DNS HOWTO Nicolai Langfeldt janl@math.uio.no v1.1, 30 June 1996 HOWTO become a totally small time DNS admin. Keywords: DNS, bind, named, dialup, ppp, slip, Internet, domain, name, hosts, resolving Legal stuff: (C)opyright 1995 Nicolai Langfeldt. Do not modify without amending copyright, distribute freely but retain copyright message. The author wishes to thank Arnt Gulbrandsen who read the drafts to this work countless times and provided many useful suggestions. Other stuff: This will never be a finished document, please send me mail about your problems and successes, it can make this a better HOWTO. So please send money, comments and/or questions to janl@ifi.uio.no. This HOWTO is dedicated to Anne Line Norheim. Though she will probably never read it since she's not that kind of girl. 1. Introduction. What this is and isn't. DNS is, to the uninitiated (you ;-), one of the more opaque areas of network administration. This HOWTO will try to make a few things clearer. It describes how to set up a simple DNS name server. For more complex setups you will need to read the Real Documentation. I'll get back to what this Real Documentation consists of in ``the last chapter''. Before you start on this you should configure your machine so that you can telnet in and out of it, and make successfully make all kinds of connections to the net, and you should especially be able to do telnet 127.0.0.1 and get your own machine. You also need a good /etc/host.conf, /etc/resolv.conf and /etc/hosts files as a starting point, since I will not explain their function here. If you don't already have all this set up and working the networking/NET-2 HOWTO explains how to set it up. Read it. If you're using SLIP or PPP you need that working. Read the PPP HOWTO if it's not. When I say `your machine' I mean the machine you are trying to set up DNS on. Not any other machine you might have that's involved in your networking effort. I assume you're not behind any kind of firewall that blocks name queries. If you are you will need a special configuration, see the section on ``firewalls and other peculiar net things''. Name serving on Unix is done by a program called named. This is a part of the bind package which is coordinated by Paul Vixie for The Internet Software Consortium. Named is included in most Linux distributions and is usually installed as /usr/sbin/named. If you have a named you can probably use it; if you don't have one you can get a binary off a Linux ftp site, or get the latest and greatest source from ftp.vix.com:/pub/bind in either the release or testing subdirectory, whatever fits your lifestyle best. DNS is a net-wide database. Take care about what you put into it. If you put junk into it, you, and others will get junk out of it. Keep your DNS tidy and consistent and you will get good service from it. Learn to use it, admin it, debug it and you will be another good admin keeping the net from falling to it's knees overloaded by mismanagement. In this document I state flatly a couple of things that are not completely true (they are at least half truths though). All in the interest of simplification. Things will probably work if you believe what I say. Tip: Make backup copies of all the files I instruct you to change if you already have them, so if after going through this nothing works you can get it back to your old, working state. 2. A caching only name server. A first stab at DNS config, very useful for dialup users. A caching only name server will find the answer to name queries and remember the answer the next time you need it. First you need a file called /etc/named.boot. This is read when named starts. For now it should simply contain: ______________________________________________________________________ ; Boot file for nicolais caching name server ; directory /var/named ; ; type domain source file or host cache . root.cache primary 0.0.127.in-addr.arpa pz/127.0.0 ______________________________________________________________________ The `directory' line tells named where to look for files. All files named subsequently will be relative to this. /var/named is the right directory according to the Linux Filesystem Standard. Personaly, I use /local/named, but I'm quirky. The file named /var/named/root.cache is named in this. /var/named/root.cache should contain this: ______________________________________________________________________ . 518400 NS D.ROOT-SERVERS.NET. . 518400 NS E.ROOT-SERVERS.NET. . 518400 NS I.ROOT-SERVERS.NET. . 518400 NS F.ROOT-SERVERS.NET. . 518400 NS G.ROOT-SERVERS.NET. . 518400 NS A.ROOT-SERVERS.NET. . 518400 NS H.ROOT-SERVERS.NET. . 518400 NS B.ROOT-SERVERS.NET. . 