WHOIS (pronounced as the phrase "who is") is a query and response protocol that is used for querying databases that store an Internet resource's registered users or assignees. These resources include domain names, IP address blocks and autonomous systems, but it is also used for a wider range of other information. The protocol stores and delivers database content in a human-readable format. [1] The current iteration of the WHOIS protocol was drafted by the Internet Society, and is documented in RFC 3912.
Whois is also the name of the command-line utility on most UNIX systems used to make WHOIS protocol queries. [2] In addition, WHOIS has a sister protocol called Referral Whois (RWhois).
This section needs additional citations for verification .(February 2017) |
Elizabeth Feinler and her team (who had created the Resource Directory for ARPANET) were responsible for creating the first WHOIS directory in the early 1970s. [3] Feinler set up a server in Stanford's Network Information Center (NIC) which acted as a directory that could retrieve relevant information about people or entities. [4] She and the team created domains, with Feinler's suggestion that domains be divided into categories based on the physical address of the computer. [5]
The process of registration was established in RFC 920. WHOIS was standardized in the early 1980s to look up domains, people, and other resources related to domain and number registrations. As all registration was done by one organization at that time, one centralized server was used for WHOIS queries. This made looking up such information very easy.
At the time of the emergence of the internet from the ARPANET, the only organization that handled all domain registrations was the Defense Advanced Research Projects Agency (DARPA) of the United States government (created during 1958. [6] ). The responsibility of domain registration remained with DARPA as the ARPANET became the Internet during the 1980s. UUNET began offering domain registration service; however, they simply handled the paperwork which they forwarded to the DARPA Network Information Center (NIC). Then the National Science Foundation directed that commercial, third-party entities would handle the management of Internet domain registration. InterNIC was formed in 1993 under contract with the NSF, consisting of Network Solutions, Inc., General Atomics and AT&T. The General Atomics contract was canceled after several years due to performance issues.
20th-century WHOIS servers were highly permissive and would allow wild-card searches. A WHOIS query of a person's last name would yield all individuals with that name. A query with a given keyword returned all registered domains containing that keyword. A query for a given administrative contact returned all domains the administrator was associated with. Since the advent of the commercialized Internet, multiple registrars and unethical spammers, such permissive searching is no longer available.
On December 1, 1999, management of the top-level domains (TLDs) com, net, and org was assigned to ICANN. At the time, these TLDs were converted to a thin WHOIS model. Existing WHOIS clients stopped working at that time. A month later, it had self-detecting Common Gateway Interface support so that the same program could operate a web-based WHOIS lookup, and an external TLD table to support multiple WHOIS servers based on the TLD of the request. This eventually became the model of the modern WHOIS client.
By 2005, there were many more generic top-level domains than there had been in the early 1980s. There are also many more country-code top-level domains. This has led to a complex network of domain name registrars and registrar associations, especially as the management of Internet infrastructure has become more internationalized. As such, performing a WHOIS query on a domain requires knowing the correct, authoritative WHOIS server to use. Tools to do WHOIS domain searches have become common and are offered by providers such as IONOS and Namecheap. [7]
In 2003, an IETF committee was formed to create a new standard for looking up information on domain names and network numbers: Cross Registry Information Service Protocol (CRISP). [8] Between January 2005 and July 2006, the working name for this proposed new standard was Internet Registry Information Service (IRIS) [9] [10] The initial IETF Proposed Standards RFCs for IRIS are:
The status of RFCs this group worked on can be found on the IETF Tools site. [11]
As of March 2009, [update] the CRISP IETF Working Group concluded, [12] after a final RFC 5144 was published by the group [13] Newton, Andrew; Sanz, Marcos (February 2008). A Domain Availability Check (DCHK) Registry Type for the Internet Registry Information Service (IRIS). IETF. doi: 10.17487/RFC5144 . RFC 5144 . Retrieved 1 June 2015..
