13. The DHCP-DDNS Server
13.1. Overview
The DHCP-DDNS Server (kea-dhcp-ddns
, known informally as D2) conducts
the client side of the Dynamic DNS protocol (DDNS, defined in RFC
2136) on behalf of the DHCPv4
and DHCPv6 servers (kea-dhcp4
and kea-dhcp6
respectively). The DHCP
servers construct DDNS update requests, known as NameChangeRequests
(NCRs), based on DHCP lease change events and then post them to D2. D2
attempts to match each request to the appropriate DNS server(s) and
carries out the necessary conversation with those servers to update the
DNS data.
13.1.1. DNS Server Selection
To match a request to the appropriate DNS servers, D2 must have a catalog of servers from which to select. In fact, D2 has two such catalogs, one for forward DNS and one for reverse DNS; these catalogs are referred to as “DDNS domain lists.” Each list consists of one or more named DDNS domains. Further, each DDNS domain has a list of one or more DNS servers that publish the DNS data for that domain.
When conducting forward-domain matching, D2 compares the fully qualified domain name (FQDN) in the request against the name of each forward DDNS domain in its catalog. The domain whose name matches the longest portion of the FQDN is considered the best match. For example, if the FQDN is “myhost.sample.example.com.”, and there are two forward domains in the catalog, “sample.example.com.” and “example.com.”, the former is regarded as the best match. In some cases, it may not be possible to find a suitable match. Given the same two forward domains there would be no match for the FQDN “bogus.net”, so the request would be rejected. Finally, if there are no forward DDNS domains defined, D2 simply disregards the forward-update portion of requests.
When conducting reverse-domain matching, D2 constructs a reverse FQDN from the lease address in the request and compares that against the name of each reverse DDNS domain. Again, the domain whose name matches the longest portion of the FQDN is considered the best match. For instance, if the lease address is “172.16.1.40” and there are two reverse domains in the catalog, “1.16.172.in-addr.arpa.” and “16.172.in-addr.arpa”, the former is the best match. As with forward matching, D2 may not find a suitable match. Given the same two domains, there would be no match for the lease address, “192.168.1.50”, and the request would be rejected. As with forward-domain matching, if there are no reverse DDNS domains defined, D2 simply disregards the reverse-update portion of requests.
13.1.2. Conflict Resolution
D2 implements the conflict resolution strategy prescribed by RFC 4703. Conflict resolution is intended to prevent different clients from mapping to the same FQDN at the same time. To make this possible, the RFC requires that forward DNS entries for a given FQDN must be accompanied by a DHCID resource record (RR). This record contains a client identifier that uniquely identifies the client to whom the name belongs. Furthermore, any DNS updater that wishes to update or remove existing forward entries for an FQDN may only do so if their client matches that of the DHCID RR.
In other words, the DHCID RR maps an FQDN to the client to whom it belongs, and thereafter changes to that mapping can only be done by or at the behest of that client.
Conflict resolution can be indirectly enabled or disabled via
the configuration parameter ddns-use-conflict-resolution
, supported
by both kea-dhcp4
and kea-dhcp6
. These servers use this parameter to
set a flag within each NameChangeRequest they send that tells D2
whether conflict resolution should be employed for that request.
By default, conflict resolution is enabled. For more details, please refer
to discussions of ddns-use-conflict-resolution
in DDNS for DHCPv4 and DDNS for DHCPv6.
When conflict resolution is disabled, D2 still adds DHCID RRs but does not use them to enforce client ownership of DNS entries. Disabling it should only be used after careful consideration.
13.1.3. Dual-Stack Environments
RFC 4703, section 5.2, describes issues that may arise with dual-stack clients. These are clients that wish to have both IPv4 and IPv6 mappings for the same FQDN. To work properly, clients must embed their IPv6 DUID within their IPv4 client identifier option, as described in RFC 4361. In this way, DNS updates for both IPv4 and IPv6 can be managed under the same DHCID RR. This feature is supported by Kea beginning with release 2.1.2.