518400 NS C.ROOT-SERVERS.NET. ; D.ROOT-SERVERS.NET. 3600000 A 128.8.10.90 E.ROOT-SERVERS.NET. 3600000 A 192.203.230.10 I.ROOT-SERVERS.NET. 3600000 A 192.36.148.17 F.ROOT-SERVERS.NET. 3600000 A 192.5.5.241 G.ROOT-SERVERS.NET. 3600000 A 192.112.36.4 A.ROOT-SERVERS.NET. 3600000 A 198.41.0.4 H.ROOT-SERVERS.NET. 3600000 A 128.63.2.53 B.ROOT-SERVERS.NET. 3600000 A 128.9.0.107 C.ROOT-SERVERS.NET. 3600000 A 192.33.4.12 ______________________________________________________________________ The file describes the root name servers in the world. This changes over time and must be maintained. See the ``maintenance section'' for how to keep it up to date. This file is described in the named man page, but it is, IMHO, best suited for people that already understand named. The next line in named.boot is the primary line. I will explain its use in a later chapter, for now just make this a file named 127.0.0 in the subdirectory pz: ______________________________________________________________________ @ IN SOA linux.bogus. hostmaster.linux.bogus. ( 1 ; Serial 28800 ; Refresh 7200 ; Retry 604800 ; Expire 86400) ; Minimum TTL NS ns.linux.bogus. 1 PTR localhost. ______________________________________________________________________ Next, you need a /etc/resolv.conf looking something like this: ______________________________________________________________________ search subdomain.your-domain.edu your-domain.edu nameserver 127.0.0.1 ______________________________________________________________________ The `search' line specifies what domains should be searched for any hostnames you want to connect to. The `nameserver' line specifies what address your machine can reach a nameserver at, in this case your own machine since that is where your named runs. (Note: Named never reads this file, the resolver that uses named does.) To illustrate what this file does: If a client tries to look up foo, foo.subdomain.your-domain.edu is tried first, then foo.your- fomain.edu, finally foo. If a client tries to look up sunsite.unc.edu, sunsite.unc.edu.subdomain.your-domain.edu is tried first, then sunsite.unc.edu.your-domain.edu, and finally sunsite.unc.edu. You may not want to put in too many domains in the search line, it takes time to search them. The example assumes you belong in the domain subdomain.your- domain.edu, your machine then, is probably called your- machine.subdomain.your-domain.edu. The search line should not contain your TLD (Top Level Domain, `edu' in this case). If you frequently need to connect to hosts in another domain you can add that domain to the search line like this: ______________________________________________________________________ search subdomain.your-domain.edu. your-domain.edu. other-domain.com. ______________________________________________________________________ and so on. Obviously you need to put real domain names in instead. Next, depending on your libc version you either need to fix /etc/nsswitch.conf or /etc/host.conf. If you already have nsswitch.conf that's what we'll fix, if not, we'll fix host.conf. /etc/nsswitch.conf This is a long file specifying where to get different kinds of data types, from what file or database. It usually contains helpful comments at the top. Find the line starting with `hosts:', it should read ______________________________________________________________________ hosts: files dns ______________________________________________________________________ If there is no line starting with `hosts:' then put in the one above. It says that programs should first look in the /etc/hosts file, then check DNS according to resolv.conf. /etc/host.conf It probably contains several lines, one should starting with order and it should look like this: ______________________________________________________________________ order hosts,bind ______________________________________________________________________ If there is no `order' line you should stick one in. It tells the host name resolving routines to first look in /etc/hosts, then ask the name server (which you in resolv.conf said is at 127.0.0.1) These two latest files are documented in the resolv(8) manpage (do `man 8 resolv') in most Linux distributions. That man page is IMHO readable, and everyone, especially DNS admins, should read it. Do it now, if you say to yourself "I'll do it later" you'll never get around to it. Starting named. After all this it's time to start named. If you're using a dialup connection connect first. Type `ndc start', and press return, no options. If that back-fires try `/usr/sbin/ndc start' instead. Now you can test your setup. If you view your syslog message