The name and address space

Track1: Host Based Internetworking The name and address space Network Training Workshop San Jose, 13-20 June 1999

What is a domain name ? Networking language hard to remember 137.138.131.253 Intermediate language not easy to find still difficult to remember DNS: Domain Name Service www.isoc.org Network Training Workshop easy to find

What is DNS? • Domain Name Service • Internet protocol • Distributed data base system for objects in a computer network • Net-wide Database • It Maps • name to address • address to name • Set of tools to manage the service

IP addresses and names • Disadvantages of an address • It is too long (192.162.16.201) • It has no representation for the organization • It is difficult to remember • IP addresses can change • Names • Human users prefer to use names instead of numbers • A name can be associated to any device that has an IP address • Advantages of names • They make reference to an organization name: *.ibm.com • They are easy to remember

Why use hierarchical names? • Internet hosts and other resources need globally unique names • Difficult to keep unstructured names unique • would require a single list of all names in use • Hierarchical names are much easier to make unique

Domain Name Hierarchy Root domain . Top-Level-Domains . . . . . . edu com gov mil net org ro fr at jp Second Level Domains ici rnc ase pub utt vsat eunet ac co gv or . . . univie uni-linz tuwien . . . . . . . roearn ns std cs lmn dsp cc mat exp itc . . . . . . ulise paul phytia alpha chris

Domain name structures • The root of system is unnamed • Top level domains are: • Within the United States of America • edu - educational institutions • com - commercial institutions • net - network support organizations • gov - government agencies • mil - military organizations • org - organizations that don’t fit in any of the above • country code according to ISO-3316 (uk, de, pl, sk, mk, ...) • Flat structure • Based on generic categories (ac, co, gv, org, net, etc.) • Based on geographical locations (waw.pl, poznan.pl, etc.)

ICANN • ICANN • Internet Corporation for Assigned Names and Numbers • ICANN is the overall authority for: • IP addresses; • top-level-domains;

Domain Name Servers • Usually host names are used in network commands (telnet, ftp, mail, gopher clients, www clients, etc. ); • Network connections always take place based on the IP address; • The system always converts host names to addresses before the network connection is made; • How to associate names with addresses? • Host table • Domain Name Server

Host Table • host table is a simple text file (/etc/hosts) which contains associations between an IP address and a list of host names. • Example: • 130.65.240.254 carlos.t1.isocws.isoc.org carlos • Disadvantage • The table should contain all the Internet hosts ( x 1,000,000 entries); • The table is very large; • Difficult to update when new hosts are connected to Internet or IP addresses are changed

Domain Name Server (DNS) • Overcomes the weaknesses of the host table • It is a distributed database system • Host names are automatically disseminated to those who ask to have access

BIND - UNIX Name Service • In UNIX, DNS is implemented by the Berkeley Internet Name Domain (BIND) software; • It is a client/server software system; • The client is called “resolver”; it generates queries for domain name information that are sent to the server; • The server is a daemon called named. • The domain name is actually an argument used by the local resolver; • The resolver is responsible for hiding the distribution of data among nameservers from the user; • The resolver is part of the operating system.

DNS Operation • To establish a connection to a remote host, a user program sends a query to the resolover, asking the IP number of a specified hostname; • The resolver starts with knowledge of at least one nameserver; • The resolver processes a user query by asking a known nameserver for the information (IP for the remote host); • If the nameserver has the answer, it will give it. • The local nameservers knows the addresses of other nameservers; • If the remote host is in a zone for which the local nameserver is not authoritative, queries will be sent to other nameservers, starting with root servers to find out the delegated nameserver for the top-level-domain, the subdomain and so on;

DNS Operation (continue) • To minimize the answer time for the next query to the same host name, the nameserver caches the information obtained by a query; the information cached is valid a certain time period as defined when that zone was configured. • Finally, the nameserver delegated for the zone containing the remote host is reached and the IP addresses is obtained and returned to the host which initiated the first query;

The resolver/server model (diagram) Authoritative Nameserver Recursive Nameserver CACHE Resolver Resolver

Resolver Configuration • Configuration file name • /etc/resolv.conf. • Designates the name servers on the network that should be sent queries. • The resolver will try to contact a name server • The resolv.conf file contains directives • ; comment • # another comment • search search-list • nameserver server-address ; multiple lines

Example - Resolver Configuration search t1.isocws.isoc.org nameserver 130.65.37.128 nameserver 130.65.37.215

Checking DNS using nslookup • nslookup commands: server <nameserver> ; set the server to be queriedset type = NS ;queries NS resourcesset type = SOA ;queries SOA resourcesset type = A ;queries A resourcesset type = MX ;queries MX resourcesset type = CNAME ;queries CNAME resourcesset type = PTR ;queries PTR resourcesset type = ANY ;queries ANY resourcesls <domain> ;lists the <domain> zonels <domain> > <file-name> ;gets the zone <domain> into the file<file-name>

