Network Working Group | D. Crocker |
Internet-Draft | Brandenburg InternetWorking |
Intended status: Best Current Practice | April 13, 2011 |
Expires: October 15, 2011 |
DNS Scoped Data Through Attribute Leaves
draft-crocker-dns-attrleaf-05
Historically, any DNS RR may occur for any domain name. Recent additions have defined DNS leaf nodes that contain a reserved node name, beginning with an underscore. The underscore construct is used to define a semantic scope for DNS records associated with the parent domain. This note explores the nature of this DNS usage and defines the "underscore names" registry with IANA.
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The core DNS technical specifications assign no semantics to domain names or their parts, and no constraints upon which resource records (RRs) may be associated with particular names. Over time, some leaf node names, such as "www" and "ftp" have come to imply support for particular services, but this is a matter of operational convention, rather than defined protocol semantics. This freedom in the basic technology has permitted a wide range of administrative and semantic policies to be used -- in parallel. Data semantics have been limited to the specification of particular resource records, on the expectation that new ones would be added as needed.
Some recent service enhancements have defined a restricted scope for the occurrence of particular resource records. That scope is a leaf node, within which the uses of specific resource records can be formally defined and constrained. The leaf has a distinguished naming convention: It uses a reserved DNS node name that begins with an underscore. Because host names are not allowed to use the underscore character, this distinguishes the name from all legal host name. Effectively, this convention creates a space for attributes that are associated with the parent domain, one level up.
An established example is the SRV record [RFC2782] which generalizes concepts long-used for email routing by the MX record [RFC0974][RFC2821]. The use of special DNS names has significant benefits and detriments. Some of these are explored in [RFC5507].
The scoping feature is particularly useful when generalized resource records are used -- notably TXT and SRV. It provides efficient separation of one use of them from another. Absent this separation, an undifferentiated mass of these RRs are returned to the client which then must parse through the internals of the records in the hope of finding ones that are relevant. With underscore-based scoping, only the relevant RRs are returns.
This specification discusses the underscore "attribute" enhancement, provides an explicit definition of it, and establishes an IANA registry for the reserved names that begin with underscore.
Some resource records are generic and support a variety of uses. Each additional use defines its own rules and, possibly, its own internal syntax and node-naming conventions to distinguish among particular types. The TXT and SRV records are the notable examples. Used freely, some of these approaches scale poorly, particularly when the same RR can be present in the same leaf node, but with different uses. An increasingly-popular approach, with excellent scaling properties, uses an underscore-based name to a define place in the DNS that is constrained to particular uses for particular RRs. This means that a direct lookup produces only the desired records, at no greater cost than a typical lookup.
In the case of TXT records, different uses have developed largely without coordination. One side-effect is that there is no consistently distinguishable internal syntax for the record; even internal inspection might not be a reliable means of distinguishing among the different uses. Underscore-based names therefore provide an administrative way of separating TXT records that might have different uses, but otherwise would have no syntactic markers for distinguishing among them.
In the case of the SRV RR distinguishing among different types of use was part of the design. [RFC2782] The SRV specification serves as a template, defining an RR that may only be used for specific applications when there is an additional specification. The template definition includes reference to tables of names from which underscore-names should be drawn. The set of <service> names is defined in terms of other IANA tables, namely any table with symbolic names. The other SRV naming field is <proto>, although its pool of names is not explicitly defined.
This specification defines a registry for DNS nodes names, used to define scope of use for specific resource records (RR). A given name defines a specific, constrained context for the use of such records. This does not constrain the use of other resource records that are not specified. The purpose of the registry is to avoid collisions resulting from the use of the same underscore name, for different applications.
Structurally, the registry is defined as a single, flat table of names that begin with underscore. In some cases, such as for SRV, an underscore name might be multi-part, as a sequence of names. Semantically, this is a hierarchical model, thereby making a flat registry unexpected.
The registry requires such hierarchies to be registered as a combinatorial case analysis set, with each entry being a full sequence of underscore names. Given a scheme that is actually structured, this flat design is inelegant. However it has the benefit of being extremely simple, with the added advantage of being easier for readers to understand, as long as these cases are small and few.
