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NAME

       csv2 - Description of the csv2 zone file that MaraDNS uses

DESCRIPTION

       The csv2 zone file format is MaraDNS' standard zone file format.  This
       zone file format uses any kind of whitespace (space, tab, and carriage
       return), or the '|' character, to delimit fields.

    Tilde delimitation

       In newer MaraDNS releases, the tilde ('~') character is used to delimit
       records in csv2 zone files; in order to maintain maximum compatibility
       with older MaraDNS zone files, this feature is only enabled if a tilde
       is placed between the first and second record. Otherwise, tildes are
       not allowed in zone files (except in comments).

       Most older MaraDNS csv2 zone files without the tilde character are
       compatible with the updated csv2 parser, unless csv2_tilde_handling is
       set to 3. All older MaraDNS csv2 zone files will parse in MaraDNS if
       csv2_tilde_handling has a value of 0. Older MaraDNS releases also
       supported the csv2_tilde_handling variable (as long as it had a value
       of 0); this allowed the same configuration and zone files to be used in
       older and newer MaraDNS releases.

    Resource record format

       This zone file format has records in the following form:

           name [+ttl] [rtype] rdata ~

       The name is the name of the record we will add, such as
       "www.example.net.".  This must be placed at the beginning of a line.
       The rtype is the record type for the record, such as "A" (ipv4 IP
       address), "MX" (mail exchanger), or "AAAA" (ipv6 IP address). The ttl
       is how long other DNS servers should store this data in their memory
       (in seconds); this field needs a '+' as its initial character. The
       rdata is the actual data for this record; the format for the rdata is
       type-specific.

       Anything in square brackets is an optional field. If the ttl is not
       specified, the ttl is set to the default ttl value (see "Default TTL"
       below).  If the rtype is not specified, it is set to be an "A" (ipv4
       address) record.

       The zone file supports comments; comments are specified by having a '#'
       anywhere between fields or records; when a '#' is seen, the csv2 parser
       ignores any character it sees (with the exception of the '{', which is
       not allowed in comments) until a newline. A '#' can usually be placed
       inside a field, and indicates the end of a field when placed there.

       A '{' character can never be placed in a comment. A '~' character is
       always allowed in a comment, and has no special meaning when placed in
       a comment.

       The following record types are supported; a description of the record
       data format accommodates the record type:

    A

       An A record stores an ipv4 address. This is the default record type
       should the record type not be specified. The record type has one field
       in it: the IP for the record. Examples:

       a.example.net.              10.11.12.13 ~
       b.example.net.        A     10.11.12.14 ~
       c.example.net. +64000 A     10.11.12.15 ~

    PTR

       A PTR record stores the name for a given ipv4 or ipv6 address, and is
       used for reverse DNS lookups. This record type has one field in it: The
       name for the record in question. Examples:

       13.12.11.10.in-addr.arpa.        PTR    a.example.net. ~
       14.12.11.10.in-addr.arpa.        PTR    b.example.net. ~
       15.12.11.10.in-addr.arpa. +64000 PTR    c.example.net. ~

    MX

       A MX record stores a mail exchange record, and is used for mail
       delivery.  This record type has two fields in it: The priority (or
       "preference" in traditional DNS parlance) of the MX record (lower
       numbers get higher priority), and the name of the mail exchanger.
       Example of mail for example.net being mailed to mail.example.net, which
       has the IP "10.11.12.16":

       example.net.      MX   10 mail.example.net. ~
       mail.example.net.      10.11.12.16 ~

    AAAA

       An AAAA record stores the ipv6 address for a given name. The IP is in
       standard ipv6 "colon delimited" format: eight 16-bit hexadecimal
       numbers are separated by colons. Two colons together indicate multiple
       streams of all-zero hex numbers. This record has only one field, the v6
       IP. Example:

       a.example.net.   AAAA    3ffe:ffff:ffe:501:ffff::b:c:d ~

    SRV

       An SRV record stores a "service" definition. This record has four
       fields: Priority, weight, port, and target. For more information,
       please refer to RFC 2782. Example:

       _http._tcp.% SRV 0 0 80 a.% ~

    NS

       An NS record specifies the name servers for a given zone. If the name
       servers are not delegation name servers (in other words, if the name
       servers are the authoritative name servers for the zone), they need to
       be at the beginning of the zone, either as the first records in the
       zone, or right after the SOA record. The NS records are optional; if
       not present, MaraDNS will make an educated guess of that NS records
       should be there, based on the IPs the MaraDNS process is bound to. This
       record has one field: The name of the name server machine. Example:

       example.net.    NS    ns1.example.net. ~
       example.net.    NS    ns2.example.net. ~

    SOA

       An SOA record stores the start of authority for a given zone file.
       This record is optional in a CSV2 zone file; should the record not be
       in the zone file, MaraDNS will synthesize an appropriate SOA record.
       This record can only exist once in a zone file: As the first record of
       the zone file. This record has seven fields: The name of the zone, the
       email address of the person responsible for the zone, and five numeric
       fields (serial, refresh, retry, expire, and minimum).  Note that the
       SOA minimum does not affect other TTLs in MaraDNS.  Example:

       x.org. SOA x.org. email@x.org. 1 7200 3600 604800 1800 ~

       The serial numeric field may be replaced by the string '/serial'; this
       string tells the CSV2 zone parser to synthesize a serial number for the
       zone based on the timestamp for the zone file. This allows one to have
       the serial number be automatically updated whenever the zone file is
       edited. Here is how this special field looks in a SOA record:

       x.org. SOA x.org. email@x.org. /serial 7200 3600 604800 1800 ~

       The '/serial' string is case-sensitive; only '/serial' in all lower
       case will parse.

    TXT

       A TXT record stores arbitrary text and/or binary data for a given host
       name. This record has one field: The text data for the record.

       A basic text record can be stored by placing ASCII data between two
       single quotes, as follows:

       example.com. TXT 'This is an example text field' ~

       Any binary data can be specified; see the csv2_txt(5) manual page for
       full details.

       If tildes are used to separate records, a TXT record can not contain a
       '|' (pipe) character, a '#' character, nor any ASCII control character;
       these characters can be added to a TXT record via the use of escape
       sequences; read the csv2_txt man page for details.

    SPF

       A SPF record is, with the exception of the numeric rtype, identical to
       a TXT record. SPF records are designed to make it more difficult to
       forge email. More information about SPF records can be found in
       RFC4408, or by performing a web search for 'sender policy framework'.

    RAW

       The RAW record is a special meta-record that allows any otherwise
       unsupported record type to be stored in a csv2 zone file. The syntax
       is:

       RAW [numeric rtype] [data] ~

       The numeric rtype is a decimal number.

       The data field can, among other thing, have backslashed hex sequences
       outside of quotes, concatenated by ASCII data inside quotes, such as
       the following example:

       example.com. RAW 40 \x10\x01\x02'Kitchen sink'\x40' data' ~

       The above example is a "Kitchen Sink" RR with a "meaning" of 16, a
       "coding" of 1, a "subcoding" of 2, and a data string of "Kitchen sink@
       data" (since hex code 40 corresponds to a @ in ASCII). Note that
       unquoted hex sequences are concatenated with quoted ASCII data, and
       that spaces are only inside quoted data.

       The format for a data field in a RAW record is almost identical to the
       format for a TXT data field. Both formats are described in full in the
       csv2_txt(5) manual page.

    FQDN4

       The FQDN4 (short for "Fully Qualified Domain Name for IPv4") record is
       a special form of the "A" record (see above) that instructs MaraDNS to
       automatically create the corresponding PTR record. For example, the
       following is one way of setting up the reverse DNS lookup for
       x.example.net:

       x.example.net. A 10.3.28.79 ~
       79.28.3.10.in-addr.arpa. PTR x.example.net. ~

       But the above two lines in a zone file can also be represented thusly:

       x.example.net. FQDN4 10.3.28.79 ~

       Note that the csv2 parser does not bother to check that any given IP
       only has a single FQDN4 record; it is up to the DNS administrator to
       ensure that a given IP has only one FQDN4 record. In the case of there
       being multiple FQDN4 records with the same IP, MaraDNS will have
       multiple entries in the corresponding PTR record, which is usually not
       the desired behavior.

