How to set up your own domain.
First of all: you read all the stuff before here right? You have to.
Before we really start this section I'm going to serve you some
theory on and an example of how DNS works. And you're going to read it because
it's good for you. If you don't want to you should at least skim it very
quickly. Stop skimming when you get to what should go in your
named.conf file.
DNS is a hierarchical, tree structured system. The top is written
`.' and pronounced `root', as is usual for tree data-structures.
Under . there are a number of Top Level Domains (TLDs); the best
known ones are ORG, COM, EDU and
NET, but there are many more. Just like a tree it has a root and it
branches out. If you have any computer science background you will recognize DNS
as a search tree, and you will be able to find nodes, leaf nodes and edges. The
dots are nodes, the edges are on the names.
When looking for a machine the query proceeds recursively into the hierarchy
starting at the root. If you want to find the address of
prep.ai.mit.edu., your nameserver has to start asking somewhere. It
starts by looking it its cache. If it knows the answer, having cached it before,
it will answer right away as we saw in the last section. If it does not know it
will see how closely it can match the requested name and use whatever
information it has cached. In the worst case there is no match but the `.'
(root) of the name, and the root servers have to be consulted. It will remove
the leftmost parts one at a time, checking if it knows anything about
ai.mit.edu., then mit.edu., then edu.,
and if not that it does know about . because that was in the hints
file. It will then ask a . server about
prep.ai.mit.edu. This . server will not know the
answer, but it will help your server on its way by giving a referral, telling it
where to look instead. These referrals will eventually lead your server to a
nameserver that knows the answer. I will illustrate that now.
+norec means that dig is asking non-recursive questions so that we
get to do the recursion ourselves. The other options are to reduce the amount of
dig produces so this won't go on for too many pages:
$ ;; Got answer:
;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 980
;; flags: qr ra; QUERY: 1, ANSWER: 0, AUTHORITY: 13, ADDITIONAL: 0
;; AUTHORITY SECTION:
. 518400 IN NS J.ROOT-SERVERS.NET.
. 518400 IN NS K.ROOT-SERVERS.NET.
. 518400 IN NS L.ROOT-SERVERS.NET.
. 518400 IN NS M.ROOT-SERVERS.NET.
. 518400 IN NS A.ROOT-SERVERS.NET.
. 518400 IN NS B.ROOT-SERVERS.NET.
. 518400 IN NS C.ROOT-SERVERS.NET.
. 518400 IN NS D.ROOT-SERVERS.NET.
. 518400 IN NS E.ROOT-SERVERS.NET.
. 518400 IN NS F.ROOT-SERVERS.NET.
. 518400 IN NS G.ROOT-SERVERS.NET.
. 518400 IN NS H.ROOT-SERVERS.NET.
. 518400 IN NS I.ROOT-SERVERS.NET.
This is a referral. It is giving us an "Authority section" only, no "Answer section". Our own nameserver refers us to a nameserver. Pick one at random:
$ dig +norec +noques +nostats +nocmd prep.ai.mit.edu. @D.ROOT-SERVERS.NET.
;; Got answer:
;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 58260
;; flags: qr; QUERY: 1, ANSWER: 0, AUTHORITY: 3, ADDITIONAL: 3
;; AUTHORITY SECTION:
mit.edu. 172800 IN NS BITSY.mit.edu.
mit.edu. 172800 IN NS STRAWB.mit.edu.
mit.edu. 172800 IN NS W20NS.mit.edu.
;; ADDITIONAL SECTION:
BITSY.mit.edu. 172800 IN A 18.72.0.3
STRAWB.mit.edu. 172800 IN A 18.71.0.151
W20NS.mit.edu. 172800 IN A 18.70.0.160
It refers us to MIT.EDU servers at once. Again pick one at random:
$ dig +norec +noques +nostats +nocmd prep.ai.mit.edu. @BITSY.mit.edu.