Note: The IETF CRISP working group is not to be confused with the Number Resource Organization's (NRO) Team of the same name "Consolidated RIR IANA Stewardship Proposal Team" (CRISP Team). [14]
In 2013, the IETF acknowledged that IRIS had not been a successful replacement for WHOIS. The primary technical reason for that appeared to be the complexity of IRIS. Further, non-technical reasons were deemed to lie in areas upon which the IETF does not pass judgment. Meanwhile, ARIN and RIPE NCC managed to serve WHOIS data via RESTful web services. The charter (drafted in February 2012) provided for separate specifications, for number registries first and for name registries to follow. [15] The working group produced five proposed standard documents:
and an informational document:
The WHOIS protocol had its origin in the ARPANET NICNAME protocol and was based on the NAME/FINGER Protocol, described in RFC 742 (1977). The NICNAME/WHOIS protocol was first described in RFC 812 in 1982 by Ken Harrenstien and Vic White of the Network Information Center at SRI International.
WHOIS was originally implemented on the Network Control Protocol (NCP) but found its major use when the TCP/IP suite was standardized across the ARPANET and later the Internet.
The protocol specification is the following (original quote): [16]
Connect to the service host TCP: service port 43 decimal NCP: ICP to socket 43 decimal, establishing two 8-bit connections Send a single "command line", ending with <CRLF>. Receive information in response to the command line. The server closes its connections as soon as the output is finished.
The command line server query is normally a single name specification. i.e. the name of a resource. However, servers accept a query, consisting of only the question mark (?) to return a description of acceptable command line formats. Substitution or wild-card formats also exist, e.g., appending a full-stop (period) to the query name returns all entries beginning with the query name.
On the modern Internet, WHOIS services are typically communicated using the Transmission Control Protocol (TCP). Servers listen to requests on the well-known port number 43. Clients are simple applications that establish a communications channel to the server, transmit a text record with the name of the resource to be queried and await the response in form of a sequence of text records found in the database. This simplicity of the protocol also permits an application, and a command line interface user, to query a WHOIS server using the Telnet protocol.
In 2014, June ICANN published the recommendation for status codes, the "Extensible Provisioning Protocol (EPP) domain status codes" [17]
Status Code | Description |
---|---|
addPeriod | This grace period is provided after the initial registration of a domain name. If the registrar deletes the domain name during this period, the registry may provide credit to the registrar for the cost of the registration. |
autoRenewPeriod | This grace period is provided after a domain name registration period expires and is extended (renewed) automatically by the registry. If the registrar deletes the domain name during this period, the registry provides a credit to the registrar for the cost of the renewal. |
inactive | This status code indicates that delegation information (name servers) has not been associated with the domain. The domain is not activated in the DNS and will not resolve. |
ok | This is the standard status for a domain, meaning it has no pending operations or prohibitions. |
pendingCreate | This status code indicates that a request to create the domain has been received and is being processed. |
pendingDelete | This status code may be mixed with redemptionPeriod or pendingRestore. In such case, depending on the status set in the domain name, otherwise (not combined with other status), the pendingDelete status code indicates that the domain has been in redemptionPeriod status for 30 days and not restored. The domain will remain in this status for several days, after which time the domain will be dropped from the registry database. Once deletion occurs, the domain is available for re-registration in accordance with the registry's policies. |
pendingRenew | This status code indicates that a request to renew the domain has been received and is being processed. |
pendingRestore | This status code indicates that your registrar has asked the registry to restore the domain that was in redemptionPeriod status. Your registry will hold the domain in this status while waiting for your registrar to provide required restoration documentation. If your registrar fails to provide documentation to the registry operator within a set time period to confirm the restoration request, the domain will revert to redemptionPeriod status. |
pendingTransfer | This status code indicates that a request to transfer the domain to a new registrar has been received and is being processed. |
pendingUpdate | This status code indicates that a request to update the domain has been received and is being processed. |
redemptionPeriod | This status code indicates that your registrar has asked the registry to delete the domain. The domain will be held in this status for 30 days. After five calendar days following the end of the redemptionPeriod, the domain is purged from the registry database and becomes available for registration. |