NAME |
---|
_service1 |
_service2._protoB |
_service3._protoC |
_service3._protoC |
_service4._protoD._useX |
_protoE._region._authority |
The flat registry design:
A registry entry MUST contain:
Per [RFC2434], IANA is requested to establish a DNS Underscore Name Registry, for DNS node names that begin with the underscore character (_) and have been specified in any published RFC, or are documented by a specification published by another standards organization. The contents of each entry are defined in Section 4.
NAME | DNS LABEL | CONSTRAINTS | RR(s) | REFERENCES | PURPOSE |
---|---|---|---|---|---|
SRV TCP | _srv._tcp | SRV | [RFC2782] | SRV template | |
SRV UDP | _srv._udp | SRV | [RFC2782] | SRV template | |
LDAP SRV | _ldap._tcp | SRV | [RFC2782] | LDAP server | |
SIP TCP | _sip._tcp | NAPTR | [RFC3263], [RFC6011] | Locating SIP Servers and UA configuration | |
SIPS TCP | _sips._tcp | NAPTR | [RFC3263], [RFC6011] | Locating SIP Servers and UA configuration | |
SIP UDP | _sip._udp | SRV | [RFC3263], [RFC6011] | Locating SIP servers and UA configuration | |
SPF | _spf | TXT | [RFC4408] | Authorized IP addresses for sending mail | |
DKIM | _domainkey | TXT | [RFC4871] | Public key for verifying DKIM signature. | |
ADSP | _adsp._domainkey | TXT | [RFC5617] | Published DKIM usage practices | |
PKI LDAP | _PKIXREP._ldap | SRV | [RFC4386] | LDAP PKI Repository | |
PKI HTTP | _PKIXREP._http | SRV | [RFC4386] | HTTP PKI Repository | |
PKI OCSP | _PKIXREP._ocsp | SRV | [RFC4386] | OCSP PKI Repository | |
VBR | _vouch | TXT | [RFC5518] | Vouch-by-refererence domain assertion | |
DDDS | --unknown!-- | SRV | [RFC3404] | Mapping DDDS query to DNS records | |
SOAP BEEP | _soap-beep._tcp | SRV | [RFC4227] | SOAP over BEEP lookup, when no port specified | |
XMLRPC BEEP | _xmlrpc-beep._tcp | SRV | [RFC3529] | Resolve url for XML-RPC using BEEP | |
Diameter SCTP | _diameter._sctp | SRV | [RFC3588] | Diameter rendezvous over SCTP | |
Diameter TCP | _diameter._tcp | SRV | [RFC3588] | Diameter rendezvous over TCP | |
Tunnel | _tunnel._tcp | SRV | [RFC3620] | Finding the appropriate address for tunneling into a particular domain | |
SLP TCP | _slpda._tcp | SRV | [RFC3832] | Discovering desired services in given DNS domains | |
SLP UDP | _slpda._udp | SRV | [RFC3832] | Discovering desired services in given DNS domains | |
IM | _im | SRV | [RFC3861] | Instant Messaging address resolution | |
Pres | _pres | SRV | [RFC3861] | Presence address resolution | |
Msg Track | _mtqp._tcp | SRV | [RFC3887] | Assist in determining the path that a particular message has taken through a messaging system | |
XMPP Client | _xmpp-client._tcp | SRV | [RFC6120] | XMPP client lookup of server | |
XMPP Server | _xmpp-server._tcp | SRV | [RFC6120] | XMPP server-server lookup | |
DDDS SRV | _??? | (unable to discern details. /dcrocker) | SRV (and NAPTR?) | [RFC3958] | Map domain name, application service name, and application protocol dynamically to target server and port |
Kerberos TCP | _kerberos._tcp | SRV | [RFC4120] | purpose | |
Kerberos UDP | _kerberos._udp | SRV | [RFC4120] | purpose | |
PKI LDAP | _pkixrep._ldap | SRV | [RFC4386] | Enables certificate-using systems to locate PKI repositories | |
PKI HTTP | _pkixrep._http | SRV | [RFC4386] | Enables certificate-using systems to locate PKI repositories | |
PKI OCSP | _pkixrep._ocsp | SRV | [RFC4386] | Enables certificate-using systems to locate PKI repositories | |
Cert Store | _certificates._tcp | SRV | [RFC4387] | Obtain certificates and certificate revocation lists (CRLs) from PKI repositories | |