;; Got answer:
;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 29227
;; flags: qr ra; QUERY: 1, ANSWER: 1, AUTHORITY: 4, ADDITIONAL: 4
;; ANSWER SECTION:
prep.ai.mit.edu. 10562 IN A 198.186.203.77
;; AUTHORITY SECTION:
ai.mit.edu. 21600 IN NS FEDEX.ai.mit.edu.
ai.mit.edu. 21600 IN NS LIFE.ai.mit.edu.
ai.mit.edu. 21600 IN NS ALPHA-BITS.ai.mit.edu.
ai.mit.edu. 21600 IN NS BEET-CHEX.ai.mit.edu.
;; ADDITIONAL SECTION:
FEDEX.ai.mit.edu. 21600 IN A 192.148.252.43
LIFE.ai.mit.edu. 21600 IN A 128.52.32.80
ALPHA-BITS.ai.mit.edu. 21600 IN A 128.52.32.5
BEET-CHEX.ai.mit.edu. 21600 IN A 128.52.32.22
This time we got a "ANSWER SECTION", and an answer for our question. The
"AUTHORITY SECTION" contains information about which servers to ask about
ai.mit.edu the next time. So you can ask them directly the next
time you wonder about ai.mit.edu names. Named also gathered
information about mit.edu, so of www.mit.edu is
requested it is much closer to being able to answer the question.
So starting at . we found the successive name servers for each
level in the domain name by referral. 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.
In the tree analogue each ``.'' in the name is a branching
point. And each part between the ``.''s are the names of individual
branches in the tree. One climbs the tree by taking the name we want
(prep.ai.mit.edu) asking the root (.) or whatever
servers father from the root toward prep.ai.mit.edu we have
information about in the cache. Once the cache limits are reached the recursive
resolver goes out asking servers, pursuing referrals (edges) further into the
name.
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 host's name when we have its
address. A important thing to note here is that the IP addresses are written in
reverse order in the in-addr.arpa domain. If you have the address
of a machine: 198.186.203.77 named proceeds to find the named
77.203.168.198.in-addr.arpa/ just like it did for prep.ai.mit.edu.
Example: Finding no cache entry for any match but `.', ask a root server,
m.root-servers.net refers you to some other root servers.
b.root-servers.net refers you directly to
bitsy.mit.edu/. You should be able to take it from there.
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.
One more thing before we start: Not all characters are allowed in host names.
We're restricted to the characters of the English alphabet: a-z, and numbers 0-9
and the character '-' (dash). Keep to those characters (BIND 9 will not bug you
if you break this rule, BIND 8 will). Upper and lower-case characters are the
same for DNS, so pat.uio.no is identical to
Pat.UiO.No.
We've already started this part with this line in named.conf:
zone "0.0.127.in-addr.arpa" {
type master;
file "pz/127.0.0";
};
Please note the lack of `.' at the end of the domain names in
this file. This says that now we will define the zone
0.0.127.in-addr.arpa, that we're the master server for it and that
it is stored in a file called pz/127.0.0. We've already set up this
file, it reads:
$TTL 3D
@ IN SOA ns.linux.bogus. hostmaster.linux.bogus. (
1 ; Serial
8H ; Refresh
2H ; Retry
4W ; Expire
1D) ; 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.conf 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 zone section of the named.conf 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.arpa the first line really means
0.0.127.in-addr.arpa. IN SOA ...
NS is the Name Server RR. There is no '@' at the start of this line; it is implicit since the previous line started with a '@'. Saves some typing that. So the NS line could also be written
0.0.127.in-addr.arpa. IN NS ns.linux.bogus
It tells DNS what machine is the name server of the domain
0.0.127.in-addr.arpa, it is ns.linux.bogus. 'ns' is a
customary name for name-servers, but as with web servers who are customarily
named www.something. The name may be anything.
And finally the PTR (Domain Name Pointer) record says that the host at
address 1 in the subnet 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, at the top (but after the $TTL
directive). It describes the zone, where it comes from (a machine called
ns.linux.bogus), who is responsible for its contents
(hostmaster@linux.bogus; you should insert your e-mail address
here), 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. Before the SOA comes a mandatory line, the $TTL 3D
line. Put it in all your zone files.