13.2. Starting and Stopping the DHCP-DDNS Server
kea-dhcp-ddns
is the Kea DHCP-DDNS server and, due to the nature of
DDNS, it runs alongside either the DHCPv4 or DHCPv6 component (or both).
Like other parts of Kea, it is a separate binary that can be run on its
own or through keactrl
(see Managing Kea with keactrl). In normal
operation, controlling kea-dhcp-ddns
with keactrl
is
recommended; however, it is also possible to run the DHCP-DDNS server
directly. It accepts the following command-line switches:
-c file
- specifies the configuration file. This is the only mandatory switch.-d
- specifies whether server logging should be switched to debug/verbose mode. In verbose mode, the logging severity and debuglevel specified in the configuration file are ignored and “debug” severity and the maximum debuglevel (99) are assumed. The flag is convenient for temporarily switching the server into maximum verbosity, e.g. when debugging.-v
- displays the Kea version and exits.-W
- displays the Kea configuration report and exits. The report is a copy of theconfig.report
file produced by./configure
; it is embedded in the executable binary.-t file
- specifies the configuration file to be tested.kea-dhcp-ddns
attempts to load it and conducts sanity checks. Certain checks are possible only while running the actual server. The actual status is reported with an exit code (0 = configuration looks okay, 1 = error encountered). Kea prints out log messages to standard output and errors to standard error when testing the configuration.
The config.report
file may also be accessed directly, via the
following command. The binary path
may be found in the install
directory or in the .libs
subdirectory in the source tree. For
example: kea/src/bin/d2/.libs/kea-dhcp-ddns
.
strings path/kea-dhcp-ddns | sed -n 's/;;;; //p'
Upon startup, the module loads its configuration and begins listening for NCRs based on that configuration.
During startup, the server attempts to create a PID file of the form:
[runstatedir]/[conf name].kea-dhcp-ddns.pid
where:
runstatedir
- is the value as passed into the build configure script; it defaults to “/usr/local/var/run”. Note that this value may be overridden at runtime by setting the environment variableKEA_PIDFILE_DIR
. This is intended primarily for testing purposes.conf name
- is the configuration file name used to start the server, minus all preceding paths and the file extension. For example, given a pathname of “/usr/local/etc/kea/myconf.txt”, the portion used would be “myconf”.
If the file already exists and contains the PID of a live process, the
server issues a DHCP_DDNS_ALREADY_RUNNING
log message and exits. It
is possible, though unlikely, that the file is a remnant of a system
crash and the process to which the PID belongs is unrelated to Kea. In
such a case it is necessary to manually delete the PID file.
13.3. Configuring the DHCP-DDNS Server
Before starting the kea-dhcp-ddns
module for the first time, a
configuration file must be created. The following default configuration
is a template that can be customized to individual requirements.
"DhcpDdns": {
"ip-address": "127.0.0.1",
"port": 53001,
"dns-server-timeout": 100,
"ncr-protocol": "UDP",
"ncr-format": "JSON",
"tsig-keys": [ ],
"forward-ddns": {
"ddns-domains": [ ]
},
"reverse-ddns": {
"ddns-domains": [ ]
}
}
The configuration can be divided into the following sections, each of which is described below:
Global Server Parameters - define values which control connectivity and global server behavior.
Control Socket - defines the Control Socket type and name.
TSIG Key Info - defines the TSIG keys used for secure traffic with DNS servers.
Forward DDNS - defines the catalog of forward DDNS domains.
Reverse DDNS - defines the catalog of reverse DDNS domains.
