This is the DNS server powering the NTP Pool system and other similar services.
For bug reports or feature requests, please create an issue. For questions or discussion, you can post to the GeoDNS category on the NTP Pool forum.
Release builds are available in a yum repository at
https://pkgs.ntppool.org/yum/
and apt (debian, ubuntu) packages at
https://pkgs.ntppool.org/apt/
.
If you don't have Go installed the easiest way to build geodns from source is to
download and install Go from https://golang.org/dl/
.
GeoDNS generally requires a recent version of Go (one of the last few major versions)
git clone https://github.com/abh/geodns.git
cd geodns
go build
./geodns -h
You can also build with goreleaser.
There's a sample configuration file in dns/example.com.json
. This is currently
derived from the test.example.com
data used for unit tests and not an example
of a "best practices" configuration.
For testing there's also a bigger test file at:
mkdir -p dns
curl -o dns/test.ntppool.org.json http://tmp.askask.com/2012/08/dns/ntppool.org.json.big
After building the server you can run it with:
./geodns -log -interface 127.1 -port 5053
To test the responses run
dig -t a test.example.com @127.1 -p 5053
or
dig -t ptr 2.1.168.192.IN-ADDR.ARPA. @127.1 -p 5053
or more simply put
dig -x 192.168.1.2 @127.1 -p 5053
The binary can be moved to /usr/local/bin, /opt/geodns/ or wherever you find appropriate.
See the sample configuration file.
Notable command line parameters (and their defaults)
- -config="./dns/"
Directory of zone files (and configuration named geodns.conf
).
- -checkconfig=false
Check configuration file, parse zone files and exit
- -interface="*"
Comma separated IPs to listen on for DNS requests.
- -port="53"
Port number for DNS requests (UDP and TCP)
- -http=":8053"
Listen address for HTTP interface. Specify as 127.0.0.1:8053
to only listen on
localhost.
- -identifier=""
Identifier for this instance (hostname, pop name or similar).
It can also be a comma separated list of identifiers where the first is the "server id" and subsequent ones are "group names", for example region of the server, name of anycast cluster the server is part of, etc. This is used in (future) reporting/statistics features.
- -log=false
Enable to get lots of extra logging, only useful for testing and debugging. Absolutely not recommended in production unless you get very few queries (less than 1-200/second).
- -cpus=4
Maximum number of CPUs to use. Set to 0 to match the number of CPUs available on the system (also the default).
GeoDNS supports query logging to JSON or Avro files (see the sample configuration file for options).
/metrics
on the http port provides a number of metrics in Prometheus format.
The runtime status page, websocket feature and StatHat integration have been replaced with Prometheus metrics.
See zone targeting options below.
Most records can have a 'weight' assigned. If any records of a particular type
for a particular name have a weight, the system will return max_hosts
records
(default 2).
If the weight for all records is 0, all matching records will be returned. The weight for a label can be any integer as long as the weights for a label and record type is less than 2 billion.
As an example, if you configure
10.0.0.1, weight 10
10.0.0.2, weight 20
10.0.0.3, weight 30
10.0.0.4, weight 40
with max_hosts
2 then .4 will be returned about 4 times more often than .1.
The geodns.conf file allows you to specify a specific directory for the GeoIP
data files and other options. See the geodns.conf.sample
file for example
configuration.
The global configuration file is not reloaded at runtime.
Most of the configuration is "per zone" and done in the zone .json files. The zone configuration files are automatically reloaded when they change.
In the zone configuration file the whole zone is a big hash (associative array). At the top level you can (optionally) set some options with the keys serial, ttl and max_hosts.
The actual zone data (dns records) is in a hash under the key "data". The keys in the hash are hostnames and the value for each hostname is yet another hash where the keys are record types (lowercase) and the values an array of records.
For example to setup an MX record at the zone apex and then have a different A record for users in Europe than anywhere else, use:
{
"serial": 1,
"data": {
"": {
"ns": [ "ns.example.net", "ns2.example.net" ],
"txt": "Example zone",
"spf": [ { "spf": "v=spf1 ~all", "weight": 1 } ],
"mx": { "mx": "mail.example.com", "preference": 10 }
},
"mail": { "a": [ ["192.168.0.1", 100], ["192.168.10.1", 50] ] },
"mail.europe": { "a": [ ["192.168.255.1", 0] ] },
"smtp": { "alias": "mail" }
}
}
The configuration files are automatically reloaded when they're updated. If a file can't be read (invalid JSON, for example) the previous configuration for that zone will be kept.
- serial
GeoDNS doesn't support zone transfers (AXFR), so the serial number is only used for debugging and monitoring. The default is the 'last modified' timestamp of the zone file.
- ttl
Set the default TTL for the zone (default 120).
-
targeting
-
max_hosts
-
contact
Set the soa 'contact' field (default is "hostmaster.$domain").
@
country continent
region and regiongroup
Each label has a hash (object/associative array) of record data, the keys are the type. The supported types and their options are listed below.
Adding support for more record types is relatively straight forward, please open a ticket in the issue tracker with what you are missing.
Each record has the format of a short array with the first element being the IP address and the second the weight.
[ [ "192.168.0.1", 10], ["192.168.2.1", 5] ]
See above for how the weights work.
Same format as A records (except the record type is "aaaa").
Internally resolved cname, of sorts. Only works internally in a zone.
"foo"
"target.example.com."
"www"
The target will have the current zone name appended if it's not a FQDN (since v2.2.0).
MX records support a weight
similar to A records to indicate how often the particular
record should be returned.
The preference
is the MX record preference returned to the client.
{ "mx": "foo.example.com" }
{ "mx": "foo.example.com", "weight": 100 }
{ "mx": "foo.example.com", "weight": 100, "preference": 10 }
weight
and preference
are optional.
NS records for the label, use it on the top level empty label (""
) to specify
the nameservers for the domain.
[ "ns1.example.com", "ns2.example.com" ]
There's an alternate legacy syntax that has space for glue records (IPv4 addresses), but in GeoDNS the values in the object are ignored so the list syntax above is recommended.
{ "ns1.example.net.": null, "ns2.example.net.": null }
Simple syntax
"Some text"
Or with weights
{ "txt": "Some text", "weight": 10 }
An SPF record is semantically identical to a TXT record with the exception that the label is set to 'spf'. An example of an spf record with weights:
{ "spf": "v=spf1 ~all]", "weight": 1 }
An spf record is typically at the root of a zone, and a label can have an array of SPF records, e.g
"spf": [ { "spf": "v=spf1 ~all", "weight": 1 } , "spf": "v=spf1 10.0.0.1", "weight": 100]
An SRV record has four components: the weight, priority, port and target. The keys for these are "srv_weight", "priority", "target" and "port". Note the difference between srv_weight (the weight key for the SRV qtype) and "weight".
An example srv record definition for the _sip._tcp service:
"_sip._tcp": {
"srv": [ { "port": 5060, "srv_weight": 100, "priority": 10, "target": "sipserver.example.com."} ]
},
Much like MX records, SRV records can have multiple targets, eg:
"_http._tcp": {
"srv": [
{ "port": 80, "srv_weight": 10, "priority": 10, "target": "www.example.com."},
{ "port": 8080, "srv_weight": 10, "priority": 20, "target": "www2.example.com."}
]
},
This software is Copyright 2012-2015 Ask Bjørn Hansen. For licensing information please see the file called LICENSE.