       FQDN4 records are not permitted in a csv2_default_zonefile. If you do
       not know what a csv2_default_zonefile is, you do not have to worry
       about this limitation.

    FQDN6

       The FQDN6 (short for "Fully Qualified Domain Name for IPv6") record is
       the ipv6 form for the FQDN4 record. Like the FQDN4 record, this record
       creates both a "forward" and "reverse" DNS record for a given host
       name. For example, onoe may have:

       x.example.net. AAAA 3ffe:ffff:ffe:501:ffff::b:c:d ~
       d.0.0.0.c.0.0.0.b.0.0.0.f.f.f.f.1.0.5.0.e.f.f.0.f.f.f.f.e.f.f.3 PTR
       x.example.net. ~

       But the above two lines in a zone file can also be represented thusly:

       x.example.net. FQDN6 3ffe:ffff:ffe:501:ffff::b:c:d ~

       Like FQDN4 records, it is the DNS administrator's duty to make sure
       only a single IP has a FQDN6 record.

       FQDN6 records are, like FQDN6 records, not permitted in a
       csv2_default_zonefile. If you do not know what a csv2_default_zonefile
       is, you do not have to worry about this limitation.

       FQDN6 records were implemented by Jean-Jacques Sarto.

    CNAME

       A CNAME record is a pointer to another host name. The CNAME record, in
       MaraDNS, affects any record type not already specified for a given host
       name. While MaraDNS allows CNAME and non-CNAME records to share the
       same host name, this is considered bad practice and is not compatible
       with some other DNS servers.

       CNAME records are not permitted in a csv2_default_zonefile. If you do
       not know what a csv2_default_zonefile is, this fact is of no relevance.

Historical and uncommon resource records

       The following resource records are mainly of historical interest, or
       are not commonly used.

    HINFO

       An HINFO record is a description of the CPU (processor) and OS that a
       given host is using. The format for this record is identical to a TXT
       record, except that the field must have precisely two chunks.

       The first chunk of a HINFO record is the CPU the host is running; the
       second chunk is the OS the host is running.

       Example:

       example.com. HINFO 'Intel Pentium III';'CentOS Linux 3.7' ~

       This resource record is not actively used--the IANA has a list of CPUs
       and OSes that this record is supposed to have.  However, this list has
       not been updated since 2002.

    WKS

       WKS records are historical records which have been superseded by SRV
       records. The format of the record is an IP, followed by a protocol
       number (6 means TCP), followed by a list of ports that a given server
       has available for services.

       For example, to advertise that example.net has the IP 10.1.2.3, and has
       a SSH, HTTP (web), and NNTP server:

       example.net. WKS 10.1.2.3 6 22,80,119 ~

       MaraDNS only allows up to 10 different port numbers in a WKS record,
       and requires that the listed port numbers are not be higher than 1023.

    MD and MF

       MD and MF records are RR types that existed before MX records, and were
       made obsolete by MX records. RFC1035 says that a DNS server can either
       reject these records or convert these records in to MX records. BIND
       rejects these records; MaraDNS converts them.

       Example:

       example.net. MD a.example.net. ~
       example.net. MF b.example.net. ~

       Is equivalent to:

       example.net. MX 0 a.example.net. ~
       example.net. MX 10 b.example.net. ~

    MB, MG, MINFO, and MR

       In the late 1980s, an alternative to MX records was proposed. This
       alternative utilized MB, MG, MINFO, and MR records. This alternative
       failed to gather popularity. However, these records were codified in
       RFC1035, and are supported by MaraDNS. Here is what the records look
       like:

       example.net. MB mail.example.net. ~
       example.net. MG mg@example.net. ~
       example.net. MINFO rm@example.net. re@example.net. ~
       example.net. MR mr@example.net. ~

       More information about these records can be found in RFC1035.

    AFSDB, RP, X25, ISDN, and RT

       AFSDB, RP, X25, ISDN, and RT are resource records which were proposed
       in RFC1183. None of these resource records are widely used.