file (usually called /var/adm/messages) while starting named (do tail -f /var/adm/messages) you should see something like: Jun 30 21:50:55 roke named[2258]: starting. named 4.9.4-REL Sun Jun 30 21:29:0 3 MET DST 1996 janl@roke.slip.ifi.uio.no:/var/tmp/bind/named Jun 30 21:50:55 roke named[2258]: cache zone "" loaded (serial 0) Jun 30 21:50:55 roke named[2258]: primary zone "0.0.127.in-addr.arpa" loaded (s erial 1) If there are any messages about errors then there is a mistake named will name the file it is in (one of named.boot and root.cache I hope :-) Kill named and go back and check the named file. $ nslookup Default Server: localhost Address: 127.0.0.1 > If that's what you get it's working. We hope. Anything else, go back and check everything. Each time you change the named.boot file you need to restart named using the ndc restart command. Now you can enter a query. Try looking up some machine close to you. pat.uio.no is close to me, at the University of Oslo: > pat.uio.no Server: localhost Address: 127.0.0.1 Name: pat.uio.no Address: 129.240.2.50 nslookup now asked your named to look for the machine pat.uio.no. It then contacted one of the name server machines named in your root.cache file, and asked its way from there. It might take tiny while before you get the result as it searches all the domains you named in /etc/resolv.conf. If you try again you get this: > pat.uio.no Server: localhost Address: 127.0.0.1 Non-authoritative answer: Name: pat.uio.no Address: 129.240.2.50 Note the `Non-authoritative answer:' line we got this time around. That means that named did not go out on the network to ask this time, it instead looked in it's cache and found it there. But the cached information might be out of date (stale). So you are informed of this (very slight) danger by it saying `Non-authorative answer:'. When nslookup says this the second time you ask for a host it's a sure sign it named caches the information and that it's working. You exit nslookup by giving the command `exit'. If you're a dialup (ppp, slip) user please read the ``section on dialup connections'', there is some advice there for you. Now you know how to set up a caching named. Take a beer, milk, or whatever you prefer to celebrate it. 3. A simple domain. How to set up your own domain. Before we really start this section I'm going to serve you some theory on how DNS works. And you're going to read it because it's good for you. If you don't `wanna' you should at least skim it very quickly. Stop skimming when you get to what should go in your named.boot file. DNS is a hierarchical system. The top is written `.' and pronounced `root'. Under . there are a number of Top Level Domains (TLDs), the best known ones are ORG, COM, EDU and NET, but there are many. When you want to find out the address of prep.ai.mit.edu your name server has to find a name server that serves edu. It asks a root.cache file is for), the . server gives a list of edu servers. I'll illustrate this here: $ nslookup Default Server: localhost Address: 127.0.0.1 Start asking a root server. > server c.root-servers.net. Default Server: c.root-servers.net Address: 192.33.4.12 Set the Query type to NS (name server records). > set q=ns Ask about edu. > edu. The trailing . here is significant, it tells the server we're asking that edu is right under ., this narrows the search somewhat. edu nameserver = A.ROOT-SERVERS.NET edu nameserver = H.ROOT-SERVERS.NET edu nameserver = B.ROOT-SERVERS.NET edu nameserver = C.ROOT-SERVERS.NET edu nameserver = D.ROOT-SERVERS.NET edu nameserver = E.ROOT-SERVERS.NET edu nameserver = I.ROOT-SERVERS.NET edu nameserver = F.ROOT-SERVERS.NET edu nameserver = G.ROOT-SERVERS.NET A.ROOT-SERVERS.NET internet address = 198.41.0.4 H.ROOT-SERVERS.NET internet address = 128.63.2.53 B.ROOT-SERVERS.NET internet address = 128.9.0.107 C.ROOT-SERVERS.NET internet address = 192.33.4.12 D.ROOT-SERVERS.NET internet address = 128.8.10.90 E.ROOT-SERVERS.NET internet address = 192.203.230.10 I.ROOT-SERVERS.NET internet address = 192.36.148.17 F.ROOT-SERVERS.NET internet address = 192.5.5.241 G.ROOT-SERVERS.NET internet address = 192.112.36.4 This tells us that *.root-servers.net serves edu., so we can go on asking c. Now we want to know who serves the next level of the domain name: mit.edu.: > mit.edu. Server: c.root-servers.net Address: 192.33.4.12 Non-authoritative answer: mit.edu nameserver = STRAWB.mit.edu mit.edu nameserver = W20NS.mit.edu mit.edu nameserver = BITSY.mit.edu Authoritative answers can be found from: STRAWB.mit.edu internet address = 18.71.0.151 W20NS.mit.edu internet address = 18.70.0.160 BITSY.mit.edu internet