Checking DNS using dig • Dig • Tool to manage DNS settings • Syntax is: dig [domain] @nameserver [query-type]

Exercise 1. Checking DNS using nslookup • nslookup commands:server <nameserver> ; set the server to be queriedset type = NS ;queries NS resourcesset type = SOA ;queries SOA resourcesset type = A ;queries A resourcesset type = MX ;queries MX resourcesset type = CNAME ;queries CNAME resourcesset type = PTR ;queries PTR resourcesset type = ANY ;queries ANY resourcesls <domain> ;lists the <domain> zonels <domain> > <file-name> ;gets the zone <domain> into <file-name>view <file-name> ;views the <file-name> file #nslookup >set type=any >www.t1.isocws.isoc.org. >org. >ls isoc.org > file1 >view file1 You can check other domains, known to you.

Exercise 2. Checking DNS using dig • dig command:# dig [zone] @nameserver [query-type] • Exercises • # dig @ns.t1.isocws.isoc.org t1.isocws.isoc.org A • # dig @ns.t1.isocws.isoc.org t1.isocws.isoc.org NS • # dig @ns.t1.isocws.isoc.org isocws.isoc.org MX • What information does give you? You can check other domains, known to you.

Remarks • DNS is essential for a proper operation of the network; • If DNS fails, connections to any remote host are no more possible; • To allow network operation in case of failures of a nameserver, each nameserver (called primary nameserver should have at least another nameserver (called secondary nameserver) which holds a copy of the zone file; • The secondary nameserver periodically queries the primary nameserver whether the zone was changed. In case of the change, it is transferred into its cache and also stored in a local file, which will be used next time at starting up as initial data; • When data about a new host should be added to the DNS database, or a change of address/name should be done, the entry is done only on the primary nameserver; the secondary nameserver will get it automatically.

Reverse Lookup • When a source host establishes a connection to a destination host, the TCP/IP packets carry out only IP addresses of the source host; • For authentication, access rights or accounting information, the destination host wants to know the name of the source host; • For this purpose, a special domain “in-addr.arpa” is used; • The reverse name is obtained by reversing the IP number and adding the name “in-addr.arpa”; • Example: address: 130.65.240.254 reverse name: 254.240.65.130.in-addr.arpa • Reverse domains form a hierarchical tree and are treated as any other Internet domain.

Reverse Domain Hierarchy .arpa .in-addr . . . . . . 187 188 189 190 191 192 193 194 195 157 158 159 160 161 162 163 164 165 166 167 168 . . . 12 13 14 15 16 17 18 19 20 21 1 2 3 4 5

Hierarchy of nameservers • Root nameserver - delegates nameservers for top-level-domains; • Nameserver for each top level domain - holds information about the top level domain, delegates nameservers for subdomains; • Nameserver for each subdomain • Nameserver for each reverse domain

Requirements for a nameserver • A query should be resolved as fast as possible; • It should be available 24 hours a day; • It should be reachable via fast communication lines; • It should be located in the central in the network topology; • It should run robust, without errors and interrupts.

Type of servers • DNS server • primary for some zones • secondary for others, • Caching Only Server • All servers & not authoritative for any zone • Forwarding Server • always forwards queries it cannot satisfy from its cache, to a fixed list of forwarding servers; the queries to the forwarding servers are recursive queries.

Files • Name server uses several files to load its data base • This section covers the files and their formats needed for named • Boot File • file - first read when named starts up • tells the server what type of server it is, which zones it has authority over and where to get its initial data. • The default location /etc/named.conf • Can be changed by setting the BOOTFILE variable when you compile named or by specifying the location on the command line when named is started up.

Domain data files • Two standard files for specifying the data for a domain • mapping addresses in names • mapping name in addresses • These files use the Standard Resource Record Format (RR) Note: The file names are arbitrary; many network administrators prefer to name their zone files after the domains they contain, especially in the average case which is where a given server is primary and/or secondary for many different zones.

Forward mapping File • This file contains all the data about the machines in this zone. • The location of this file is specified in the boot file. • Declare in named.conf file

Reverse mapping File • This file specifies the IN-ADDR.ARPA domain • Declared in named.conf file • This is a special domain for allowing address to name mapping. • Special domain formed to allow inverse mapping • The IN-ADDR.ARPA domain has four labels preceding it. (4 octets of an Internet address) • E.g. Internet address 128.32.0.4 • domain 4.0.32.128.IN-ADDR.ARPA.