       With the exception of the ISDN record, the format of these records is
       identical to the examples in RFC1183. The format of the ISDN record is
       identical unless the record has a subaddress (SA). If an ISDN record
       has a subaddress, it is separated from the ISDN-address by a ';'
       instead of whitespace.

       If used, here is how the records would look in a csv2 zone file:

       example.net. AFSDB 1 afsdb.example.net. ~
       example.net. RP rp@example.net. rp.example.net. ~
       example.net. RP rp2@example.net. . ~
       example.net. X25 311061700956 ~
       example.net. ISDN 150862028003217 ~
       example.net. ISDN 150862028003217;004 ~
       example.net. RT 10 relay.example.net. ~

    NSAP and NSAP-PTR

       NSAP and NSAP-PTR records were proposed in RFC1706. A NSAP record is a
       hexadecimal number preceded by the string "0x" and with optional dots
       between bytes. This hexadecimal number is converted in to a binary
       number by MaraDNS. A NSAP-PTR record is identical to a PTR record, but
       has a different RTYPE.

       More information about these records can be obtained from RFC1706.

       If used, here is how the records would look in a csv2 zone file:

       example.net. NSAP 0x47.0005.80.005a00.0000.0001.e133.ffffff000162.00 ~
       example.net. NSAP-PTR nsap.example.net. ~

    PX

       The PX RR is an obscure RR described in RFC2163. A PX record looks like
       this in a CSV2 zone file:

       example.net. PX 15 px1.example.net. px2.example.net. ~

    GPOS

       An GPOS record is a description of the location of a given server.  The
       format for this record is identical to a TXT record, except that the
       field must have precisely three chunks.

       The first chunk of a GPOS record is the longitude; the second chunk is
       the latitude; the third chunk is the altitude (in meters).

       Example:

       example.net. GPOS '-98.6502';'19.283';'2134' ~

       More information about this record can be found in RFC1712.

       This resource record is not actively used; for the relatively few
       people who encode their position in DNS, the LOC record is far more
       common.

    LOC

       The LOC resource record is an uncommonly used resource record that
       describes the position of a given server. LOC records are described in
       RFC1876.

       Note that MaraDNS' LOC parser assumes that the altitude, size,
       horizontal, and vertical precision numbers are always expressed in
       meters. Also note that that sub-meter values for size, horizontal, and
       vertical precision are not allowed. Additionally, the altitude can not
       be greater than 21374836.47 meters.

       Example:

       example.net. LOC 19 31 2.123 N 98 3 4 W 2000m 2m 4m 567m ~

SLASH COMMANDS

       In addition to being able to have resource records and comments, csv2
       zone files can also have special slash commands. These slash commands,
       with the exception of the '/serial' slash command (see "SOA" above),
       can only be placed where the name for a record would be placed.  Like
       resource records, a tilde is to be placed after the slash command. Note
       also that slash commands are case-sensitive, and the command in
       question must be in all-lower-case.

       These commands are as follows:

    Default TTL

       The default TTL is the TTL for a resource record without a TTL
       specified.  This can be changed with the '/ttl' slash command. This
       command takes only a single argument: The time, in seconds, for the new
       default TTL.  The '/ttl' slash command only affects the TTL of records
       that follow the command. A zone file can have multiple '/ttl' slash
       commands.

       The default TTL is 86400 seconds (one day) until changed by the '/ttl'
       slash command.

       In the following example, a.ttl.example.com will have a TTL of 86400
       seconds (as long as the zone file with this record has not previously
       used the '/ttl' slash command), b.ttl.example.com and d.ttl.example.com
       will have a TTL of 3600 seconds, c.ttl.example.com will have a TTL of
       9600 seconds, and e.ttl.example.com will have a TTL of 7200 seconds:

       a.ttl.example.com.       10.0.0.1 ~
       /ttl 3600 ~
       b.ttl.example.com.       10.0.0.2 ~
       c.ttl.example.com. +9600 10.0.0.3 ~
       d.ttl.example.com.       10.0.0.4 ~
       /ttl 7200 ~
       e.ttl.example.com.       10.0.0.5 ~

    Origin

       It is possible to change the host name suffix that is used to
       substitute the percent in a csv2 zone file. This suffix is called, for
       historical and compatibility reasons, "origin". This is done as the
       slash command '/origin', taking the new origin as the one argument to
       this function.  Note that changing the origin does not change the
       domain suffix used to determine whether a given domain name is
       authoritative.