address = 18.72.0.3 steawb, w20ns and bitsy serves mit, select one and inquire about ai.mit.edu: > server W20NS.mit.edu. Hostnames are not case sensitive, but I use my mouse to cut and paste so it gets copied as-is from the screen. Server: W20NS.mit.edu Address: 18.70.0.160 > ai.mit.edu. Server: W20NS.mit.edu Address: 18.70.0.160 Non-authoritative answer: ai.mit.edu nameserver = WHEATIES.AI.MIT.EDU ai.mit.edu nameserver = ALPHA-BITS.AI.MIT.EDU ai.mit.edu nameserver = GRAPE-NUTS.AI.MIT.EDU ai.mit.edu nameserver = TRIX.AI.MIT.EDU ai.mit.edu nameserver = MUESLI.AI.MIT.EDU Authoritative answers can be found from: AI.MIT.EDU nameserver = WHEATIES.AI.MIT.EDU AI.MIT.EDU nameserver = ALPHA-BITS.AI.MIT.EDU AI.MIT.EDU nameserver = GRAPE-NUTS.AI.MIT.EDU AI.MIT.EDU nameserver = TRIX.AI.MIT.EDU AI.MIT.EDU nameserver = MUESLI.AI.MIT.EDU WHEATIES.AI.MIT.EDU internet address = 128.52.32.13 WHEATIES.AI.MIT.EDU internet address = 128.52.35.13 ALPHA-BITS.AI.MIT.EDU internet address = 128.52.32.5 ALPHA-BITS.AI.MIT.EDU internet address = 128.52.37.5 GRAPE-NUTS.AI.MIT.EDU internet address = 128.52.32.4 GRAPE-NUTS.AI.MIT.EDU internet address = 128.52.36.4 TRIX.AI.MIT.EDU internet address = 128.52.32.6 TRIX.AI.MIT.EDU internet address = 128.52.38.6 MUESLI.AI.MIT.EDU internet address = 128.52.32.7 MUESLI.AI.MIT.EDU internet address = 128.52.39.7 So weaties.ai.mit.edu is a nameserver for ai.mit.edu: > server WHEATIES.AI.MIT.EDU. Default Server: WHEATIES.AI.MIT.EDU Addresses: 128.52.32.13, 128.52.35.13 Now I change query type, we've found the name server so now we're going to ask about everything wheaties knows about prep.ai.mit.edu. > set q=any > prep.ai.mit.edu. Server: WHEATIES.AI.MIT.EDU Addresses: 128.52.32.13, 128.52.35.13 prep.ai.mit.edu CPU = dec/decstation-5000.25 OS = unix prep.ai.mit.edu inet address = 18.159.0.42, protocol = tcp #21 #23 #25 #79 prep.ai.mit.edu preference = 1, mail exchanger = life.ai.mit.edu prep.ai.mit.edu internet address = 18.159.0.42 ai.mit.edu nameserver = alpha-bits.ai.mit.edu ai.mit.edu nameserver = wheaties.ai.mit.edu ai.mit.edu nameserver = grape-nuts.ai.mit.edu ai.mit.edu nameserver = mini-wheats.ai.mit.edu ai.mit.edu nameserver = trix.ai.mit.edu ai.mit.edu nameserver = muesli.ai.mit.edu ai.mit.edu nameserver = count-chocula.ai.mit.edu ai.mit.edu nameserver = life.ai.mit.edu ai.mit.edu nameserver = mintaka.lcs.mit.edu life.ai.mit.edu internet address = 128.52.32.80 alpha-bits.ai.mit.edu internet address = 128.52.32.5 wheaties.ai.mit.edu internet address = 128.52.35.13 wheaties.ai.mit.edu internet address = 128.52.32.13 grape-nuts.ai.mit.edu internet address = 128.52.36.4 grape-nuts.ai.mit.edu internet address = 128.52.32.4 mini-wheats.ai.mit.edu internet address = 128.52.32.11 mini-wheats.ai.mit.edu internet address = 128.52.54.11 mintaka.lcs.mit.edu internet address = 18.26.0.36 So starting at . we found the successive nameservers for the next level in the domain name. If you had used your own DNS server instead of using all those other servers, your named would of-course cache all the information it found while digging this out for you, and it would not have to ask again for a while. A much less talked about, but just as important domain is in- addr.arpa. It too is nested like the `normal' domains. in-addr.arpa allows us to get the hosts name when we have it's address. A important thing here is to note that ip#s are written in reverse order in the in-addr.arpa domain. If you have the address of a machine: 192.128.52.43 named procedes just like for the prep.ai.mit.edu example: find arpa. servers. Find in-addr.arpa. servers, find 192.in- addr.arpa. servers, find 128.192.in-addr.arpa. servers, find 52.128.192.in-addr.arpa. servers. Find needed records for 43.52.128.192.in-addr.arpa. Clever huh? (say `yes'). Also, the reversion of the numbers is kinda confusing the first 2 years. I have just told a lie. DNS does not work literally the way I just told you. But it's close enough. Our own doman. Now to define our own domain. We're going to make the domain linux.bogus and define machines in it. I use a totally bogus domain name to make sure we disturb no-one Out There. We've already started this part with this line in named.boot: ______________________________________________________________________ primary 0.0.127.in-addr.arpa pz/127.0.0 ______________________________________________________________________ Please note the lack of `.' at the end of the domain names in this file. The first line names the file pz/127.0.0 as defining 0.0.127.in-addr.arpa. We've already set up this file, it reads: ______________________________________________________________________ @ IN SOA linux.bogus. hostmaster.linux.bogus. ( 1 ; Serial 28800 ; Refresh 7200 ; Retry 604800 ; Expire 86400) ; Minimum TTL NS ns.linux.bogus. 