13.3.1. Global Server Parameters
ip-address
- the IP address on which D2 listens for requests. The default is the local loopback interface at address 127.0.0.1. Either an IPv4 or IPv6 address may be specified.port
- the port on which D2 listens for requests. The default value is 53001.dns-server-timeout
- the maximum amount of time, in milliseconds, that D2 will wait for a response from a DNS server to a single DNS update message.ncr-protocol
- the socket protocol to use when sending requests to D2. Currently only UDP is supported.ncr-format
- the packet format to use when sending requests to D2. Currently only JSON format is supported.
D2 must listen for change requests on a known address and port. By default it listens at 127.0.0.1 on port 53001. The following example illustrates how to change D2’s global parameters so it will listen at 192.168.1.10 port 900:
"DhcpDdns": {
"ip-address": "192.168.1.10",
"port": 900,
...
}
}
Warning
It is possible for a malicious attacker to send bogus NameChangeRequests to the DHCP-DDNS server. Addresses other than the IPv4 or IPv6 loopback addresses (127.0.0.1 or ::1) should only be used for testing purposes; note that local users may still communicate with the DHCP-DDNS server.
Note
If the ip-address
and port
are changed, the corresponding values in
the DHCP servers’ dhcp-ddns
configuration section must be changed.
13.3.2. Management API for the D2 Server
The management API allows the issuing of specific management commands, such as configuration retrieval or shutdown. For more details, see Management API. Currently, the only supported communication channel type is the UNIX stream socket. By default there are no sockets open; to instruct Kea to open a socket, the following entry in the configuration file can be used:
"DhcpDdns": {
"control-socket": {
"socket-type": "unix",
"socket-name": "/path/to/the/unix/socket"
},
...
}
The length of the path specified by the socket-name
parameter is
restricted by the maximum length for the UNIX socket name on the
operating system, i.e. the size of the sun_path
field in the
sockaddr_un
structure, decreased by 1. This value varies on
different operating systems, between 91 and 107 characters. Typical
values are 107 on Linux and 103 on FreeBSD.
Communication over the control channel is conducted using JSON structures. See the Control Channel section in the Kea Developer’s Guide for more details.
The D2 server supports the following operational commands:
build-report
config-get
config-reload
config-set
config-test
config-write
list-commands
shutdown
status-get
version-get
Since Kea version 2.0.0, the D2 server also supports the following operational commands for statistics:
statistic-get
statistic-get-all
statistic-reset
statistic-reset-all
The shutdown
command supports the extra type
argument, which controls the
way the D2 server cleans up on exit.
The supported shutdown types are:
normal
- stops the queue manager and finishes all current transactions before exiting. This is the default.drain_first
- stops the queue manager but continues processing requests from the queue until it is empty.now
- exits immediately.
An example command may look like this:
{
"command": "shutdown"
"arguments": {
"exit-value": 3,
"type": "drain_first"
}
}
13.3.3. TSIG Key List
A DDNS protocol exchange can be conducted with or without a transaction signature, or TSIG (defined in RFC 2845). This configuration section allows the administrator to define the set of TSIG keys that may be used in such exchanges.
To use TSIG when updating entries in a DNS domain, a key must be defined in the TSIG key list and referenced by name in that domain’s configuration entry. When D2 matches a change request to a domain, it checks whether the domain has a TSIG key associated with it. If so, D2 uses that key to sign DNS update messages sent to and verify responses received from the domain’s DNS server(s). For each TSIG key required by the DNS servers that D2 is working with, there must be a corresponding TSIG key in the TSIG key list.
As one might gather from the name, the tsig-key
section of the D2
configuration lists the TSIG keys. Each entry describes a TSIG key used
by one or more DNS servers to authenticate requests and sign responses.