renewPeriod | This grace period is provided after a domain name registration period is explicitly extended (renewed) by the registrar. If the registrar deletes the domain name during this period, the registry provides a credit to the registrar for the cost of the renewal. |
serverDeleteProhibited | This status code prevents the domain from being deleted. It is an uncommon status that is usually enacted during legal disputes, at your request, or when a redemptionPeriod status is in place. |
serverHold | This status code is set by the domain's Registry Operator. The domain is not activated in the DNS. |
serverRenewProhibited | This status code indicates the domain's Registry Operator will not allow your registrar to renew the domain. It is an uncommon status that is usually enacted during legal disputes or when the domain is subject to deletion. |
serverTransferProhibited | This status code prevents the domain from being transferred from your current registrar to another. It is an uncommon status that is usually enacted during legal or other disputes, at your request, or when a redemptionPeriod status is in place. |
serverUpdateProhibited | This status code locks the domain preventing it from being updated. It is an uncommon status that is usually enacted during legal disputes, at your request, or when a redemptionPeriod status is in place. |
transferPeriod | This grace period is provided after the successful transfer of a domain name from one registrar to another. If the new registrar deletes the domain name during this period, the registry provides a credit to the registrar for the cost of the transfer. |
WHOIS lookups were traditionally performed with a command line interface application, but now many alternative web-based tools exist.
A WHOIS database consists of a set of text records for each resource. These text records consists of various items of information about the resource itself, and any associated information of assignees, registrants, administrative information, such as creation and expiration dates.
Two data models exist for storing resource information in a WHOIS database, the thick and the thin model.
WHOIS information can be stored and looked up according to either a thick or a thin data model:
The thick model usually ensures consistent data and slightly faster queries, since only one WHOIS server needs to be contacted. If a registrar goes out of business, a thick registry contains all important information (if the registrant entered correct data, and privacy features were not used to obscure the data) and registration information can be retained. But with a thin registry, the contact information might not be available, and it could be difficult for the rightful registrant to retain control of the domain. [18]
If a WHOIS client did not understand how to deal with this situation, it would display the full information from the registrar. The WHOIS protocol has no standard for determining how to distinguish the thin model from the thick model.
Specific details of which records are stored vary among domain name registries. Some top-level domains, including com and net , operate a thin WHOIS, requiring domain registrars to maintain their own customers' data. The other global top-level registries, including org , operate a thick model. [19] Each country-code top-level registry has its own national rules.
Developer(s) | RIPE NCC (original BSD client), Marco d'Itri (modern Linux client) |
---|---|
Stable release | 5.5.19 / 2023-10-08 |
Operating system | Unix, Unix-like, ReactOS [20] |
Platform | Cross-platform |
Type | Command |
License | BSD License (BSD and ReactOS), GPL (Linux) |
Website | github |
The first applications written for the WHOIS information system were command-line interface tools for Unix and Unix-like operating systems (i.e. Solaris, Linux etc.). WHOIS client and server software is distributed as free open-source software and binary distributions are included with all Unix-like systems. Various commercial Unix implementations may use a proprietary implementation (for example, Solaris 7).
A WHOIS command line client passes a phrase given as an argument directly to the WHOIS server. Various free open source examples can still be found on sites such as sourceforge.net. However, most modern WHOIS tools implement command line flags or options, such as the -h option to access a specific server host, but default servers are preconfigured. Additional options may allow control of the port number to connect on, displaying additional debugging data, or changing recursion/referral behavior.
Like most TCP/IP client–server applications, a WHOIS client takes the user input and then opens an Internet socket to its destination server. The WHOIS protocol manages the transmission of the query and reception of results.
With the advent of the World Wide Web and especially the loosening up of the Network Solutions monopoly, looking up WHOIS information via the web has become quite common. At present, popular web-based WHOIS-queries may be conducted from ARIN, [21] RIPE [22] and APNIC. [23] Most early web-based WHOIS clients were merely front-ends to a command-line client, where the resulting output just gets displayed on a web page with little, if any, clean-up or formatting.
