How to configure network zones¶
Note
Network zones are available for the OVN network and the Bridge network.
Network zones can be used to serve DNS records for LXD networks.
You can use network zones to automatically maintain valid forward and reverse records for all your instances. This can be useful if you are operating a LXD cluster with multiple instances across many networks.
Having DNS records for each instance makes it easier to access network services running on an instance. It is also important when hosting, for example, an outbound SMTP service. Without correct forward and reverse DNS entries for the instance, sent mail might be flagged as potential spam.
Each network can be associated to different zones:
Forward DNS records - multiple comma-separated zones (no more than one per project)
IPv4 reverse DNS records - single zone
IPv6 reverse DNS records - single zone
LXD will then automatically manage forward and reverse records for all instances, network gateways and downstream network ports and serve those zones for zone transfer to the operator’s production DNS servers.
Project views¶
Projects have a features.networks.zones
feature, which is disabled by default.
This controls which project new networks zones are created in.
When this feature is enabled new zones are created in the project, otherwise they are created in the default project.
This allows projects that share a network in the default project (i.e those with features.networks=false
) to have their own project level DNS zones that give a project oriented
“view” of the addresses on that shared network (which only includes addresses from instances in their project).
Generated records¶
Forward records¶
If you configure a zone with forward DNS records for lxd.example.net
for your network, it generates records that resolve the following DNS names:
For all instances in the network:
<instance_name>.lxd.example.net
For the network gateway:
<network_name>.gw.lxd.example.net
For downstream network ports (for network zones set on an uplink network with a downstream OVN network):
<project_name>-<downstream_network_name>.uplink.lxd.example.net
Manual records added to the zone.
You can check the records that are generated with your zone setup with the dig
command.
This assumes that core.dns_address
was set to <DNS_server_IP>:<DNS_server_PORT>
. (Setting that configuration
option causes the backend to immediately start serving on that address.)
In order for the dig
request to be allowed for a given zone, you must set the
peers.NAME.address
configuration option for that zone. NAME
can be anything random. The value must match the
IP address where your dig
is calling from. You must leave peers.NAME.key
for that same random NAME
unset.
For example: lxc network zone set lxd.example.net peers.whatever.address=192.0.2.1
.
Note
It is not enough for the address to be of the same machine that dig
is calling from; it needs to
match as a string with what the DNS server in lxd
thinks is the exact remote address. dig
binds to
0.0.0.0
, therefore the address you need is most likely the same that you provided to core.dns_address
.
For example, running dig @<DNS_server_IP> -p <DNS_server_PORT> axfr lxd.example.net
might give the following output:
user@host:~$
dig @192.0.2.200 -p 1053 axfr lxd.example.net
lxd.example.net. 3600 IN SOA lxd.example.net. ns1.lxd.example.net. 1669736788 120 60 86400 30
lxd.example.net. 300 IN NS ns1.lxd.example.net.
lxdtest.gw.lxd.example.net. 300 IN A 192.0.2.1
lxdtest.gw.lxd.example.net. 300 IN AAAA fd42:4131:a53c:7211::1
default-ovntest.uplink.lxd.example.net. 300 IN A 192.0.2.20
default-ovntest.uplink.lxd.example.net. 300 IN AAAA fd42:4131:a53c:7211:216:3eff:fe4e:b794
c1.lxd.example.net. 300 IN AAAA fd42:4131:a53c:7211:216:3eff:fe19:6ede
c1.lxd.example.net. 300 IN A 192.0.2.125
manualtest.lxd.example.net. 300 IN A 8.8.8.8
lxd.example.net. 3600 IN SOA lxd.example.net. ns1.lxd.example.net. 1669736788 120 60 86400 30
Reverse records¶
If you configure a zone for IPv4 reverse DNS records for 2.0.192.in-addr.arpa
for a network using 192.0.2.0/24
, it generates reverse PTR
DNS records for addresses from all projects that are referencing that network via one of their forward zones.
For example, running dig @<DNS_server_IP> -p <DNS_server_PORT> axfr 2.0.192.in-addr.arpa
might give the following output:
user@host:~$
dig @192.0.2.200 -p 1053 axfr 2.0.192.in-addr.arpa
2.0.192.in-addr.arpa. 3600 IN SOA 2.0.192.in-addr.arpa. ns1.2.0.192.in-addr.arpa. 1669736828 120 60 86400 30
2.0.192.in-addr.arpa. 300 IN NS ns1.2.0.192.in-addr.arpa.
1.2.0.192.in-addr.arpa. 300 IN PTR lxdtest.gw.lxd.example.net.