Every entry in the list has three parameters:
name
- is a unique text label used to identify this key within the list. This value is used to specify which key (if any) should be used when updating a specific domain. As long as the name is unique its content is arbitrary, although for clarity and ease of maintenance it is recommended that it match the name used on the DNS server(s). This field cannot be blank.algorithm
- specifies which hashing algorithm should be used with this key. This value must specify the same algorithm used for the key on the DNS server(s). The supported algorithms are listed below:HMAC-MD5
HMAC-SHA1
HMAC-SHA224
HMAC-SHA256
HMAC-SHA384
HMAC-SHA512
This value is not case-sensitive.
digest-bits
- is used to specify the minimum truncated length in bits. The default value 0 means truncation is forbidden; non-zero values must be an integral number of octets, and be greater than both 80 and half of the full length. (Note that in BIND 9 this parameter is appended to the algorithm name, after a dash.)secret
- is used to specify the shared secret key code for this key. This value is case-sensitive and must exactly match the value specified on the DNS server(s). It is a base64-encoded text value.
As an example, suppose that a domain D2 will be updating is maintained by a BIND 9 DNS server, which requires dynamic updates to be secured with TSIG. Suppose further that the entry for the TSIG key in BIND 9’s named.conf file looks like this:
:
key "key.four.example.com." {
algorithm hmac-sha224;
secret "bZEG7Ow8OgAUPfLWV3aAUQ==";
};
:
By default, the TSIG key list is empty:
"DhcpDdns": {
"tsig-keys": [ ],
...
}
A new key must be added to the list:
"DhcpDdns": {
"tsig-keys": [
{
"name": "key.four.example.com.",
"algorithm": "HMAC-SHA224",
"secret": "bZEG7Ow8OgAUPfLWV3aAUQ=="
}
],
...
}
These steps must be repeated for each TSIG key needed, although the same TSIG key can be used with more than one domain.
13.3.4. Forward DDNS
The forward DDNS section is used to configure D2’s forward-update behavior. Currently it contains a single parameter, the catalog of forward DDNS domains, which is a list of structures.
"DhcpDdns": {
"forward-ddns": {
"ddns-domains": [ ]
},
...
}
By default, this list is empty, which causes the server to ignore the forward-update portions of requests.
13.3.4.1. Adding Forward DDNS Domains
A forward DDNS domain maps a forward DNS zone to a set of DNS servers which maintain the forward DNS data (i.e. name-to-address mapping) for that zone. Each zone served needs one forward DDNS domain. Some or all of the zones may be maintained by the same servers, but one DDNS domain is still needed for each zone. Remember that matching a request to the appropriate server(s) is done by zone and a DDNS domain only defines a single zone.
This section describes how to add forward DDNS domains; repeat these steps for each forward DDNS domain desired. Each forward DDNS domain has the following parameters:
name
- this is the fully qualified domain name (or zone) that this DDNS domain can update. This value is compared against the request FQDN during forward matching. It must be unique within the catalog.key-name
- if TSIG is used with this domain’s servers, this value should be the name of the key from the TSIG key list. If the value is blank (the default), TSIG will not be used in DDNS conversations with this domain’s servers.dns-servers
- this is a list of one or more DNS servers which can conduct the server side of the DDNS protocol for this domain. The servers are used in a first-to-last preference; in other words, when D2 begins to process a request for this domain, it will pick the first server in this list and attempt to communicate with it. If that attempt fails, D2 will move to the next one in the list and so on, until either it is successful or the list is exhausted.
To create a new forward DDNS domain, add a new domain element and set its parameters:
"DhcpDdns": {
"forward-ddns": {
"ddns-domains": [
{
"name": "other.example.com.",
"key-name": "",
"dns-servers": [
]
}
]
}
}
It is possible to add a domain without any servers; however, if that domain matches a request, the request will fail. To make the domain useful, at least one DNS server must be added to it.
13.3.4.1.1. Adding Forward DNS Servers
This section describes how to add DNS servers to a forward DDNS domain. Repeat these instructions as needed for all the servers in each domain.
Forward DNS server entries represent actual DNS servers which support the server side of the DDNS protocol. Each forward DNS server has the following parameters:
hostname
- the resolvable host name of the DNS server; this parameter is not yet implemented.ip-address
- the IP address at which the server listens for DDNS requests. This may be either an IPv4 or an IPv6 address.port
- the port on which the server listens for DDNS requests. It defaults to the standard DNS service port of 53.
