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Domain Name System (DNS)

Domain Name System (DNS). Shivkumar Kalyanaraman Rensselaer Polytechnic Institute shivkuma@ecse.rpi.edu http://www.ecse.rpi.edu/Homepages/shivkuma. Naming hierarchy Server hierarchy Name resolution Other information in name servers Ref: Chap 14, RFC 1034. Overview. Why Names?.

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Domain Name System (DNS)

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  1. Domain Name System (DNS) Shivkumar Kalyanaraman Rensselaer Polytechnic Institute shivkuma@ecse.rpi.edu http://www.ecse.rpi.edu/Homepages/shivkuma

  2. Naming hierarchy • Server hierarchy • Name resolution • Other information in name servers • Ref: Chap 14, RFC 1034 Overview

  3. Why Names? • Computers use addresses • Humans cannot remember IP addresses  Need namesExample, “shiva” for 128.113.50.56 • Simplest Solution: Each computer has a unique name and has a built in table of name to address translation (mapping) • Problem: Not scalable • Solution: DNS (Adopted in 1983) • Hierarchical Names: shiv.ecse.rpi.edu

  4. Name Hierarchy Unnamed root ... com edu gov au us dec rpi nsf co va ecse ipl hr reston cnri

  5. Name Hierarchy • Unique domain suffix is assigned by Internet Authority • The domain administrator has complete control over the domain • No limit on number of sub-domains or number of levels • computer.site.division.company.com • Domains within an organization do not have to be uniform in number of subdomains or levels

  6. Name Hierarchy (Continued) • Name space is not related to physical interconnection, e.g., ecse.rpi.edu and ipl.rpi.edu could be on the same floor or in different cities • Geographical hierarchy is also allowed, e.g., cnri.reston.va.us • A name could be a subdomain (eg: ecse.rpi.edu) or an individual object (eg: cortez.rpi.edu)

  7. Top Level Domains Domain Name/ Assignment com Commercial edu Educational gov Government mil Military net Network org Other organizations arpa Advanced Research Project Agency country code au, uk, ca

  8. Server Hierarchy • Servers are organized in a hierarchy • Each server has an authority over a part of the naming hierarchy • It needs to know other servers who are responsible for other subdomains • A single node in the naming tree cannot be split among multiple servers • A given level of hierarchy can be partitioned into multiple servers

  9. Server Hierarchy (Example) com com foobar foobar soap soap candy candy peanut almond walnut peanut almond walnut

  10. Server Hierarchy (Continued) • Authority has the name to address translation table • Responsible Either has the name to address translation table or knows the server who has • But such a reply is called “non-authoritative” reply • Root server knows about servers for top-level domains, e.g., com • Each server knows the root server

  11. Server Hierarchy: Example RootServer Serverfor com Serverfor edu Serverfor gov Serverfor au Serverfor us Server for dec.com Serverfor rpi.edu Server fornsf.gov server forco.au Server forva.us

  12. Server Hierarchy: Better • Fewer servers • More entries/links per server • Fewer levels to traverse before resolving a name RootServer Server for dec.com Serverfor rpi.edu Server fornsf.gov server forco.au Server forva.us

  13. Name Resolution • Each computer has a name resolver routine, e.g., gethostbyname & gethostbyaddr in UNIX • Each resolver knows the IP address of a local DNS server • Resolver sends a DNS request to the server • DNS server either gives the answer, forwards the request to another server, or gives a referral • Referral = Next server to whom request should be sent • Recursive Query: Give me an answer (Don't give me a referral)

  14. Query Response Query Response Query Query Response Response Cache Cache Recursion! NameServer NameServer Data-base Data-base User NameResolver NameServer Data-base Cache Cache

  15. Referral Query Query Query Response Response Name Resolution (Continued) Cache Cache NameServer NameServer Data-base Query Data-base Response User NameResolver NameServer Data-base Cache Cache

  16. DNS Optimization • Spatial Locality: Local computers referenced more often than remote • Temporal Locality: Same set of domains referenced repeatedly Caching • Each entry has a time to live (TTL) • Replication: Multiple servers. Multiple roots. Ask the geographically closest server.

  17. Identification Parameter Number of Questions Number of Answers Number of Authority Number of Additional DNS Message Format Question Section... Answer Section... Authority Section... Additional Information Section...

  18. Query Type Query Class Type Class Format (Continued) • Format of the query section entries: Query Domain Name... • Format of other section entries: Resource Domain Name Time to live Resource Data Length Resource Data

  19. DNS Message Format (Continued) Bit Meaning 0 Operation: 0=Query, 1=Response 1-4 Query type: 0=Standard, 1=Inverse, 2,3 obsolete 5 Set if answer authoritative 6 Set if message truncated 7 Set if recursion desired 8 Set if recursion available 9-11 Reserved 12-15 Response type: 0=No error, 1=Format error, 2=Server Failure, 3=Name does not exist

  20. Types of DNS Entries • DNS used other types of resolution • Eg: also for finding mail server, pop server, responsible person, etc for a computer • DNS database has multiple “types” • Record type AAddress of X • Record type MXMail exchanger of X

  21. Types of DNS Entries (Continued) • DNS database may also have multiple “classes” • Can support name resolution for multiple protocols eg: IP, SNA, DECbit etc • Pointer queries: given IP address find name

  22. Resource Record Types Type Meaning A Host Address CNAME Canonical Name (alias) HINFO CPU and O/S MINFO Mailbox Info MX Mail Exchanger NS Authoritative name server for a domain PTR Pointer to a domain name (link) RP Responsible person SOA Start of zone authority (Which part of naming hierarchy implemented) TXT Arbitrary Text

  23. Summary • DNS: Maps names to addresses • Names are hierarchical. Administration is also hierarchical. • No standard for number of levels • Replication and caching is used for performance optimization.

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