Currently, web based WHOIS clients usually perform the WHOIS queries directly and then format the results for display. Many such clients are proprietary, authored by domain name registrars.
The need for web-based clients came from the fact that command-line WHOIS clients largely existed only in the Unix and large computing worlds. Microsoft Windows and Macintosh computers had no WHOIS clients installed by default, so registrars had to find a way to provide access to WHOIS data for potential customers. Many end-users still rely on such clients, even though command line and graphical clients exist now for most home PC platforms. Microsoft provides the Sysinternals Suite that includes a whois client at no cost.
CPAN has several Perl modules available that work with WHOIS servers. Many of them are not current and do not fully function with the current (2005) WHOIS server infrastructure. However, there is still much useful functionality to derive including looking up AS numbers and registrant contacts.[ citation needed ]
WHOIS services are mainly run by registrars and registries; for example the Public Interest Registry (PIR) maintains the .ORG registry and associated WHOIS service. [24]
WHOIS servers operated by regional Internet registries (RIR) can be queried directly to determine the Internet service provider responsible for a particular resource.
The records of each of these registries are cross-referenced, so that a query to ARIN for a record which belongs to RIPE will return a placeholder pointing to the RIPE WHOIS server. This lets the WHOIS user making the query know that the detailed information resides on the RIPE server. In addition to the RIRs servers, commercial services exist, such as the Routing Assets Database used by some large networks (e.g., large Internet providers that acquired other ISPs in several RIR areas).
There is currently no widely extended way for determining the responsible WHOIS server for a DNS domain, though a number of methods are in common use for top-level domains (TLDs). Some registries use DNS SRV records (defined in RFC 2782 [25] ) to allow clients to discover the address of the WHOIS server. [26] Some WHOIS lookups require searching the procuring domain registrar to display domain owner details.
Normally the contact information of the resources assignee is returned. However, some registrars offer private registration, in which case the contact information of the registrar is shown instead.
Some registry operators are wholesalers, meaning that they typically provide domain name services to a large number of retail registrars, who in turn offer them to consumers. For private registration, only the identity of the wholesale registrar may be returned. In this case, the identity of the individual as well as the retail registrar may be hidden.
Below is an example of WHOIS data returned for an individual resource holder. This is the result of a WHOIS query of example.com:
> whois example.com [Querying whois.verisign-grs.com][Redirected to whois.iana.org][Querying whois.iana.org][whois.iana.org]% IANA WHOIS server% for more information on IANA, visit http://www.iana.org% This query returned 1 objectdomain: EXAMPLE.COMorganisation: Internet Assigned Numbers Authoritycreated: 1992-01-01source: IANA
Referral Whois (RWhois) is an extension of the original WHOIS protocol and service. RWhois extends the concepts of WHOIS in a scalable, hierarchical fashion, potentially creating a system with a tree-like architecture. Queries are deterministically routed to servers based on hierarchical labels, reducing a query to the primary repository of information. [27]
Lookups of IP address allocations are often limited to the larger Classless Inter-Domain Routing (CIDR) blocks (e.g., /24, /22, /16), because usually only the regional Internet registries (RIRs) and domain registrars run RWhois or WHOIS servers, although RWhois is intended to be run by even smaller local Internet registries, to provide more granular information about IP address assignment.
RWhois is intended to replace WHOIS, providing an organized hierarchy of referral services where one could connect to any RWhois server, request a look-up and be automatically re-directed to the correct server(s). However, while the technical functionality is in place, adoption of the RWhois standard has been weak.
RWhois services are typically communicated using the Transmission Control Protocol (TCP). Servers listen to requests on the well-known port number 4321.
Rwhois was first specified in RFC 1714 in 1994 by Network Solutions, [27] but the specification was superseded in 1997 by RFC 2167. [28]
The referral features of RWhois are different than the feature of a WHOIS server to refer responses to another server, which RWhois also implements.
One criticism of WHOIS is the lack of full access to the data. [29] [30] Few parties have realtime access to the complete databases.
