same domain, although this will + usually be the case. There is also no restriction on the number + of name servers that can have authority over a particular domain; + most domains will have redundant authoritative name servers. The + assumption is that different authoritative copies are identical, + even though inconsistencies are possible as updates are made. + + Name server functions are designed to allow for very simple + implementations of name servers. The simplest name server has a + static set of information and uses datagrams to receive queries + and return responses. + + More sophisticated name server implementations can improve the + performance of their clients by caching information from other + domains. Although this information can be acquired in a number of + ways, the normal method is to store the information acquired by a + + +Mockapetris [Page 13] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + resolver when the resolver consults other name servers. In a + sophisticated host, the resolver and name server will coordinate + their actions and use a shared database. This cooperation + requires the incorporation of a time-to-live (TTL) field in all + cached resource records. Caching is discussed in the resolver + section of this memo; this section is devoted to the actions of a + name servers that don't cache. + + In order to free simple name servers of the requirement of + managing these timeouts, simple name servers should only contain + resource records that are expected to remain constant over very + long periods or resource records for which the name server is an + authority. In the following discussion, the TTL field is assumed + to be stored in the resource record but is omitted in descriptions + of databases and responses in the interest of clarity. + + Authority and administrative control of domains + + Although we want to have the potential of delegating the + privileges of name space management at every node, we don't want + such delegation to be required. + + Hence we introduce the concept of authority. Authority is vested + in name servers. A name server has authority over all of its + domain until it delegates authority for a subdomain to some other + name server. + + Any administrative entity that wishes to establish its own domain + must provide a name server, and have that server accepted by the + parent name server (i.e. the name server that has authority over + the place in the domain name space that will hold the new domain). + While the principles of authority allow acceptance to be at the + discretion of parent name servers, the following criteria are used + by the root, and are recommended to all name servers because they + are responsible for their children's actions: + + 1. It must register with the parent administrator of domains. + + 2. It must identify a responsible person. + + 3. In must provide redundant name servers. + + The domain name must be registered with the administrator to avoid + name conflicts and to make the domain related information + available to other domains. The central administrator may have + further requirements, and a domain is not registered until the + central administrator agrees that all requirements are met. + + There must be a responsible person associated with each domain to + + +Mockapetris [Page 14] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + be a contact point for questions about the domain, to verify and + update the domain related information, and to resolve any problems + (e.g., protocol violations) with hosts in the domain. + + The domain must provide redundant (i.e., two or more) name servers + to provide the name to address resolution service. These name + servers must be accessible from outside the domain (as well as + inside) and must resolve names for at least all the hosts in the + domain. + + Once the central administrator is satisfied, he will communicate + the existence to the appropriate administrators of other domains + so that they can incorporate NS records for the new name server + into their databases. + + Name server logic + + The processing steps that a name server performs in responding to + a query are conceptually simple, although implementations may have + internal databases that are quite complex. + + For purposes of explanation, we assume that the query consists of + a type QTYPE, a class QCLASS, and a domain name QNAME; we assume + that the name server stores its RRs in sets where each set has all + of the RRs for a particular domain. Note that this database + structure and the following algorithms are meant to illustrate one + possible implementation, rather than a specification of how all + servers must be implemented. + + The following notation is used: + + ord(DOMAIN-NAME) returns the number of labels in DOMAIN-NAME. + + findset(DOMAIN-NAME) returns a pointer to the set of stored RRs + for DOMAIN-NAME, or NULL if there is no such + information. + + set(POINTER) refers to a set located previously by + findset, where POINTER is the value returned + by findset. + + relevant(QTYPE,TYPE) returns true if a RR of the specified TYPE is + relevant to the