To create a new forward DNS server, a new server element must be added to the domain and its parameters filled in. If, for example, the service is running at “172.88.99.10”, set the forward DNS server as follows:
"DhcpDdns": {
"forward-ddns": {
"ddns-domains": [
{
"name": "other.example.com.",
"key-name": "",
"dns-servers": [
{
"ip-address": "172.88.99.10",
"port": 53
}
]
}
]
}
}
Note
Since hostname
is not yet supported, the parameter ip-address
must be set to the address of the DNS server.
13.3.5. Reverse DDNS
The reverse DDNS section is used to configure D2’s reverse update behavior, and the concepts are the same as for the forward DDNS section. Currently it contains a single parameter, the catalog of reverse DDNS domains, which is a list of structures.
"DhcpDdns": {
"reverse-ddns": {
"ddns-domains": [ ]
}
...
}
By default, this list is empty, which causes the server to ignore the reverse-update portions of requests.
13.3.5.1. Adding Reverse DDNS Domains
A reverse DDNS domain maps a reverse DNS zone to a set of DNS servers which maintain the reverse DNS data (address-to-name mapping) for that zone. Each zone served needs one reverse DDNS domain. Some or all of the zones may be maintained by the same servers, but one DDNS domain entry is needed for each zone. Remember that matching a request to the appropriate server(s) is done by zone and a DDNS domain only defines a single zone.
This section describes how to add reverse DDNS domains; repeat these steps for each reverse DDNS domain desired. Each reverse DDNS domain has the following parameters:
name
- this is the fully qualified reverse zone that this DDNS domain can update. This is the value used during reverse matching, which compares it with a reversed version of the request’s lease address. The zone name should follow the appropriate standards; for example, to support the IPv4 subnet 172.16.1, the name should be “1.16.172.in-addr.arpa.”. Similarly, to support an IPv6 subnet of 2001:db8:1, the name should be “1.0.0.0.8.B.D.0.1.0.0.2.ip6.arpa.” The name must be unique within the catalog.key-name
- if TSIG is used with this domain’s servers, this value should be the name of the key from the TSIG key list. If the value is blank (the default), TSIG will not be used in DDNS conversations with this domain’s servers.dns-servers
- this is a list of one or more DNS servers which can conduct the server side of the DDNS protocol for this domain. Currently, the servers are used in a first-to-last preference; in other words, when D2 begins to process a request for this domain, it will pick the first server in this list and attempt to communicate with it. If that attempt fails, D2 will move to the next one in the list and so on, until either it is successful or the list is exhausted.
To create a new reverse DDNS domain, a new domain element must be added and its parameters set. For example, to support subnet 2001:db8:1::, the following configuration could be used:
"DhcpDdns": {
"reverse-ddns": {
"ddns-domains": [
{
"name": "1.0.0.0.8.B.D.0.1.0.0.2.ip6.arpa.",
"key-name": "",
"dns-servers": [
]
}
]
}
}
It is possible to add a domain without any servers; however, if that domain matches a request, the request will fail. To make the domain useful, at least one DNS server must be added to it.
13.3.5.1.1. Adding Reverse DNS Servers
This section describes how to add DNS servers to a reverse DDNS domain. Repeat these instructions as needed for all the servers in each domain.
Reverse DNS server entries represent actual DNS servers which support the server side of the DDNS protocol. Each reverse DNS server has the following parameters:
hostname
- the resolvable host name of the DNS server; this value is currently ignored.ip-address
- the IP address at which the server listens for DDNS requests.port
- the port on which the server listens for DDNS requests. It defaults to the standard DNS service port of 53.