Others cite the competing goal of domain privacy as a criticism, although this problem is strongly mitigated by domain privacy services. Currently, the Internet Corporation for Assigned Names and Numbers (ICANN) broadly requires that the mailing address, phone number and e-mail address of those owning or administering a domain name to be made publicly available through the "WHOIS" directories. The registrant's (domain owner's) contact details, such as address and telephone number, are easily accessible to anyone who queries a WHOIS server. However, that policy enables spammers, direct marketers, identity thieves or other attackers to loot the directory for personal information about these people. Although ICANN has been exploring changing WHOIS to enable greater privacy, there is a lack of consensus among major stakeholders as to what type of change should be made. [31] Some domain registrars offer private registrations (also known as domain privacy), by which the contact information of the registrar is shown instead of the customer's. With the offer of private registration from many registrars, some of the risk has been mitigated. [32]
Studies have shown that spammers can and do harvest plain-text email addresses from WHOIS servers. [33] For this reason, some WHOIS servers and websites offering WHOIS queries have implemented rate-limiting systems, such as web-based CAPTCHA and limited amounts of search queries per user IP address. [32]
The WHOIS requirements conflict with the General Data Protection Regulation (GDPR), effective in the European Union 25 May 2018, which places strict regulations on the processing and publication of personally identifiable information. ICANN stated in November 2017 that it would not reprimand "noncompliance with contractual obligations related to the handling of registration data" if registrars provide alternative solutions for compliance with its rules, until the WHOIS requirements are updated to take GDPR into account. [32] [34]
The WHOIS protocol was not written with an international audience in mind. A WHOIS server and/or client cannot determine the text encoding in effect for the query or the database content. Many servers were originally using US-ASCII and Internationalization concerns were not taken into consideration until much later. [35] This might impact the usability or usefulness of the WHOIS protocol in countries outside the USA. [1] In the case of internationalized domain names it is the responsibility of the client application to perform the translation of the domain name between its native language script and the DNS name in punycode.
In cases where the registrant's (Domain Owner) identity is public, anyone can easily confirm the status of a domain via WHOIS.
In the case of private registrations, ascertaining registration information may be more difficult. If a registrant, who acquired a domain name, wants to verify the registrar has completed the registration process, three steps may be required:
This provides some confidence that the retailer actually registered the name. But if the registrar goes out of business, as with the failure of RegisterFly in 2007, the rightful domain holder with privacy-protected registrations may have difficulty regaining the administration of their domain name. [18] Registrants using "private registration" can attempt to protect themselves by using a registrar that places customer data in escrow with a third party.
ICANN requires that every registrant of a domain name be given the opportunity to correct any inaccurate contact data associated with their domain. For this reason, registrars are required to periodically send the holder the contact information on record for verification, but they do not provide any guarantee about the accuracy of information if the registrant provided inaccurate information.
The examples and perspective in this section deal primarily with the United States and do not represent a worldwide view of the subject.(May 2018) |
WHOIS has generated policy issues in the United States federal government. As noted above, WHOIS creates a privacy issue which is also tied to free speech and anonymity. However, WHOIS is an important tool for law enforcement officers investigating violations like spam and phishing to track down the holders of domain names. As a result, law enforcement agencies have sought to make WHOIS records both open and verified: [36]
The Expert Working Group (EWG) of the Internet Corporation for Assigned Names and Numbers (ICANN) recommended on 24 June 2013 that WHOIS should be scrapped. It recommends that WHOIS be replaced with a system that keeps information secret from most Internet users, and only discloses information for "permissible purposes". [41] ICANN's list of permissible purposes includes domain-name research, domain-name sale and purchase, regulatory enforcement, personal data protection, legal actions, and abuse mitigation. [42] Although WHOIS has been a key tool of journalists in determining who was disseminating certain information on the Internet, [43] the use of WHOIS by the free press is not included in ICANN's proposed list of permissible purposes.