specified QTYPE. For + example, relevant(MAILA,MF) is true and + relevant(MAILA,NS) is false. + + right(NAME,NUMBER) returns a domain name that is the rightmost + NUMBER labels in the string NAME. + + + +Mockapetris [Page 15] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + copy(RR) copies the resource record specified by RR + into the response. + + The name server code could be represented as the following + sequence of steps: + + { find out whether the database makes this server + authoritative for the domain name specified by QNAME } + + for i:=0 to ord(QNAME) { sequence through all nodes in QNAME } + do begin + ptr:=findset(right(QNAME,i)); + if ptr<>NULL + then { there is domain data for this domain name } + begin + for all RRs in set(ptr) + do if type(RR)=NS and class(RR)=QCLASS + then begin + auth=false; + NSptr:=ptr + end; + for all RRs in set(ptr) + do if type(RR)=SOA and class(RR)=QCLASS + then auth:=true + end + end; + end; + + { copy out authority search results } + + if auth + then { if authority check for domain found } + if ptr=null + then return(Name error) + else + else { if not authority, copy NS RRs } + for all RRs in set(nsptr) + do if (type(RR)=NS and class(RR)=QCLASS) + or + (QCLASS=*) + then copy(RR); + + { Copy all RRs that answer the question } + + for all RRs in set(ptr) + do if class(RR)=QCLASS and relevant(QTYPE,type(RR)) + then copy(RR); + + The first section of the code (delimited by the for loop over all + + +Mockapetris [Page 16] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + of the subnodes of QNAME) discovers whether the name server is + authoritative for the domain specified by QNAME. It sequences + through all containing domains of QNAME, starting at the root. If + it encounters a SOA it knows that the name server is authoritative + unless it finds a lower NS RR which delegates authority. If the + name server is authoritative, it sets auth=true; if the name + server is not authoritative, it sets NSptr to point to the set + which contains the NS RR closest to the domain specified by QNAME. + + The second section of the code reflects the result of the + authority search into the response. If the name server is + authoritative, the code checks to see that the domain specified by + QNAME exists; if not, a name error is returned. If the name + server is not authoritative, the code copies the RRs for a closer + name server into the response. + + The last section of the code copies all relevant RRs into the + response. + + Note that this code is not meant as an actual implementation and + is incomplete in several aspects. For example, it doesn't deal + with providing additional information, wildcards, QCLASS=*, or + with overlapping zones. The first two of these issues are dealt + with in the following discussions, the remaining issues are + discussed in [14]. + + Additional information + + When a resolver returns information to a user program, the + returned information will often lead to a second query. For + example, if a mailer asks a resolver for the appropriate mail + agent for a particular domain name, the name server queried by the + resolver returns a domain name that identifies the agent. In + general, we would expect that the mailer would then request the + domain name to address binding for the mail agent, and a new name + server query would result. + + To avoid this duplication of effort, name servers return + additional information with a response which satisfies the + anticipated query. This information is kept in a separate section + of the response. Name servers are required to complete the + appropriate additional information if such information is + available, but the requestor should not depend on the presence of + the information since the name server may not have it. If the + resolver caches the additional information, it can respond to the + second query without an additional network transaction. + + The appropriate information is defined in [14], but generally + + + +Mockapetris [Page 17] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + consists of host to address bindings for domain names in returned + RRs. + + Aliases and canonical names + + In existing systems, hosts and other resources often have several + names that identify the same resource. For example, under current + ARPA Internet naming support, USC-ISIF and ISIF 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 Mockapetris@ISIF, Mockapetris@ISIB, etc., 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 name and all others are aliases. + + The domain system provides a similar feature using the canonical + name (CNAME) RR. When a name server fails to find a desired RR in + a set associated with some domain name, it checks to see if the + resource set contains a CNAME record with a matching class. If + so, the name server includes the CNAME record in the response, and + continues the query at the domain name specified in the data field + of the CNAME record. + + Suppose a name server was processing a query with QNAME=ISIF.ARPA, + QTYPE=A, and QCLASS=IN, and had the following resource records: + + ISIF.ARPA CNAME IN F.ISI.ARPA + F.ISI.ARPA A IN 10.2.0.52 + + Both of these RRs would be returned in the response. + + In the above example, because ISIF.ARPA has no RRs other than the + CNAME RR, the resources associated with ISIF.ARPA will appear to + be exactly those associated with F.ISI.ARPA for the IN CLASS. + Since the CNAME is effective only when the search fails, a CNAME + can also be used to construct defaults. For example, suppose the + name server had the following set of RRs: + + F.ISI.ARPA A IN 10.2.0.52 + F.ISI.ARPA MD IN F.ISI.ARPA + XXXX.ARPA CNAME IN F.ISI.ARPA + XXXX.ARPA MF IN A.ISI.ARPA + + Using this database, type A queries for XXXX.ARPA would return the + XXXX.ARPA CNAME RR and the F.ISI.ARPA A RR, but MAILA or MF + queries to XXXX.ARPA would return the XXXX.ARPA MF RR without any + information from F.ISI.ARPA. This structure might be used to send + + +Mockapetris [Page 18] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + mail addressed to XXXX.ARPA to A.ISI.ARPA and to direct TELNET for + XXXX.ARPA to F.ISI.ARPA. + + Wildcards + + In certain cases, an administrator may wish to associate default + resource information for all or part of a domain. For example, + the CSNET domain administrator may wish to establish IN class mail + forwarding for all hosts in the CSNET domain without IN + capability. In such a case, the domain system provides a special + label "*" that matches any other label. Note that "*" matches + only a single label, and not zero or more than one label. Note + also that the "*" is distinct from the "*" values for QCLASS and + QTYPE. + + The semantics of "*" depend upon whether it appears in a query + domain name (QNAME) or in a RR in a database. + + When an "*" is used in a QNAME, it can only match a "*" in a + resource record. + + When "*" appears in a RR in a database, it can never override + an existing exact match. For example, if a name server + received a query for the domain UDEL.CSNET, and had appropriate + RRs for both UDEL.CSNET and *.CSNET, the UDEL.CSNET RRs would + be used and the *.CSNET RRs would be ignored. If a query to + the same database specified FOO.CSNET, the *.CSNET RR would be + used, but the corresponding labels from the QNAME would replace + the "*". Thus the FOO.CSNET query would match the *.CSNET RR + and return a RR for FOO.CSNET rather than *.CSNET. + + RRs containing "*" labels are copied exactly when zones are + transfered via name server maintenance operations. + + These semantics are easily implemented by having the name server + first search for an exact match for a query, and then replacing + the leftmost label with a "*" and trying again, repeating the + process until all labels became "*" or the search succeeded. + + TYPE=* in RRs is prohibited. If it were to be allowed, the + requestor would have no way of interpreting the data in the RR + because this data is type dependent. + + CLASS=* is also prohibited. Similar effects can be achieved using + QCLASS=*, and allowing both QCLASS=* and CLASS=* leads to + complexities without apparent benefit. + + + + + +Mockapetris [Page 19] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + A scenario + + In our sample domain space, suppose we wanted separate + administrative control for the root, DDN, ARPA, CSNET, MIT and ISI + domains. We might allocate name servers as follows: + + |(B.ISI.ARPA) + |(UDEL.CSNET) + +------------------+------------------+ + | | | + DDN ARPA CSNET + |(JCS.DDN) |(F.ISI.ARPA) |(UDEL.ARPA) + +-----+-----+ |(A.ISI.ARPA)+-----+-----+ + | | | | | | + JCS ARMY NAVY | UDEL UCI + | + +--------+---------------+---------------+--------+ + | | | | | + DTI MIT ISI UDEL NBS + |(AI.MIT.ARPA) |(F.ISI.ARPA) + +---+---+ +---+---+ + | | | | | + DMS AI A B F + + 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 B.ISI.ARPA and UDEL.CSNET, the + DDN name server is on JCS.DDN, the CSNET domain server is on + UDEL.ARPA, etc. + + In an actual system, all domains should have redundant name + servers, but in this example only the ARPA domain has redundant + servers A.ISI.ARPA and F.ISI.ARPA. (The B.ISI.ARPA and UDEL.CSNET + name servers happen to be not redundant because they handle + different classes.) The F.ISI.ARPA name server has authority over + the ARPA domain, but delegates authority over the MIT.ARPA domain + to the name server on AI.MIT.ARPA. The A.ISI.ARPA name server + also has authority over the ARPA domain, but delegates both the + ISI.ARPA and MIT.ARPA domains to other name servers. + + + + + + + + + + +Mockapetris [Page 20] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + B.ISI.ARPA Name server for " " + + B.ISI.ARPA has the root name server for the IN class. Its + database might contain: + + Domain Resource Record + + " " SOA IN A.ISI.ARPA + DDN NS IN JCS.DDN + ARPA NS IN F.ISI.ARPA + CSNET NS IN UDEL.ARPA + " " NS IN B.ISI.ARPA + " " NS CS UDEL.CSNET + + JCS.DDN A IN 9.0.0.1 + F.ISI.ARPA A IN 10.2.0.52 + UDEL.CSNET A CS 302-555-0000 + UDEL.ARPA A IN 10.0.0.96 + + The SOA record for the root is necessary so that the name server + knows that it is authoritative for the root domain for class IN. + The contents of the SOA resource record point back