To create a new reverse DNS server, a new server element must be added to the domain and its parameters specified. If, for example, the service is running at “172.88.99.10”, then set it as follows:
"DhcpDdns": {
"reverse-ddns": {
"ddns-domains": [
{
"name": "1.0.0.0.8.B.D.0.1.0.0.2.ip6.arpa.",
"key-name": "",
"dns-servers": [
{
"ip-address": "172.88.99.10",
"port": 53
}
]
}
]
}
}
Note
Since hostname
is not yet supported, the parameter ip-address
must be set to the address of the DNS server.
13.3.5.2. Per-DNS-Server TSIG Keys
Since Kea version 2.0.0, a TSIG key can be specified in a DNS server configuration. The priority rule is:
if a not-empty key name is specified in a DNS server entry, this TSIG key protects DNS updates sent to this server.
if the DNS server entry is empty, but a not-empty key name is specified in the parent’s domain entry, the parent domain’s TSIG key protects DNS updates sent to this server.
if the DNS server entry is empty, and no key name is specified in its parent domain entry, no TSIG protects DNS updates sent to this server.
For instance, in this configuration:
"DhcpDdns": {
"forward-ddns": {
"ddns-domains": [
{
"name": "other.example.com.",
"key-name": "foo",
"dns-servers": [
{
"ip-address": "172.88.99.10",
"port": 53
},
{
"ip-address": "172.88.99.11",
"port": 53,
"key-name": "bar"
}
]
}
]
},
"reverse-ddns": {
"ddns-domains": [
{
"name": "1.0.0.0.8.B.D.0.1.0.0.2.ip6.arpa.",
"dns-servers": [
{
"ip-address": "172.88.99.12",
"port": 53
},
{
"ip-address": "172.88.99.13",
"port": 53,
"key-name": "bar"
}
]
}
]
},
"tsig-keys": [
{
"name": "foo",
"algorithm": "HMAC-MD5",
"secret": "LSWXnfkKZjdPJI5QxlpnfQ=="
},
{
"name": "bar",
"algorithm": "HMAC-SHA224",
"secret": "bZEG7Ow8OgAUPfLWV3aAUQ=="
}
]
}
The 172.88.99.10 server will use the “foo” TSIG key, the 172.88.99.11 and 172.88.99.13 servers will use the “bar” key. and 172.88.99.12 will not use TSIG.
13.3.6. User Contexts in DDNS
See Comments and User Context for additional background regarding the user context idea.
User contexts can be specified on a global scope, a DDNS domain, a DNS server, a TSIG key, and loggers. One other useful usage is the ability to store comments or descriptions; the parser translates a “comment” entry into a user context with the entry, which allows a comment to be attached inside the configuration itself.
13.3.7. Example DHCP-DDNS Server Configuration
This section provides a sample DHCP-DDNS server configuration, based on a small example network. Let’s suppose our example network has three domains, each with their own subnet.
Domain |
Subnet |
Forward DNS Servers |
Reverse DNS Servers |
---|---|---|---|
four.example.com |
192.0.2.0/24 |
172.16.1.5, 172.16.2.5 |
172.16.1.5, 172.16.2.5 |
six.example.com |
2001:db8:1::/64 |
3001:1::50 |
3001:1::51 |
example.com |
192.0.0.0/16 |
172.16.2.5 |
172.16.2.5 |
We need to construct three forward DDNS domains:
# |
DDNS Domain Name |
DNS Servers |
---|---|---|
four.example.com. |
172.16.1.5, 172.16.2.5 |
|
six.example.com. |
3001:1::50 |
|
example.com. |
172.16.2.5 |
As discussed earlier, FQDN-to-domain matching is based on the longest match. The FQDN “myhost.four.example.com.” matches the first domain (“four.example.com”), while “admin.example.com.” matches the third domain (“example.com”). The FQDN “other.example.net.” fails to match any domain and is rejected.
The following example configuration specifies the forward DDNS domains.
