Rob Austein da50e02dda Doc nits. | 7 yıl önce | |
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README.md | 7 yıl önce | |
git-remote-only | 7 yıl önce | |
zc | 7 yıl önce |
This is a small tool for generating DNS zones from relatively simple text files, with some automation to handle complex or repetitive tasks and to automate generation of reverse zone data.
zc
("zone compiler") is a Python script which uses an external
package (Bob Halley's excellent dnspython toolkit) to do a lot of
the the heavy lifting.
zc
can be used either as a straightforward command line tool or as a
pair of pre-receive
and post-receive
hooks in a bare git
repository. In the latter mode, zc
pulls its input data and
configuration directly from commits pushed to the master branch in the
git repository, using another external library (GitPython).
Upshot of all this is that, once the git repository has been set up, you just clone a copy of the repository, edit flat text files with your favorite editor, commit and push, and you're done. Compilation will happen automatically when you push, any serious errors will abort the push so you can fix them and try again, and output will be installed automatically if there were no serious errors.
If you just want to use zc
as a command line tool, it's simple.
Usage as of this writing (subject to change, run zc --help
for
current syntax):
usage: zc [-h] [-o OUTPUT_DIRECTORY] [-l {debug,info,warning,error}]
input [input ...]
Generate zone files from a simpl(er) flat text file.
General intent here is to let users specify normal hosts in a simple
and compact format, with a few utilities we provide to automate
complex or repetitive stuff, including automatic generation of AAAA
RRs based on a mapping scheme from A RRs.
After generating the text of the forward zone, we run it through
dnspython's zone parser, then generate reverse zones by translating
the A and AAAA RRs in the forward zone into the corresponding PTR RRs.
positional arguments:
input input file
optional arguments:
-h, --help show this help message and exit
-o OUTPUT_DIRECTORY, --output-directory OUTPUT_DIRECTORY
directory for output files (default: .)
-l {debug,info,warning,error}, --log-level {debug,info,warning,error}
how loudly to bark (default: warning)
You can supply more than one input file, zc
will process them all
together before writing out any of the zone files.
When used as git hooks, configuration can't come from the command line, so it comes from two places:
A file called config.json
in the repository, and
Variables set in the configuration of the bare git repository where
the pre-receive
and post-receive
hooks are installed.
The general idea is that stuff which should be under control of the
data owner is controlled by config.json
, while stuff that should be
controlled by the server operator is controlled by configuration
variables in the server git repository. These are described below.
The general idea is that we want to make sure that the zones compile
correctly before allowing the git push
operation to complete,
then, assuming everything's OK, we want to install the zones after
the commit completes.
All the real work happens in the pre-receive
hook, the
post-receive
hook's job is just to trigger final installation of the
output zone files after git-receive-pack
finishes accepting the
push. If you don't understand git well enough to know what that
means, don't worry about it. If you want to learn more, see
githooks, but the learning curve necessary for the documentation
to make any sense is a bit steep, so bring a bag lunch.
zc
determines whether it's running as one of the git hooks or not by
examining the name by which it was invoked: if the name ends with
/pre-receive
or /post-receive
, it's a hook, otherwise you get the
command line behavior. In practice, this means that you can just
install zc
, symlink the correct hook names to whereever you
installed the zc
script, and the right thing should happen.
config.json
settingsThe list of input files and the verbosity are set in the JSON file, while the output directory is set in the git configuration on the server where the bare git repository lives.
{
"zones": ["foo.zone", "bar.zone"],
"log-level": "info"
}
The zones
parameter is mandatory, and specifies the names of the
input files within the git repository (at the moment we only look at
the top-level directory -- we could change this given a reason).
The log-level
parameter is optional, and defaults to warning
.
All of the following settings have defaults except for zc.output-directory
.
git --git-dir /where/ever.git config zc.output-directory /my/output/directory
The zc.output-directory
parameter in the git repository's
configuration file specifies the location of the directory to which
zc
should write its final output. zc
also uses this directory to
stash a FIFO which it uses to coordinate actions between the
pre-receive
and post-receive
hooks.