to A.ISI.ARPA + and denote that the master data for the zone of authority is + originally from this host. The first three NS records denote + delegation of authority. The NS root entry for the B.ISI.ARPA + name server is necessary so that this name server knows about + itself, and can respond correctly to a query for NS information + about the root (for which it is an authority). The root entry for + class CS denotes that UDEL.CSNET is the authoritative name server + for the CS class root. UDEL.CSNET and UDEL.ARPA may or may not + refer to the same name server; from this information it is + impossible to tell. + + If this name server was sent a query specifying QTYPE=MAILA, + QCLASS=IN, QNAME=F.ISI.ARPA, it would begin processing (using the + previous algorithm) by determining that it was not an authority + for F.ISI.ARPA. The test would note that it had authority at " ", + but would also note that the authority was delegated at ARPA and + never reestablished via another SOA. Thus the response would + return the NS record for the domain ARPA. + + Any queries presented to this server with QCLASS=CS would result + in the UDEL.CSNET NS record being returned in the response. + + + + + + + + +Mockapetris [Page 21] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + F.ISI.ARPA Name server for ARPA and ISI.ARPA + + In the same domain space, the F.ISI.ARPA database for the domains + ARPA and ISI.ARPA might be: + + Domain Resource Record + + " " NS IN B.ISI.ARPA + " " NS CS CSNET.UDEL + ARPA SOA IN B.ISI.ARPA + ARPA NS IN A.ISI.ARPA + ARPA NS IN F.ISI.ARPA + MIT.ARPA NS IN AI.MIT.ARPA + ISI.ARPA SOA IN F.ISI.ARPA + ISI.ARPA NS IN F.ISI.ARPA + + A.ISI.ARPA MD IN A.ISI.ARPA + ISI.ARPA MD IN F.ISI.ARPA + A.ISI.ARPA MF IN F.ISI.ARPA + B.ISI.ARPA MD IN B.ISI.ARPA + B.ISI.ARPA MF IN F.ISI.ARPA + F.ISI.ARPA MD IN F.ISI.ARPA + F.ISI.ARPA MF IN A.ISI.ARPA + DTI.ARPA MD IN DTI.ARPA + NBS.ARPA MD IN NBS.ARPA + UDEL.ARPA MD IN UDEL.ARPA + + A.ISI.ARPA A IN 10.1.0.32 + F.ISI.ARPA A IN 10.2.0.52 + B.ISI.ARPA A IN 10.3.0.52 + DTI.ARPA A IN 10.0.0.12 + AI.MIT.ARPA A IN 10.2.0.6 + DMS.MIT.ARPA A IN 10.1.0.6 + NBS.ARPA A IN 10.0.0.19 + UDEL.ARPA A IN 10.0.0.96 + + For the IN class, the SOA RR for ARPA denotes that this name + server is authoritative for the domain ARPA, and that the master + file for this authority is stored on B.ISI.ARPA. This zone + extends to ISI.ARPA, where the database delegates authority back + to this name server in another zone, and doesn't include the + domain MIT.ARPA, which is served by a name server on AI.MIT.ARPA. + + This name server is not authoritative for any data in the CS + class. It has a pointer to the root server for CS data which + could be use to resolve CS class queries. + + Suppose this name server received a query of the form + QNAME=A.ISI.ARPA, QTYPE=A, and QCLASS=IN. The authority search + + +Mockapetris [Page 22] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + would notice the NS record for " ", its SOA at ARPA, a delegation + at ISI.ARPA, and the reassumption of authority at ISI.ARPA. Hence + it would know that it was an authority for this query. It would + then find the A record for A.ISI.ARPA, and return a datagram + containing this record. + + Another query might be QNAME=B.ISI.ARPA, QTYPE=MAILA, QCLASS=*. + In this case the name server would know that it cannot be + authoritative because of the "*" value of QCLASS, and would look + for records for domain B.ISI.ARPA that match. Assuming that the + name server performs the additional record inclusion mentioned in + the name server algorithm, the returned datagram would include: + + ISI.ARPA NS IN F.ISI.ARPA + " " NS CS UDEL.CSNET + B.ISI.ARPA MD IN B.ISI.ARPA + B.ISI.ARPA MF IN F.ISI.ARPA + B.ISI.ARPA A IN 10.3.0.52 + F.ISI.ARPA A IN 10.2.0.52 + + If the query were QNAME=DMS.MIT.ARPA, QTYPE=MAILA, QCLASS=IN, the + name server would discover that AI.MIT.ARPA was the authoritative + name server and return the following: + + MIT.ARPA NS IN AI.MIT.ARPA + AI.MIT.ARPA A IN 10.2.0.6 + + In this case, the requestor is directed to seek information from + the MIT.ARPA domain name server residing on AI.MIT.ARPA. + + + + + + + + + + + + + + + + + + + + + + +Mockapetris [Page 23] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + UDEL.ARPA and UDEL.CSNET name server + + In the previous discussion of the sample domain, we stated that + UDEL.CSNET and UDEL.ARPA might be the same name server. In this + example, we assume that this is the case. As such, the name + server is an authority for the root for class CS, and an authority + for the CSNET domain for class IN. + + This name server deals with mail forwarding between the ARPA + Internet and CSNET systems. Its RRs illustrate one approach to + solving this problem. The name server has the following resource + records: + + " " SOA CS UDEL.CSNET + " " NS CS UDEL.CSNET + " " NS IN B.ISI.ARPA + CSNET SOA IN UDEL.ARPA + CSNET NS IN UDEL.ARPA + ARPA NS IN A.ISI.ARPA + + *.CSNET MF IN UDEL.ARPA + UDEL.CSNET MD CS UDEL.CSNET + UCI.CSNET MD CS UCI.CSNET + UDEL.ARPA MD IN UDEL.ARPA + + B.ISI.ARPA A IN 10.3.0.52 + UDEL.ARPA A IN 10.0.0.96 + UDEL.CSNET A CS 