The EWG collected public input on the initial report until 13 September 2013. Its final report was issued on 6 June 2014, without meaningful changes to the recommendations. [44] As of March 2015 [update] , ICANN is in the "process of re-inventing WHOIS," working on "ICANN WHOIS Beta." [45] [46]
On January 19, 2023, ICANN opened voting on a global amendment to all its registry and registrar agreements. In it they defined an RDAP Ramp-Up Period of 180 days starting with the effectiveness of this amendment. 360 days after this period is defined as the WHOIS Services Sunset Date, after which it is not a requirement for registries and registrars to offer a WHOIS service and instead only an RDAP service is required. All voting thresholds were met within the 60 day voting period and the amendment was approved by the ICANN Board. The date for WHOIS Sunset for gTLDs was set as 28 January 2025. [47]
The Domain Name System (DNS) is a hierarchical and distributed name service that provides a naming system for computers, services, and other resources on the Internet or other Internet Protocol (IP) networks. It associates various information with domain names assigned to each of the associated entities. Most prominently, it translates readily memorized domain names to the numerical IP addresses needed for locating and identifying computer services and devices with the underlying network protocols. The Domain Name System has been an essential component of the functionality of the Internet since 1985.
The Internet Corporation for Assigned Names and Numbers is a global multistakeholder group and nonprofit organization headquartered in the United States responsible for coordinating the maintenance and procedures of several databases related to the namespaces and numerical spaces of the Internet, ensuring the Internet's stable and secure operation. ICANN performs the actual technical maintenance work of the Central Internet Address pools and DNS root zone registries pursuant to the Internet Assigned Numbers Authority (IANA) function contract. The contract regarding the IANA stewardship functions between ICANN and the National Telecommunications and Information Administration (NTIA) of the United States Department of Commerce ended on October 1, 2016, formally transitioning the functions to the global multistakeholder community.
A top-level domain (TLD) is one of the domains at the highest level in the hierarchical Domain Name System of the Internet after the root domain. The top-level domain names are installed in the root zone of the name space. For all domains in lower levels, it is the last part of the domain name, that is, the last non-empty label of a fully qualified domain name. For example, in the domain name www.example.com, the top-level domain is .com. Responsibility for management of most top-level domains is delegated to specific organizations by the ICANN, an Internet multi-stakeholder community, which operates the Internet Assigned Numbers Authority (IANA), and is in charge of maintaining the DNS root zone.
A name server is a computer application that implements a network service for providing responses to queries against a directory service. It translates an often humanly meaningful, text-based identifier to a system-internal, often numeric identification or addressing component. This service is performed by the server in response to a service protocol request.
In the Internet, a domain name is a string that identifies a realm of administrative autonomy, authority or control. Domain names are often used to identify services provided through the Internet, such as websites, email services and more. Domain names are used in various networking contexts and for application-specific naming and addressing purposes. In general, a domain name identifies a network domain or an Internet Protocol (IP) resource, such as a personal computer used to access the Internet, or a server computer.
The Internet Assigned Numbers Authority (IANA) is a standards organization that oversees global IP address allocation, autonomous system number allocation, root zone management in the Domain Name System (DNS), media types, and other Internet Protocol–related symbols and Internet numbers.
A domain name registry is a database of all domain names and the associated registrant information in the top level domains of the Domain Name System (DNS) of the Internet that enables third party entities to request administrative control of a domain name. Most registries operate on the top-level and second-level of the DNS.
The domain com is a top-level domain (TLD) in the Domain Name System (DNS) of the Internet. Created in the first group of Internet domains at the beginning of 1985, its name is derived from the word commercial, indicating its original intended purpose for subdomains registered by commercial organizations. Later, the domain opened for general purposes.
The Domain Name System Security Extensions (DNSSEC) are a suite of extension specifications by the Internet Engineering Task Force (IETF) for securing data exchanged in the Domain Name System (DNS) in Internet Protocol (IP) networks. The protocol provides cryptographic authentication of data, authenticated denial of existence, and data integrity, but not availability or confidentiality.
A domain name registrar is a company, person, or office that manages the reservation of Internet domain names.