Now restart your named (rndc stop; named) and use
dig to examine your handy work. -x asks for the
inverse query:
$ dig -x 127.0.0.1
;; Got answer:
;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 30944
;; flags: qr aa rd ra; QUERY: 1, ANSWER: 1, AUTHORITY: 1, ADDITIONAL: 0
;; QUESTION SECTION:
;1.0.0.127.in-addr.arpa. IN PTR
;; ANSWER SECTION:
1.0.0.127.in-addr.arpa. 259200 IN PTR localhost.
;; AUTHORITY SECTION:
0.0.127.in-addr.arpa. 259200 IN NS ns.linux.bogus.
;; Query time: 3 msec
;; SERVER: 127.0.0.1#53(127.0.0.1)
;; WHEN: Sun Dec 23 03:02:39 2001
;; MSG SIZE rcvd: 91
So it manages to get localhost from 127.0.0.1, good. Now for our
main task, the linux.bogus domain, insert a new 'zone' section in
named.conf:
zone "linux.bogus" {
type master;
notify no;
file "pz/linux.bogus";
};
Note again the lack of ending `.' on the domain name in the
named.conf file.
In the linux.bogus zone file we'll put some totally bogus data:
;
; Zone file for linux.bogus
;
; The full zone file
;
$TTL 3D
@ IN SOA ns.linux.bogus. hostmaster.linux.bogus. (
199802151 ; serial, todays date + todays serial #
8H ; refresh, seconds
2H ; retry, seconds
4W ; expire, seconds
1D ) ; minimum, seconds
;
NS ns ; Inet Address of name server
MX 10 mail.linux.bogus ; Primary Mail Exchanger
MX 20 mail.friend.bogus. ; Secondary Mail Exchanger
;
localhost A 127.0.0.1
ns A 192.168.196.2
mail A 192.168.196.4
Two things must be noted about the SOA record. ns.linux.bogus
must be a actual machine with a A record. It is not legal to have a
CNAME record for the machine mentioned in the SOA record. Its name need not be
`ns', it could be any legal host name. Next, hostmaster.linux.bogus
should be read as hostmaster@linux.bogus. This should be a mail alias, or a
mailbox, where the person(s) maintaining DNS should read mail frequently. Any
mail regarding the domain will be sent to the address listed here. The name need
not be `hostmaster', it can be your normal e-mail address, but the e-mail
address `hostmaster' is often expected to work as well.
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 to mail.linux.bogus or
mail.friend.bogus. The number before each machine name is that MX
RR's priority. The RR with the lowest number (10) is the one mail should be sent
to if possible. If that fails the mail can be sent to one with a higher number,
a secondary mail handler, i.e., mail.friend.bogus which has
priority 20 here.
Reload named by running rndc reload. Examine the results with
dig:
$ dig any linux.bogus
; <<>> DiG 9.1.3 <<>> any linux.bogus
;; global options: printcmd
;; Got answer:
;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 55239
;; flags: qr aa rd ra; QUERY: 1, ANSWER: 4, AUTHORITY: 1, ADDITIONAL: 1
;; QUESTION SECTION:
;linux.bogus. IN ANY
;; ANSWER SECTION:
linux.bogus. 259200 IN SOA ns.linux.bogus. \
hostmaster.linux.bogus. 199802151 28800 7200 2419200 86400
linux.bogus. 259200 IN NS ns.linux.bogus.
linux.bogus. 259200 IN MX 20 mail.friend.bogus.
linux.bogus. 259200 IN MX 10 mail.linux.bogus.linux.bogus.
;; AUTHORITY SECTION:
linux.bogus. 259200 IN NS ns.linux.bogus.
;; ADDITIONAL SECTION:
ns.linux.bogus. 259200 IN A 192.168.196.2
;; Query time: 4 msec
;; SERVER: 127.0.0.1#53(127.0.0.1)
;; WHEN: Sun Dec 23 03:06:45 2001
;; MSG SIZE rcvd: 184
Upon careful examination you will discover a bug. The line
linux.bogus. 259200 IN MX 10 mail.linux.bogus.linux.bogus.
is all wrong. It should be
linux.bogus. 259200 IN MX 10 mail.linux.bogus.