302-555-0000 + UCI.CSNET A CS 714-555-0000 + + Suppose this name server received a query of the form + QNAME=UCI.CSNET, QTYPE=MAILA, and QCLASS=IN. The name server + would discover it was authoritative for the CSNET domain under + class IN, but would find no explicit mail data for UCI.CSNET. + However, using the *.CSNET record, it would construct a reply: + + UCI.CSNET MF IN UDEL.ARPA + UDEL.ARPA A IN 10.0.0.96 + + If this name server received a query of the form QNAME=UCI.CSNET, + QTYPE=MAILA, and QCLASS=CS, the name server would return: + + UCI.CSNET MD CS UCI.CSNET + UCI.CSNET A CS 714-555-0000 + + Note that although this scheme allows for forwarding of all mail + addressed as .CSNET, it doesn't help with names that + have more than two components, e.g. A.B.CSNET. Although this + problem could be "fixed" by a series of MF entries for *.*.CSNET, + + +Mockapetris [Page 24] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + *.*.*.CSNET, etc, a more tasteful solution would be to introduce a + cleverer pattern matching algorithm in the CSNET name server. + + Summary of requirements for name servers + + The requirements for a name server are as follows: + + 1. It must be recognized by its parent. + + 2. It must have complete resource information for all domain + names for which it is the authority. + + 3. It must periodically refresh authoritative information from + a master file or name server which holds the master. + + 4. If it caches information it must also handle TTL management + for that information. + + 5. It must answer simple queries. + + Inverse queries + + 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 query might map a domain name + to a host address, the corresponding inverse query might map the + address 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 an 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. In general, a resolver or other program that wishes to + guarantee that an inverse query will work must use a name server + that is known to have the appropriate data, or ask all name + servers in a domain of interest. + + For example, if a resolver wishes to perform an inverse query for + an arbitrary host on the ARPA Internet, it must consult a set of + name servers sufficient to know that all IN data was considered. + In practice, a single inverse query to a name server that has a + fairly comprehensive database should satisfy the vast majority of + inverse queries. + + A detailed discussion of inverse queries is contained in [14]. + + + +Mockapetris [Page 25] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + Completion services + + Some existing systems provide the ability to complete partial + specifications of arguments. The general principle is that the + user types the first few characters of the argument and then hits + an escape character to prompt the system to complete the rest. + Some completion systems require that the user type enough of the + argument to be unique; others do not. + + Other systems allow the user to specify one argument and ask the + system to fill in other arguments. For example, many mail systems + allow the user to specify a username without a host for local mail + delivery. + + The domain system defines name server completion transactions that + perform the analogous service for the domain system. + Implementation of this service is optional in a name server, but + all name servers must at least be able to understand a completion + request and return an error response. + + When a resolver wishes to request a completion, it sends a name + server a message that sets QNAME to the partial string, QTYPE to + the type of resource desired, and QCLASS to the desired class. + The completion request also includes a RR for the target domain. + The target domain RR identifies the preferred location of the + resource. In completion requests, QNAME must still have a null + label to terminate the name, but its presence is ignored. Note + that a completion request is not a query, but shares some of the + same field formats. + + For example, a completion request might contain QTYPE=A, QNAME=B, + QCLASS=IN and a RR for ISI.ARPA. This request asks for completion + for a resource whose name begins with "B" and is "close" to + ISI.ARPA. This might be a typical shorthand used in the ISI + community which uses "B" as a way of referring to B.ISI.ARPA. + + The first step in processing a completion request is to look for a + "whole label" match. When the name server receives the request + mentioned above, it looks at all records that are of type A, class + IN, and whose domain name starts (on the left) with the labels of + QNAME, in this case, "B". If multiple records match, the name + server selects those whose domain names match (from the right) the + most labels of the preferred domain name. If there are still + multiple candidates, the name server selects the records that have + the shortest (in terms of octets in the name) domain name. If + several records remain, then the name server returns them all. + + If no records are found in the previous algorithm, the name server + assumes that the rightmost label in QNAME is