1 PTR localhost. ______________________________________________________________________ Please note the `.' at the end of all the full domain names in this file, in contrast to the named.boot file above. Some people like to start each zone file with a $ORIGIN directive, but this is superfluous. The origin (where in the DNS hierarchy it belongs) of a zone file is specified in the `domain' column of the named.boot file, in this case it's 0.0.127.in-addr.arpa. This `zone file' contains 3 `resource records' (RRs): A SOA RR. A NS RR and a PTR RR. SOA is short for Start Of Authority. The `@' is a special notation meaning the origin, and since the `domain' column for this file says 0.0.127.in-addr.arps the first line really says 0.0.127.IN-ADDR.ARPA. IN SOA ... NS is the Name Server RR, it tells DNS what machine is the name server of the domain. And finally the PTR record says that 1 (equals 1.0.0.127.IN-ADDR.ARPA, i.e. 127.0.0.1) is named localhost. The SOA record is the preamble to all zone files, and there should be exactly one in each zone file, the very first record. It describes the zone, where it comes from (a machine called linux.bogus), who is responsible for its contents (hostmaster@linux.bogus), what version of the zone file this is (serial: 1), and other things having to do with caching and secondary DNS servers. For the rest of the fields ,refresh, retry, expire and minimum use the numbers used in this HOWTO and you should be safe. The NS record tells us who does DNS serving for 0.0.127.in-addr.arpa, it is ns.linux.bogus. The PTR record tells us that 1.0.0.127.in- addr.arpa (aka 127.0.0.1) is known as localhost. Now restart your named (the command is ndc restart) and use nslookup to examine what you've done: $ nslookup Default Server: localhost Address: 127.0.0.1 > 127.0.0.1 Server: localhost Address: 127.0.0.1 Name: localhost Address: 127.0.0.1 so it manages to get localhost from 127.0.0.1, good. Don't push it. Now for our main task, the linux.bogus domain, insert a new primary line in named.boot: ______________________________________________________________________ primary linux.bogus pz/linux.bogus ______________________________________________________________________ Note the continued lack of ending `.' on the domain name in the named.boot file. In the linux.bogus zone file we'll put some totally bogus data: ______________________________________________________________________ ; ; Zone file for linux.bogus ; ; Mandatory minimum for a working domain ; @ IN SOA linux.bogus. hostmaster.linux.bogus. ( 199511301 ; serial, todays date + todays serial # 28800 ; refresh, seconds 7200 ; retry, seconds 3600000 ; expire, seconds 86400 ) ; minimum, seconds NS ns.linux.bogus. NS ns.friend.bogus. MX 10 mail.linux.bogus ; Primary Mail Exchanger MX 20 mail.friend.bogus. ; Secondary Mail Exchanger localhost A 127.0.0.1 ns A 127.0.0.2 mail A 127.0.0.4 ______________________________________________________________________ There is one new RR type in this file, the MX, or Mail eXchanger RR. It tells mail systems where to send mail that is addressed to someone@linux.bogus, namely too mail.linux.bogus or mail.friend.bogus. The number before each machine name is that MX RRs priority, The RR with the lowest number (10) is the one mail should be sent to primarily. If that fails it can be sent to one with a higher number, a secondary mail handler, i.e. mail.friend.bogus which has priority 20 here. Restart named by running ndc restart. Examine the results with nslookup: $ nslookup > set q=any > linux.bogus Server: localhost Address: 127.0.0.1 linux.bogus origin = linux.bogus mail addr = hostmaster.linux.bogus serial = 199511301 refresh = 28800 (8 hours) retry = 7200 (2 hours) expire = 604800 (7 days) minimum ttl = 86400 (1 day) linux.bogus nameserver = ns.linux.bogus linux.bogus nameserver = ns.friend.bogus linux.bogus preference = 10, mail exchanger = mail.linux.bogus.linux.bogus linux.bogus preference = 20, mail exchanger = mail.friend.bogus linux.bogus nameserver = ns.linux.bogus linux.bogus nameserver = ns.friend.bogus ns.linux.bogus internet address = 127.0.0.2 mail.linux.bogus internet address = 127.0.0.4 Upon careful examination you will discover a bug. The line linux.bogus preference = 10, mail exchanger = mail.linux.bogus.linux.bogu s is all wrong. It should be linux.bogus preference = 10, mail exchanger = mail.linux.bogus I deliberately made a mistake so you could learn from it :-) Looking in the zone file we find that the line @ MX 10 mail.linux.bogus ; Primary Mail Exchanger is missing a period. Or has a 'linux.bogus' too many. If a machine name does not end in a period in a zone file the origin is added to it's end. So either ______________________________________________________________________ @ MX 10 mail.linux.bogus. ; Primary Mail Exchanger ______________________________________________________________________ or ______________________________________________________________________ @ MX 10 mail ; Primary Mail Exchanger ______________________________________________________________________ is correct. I prefer the latter form, it's less to type. In a zone file the domain should either be written out and ended with a `.' or it should not be included at all, in which case it defaults to the origin. I must stress that in the named.boot file there should not be `.'s after the domain names. You have no idea how many times a `.' too many or few have fouled up things and confused the h*ll out of people. So having made my point here is the new zone file, with some extra information in it as well: ______________________________________________________________________ ; ; Zone file for linux.bogus ; ; Mandatory minimum for a working domain ; @ IN SOA linux.bogus. hostmaster.linux.bogus. ( 199511301 ; serial, todays date + todays serial # 28800 ; refresh, seconds 7200 ; retry, seconds 604800 ; expire, seconds 86400 ) ; minimum, seconds NS ns ; Inet Address of name server NS ns.friend.bogus. MX 10 mail ; Primary Mail Exchanger MX 20 mail.friend.bogus. ; Secondary Mail Exchanger localhost A 127.0.0.1 ns A 127.0.0.2 mail A 127.0.0.4 ; ; Extras ; @ TXT "Linux.Bogus, your DNS consultants" ns MX 10 mail MX 20 mail.friend.bogus. HINFO "Pentium" "Linux 1.2" TXT "RMS" richard CNAME ns www CNAME ns donald A 127.0.0.3 MX 10 mail MX 20 mail.friend.bogus. HINFO "i486" "Linux 1.2" TXT "DEK" mail MX 10 mail MX 20 mail.friend.bogus. HINFO "386sx" "Linux 1.0.9" ftp A 127.0.0.5 MX 10 mail MX 20 mail.friend.bogus. HINFO "P6" "Linux 1.3.59" ______________________________________________________________________ You might want to move the first three A records so that they're placed next to their respective other records, instead on top like that. There are a number of new RRs here: HINFO (Host INFOrmation) has two parts, it's a good habit to quote each. The first part is the hardware or CPU on the machine, and the second part the software or OS on the machine. ns has a Pentium CPU and runs Linux 1.2. The TXT record is a free text record that you can use for anything you like. CNAME (Canonical NAME) is a way to give each machine several names. So richard and www is a alias for ns. It's important to note that A MX, CNAME and SOA record should never refer to a CNAME record, they should only refer to something with a A record, so it would wrong to have ______________________________________________________________________ foobar CNAME richard ; NO! ______________________________________________________________________ but correct to have ______________________________________________________________________ foobar CNAME ns ; Yes! ______________________________________________________________________ It's also important to note that a CNAME is not a legal host name for a e-mail address: webmaster@www.linux.bogus is an illegal e-mail address given the setup above. You can expect quite a few mail admins Out There to enforce this rule even if it works for you. The way to avoid this is to use A records (and perhaps some others too, like a MX record) instead: ______________________________________________________________________ www A 127.0.0.2 ______________________________________________________________________ Paul Vixie, the primary named wizard, recommends not using CNAME. So consider not using it very seriously. Load the new database by running ndc reload, this causes named to read its files again. $ nslookup Default Server: localhost Address: 127.0.0.1 > ls -d linux.bogus This means that all records should be listed. [localhost] linux.bogus. SOA linux.bogus hostmaster.linux.bogus. (1995 11301 28800 7200 604800 86400) linux.bogus. NS ns.linux.bogus linux.bogus. NS ns.friend.bogus linux.bogus. MX 10 mail.linux.bogus linux.bogus. MX 20 mail.friend.bogus linux.bogus. TXT "Linux.Bogus, your DNS consultants" localhost A 127.0.0.1 mail A 127.0.0.4 mail MX 10 mail.linux.bogus mail MX 20 mail.friend.bogus mail HINFO 386sx Linux 1.0.9 donald A 127.0.0.3 donald MX 10 mail.linux.bogus donald MX 20 mail.friend.bogus donald HINFO i486 Linux 1.2 donald TXT "DEK" www CNAME ns.linux.bogus richard CNAME ns.linux.bogus ftp A 127.0.0.5 