The Extensible Provisioning Protocol (EPP) is a flexible protocol designed for allocating objects within registries over the Internet. The motivation for the creation of EPP was to create a robust and flexible protocol that could provide communication between domain name registries and domain name registrars. These transactions are required whenever a domain name is registered or renewed, thereby also preventing domain hijacking. Prior to its introduction, registries had no uniform approach, and many different proprietary interfaces existed. While its use for domain names was the initial driver, the protocol is designed to be usable for any kind of ordering and fulfilment system.
.ae is the country code top-level domain (ccTLD) in the Domain Name System of the Internet for the United Arab Emirates. It is administered by .aeDA which is part of the Telecommunications and Digital Government Regulatory Authority of UAE (TDRA).
The domain name arpa is a top-level domain (TLD) in the Domain Name System (DNS) of the Internet. It is used predominantly for the management of technical network infrastructure. Prominent among such functions are the subdomains in-addr.arpa and ip6.arpa, which provide namespaces for reverse DNS lookup of IPv4 and IPv6 addresses, respectively.
.tw is the Internet country code top-level domain (ccTLD) for Taiwan. The domain name is based on the ISO 3166-1 alpha-2 country code TW. The registry is maintained by the Taiwan Network Information Center (TWNIC), a Taiwanese non-profit organization appointed by the National Communications Commission (NCC) and the Ministry of Transportation and Communication. Since 1 March 2001, TWNIC has stopped allowing itself to sign up new domain names directly, instead allowing new registration through its contracted reseller registrars. As of May 2023, there are 17 registrars.
The domain names example.com, example.net, example.org, and example.edu are second-level domain names in the Domain Name System of the Internet. They are reserved by the Internet Assigned Numbers Authority (IANA) at the direction of the Internet Engineering Task Force (IETF) as special-use domain names for documentation purposes. The domain names are used widely in books, tutorials, sample network configurations, and generally as examples for the use of domain names. The Internet Corporation for Assigned Names and Numbers (ICANN) operates web sites for these domains with content that reflects their purpose.
.na is the Internet country code top-level domain (ccTLD) for Namibia corresponding to the two letter code from the ISO-3166 standard.
.biz is a generic top-level domain (gTLD) in the Domain Name System of the Internet. It is intended for registration of domains to be used by businesses. The name is a phonetic spelling of the first syllable of business.
The Registration Data Access Protocol (RDAP) is a computer network communications protocol standardized by a working group at the Internet Engineering Task Force in 2015, after experimental developments and thorough discussions. It is a successor to the WHOIS protocol, used to look up relevant registration data from such Internet resources as domain names, IP addresses, and autonomous system numbers.
The CRISP (Cross-Registry Information Service Protocol) WG will define a standard mechanism that can be used for finding authoritative information associated with a label, a protocol to transport queries and responses for accessing that information, and a first profile (schema & queries) to support commonly-required queries for domain registration information.
The Nicname/Whois protocol has served well, but it remains unchanged since it was first published in the early 1980s, despite great change in the infrastructure and administration of the Internet. There is now more diversity with domain names and IP networks and associated contacts, as well as among the users submitting queries via Whois. The protocol is now so fragmented in terms of information flow and output that queries yield inconsistent results under current conditions. To address the needs of today's Internet, the IETF Cross Registry Internet Service Protocol (CRISP) working group is developing a new protocol, the Internet Registry Information Service (IRIS), to replace Whois.
CRISP – Cross-Registry Internet Service Protocol: The CRISP Working Group was tasked with finding a solution to the problems that currently infest the Nicname/Whois protocol. The CRISP Working Group created a list of functional requirements. Proposals meeting these requirements were evaluated. IRIS was selected as the protocol to publish as a standard. Now an IETF Proposed Standard: RFCs: 3981, 3982, 3983
The Cross Registry Information Service Protocol (crisp) working group in the Applications Area has concluded.
Current gTLD registry agreements vary between thin and thick Whois outputs: com, net and jobs are thin; all other gTLD agreements – aero, asia, biz, cat, coop, info, mobi, museum, name, org, pro, tel, travel – are thick.