not complete, and + + +Mockapetris [Page 26] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + looks for records that match but require addition of characters to + the rightmost label of QNAME. For example, the previous search + would not match BB.ARPA to B, but this search would. If multiple + hits are found, the same discarding strategy is followed. + + A detailed discussion of completion can be found in [14]. + +RESOLVERS + + 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. + + Because a resolver may need to consult several name servers, the + amount of time that a resolver will take to complete can vary. + This variance is part of the justification for the split between + name servers and resolvers; name servers may use datagrams and + have a response time that is essentially equal to network delay + plus a short service time, while resolvers may take an essentially + indeterminate amount of time. + + We expect to see two types of resolvers: simple resolvers that can + chain through multiple name servers when required, and more + complicated resolvers that cache resource records for use in + future queries. + + Simple resolvers + + A simple resolver needs the following capabilities: + + 1. It must know how to access a name server, and should know the + authoritative name server for the host that it services. + + 2. It must know the protocol capabilities for its clients so that + it can set the class fields of the queries it sends to return + information that is useful to its clients. If the resolver + serves a client that has multiple protocol capabilities, it + should be able to support the preferences of the client. + + The resolver for a multiple protocol client can either collect + information for all classes using the * class value, or iterate + on the classes supported by the client. Note that in either + case, the resolver must understand the preferences of the host. + For example, the host that supports both CSNET and ARPA + + +Mockapetris [Page 27] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + Internet protocols might prefer mail delivery (MD) to mail + forwarding (MF), regardless of protocol, or might prefer one + protocol regardless of whether MD or MF is required. Care is + required to prevent loops. + + 3. The resolver must be capable of chaining through multiple name + servers to get to an authoritative name server for any query. + The resolver should guard against loops in referrals; a simple + policy is to discard referrals that don't match more of the + query name than the referring name server, and also to avoid + querying the same name server twice (This test should be done + using addresses of name servers instead of domain names to + avoid problems when a name server has multiple domain names or + errors are present in aliases). + + 4. The resolver must be able to try alternate name servers when a + name server doesn't respond. + + 5. The resolver must be able to communicate different failure + conditions to its client. These failure conditions include + unknown domain name, unknown resource for a know domain name, + and inability to access any of the authoritative name servers + for a domain. + + 6. If the resolver uses datagrams for queries, it must recover + from lost and duplicate datagrams. + + Resolvers with cache management + + Caching provides a tool for improving the performance of name + service, but also is a potential source of incorrect results. For + example, a database might cache information that is later changed + in the authoritative name servers. While this problem can't be + eliminated without eliminating caching, it can be reduced to an + infrequent problem through the use of timeouts. + + When name servers return resource records, each record has an + associated time-to-live (TTL) field. This field is expressed in + seconds, and has 16 bits of significance. + + When a resolver caches a returned resource record it must also + remember the TTL field. The resolver must discard the record when + the equivalent amount of time has passed. If the resolver shares + a database with a name server, it must decrement the TTL field of + imported records periodically rather than simply deleting the + record. This strategy is necessary to avoid exporting a resource + record whose TTL field doesn't reflect the amount of time that the + resource record has been cached. Of course, the resolver should + + + +Mockapetris [Page 28] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + + not decrement the TTL fields of records for which the associated + name server is an authority. + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Mockapetris [Page 29] + + +RFC 882 November 1983 + Domain Names - Concepts and Facilities + + +Appendix 1 - Domain Name Syntax Specification + + The preferred syntax of domain names is given by the following BNF + rules. Adherence to this syntax will result in fewer problems with + many applications that use domain names (e.g., mail, TELNET). Note + that some applications described in [14] use domain names containing + binary information and hence do not follow this syntax. + + ::= | " " + + ::=