       Here is one example usage of the '/origin' slash command:

       /origin example.com. ~
       www.% 10.1.0.1 ~
       % MX 10 mail.% ~
       mail.% 10.1.0.2 ~
       /origin example.org. ~
       www.% 10.2.0.1 ~
       % MX 10 mail.% ~
       mail.% 10.2.0.2 ~

       Which is equivalent to:

       www.example.com. 10.1.0.1 ~
       example.com. MX 10 mail.example.com. ~
       mail.example.com. 10.1.0.2 ~
       www.example.org. 10.2.0.1 ~
       example.org. MX 10 mail.example.org. ~
       mail.example.org. 10.2.0.2 ~

       It is also possible to make the current origin be part of the new
       origin:

       /origin example.com. ~
       % 10.3.2.1 ~ # example.com now has IP 10.3.2.1
       /origin mail.% ~
       % 10.3.2.2 ~ # mail.example.com now has IP 10.3.2.2

    Opush and Opop

       The '/opush' and '/opop' slash commands use a stack to remember and
       later recall values for the origin (see origin above). The '/opush'
       command is used just like the '/origin' command; however, the current
       origin is placed on a stack instead of discarded. The '/opop' command
       removes ("pops") the top element from this stack and makes the element
       the origin.

       For example:

       /origin example.com. ~
       /opush mail.% ~ # origin is now mail.example.com; example.com is on stack
       a.% 10.4.0.1 ~ # a.mail.example.com has IP 10.4.0.1
       /opush web.example.com. ~ # mail.example.com and example.com are on stack
       a.% 10.5.0.1 ~ # a.web.example.com has IP 10.5.0.1
       b.% 10.5.0.2 ~ # b.web.example.com has IP 10.5.0.2
       /opop ~ # origin is now mail.example.com again
       b.% 10.4.0.2 ~ # b.mail.example.com has IP 10.4.0.2
       /opop ~ # origin is now example.com
       % MX 10 a.mail.% ~ # example.com. MX 10 a.mail.example.com.
       % MX 20 b.mail.% ~ # example.com. MX 20 b.mail.example.com.

       The opush/opop stack can have up to seven elements on it.

    Read

       The '/read' slash commands allows one to have the contents of another
       file in a zone. The '/read' command takes a single argument: A filename
       that one wishes to read. The filename is only allowed to have letters,
       numbers, the '-' character, the '_' character, and the '.' character in
       it.

       The file needs to be in the same directory as the zone file. The file
       will be read with the same privileges as the zone file; content in the
       file should come from a trusted source or be controlled by the system
       administrator.

       Let us suppose that we have the following in a zone file:

       mail.foo.example.com. 10.3.2.1 ~
       /read foo ~
       foo.example.com. MX 10 mail.foo.example.com. ~

       And a file foo with the following contents:

       foo.example.com. 10.1.2.3 ~
       foo.example.com. TXT 'Foomatic!' ~

       Then foo.example.com will have an A record with the value 10.1.2.3, a
       TXT value of 'Foomatic!', and a MX record with priority 10 pointing to
       mail.foo.example.com. mail.foo.example.com will have the IP 10.3.2.1.