There is no default for zc.output-directory
, you must set it.
git --git-dir /where/ever.git config zc.hook-timeout 15
zc.hook-timeout
controls how many seconds the pre-receive
hook
should wait for confirmation from the post-receive
hook before
giving up. The default value of 15 seconds should be fine unless your
server is really slow.
git --git-dir /where/ever.git config zc.post-command 'rndc reload'
zc.post-command
, if set, specifies a command to run after all
generated files have been installed. The default is not to run any
such command.
git --git-dir /where/ever.git config zc.log-file /var/log/zc/zc.log
git --git-dir /where/ever.git config zc.log-level warning
git --git-dir /where/ever.git config zc.log-file-hours 24
git --git-dir /where/ever.git config zc.log-file-count 7
When running in git hook mode, zc
can log to both stderr
(which
git passes back to the user executing the push) and to a log file.
The zc.log-*
parameters control the log file.
zc.log-file
is the name of the log file; if not set, zc
will not
log to a file.
zc.log-level
is optional, and defaults to warning
.
zc.log-file-hours
controls how many hours should elapse before zc
rotates its log file. The default is 24 hours.
zc.log-file-count
controls how many old log files zc
should keep.
The default is 7.
Other than config.json
, the input files to zc
look the same
regardless of whether you're running zc
on the command line or via
git hooks.
While zc
generates both forward and reverse zones, the underlying
mechanisms are (deliberately) very different, so it's simplest to
consider them separately. Forward zones are driven from human-edited
files, while reverse zones are generated completely automatically from
the corresponding forward zones.
Forward zone generation starts with a flat text file which is parsed line-by-line to produce a forward zone file. There three basic kinds of lines in this file:
Stuff passed unchanged through zc
: blank lines, comments, raw DNS
RRs (for things other than addresses), and standard control
operations like $TTL and $ORIGIN.
Name-address pairs, processed to generate A and AAAA RRs.
Control operations, all of which have names starting with "$".
zc
requires that the text file start with a $ORIGIN
control to
specify the name of the zone itself.
Other than the above, the one bit of processing zc
performs is
replacement of the string "@SERIAL@ in an SOA RR with a
seconds-since-epoch integer timestamp.
"Name-address pairs" are exactly what they sound like: something that a DNS zone file parser would consider a valid owner name, and and an IP address (IPv4 or IPv6).
Processing of one name-address pair produces either one or two RRs,
depending on whether automatic generation of IPv6 addresses from IPv4
addresses is enabled when zc
processes this name-address pair (see
the $MAP
control operation, below).
Example:
$MAP yes
; A couple of dual-stack hosts, with IPv6 addresses generated
; algorithmically from the IPv4 addresses.
tweedledee 10.0.0.1
tweedledum 10.0.0.2
$MAP no
; Three single-stack hosts, addresses are what you see, RR type
; inferred from the address family
larry 10.0.0.3
moe 2002:a00::4
curly 10.0.0.5
$MAP
and $MAP_RULE
The $MAP
control operation enables or disables automatic generation
of IPv6 addresses from IPv4 addresses, according to zone-specific
mappings specified by the $MAP_RULE
operation.
$MAP
is simple: it takes one argument, yes
or no
(on
,
off
, true
, and false
are allowed as aliases).
$MAP_RULE
takes two arguments: a prefix and a format string. You
can specify $MAP_RULE
more than once to build up an ordered set of
mapping rules. When mapping is enabled, a given address will be
checked against the prefix of each rule in turn: the format string
from the first matching rule (if any) will be used to format the
mapped address.
Format strings are in the syntax used by Python's str.format()
operator; the .format()
operator will be called with one argument,
the input address converted to a tuple of integers, one per byte in
the binary representation of the input address. So an input address
of 10.0.0.44
would be yield the tuple (10, 0, 0, 44)
, and so forth.
$MAP_RULE 10.1.3.0/24 2002:a00:0000:f{0[2]}::{0[3]}
$MAP_RULE 10.1.0.0/16 2002:a00:0000:{0[2]}::{0[3]}
$MAP on
larry 10.1.2.3
moe 10.1.3.2
$MAP off
curly 10.1.4.1
This mechanism is intended primarily for mapping IPv4 addresses to IPv6 addresses. The mechanism itself is address-family-agnostic: in principal, it should work equally well in the other direction if you can specify a useful set of rules, but the author has not tested this.