I deliberately made a mistake so you could learn from it :-) Looking in the zone file we find this line:
MX 10 mail.linux.bogus ; Primary Mail Exchanger
It 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 its end causing
the double linux.bogus.linux.bogus. 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. There are some BIND
experts that disagree, and some that agree with this. 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.conf 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
;
; The full zone file
;
$TTL 3D
@ IN SOA ns.linux.bogus. hostmaster.linux.bogus. (
199802151 ; serial, todays date + todays serial #
8H ; refresh, seconds
2H ; retry, seconds
4W ; expire, seconds
1D ) ; minimum, seconds
;
TXT "Linux.Bogus, your DNS consultants"
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
gw A 192.168.196.1
TXT "The router"
ns A 192.168.196.2
MX 10 mail
MX 20 mail.friend.bogus.
www CNAME ns
donald A 192.168.196.3
MX 10 mail
MX 20 mail.friend.bogus.
TXT "DEK"
mail A 192.168.196.4
MX 10 mail
MX 20 mail.friend.bogus.
ftp A 192.168.196.5
MX 10 mail
MX 20 mail.friend.bogus.
CNAME (Canonical NAME) is a way to give each machine several names. So www is an alias for ns. CNAME record usage is a bit controversial. But it's safe to follow the rule that a MX, CNAME or SOA record should never refer to a CNAME record, they should only refer to something with an A record, so it is inadvisable to have
foobar CNAME www ; NO!
but correct to have
foobar CNAME ns ; Yes!
Load the new database by running rndc reload, which causes named
to read its files again.
$ dig linux.bogus axfr
; <<>> DiG 9.1.3 <<>> linux.bogus axfr
;; global options: printcmd
linux.bogus. 259200 IN SOA ns.linux.bogus. hostmaster.linux.bogus. 199802151 28800 7200 2419200 86400
linux.bogus. 259200 IN NS ns.linux.bogus.
linux.bogus. 259200 IN MX 10 mail.linux.bogus.
linux.bogus. 259200 IN MX 20 mail.friend.bogus.
donald.linux.bogus. 259200 IN A 192.168.196.3
donald.linux.bogus. 259200 IN MX 10 mail.linux.bogus.
donald.linux.bogus. 259200 IN MX 20 mail.friend.bogus.
donald.linux.bogus. 259200 IN TXT "DEK"
ftp.linux.bogus. 259200 IN A 192.168.196.5
ftp.linux.bogus. 259200 IN MX 10 mail.linux.bogus.
ftp.linux.bogus. 259200 IN MX 20 mail.friend.bogus.
gw.linux.bogus. 259200 IN A 192.168.196.1
gw.linux.bogus. 259200 IN TXT "The router"
localhost.linux.bogus. 259200 IN A 127.0.0.1
mail.linux.bogus. 259200 IN A 192.168.196.4
mail.linux.bogus. 259200 IN MX 10 mail.linux.bogus.
mail.linux.bogus. 259200 IN MX 20 mail.friend.bogus.
ns.linux.bogus. 259200 IN MX 10 mail.linux.bogus.
ns.linux.bogus. 259200 IN MX 20 mail.friend.bogus.
ns.linux.bogus. 259200 IN A 192.168.196.2
www.linux.bogus. 259200 IN CNAME ns.linux.bogus.
linux.bogus. 259200 IN SOA ns.linux.bogus. hostmaster.linux.bogus. 199802151 28800 7200 2419200 86400
;; Query time: 41 msec
;; SERVER: 127.0.0.1#53(127.0.0.1)
;; WHEN: Sun Dec 23 03:12:31 2001
;; XFR size: 23 records
That's good. As you see it looks a bit like the zone file itself. Let's check
what it says for www alone:
$�dig www.linux.bogus
; <<>> DiG 9.1.3 <<>> www.linux.bogus
;; global options: printcmd
;; Got answer:
;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 16633
;; flags: qr aa rd ra; QUERY: 1, ANSWER: 2, AUTHORITY: 1, ADDITIONAL: 0
;; QUESTION SECTION:
;www.linux.bogus. IN A
;; ANSWER SECTION:
www.linux.bogus. 259200 IN CNAME ns.linux.bogus.
ns.linux.bogus. 259200 IN A 192.168.196.2
;; AUTHORITY SECTION:
linux.bogus. 259200 IN NS ns.linux.bogus.