20.2.0.192.in-addr.arpa. 300 IN PTR default-ovntest.uplink.lxd.example.net.
125.2.0.192.in-addr.arpa. 300 IN PTR c1.lxd.example.net.
2.0.192.in-addr.arpa. 3600 IN SOA 2.0.192.in-addr.arpa. ns1.2.0.192.in-addr.arpa. 1669736828 120 60 86400 30
Enable the built-in DNS server¶
To make use of network zones, you must enable the built-in DNS server.
To do so, set the core.dns_address
configuration option (see Core configuration) to a local address on the LXD server.
To avoid conflicts with an existing DNS we suggest not using the port 53.
This is the address on which the DNS server will listen.
Note that in a LXD cluster, the address may be different on each cluster member.
Note
The built-in DNS server supports only zone transfers through AXFR.
It cannot be directly queried for DNS records.
Therefore, the built-in DNS server must be used in combination with an external DNS server (bind9
, nsd
, …), which will transfer the entire zone from LXD, refresh it upon expiry and provide authoritative answers to DNS requests.
Authentication for zone transfers is configured on a per-zone basis, with peers defined in the zone configuration and a combination of IP address matching and TSIG-key based authentication.
Create and configure a network zone¶
Use the following command to create a network zone:
lxc network zone create <network_zone> [configuration_options...]
The following examples show how to configure a zone for forward DNS records, one for IPv4 reverse DNS records and one for IPv6 reverse DNS records, respectively:
lxc network zone create lxd.example.net
lxc network zone create 2.0.192.in-addr.arpa
lxc network zone create 1.0.0.0.1.0.0.0.8.b.d.0.1.0.0.2.ip6.arpa
Note
Zones must be globally unique, even across projects. If you get a creation error, it might be due to the zone already existing in another project.
You can either specify the configuration options when you create the network or configure them afterwards with the following command:
lxc network zone set <network_zone> <key>=<value>
Use the following command to edit a network zone in YAML format:
lxc network zone edit <network_zone>
Configuration options¶
The following configuration options are available for network zones:
Key |
Type |
Required |
Default |
Description |
---|---|---|---|---|
|
string |
no |
- |
IP address of a DNS server |
|
string |
no |
- |
TSIG key for the server |
|
string set |
no |
- |
Comma-separated list of DNS server FQDNs (for NS records) |
|
bool |
no |
|
Whether to generate records for NAT-ed subnets |
|
* |
no |
- |
User-provided free-form key/value pairs |
Note
When generating the TSIG key using tsig-keygen
, the key name must follow the format <zone_name>_<peer_name>.
.
For example, if your zone name is lxd.example.net
and the peer name is bind9
, then the key name must be lxd.example.net_bind9.
.
If this format is not followed, zone transfer might fail.
Add a network zone to a network¶
To add a zone to a network, set the corresponding configuration option in the network configuration:
For forward DNS records:
dns.zone.forward
For IPv4 reverse DNS records:
dns.zone.reverse.ipv4
For IPv6 reverse DNS records:
dns.zone.reverse.ipv6
For example:
lxc network set <network_name> dns.zone.forward="lxd.example.net"
Zones belong to projects and are tied to the networks
features of projects.
You can restrict projects to specific domains and sub-domains through the restricted.networks.zones
project configuration key.
Add custom records¶
A network zone automatically generates forward and reverse records for all instances, network gateways and downstream network ports. If required, you can manually add custom records to a zone.
To do so, use the lxc network zone record
command.
Create a record¶
Use the following command to create a record:
lxc network zone record create <network_zone> <record_name>
This command creates an empty record without entries and adds it to a network zone.
Record properties¶
Records have the following properties:
Property |
Type |
Required |
Description |
---|---|---|---|
|
string |
yes |
Unique name of the record |
|
string |
no |
Description of the record |
|
entry list |
no |
A list of DNS entries |
|
string set |
no |
Configuration options as key/value pairs (only |
Add or remove entries¶
To add an entry to the record, use the following command:
lxc network zone record entry add <network_zone> <record_name> <type> <value> [--ttl <TTL>]
This command adds a DNS entry with the specified type and value to the record.
For example, to create a dual-stack web server, add a record with two entries similar to the following:
lxc network zone record entry add <network_zone> <record_name> A 1.2.3.4
lxc network zone record entry add <network_zone> <record_name> AAAA 1234::1234
You can use the --ttl
flag to set a custom time-to-live (in seconds) for the entry.
Otherwise, the default of 300 seconds is used.
You cannot edit an entry (except if you edit the full record with lxc network zone record edit
), but you can delete entries with the following command:
lxc network zone record entry remove <network_zone> <record_name> <type> <value>