ftp MX 10 mail.linux.bogus ftp MX 20 mail.friend.bogus ftp HINFO P6 Linux 1.3.59 ns A 127.0.0.2 ns MX 10 mail.linux.bogus ns MX 20 mail.friend.bogus ns HINFO Pentium Linux 1.2 ns TXT "RMS" linux.bogus. SOA linux.bogus hostmaster.linux.bogus. (1995 11301 28800 7200 604800 86400) That's good. Let's check what it says for www alone: > set q=any > www.linux.bogus. Server: localhost Address: 127.0.0.1 www.linux.bogus canonical name = ns.linux.bogus ns.linux.bogus linux.bogus nameserver = ns.linux.bogus linux.bogus nameserver = ns.friend.bogus ns.linux.bogus internet address = 127.0.0.2 and ns.linux.bogus has the address 127.0.0.2. Looks good too. Winding down Of course, this domain is highly bogus, and so are all the addresses in it. For a real domain insert the real domain names and addresses and all the other information. When that is done you need a reverse lookup zone file, it should be like the 127.0.0 file and contain exactly one PTR RR for each address in use, i.e. 127.0.0.2 PTR ns.linux.bogus. 127.0.0.3 PTR donald.linux.bogus. 127.0.0.4 PTR mail.linux.bogus. 127.0.0.5 PTR ftp.linux.bogus. for our example domain (in addition to the SOA RR of-course). The domain name (origin) of the file should be reversed just as with 127.0.0 versus 0.0.127.in-addr.arpa. Now it's time for you to play around with things and set up your domain. When you've finished playing with the linux.bogus domain remove it from your named.boot file. 4. Firewalls and other odd things. Q: How do use DNS from inside a firewall? A: A couple of hints: `forwarders', `slave', and have a look in the literature list at the end of this HOWTO. Q: How do I make DNS rotate through the available addresses for a service, say www.busy.site to obtain a load balancing effect, or similar? A: Make several A records for www.busy.site and bind 4.9.3 or later will round-robin the answers. It will not work with earlier versions of bind. 5. Maintenance Keeping it working. There is one maintenance task you have to do on nameds, other than keeping them running. That's keeping the root.cache file updated. The easiest way is using dig, first run dig with no arguments, you will get the root.cache according to your own server. Then ask one of the listed root servers with dig @rootserver. You will note that the output looks terribly like a root.cache file except for a couple of extra numbers. Those numbers are harmless. Save it to a file (dig . @e.root-servers.net >root.cache.new) and replace the old root.cache with it. Remember to restart named after replacing the cache file. Al Longyear sent me this script that can be run automatically to update named.cache, install it a crontab entry for it and forget it. The script assumes you have mail working and that the mail-alias `hostmaster' is defined. You should hack it to suit your setup. ______________________________________________________________________ #!/bin/sh # # Update the nameserver cache information file once per month. # This is run automatically by a cron entry. # ( echo "To: hostmaster " echo "From: system " echo "Subject: Automatic update of the named.boot file" echo export PATH=/sbin:/usr/sbin:/bin:/usr/bin: cd /var/named dig . @rs.internic.net >named.cache.new echo "The named.boot file has been updated to contain the following information:" echo cat named.boot.new chown root.root named.cache.new chmod 444 named.cache.new rm -f named.cache.old mv named.cache named.cache.old mv named.cache.new named.cache ndc restart echo echo "The nameserver has been restarted to ensure that the update is complete. " echo "The previous named.cache file is now called /var/named/named.cache.old." ) 2>&1 | /usr/lib/sendmail -t exit 0 ______________________________________________________________________ 6. Automatic setup for dialup connections. This section explains how I have set things up to automate everything. My way might not suit you at all, but you might get a idea from something I've done. Also, I use ppp for dialup, while many use slip or cslip, so almost everything in your setup can be different from mine. But slip's dip program should be able to do many of the things I do. Normally, when I'm not connected to the net I have a resolv.conf file simply containing the line domain uio.no This ensures I don't have to wait for the hostname resolving library to try to connect to a nameserver that can't help me. But when I connect I want to start my named and have a resolv.conf looking like the one described above. I have solved this by keeping two resolv.conf 'template' files named resolv.conf.local and resolv.conf.connected. The latter looks like the resolv.conf described before in this document. To automatically connect to the net I run a script called 'ppp-on': ______________________________________________________________________ #!