;; Query time: 5 msec
;; SERVER: 127.0.0.1#53(127.0.0.1)
;; WHEN: Sun Dec 23 03:14:14 2001
;; MSG SIZE rcvd: 80
In other words, the real name of www.linux.bogus is
ns.linux.bogus, and it gives you some of the information it has
about ns as well, enough to connect to it if you were a program.
Now we're halfway.
Now programs can convert the names in linux.bogus to addresses which they can connect to. But also required is a reverse zone, one making DNS able to convert from an address to a name. This name is used by a lot of servers of different kinds (FTP, IRC, WWW and others) to decide if they want to talk to you or not, and if so, maybe even how much priority you should be given. For full access to all services on the Internet a reverse zone is required.
Put this in named.conf:
zone "196.168.192.in-addr.arpa" {
type master;
notify no;
file "pz/192.168.196";
};
This is exactly as with the 0.0.127.in-addr.arpa, and the
contents are similar:
$TTL 3D
@ IN SOA ns.linux.bogus. hostmaster.linux.bogus. (
199802151 ; Serial, todays date + todays serial
8H ; Refresh
2H ; Retry
4W ; Expire
1D) ; Minimum TTL
NS ns.linux.bogus.
1 PTR gw.linux.bogus.
2 PTR ns.linux.bogus.
3 PTR donald.linux.bogus.
4 PTR mail.linux.bogus.
5 PTR ftp.linux.bogus.
Now you reload your named (rndc reload) and examine your work
with dig again:
$ dig -x 192.168.196.4 ;; Got answer: ;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 58451 ;; flags: qr aa rd ra; QUERY: 1, ANSWER: 1, AUTHORITY: 1, ADDITIONAL: 1 ;; QUESTION SECTION: ;4.196.168.192.in-addr.arpa. IN PTR ;; ANSWER SECTION: 4.196.168.192.in-addr.arpa. 259200 IN PTR mail.linux.bogus. ;; AUTHORITY SECTION: 196.168.192.in-addr.arpa. 259200 IN NS ns.linux.bogus. ;; ADDITIONAL SECTION: ns.linux.bogus. 259200 IN A 192.168.196.2 ;; Query time: 4 msec ;; SERVER: 127.0.0.1#53(127.0.0.1) ;; WHEN: Sun Dec 23 03:16:05 2001 ;; MSG SIZE rcvd: 107
so, it looks OK, dump the whole thing to examine that too:
$ dig 196.168.192.in-addr.arpa. AXFR
; <<>> DiG 9.1.3 <<>> 196.168.192.in-addr.arpa. AXFR
;; global options: printcmd
196.168.192.in-addr.arpa. 259200 IN SOA ns.linux.bogus. \
hostmaster.linux.bogus. 199802151 28800 7200 2419200 86400
196.168.192.in-addr.arpa. 259200 IN NS ns.linux.bogus.
1.196.168.192.in-addr.arpa. 259200 IN PTR gw.linux.bogus.
2.196.168.192.in-addr.arpa. 259200 IN PTR ns.linux.bogus.
3.196.168.192.in-addr.arpa. 259200 IN PTR donald.linux.bogus.
4.196.168.192.in-addr.arpa. 259200 IN PTR mail.linux.bogus.
5.196.168.192.in-addr.arpa. 259200 IN PTR ftp.linux.bogus.
196.168.192.in-addr.arpa. 259200 IN SOA ns.linux.bogus. \
hostmaster.linux.bogus. 199802151 28800 7200 2419200 86400
;; Query time: 6 msec
;; SERVER: 127.0.0.1#53(127.0.0.1)
;; WHEN: Sun Dec 23 03:16:58 2001
;; XFR size: 9 records
Looks good! If your output didn't look like that look for error-messages in your syslog, I explained how to do that in the first section under the heading Starting named
There are some things I should add here. The IP numbers used in the examples
above are taken from one of the blocks of 'private nets', i.e., they are not
allowed to be used publicly on the Internet. So they are safe to use in an
example in a HOWTO. The second thing is the notify no; line. It
tells named not to notify its secondary (slave) servers when it has gotten a
update to one of its zone files. In BIND 8 and later the named can notify the
other servers listed in NS records in the zone file when a zone is updated. This
is handy for ordinary use. But for private experiments with zones this feature
should be off --- we don't want the experiment to pollute the Internet do we?