$RANGE
The $RANGE
control operation is a variation on the same general idea
as the (BIND9-specific) $GENERATE
control operation, but is, in the
author's opinion, a bit easier both to use and to read. For all but
the most esoteric uses, it takes three or four arguments:
A format string to generate the name field of the resulting RRs.
A start addresses (IPv4 or IPv6).
A stop address
An optional numeric offset
.
The basic idea here is to generate a sequence of A or AAAA RRs (type selected automatically to fit the addresses provided) for every address in the specified range, inclusive, with names generated according to a format string containing a numeric field.
An offset
value of zero would start with the name generated by
applying the format string to the number zero; an offset
value of
one would start with the name generated by applying the format string
to the number 1, and so forth. If the offset
field isn't specified
at all, it defaults to the numeric value of the least significant
octet of the start address.
Examples:
; Access points using $RANGE. This is equivalent to:
;
; ap-101 10.0.1.101
; ap-102 10.0.1.102
; ...
; ap-200 10.0.1.200
$RANGE ap-{:d} 10.0.1.101 10.0.1.200
; Switches, also using $RANGE, but with the numeric input to the
; format string explicitly specified rather than inferred from the
; IPv4 addressing. Equivalent to:
;
; sw-1 10.0.3.17
; sw-2 10.0.3.18
; ...
; sw-26 10.0.3.42
$RANGE sw-{:d} 10.0.3.17 10.0.3.42 1
; Finally, a whole lot of DHCP client addresses, for IPv4
; addresses ranging from 10.1.0.50 to 10.2.255.254, names left as
; an exercise for the reader.
$RANGE dhcp-f{:03x} 10.1.0.50 10.2.255.254 50
$INCLUDE
and $GENERATE
The $INCLUDE
and $GENERATE
control operators are not currently implemented.
$INCLUDE
is a standard control operator, but we appear to have no
current need for it.
$GENERATE
is a BIND-specific control operator. We could implement
it if there were a real need, but the $RANGE
operator covers the
things for which we have been using $GENERATE
in the forward zone.
Our current use of $GENERATE
in reverse zones is a source of
consistency problems, and is therefore unsupported with prejudice.
$REVERSE_ZONE
The $REVERSE_ZONE
control operation has no effect on the forward
zone. Rather, it's a mechanism for specifying the list of reverse
zones which should be generated from this forward zone. We include
this in the input source for the forward zone in order to keep all the
data describing the zone in one place.
If you don't use the $REVERSE_ZONE
control, zc
will not generate
any reverse data for this forward zone.
Sample:
$REVERSE_ZONE 0.10.in-addr.arpa
$REVERSE_ZONE 1.10.in-addr.arpa
$REVERSE_ZONE 2.10.in-addr.arpa
$REVERSE_ZONE 0.0.0.0.0.0.a.0.2.0.0.2.ip6.arpa
As noted above, reverse zones are generated entirely from data extracted from the forward zone. This is deliberate: we are trying to make sure that the reverse data corresponds to the forward data, and giving the user an opportunity to get creative here is just asking for trouble.
The basic strategy is:
Create a reverse zone object for every name listed in the forward
zone's source via $REVERSE_ZONE
operators.
For each A
and AAAA
RR in the forward zone, generate the
corresponding PTR
RR and and find the reverse zone in which that
RR belongs; whine for each PTR RR that doesn't fit into any
specified reverse zone.
Populate the zone apex data (SOA and apex NS RRsets) of each reverse zone by copying the corresponding rdata from the forward zone. Yes, this assumes that the forward and reverse zones are served by the same servers; we could "fix" that given a need, but as of this writing no such need exists, and this keeps it simple.
Copyright (c) 2017, Grunchweather Associates
Permission to use, copy, modify, and/or distribute this software for any purpose with or without fee is hereby granted, provided that the above copyright notice and this permission notice appear in all copies.
THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.