Standard Resource Record Format (RR) • The records in the name server data files are called resource records. The Standard Resource Record Format (RR) is specified in RFC1035. • General description of these records: • {name} {ttl} addr-class Record Type Record Specific data • the name may be left blank • The second field is an optional time to live field. (default ttl is specified in the Start Of Authority resource record). • The third field is the address class currently, only one class is supported: IN

IP address for a host • A record • Owner is host name • Data is IP address ; IP address of infoserver.xyz.com www.dns.net. 86400 IN A 196.34.13.9

Information needed by the DNS infrastructure itself • SOA record • Each zone has exactly one SOA record • NS records • Each zone has several nameservers that are listed as having authoritative information about domains in the zone • One NS record for each such nameserver

SOA record • Every zone has exactly one SOA record • The domain name at the top of the zone owns the SOA record • Data portion of SOA record contains: • MNAME - name of master nameserver • RNAME - email address of zone administrator • The Five Magic Numbers • SERIAL - serial number • REFRESH RETRY EXPIRE MINIMUM - timing parameters

NS record • Each zone has several listed nameservers • One NS record for each listed nameserver • primary and secondary • the data portion of each NS record contains the domain name of a nameserver • Does not contain IP address • Get that from an A record for the nameserver

SOA and NS record example ; owner TTL class type data xyz.com. 86400 IN SOA ns1.xyz.com. fred.xyz.com. ( 199906141 ; serial 21600 ; refresh 3600 ; retry 2600000 ; expire 900 ) ; minimum xyz.com. 86400 IN NS ns1.xyz.com. xyz.com. 86400 IN NS ns2.xyz.com. xyz.com. 86400 IN NS server.where.example.

SOA and NS example using some shortcuts $ORIGIN xyz.com. $TTL 86400 ; owner TTL class type data @ IN SOA ns1.xyz.com. fred.xyz.com. ( 199710161 ; serial 21600 ; refresh 3600 ; retry 2600000 ; expire 900 ) ; minimum NS ns1 NS ns2 NS server.where.example.

More RRs above and below zone cuts • RRs in the child zone (below the cut) • SOA and NS records (authoritative) • RRs in the parent zone (above the cut) • NS records (should be identical to those in the child zone) • glue records • the child zone’s nameservers sometimes need A records in the parent zone

Zone cut example - RRs in the child zone • parent is COM zone; child is XYZ.COM zone • child zone has SOA and NS records, and A records for hosts xyz.com. IN SOA xxx xxx xxx xxx xxx xxx xxx NS ns1.xyz.com. NS another.where.edu. ns1.xyz.com. A 193.226.0.3 ; the xyz.com zone does not have an A record ; for another.where.edu.

Zone cut example - RRs in the parent zone • parent is COM zone; child is XYZ.COM zone • parent zone has its own SOA and NS records, plus copies of child zone’s NS records, plus glue records COM. IN SOA xxx xxx xxx xxx xxx xxx xxx NS xxxxxxx NS yyyyyyy xyz.com. NS ns1.xyz.com. NS another.where.ro. ns1.xyz.com. A 192.0.2.3 ; the com zone does not have an A record ; for another.elsewhere.edu.

Hostname for an IP address • PTR record • Owner is IP address, mapped into the in-addr.arpa domain • Data is name of host with that IP address ; host name for IP address 192.0.3.2 3.0.226.193.in-addr.arpa. PTR infoserver.ici.ro.

Information about mail routing • MX record • Owner is name of email domain • Data contains preference value, and name of host that receives incoming email ; send xyz.com’s email to mailserver or backupserver xyz.com. MX 0 mail.xyz.ro. xyz.com. MX 10 backup.xyz.ro.

Free form text • TXT record • Owner is any domain name • Data is any text associated with the domain name • Very few conventions about how to use it .ro. TXT “George Macri - Tech-contact”

Alias to canonical name mapping • CNAME record • Owner is non-canonical domain name (alias) • Data is canonical domain name ; ftp.rnc.ro is an alias ; info.ici.ro is the canonical name ftp.rnc.ro. CNAME info.ici.ro.

BIND 8 Highlights • DNS Dynamic Updates (RFC 2136) • DNS Change Notification (RFC 1996) • Completely new configuration syntax • Flexible, categorized logging system • IP-address-based access control for queries, zone transfers, and updates that may be specified on a zone-by-zone basis • More efficient zone transfers • Improved performance for servers with thousands of zones • The server no longer forks for outbound zone transfers • Many bug fixes

Statements • A BIND 8 configuration consists of statements and comments. • Statements end with a semicolon. • Statements supported: • acl • defines a named IP address matching list, for access control and other uses • include • includes a file • key • specifies key information for use in authentication and authorization • logging • specifies what the server logs, and where the log messages are sent • options • controls global server configuration options and sets defaults for other statements • server • zone

Example Config File /* A simple BIND 8 configuration */ options { directory "/var/named"; }; }; zone ”rnc.ro" in { type master; file "master/isc.org"; };

Example Config File (cont.) zone ”ici.ro" in { type slave; file "slave/vix.com"; masters { 192.162.16.31; }; }; zone "." in { type hint; file "named.cache"; }; zone "0.0.127.in-addr.arpa" in { type master; file "master/127.0.0"; };

Domain Management • Starting named • Named signaling processing • Debugging DNS • Tools • nslookup • dig • host

The name and address space