And, of course, this domain is highly bogus, and so are all the addresses in it. For a real example of a real-life domain see the next main-section.
There are a couple of ``gotchas'' that normally are avoided with name lookups that are often seen when setting up reverse zones. Before you go on you need reverse lookups of your machines working on your own nameserver. If it isn't go back and fix it before continuing.
I will discuss two failures of reverse lookups as seen from outside your network:
When you ask a service provider for a network-address range and a domain name the domain name is normally delegated as a matter of course. A delegation is the glue NS record that helps you get from one nameserver to another as explained in the dry theory section above. You read that, right? If your reverse zone doesn't work go back and read it. Now.
The reverse zone also needs to be delegated. If you got the
192.168.196 net with the linux.bogus domain from your
provider they need to put NS records in for your reverse zone as
well as for your forward zone. If you follow the chain from
in-addr.arpa and up to your net you will probably find a break in
the chain, most probably at your service provider. Having found the break in the
chain contact your service-provider and ask them to correct the error.
This is a somewhat advanced topic, but classless subnets are very common these days and you probably have one if you're a small company.
A classless subnet is what keeps the Internet going these days. Some years ago there was much ado about the shortage of IP numbers. The smart people in IETF (the Internet Engineering Task Force, they keep the Internet working) stuck their heads together and solved the problem. At a price. The price is in part that you'll get less than a ``C'' subnet and some things may break. Please see Ask Mr. DNS for an good explanation of this and how to handle it.
Did you read it? I'm not going to explain it so please read it.
The first part of the problem is that your ISP must understand the technique described by Mr. DNS. Not all small ISPs have a working understanding of this. If so you might have to explain to them and be persistent. But be sure you understand it first ;-). They will then set up a nice reverse zone at their server which you can examine for correctness with dig.
The second and last part of the problem is that you must understand the technique. If you're unsure go back and read about it again. Then you can set up your own classless reverse zone as described by Mr. DNS.
There is another trap lurking here. (Very) Old resolvers will not be
able to follow the CNAME trick in the resolving chain and will fail
to reverse-resolve your machine. This can result in the service assigning it an
incorrect access class, deny access or something along those lines. If you
stumble into such a service the only solution (that I know of) is for your ISP
to insert your PTR record directly into their trick classless zone file instead
of the trick CNAME record.
Some ISPs will offer other ways to handle this, like Web based forms for you to input your reverse-mappings in or other automagical systems.
Once you have set up your zones correctly on the master servers you need to set up at least one slave server. Slave servers are needed for robustness. If your master goes down the people out there on the net will still be able to get information about your domain from the slave. A slave should be as long away from you as possible. Your master and slave should share as few as possible of these: Power supply, LAN, ISP, city and country. If all of these things are different for your master and slave you've found a really good slave.
A slave is simply a nameserver that copies zone files from a master. You set it up like this:
zone "linux.bogus" {
type slave;
file "sz/linux.bogus";
masters { 192.168.196.2; };
};
A mechanism called zone-transfer is used to copy the data. The zone transfer is controlled by your SOA record:
@ IN SOA ns.linux.bogus. hostmaster.linux.bogus. (
199802151 ; serial, todays date + todays serial #
8H ; refresh, seconds
2H ; retry, seconds
4W ; expire, seconds
1D ) ; minimum, seconds
A zone is only transferred if the serial number on the master is larger than on the slave. Every refresh interval the slave will check if the master has been updated. If the check fails (because the master is unavailable) it will retry the check every retry interval. If it continues to fail as long as the expire interval the slave will remove the zone from it's filesystem and no longer be a server for it.