/bin/sh echo calling... pppd ______________________________________________________________________ pppd has a file called options that tells it the particulars of how to get connected. Once my ppp connection is up the pppd starts a script called ip-up (this is described in the pppd man page). This is parts of the script: ______________________________________________________________________ #!/bin/sh interface="$1" device="$2" speed="$3" myip="$4" upip="$5" ... cp -v /etc/resolv.conf.connected /etc/resolv.conf ... /usr/sbin/named ______________________________________________________________________ I.e. I start my named there. When ppp is disconnected pppd runs a script called ip-down: ______________________________________________________________________ #!/bin/sh cp /etc/resolv.conf.local /etc/resolv.conf read namedpid >/etc/hosts ______________________________________________________________________ hosts.ppp simply contains ______________________________________________________________________ 127.0.0.1 localhost ______________________________________________________________________ and the echo thing inserts the ip# i have received for my host name (roke). You should use the name your host knows itself by instead. This can be found with the hostname command. It is probably not smart to run named when you are not connected to the net, this is because named will try to send queries to the net and it has a long timeout, and you have to wait for this timeout every time some program tries to resolve a name. If you're using dialup you should start named when connecting and kill it when disconnecting. I have received mail saying it isn't so, but I have not been able to make it work having to wait for long timeouts. Please mail all details if you have better information. Some people like to use a forwarders directive on slow connections. If your internet provider has DNS servers at 1.2.3.4 and 1.2.3.5 you can insert the line ______________________________________________________________________ forwarders 1.2.3.4 1.2.3.5 ______________________________________________________________________ in the named.boot file. Also leave the named.cache file empty. That will decrease the amount of IP traffic your host originates, any possibly speed things up. This especially important if you're paying pr. byte that goes over the wire. This has the added value of letting you off the one maintenance duty you have as a caching named maintainer: you don't have to update a empty named.cache file. 7. How to become a bigger time DNS admin. Documentation and tools. Real Documentation exists. Online and in print. The reading of several of these is required to make the step from small time DNS admin to a big time one. In print the standard book is DNS and BIND by C. Liu and P. Albitz from O'Reilly & Associates, Sebastopol, CA, ISBN 0-937175-82-X. I read this, it's excellent. There is also a section in on DNS in TCP/IP Network Administration, by Craig Hunt from O'Reilly..., ISBN 0-937175-82-X. Another must for Good DNS administration (or good anything for that matter) is Zen and the Art of Motorcycle Maintenance by Robert M. Prisig :-) Available as ISBN 0688052304 and others. Online you will find stuff on , ; A FAQ, a reference manual (BOG; Bind Operations Guide) as well as papers and protocol definitions and DNS hacks. I have not read most of these, but then I'm not a big-time DNS admin either. Arnt Gulbrandsen on the other hand has read BOG and he's extatic about it :-). The newsgroup comp.protocols.tcp- ip.domains is about DNS. In addition there are a number of RFCs about DNS, the most important are probably these: RFC 1918 Y. Rekhter, R. Moskowitz, D. Karrenberg, G. de Groot, E. Lear, Address Allocation for Private Internets, 02/29/1996. RFC 1912 D. Barr, Common DNS Operational and Configuration Errors, 02/28/1996. RFC 1713 A. Romao, Tools for DNS debugging, 11/03/1994. RFC 1712 C. Farrell, M. Schulze, S. Pleitner, D. Baldoni, DNS Encoding of Geographical Location, 11/01/1994. RFC 1183 R. Ullmann, P. Mockapetris, L. Mamakos, C. Everhart, New DNS RR Definitions, 10/08/1990. RFC 1035 P. Mockapetris, Domain names - implementation and specification, 11/01/1987. RFC 1034 P. Mockapetris, Domain names - concepts and facilities, 11/01/1987. RFC 1033 M. Lottor, Domain administrators operations guide, 11/01/1987. RFC 1032 M. Stahl, Domain administrators guide, 11/01/1987. RFC 974 C. Partridge, Mail routing and the domain system, 01/01/1986.