Cert Revocation Store | _crls._tcp | SRV | [RFC4387] | Obtain certificates and certificate revocation lists (CRLs) from PKI repositories | |
PGP Key Store | pgpkeys._tcp | SRV | [RFC4387] | Obtain certificates and certificate revocation lists (CRLs) from PKI repositories | |
MSRP Relay Locator | _msrp._tcp | SRV | [RFC4976] | purpose | |
Mobile IPv6 Bootstrap | _mip6._ipv6 | SRV | [RFC5026], [RFC5555] | Bootstrap Mobile IPv6 Home Agent information from non-topological information | |
Digital Video Broadcasting TCP | _dvbservdsc._tcp | SRV | [RFC5328] | Discover non-default DVB entry points addresses | |
Digital Video Broadcasting UDP | _dvbservdsc._udp | SRV | [RFC5328] | Discover non-default DVB entry points addresses | |
CAPWAP AC | _capwap-control._udp | rrs | [RFC5415] | Discover the CAPWAP AC address(es) | |
IM SIP | _im._sip | SRV | [RFC5509] | For resolving Instant Messaging and Presence services with SIP | |
Pres SIP | _pres._sip | SRV | [RFC5509] | For resolving Instant Messaging and Presence services with SIP | |
IEEE 802.21 Mobility TCP | _mihis._tcp | NAPTR, SRV | [RFC5679] | Discovering servers that provide IEEE 802.21-defined Mobility Services | |
IEEE 802.21 Mobility UDP | _mihis._udp | NAPTR, SRV | [RFC5679] | Discovering servers that provide IEEE 802.21-defined Mobility Services | |
STUN Client/Server TCP | _stun._.tcp | SRV | [RFC5389] | Find a STUN server | |
STUN Client/Server UDP | _stun._.udp | SRV | [RFC5389] | Find a STUN server | |
STUN Client/Server TLS | _stuns._.tcp | SRV | [RFC5389] | Find a STUN server | |
TURN TCP | _turn._tcp | SRV | [RFC5766], [RFC5928] | Control the operation of a relay to bypass NAT | |
TURN UDP | _turn._udp | SRV | [RFC5766], [RFC5928] | Control the operation of a relay to bypass NAT | |
TURN TLS | _turns._tcp | SRV | [RFC5766], [RFC5928] | Control the operation of a relay to bypass NAT | |
STUN NAT Behavior Discovery TCP | _stun-behavior._tcp | SRV | [RFC5780] | Discover the presence and current behavior of NATs and firewalls between the STUN client and the STUN server | |
STUN NAT Behavior Discovery UDP | _stun-behavior._udp | SRV | [RFC5780] | Discover the presence and current behavior of NATs and firewalls between the STUN client and the STUN server | |
STUN NAT Behavior Discovery TLS | _stun-behaviors._tcp | SRV | [RFC5780] | Discover the presence and current behavior of NATs and firewalls between the STUN client and the STUN server | |
Sieve Management | _sieve._tcp | SRV | [RFC5804] | Manage Sieve scripts on a remote server | |
AFS VLDB | _afs3-vlserver._udp | SRV | [RFC5864] | Locate services for the AFS distributed file system | |
AFS PTS | _afs3-prserver._udp | SRV | [RFC5864] | Locate services for the AFS distributed file system | |
Mail MSA Submission | _submission._tcp | SRV | [RFC6186] | Locate email services | |
IMAP | _imap._tcp | SRV | [RFC6186] | Locate email services | |
IMAP TLS | _imaps._tcp | SRV | [RFC6186] | Locate email services | |
POP | _pop3._tcp | SRV | [RFC6186] | Locate email services | |
POP TLS | _pop3s._tcp | SRV | [RFC6186] | Locate email services |
Numerous specifications have defined their own, independent registries for use of underscore names. It is likely that adoption of the proposed, integrated registry should render these piecemeal registries obsolete
Registries that are candidates for replacement include:
This memo raises no security issues.
[RFC2434] | Narten, T. and H. Alvestrand, "Guidelines for Writing an IANA Considerations Section in RFCs", RFC 2434, October 1998. |
Thanks go to Bill Fenner, Tony Hansen, Peter Koch, Olaf Kolkman, and Andrew Sullivan for diligent review of the earlier drafts.