       Note that no pre-processing nor post-processing of the origin is done
       by the '/read' command; should the file read change the origin, this
       changed value will affect any records after the '/read' command.  For
       example, let us suppose db.example.com looks like this:

       /origin foo.example.com. ~
       % TXT 'Foomatic!' ~
       /read foo ~
       % MX 10 mail.foo.example.com. ~

       And the file foo looks like this:

       % 10.1.2.3 ~
       /origin mail.% ~
       % 10.3.2.1 ~

       Then the following records will be created:

       foo.example.com.      TXT   'Foomatic!' ~
       foo.example.com.      A     10.1.2.3 ~
       mail.foo.example.com. A     10.3.2.1 ~
       mail.foo.example.com. MX 10 mail.foo.example.com. ~

       To have something that works like '$INCLUDE filename' in a RFC1035
       master file, do the following:

       /opush % ~
       /read filename ~
       /opop ~

       Or, for that matter, the equivalent of '$INCLUDE filename neworigin':

       /opush neworigin. ~
       /read filename ~
       /opop ~

EXAMPLE ZONE FILE

       # This is an example csv2 zone file

       # First of all, csv2 zone files do not need an SOA record; however, if
       # one is provided, we will make it the SOA record for our zone
       # The SOA record needs to be the first record in the zone if provided
       # This is a commented out record and disabled.

       #%   SOA  % email@% 1 7200 3600 604800 1800 ~

       # Second of all, csv2 zone files do not need authoritative NS records.
       # If they aren't there, MaraDNS will synthesize them, based on the IP
       # addresses MaraDNS is bound to.  (She's pretty smart about this; if
       # Mara is bound to both public and private IPs, only the public IPs will
       # be synthesized as NS records)

       #%   NS   a.% ~
       #%   NS   b.% ~

       # Here are some A (ipv4 address) records; since this is the most
       # common field, the zone file format allows a compact representation
       # of it.
       a.example.net.      10.10.10.10 ~
       # Here, you can see that a single name, "b.example.net." has multiple IPs
       # This can be used as a primitive form of load balancing; MaraDNS will
       # rotate the IPs so that first IP seen by a DNS client changes every time
       # a query for "b.example.net." is made
       b.example.net.  10.10.10.11 ~
       b.example.net.  10.10.10.12 ~

       # We can have the label in either case; it makes no difference
       Z.EXAMPLE.NET.      10.2.3.4 ~
       Y.EXAMPLE.net.  10.3.4.5 ~

       # We can use the percent shortcut.  When the percent shortcut is present,
       # it indicates that the name in question should terminate with the name
       # of the zone we are processing.
       percent.% a         10.9.8.7 ~

       # And we can have star records
       #*.example.net.  A       10.11.12.13 ~

       # We can have a ttl in a record; however the ttl needs a '+' before it:
       # Note that the ttl has to be in seconds, and is before the RTYPE
       d.example.net. +86400 A 10.11.12.13 ~

       f.example.net. # As you can see, records can span multiple lines
                 A    10.2.19.83 ~

       # This allows well-commented records, like this:
       c.example.net.           # Our C class machine
               +86400      # This record is stored for one day
               A           # A record
               10.1.1.1    # Where we are
               ~               # End of record

       # We can even have something similar to csv1 if we want...
       e.example.net.|+86400|a|10.2.3.4|~
       h.example.net.|a|10.9.8.7|~
       # Here, we see we can specify the ttl but not the rtype if desired
       g.example.net.|+86400|10.11.9.8|~

       # Here is a MX record
       % mx 10 mail.% ~
       mail.% +86400 IN A 10.22.23.24 ~

       # We even have a bit of ipv6 support
       a.example.net.           aaaa      3ffe:ffff:1:2:3::4:f ~

       # Not to mention support for SRV records
       _http._tcp.%    srv   0 0 80 a.% ~

       # TXT records, naturally
       example.net.    txt 'This is some text' ~

       # Starting with MaraDNS 1.2.08, there is also support for SPF records,
       # which are identical to TXT records.  See RFC4408 for more details.
       example.net.    spf 'v=spf1 +mx a:colo.example.com/28 -all' ~

LEGAL DISCLAIMER

       THIS SOFTWARE IS PROVIDED BY THE AUTHORS ''AS IS'' AND ANY EXPRESS OR
       IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
       WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
       DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE LIABLE FOR
       ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
       DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
       OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
       HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
       STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
       IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
       POSSIBILITY OF SUCH DAMAGE.

AUTHOR

       Sam Trenholme http://www.samiam.org/