"DhcpDdns": {
"comment": "example configuration: forward part",
"forward-ddns": {
"ddns-domains": [
{
"name": "four.example.com.",
"key-name": "",
"dns-servers": [
{ "ip-address": "172.16.1.5" },
{ "ip-address": "172.16.2.5" }
]
},
{
"name": "six.example.com.",
"key-name": "",
"dns-servers": [
{ "ip-address": "2001:db8::1" }
]
},
{
"name": "example.com.",
"key-name": "",
"dns-servers": [
{ "ip-address": "172.16.2.5" }
],
"user-context": { "backup": false }
},
]
}
}
Similarly, we need to construct the three reverse DDNS domains:
# |
DDNS Domain Name |
DNS Servers |
---|---|---|
2.0.192.in-addr.arpa. |
172.16.1.5, 172.16.2.5 |
|
1.0.0.0.8.d.b.0.1.0.0.2.ip6.arpa. |
3001:1::50 |
|
0.182.in-addr.arpa. |
172.16.2.5 |
An address of “192.0.2.150” matches the first domain, “2001:db8:1::10” matches the second domain, and “192.0.50.77” matches the third domain.
These reverse DDNS domains are specified as follows:
"DhcpDdns": {
"comment": "example configuration: reverse part",
"reverse-ddns": {
"ddns-domains": [
{
"name": "2.0.192.in-addr.arpa.",
"key-name": "",
"dns-servers": [
{ "ip-address": "172.16.1.5" },
{ "ip-address": "172.16.2.5" }
]
}
{
"name": "1.0.0.0.8.B.D.0.1.0.0.2.ip6.arpa.",
"key-name": "",
"dns-servers": [
{ "ip-address": "2001:db8::1" }
]
}
{
"name": "0.192.in-addr.arpa.",
"key-name": "",
"dns-servers": [
{ "ip-address": "172.16.2.5" }
]
}
]
}
}
13.4. DHCP-DDNS Server Statistics
Kea version 2.0.0 introduced statistics support for DHCP-DDNS.
Statistics are divided into three groups: NameChangeRequests, DNS updates, and per-TSIG-key DNS updates. While the statistics of the first two groups are cumulative, i.e. not affected by configuration change or reload, per-key statistics are reset to 0 when the underlying object is (re)created.
Currently Kea’s statistics management has the following limitations:
only integer samples (i.e. a counter and a timestamp) are used;
the maximum sample count is 1;
there is no API to remove one or all statistics;
there is no API to set the maximum sample count or age.
Note
Hook libraries, such as the the ISC subscriber-only GSS-TSIG library, make new statistics available in Kea.
More information about Kea statistics can be found at Statistics.
13.4.1. NCR Statistics
The NameChangeRequest statistics are:
ncr-received
- the number of received valid NCRsncr-invalid
- the number of received invalid NCRsncr-error
- the number of errors in NCR receptions other than an I/O cancel on shutdown
13.4.2. DNS Update Statistics
The global DNS update statistics are:
update-sent
- the number of DNS updates sentupdate-signed
- the number of DNS updates sent and protected by TSIGupdate-unsigned
- the number of DNS updates sent and not protected by TSIGupdate-success
- the number of DNS updates which successfully completedupdate-timeout
- the number of DNS updates which completed on timeoutupdate-error
- the number of DNS updates which completed with an error other than timeout
13.4.3. Per-TSIG-Key DNS Update Statistics
The per TSIG key DNS update statistics are:
update-sent
- the number of DNS updates sentupdate-success
- the number of DNS updates which successfully completedupdate-timeout
- the number of DNS updates which completed on timeoutupdate-error
- the number of DNS updates which completed with an error other than timeout
The name format for per-key statistics is key[<key-DNS-name>].<stat-name>
:
for instance, the name of the update-sent
statistics for the
key.example.com.
TSIG key is key[key.example.com.].update-sent
.
13.5. DHCP-DDNS Server Limitations
The following are the current limitations of the DHCP-DDNS server.
Requests received from the DHCP servers are placed in a queue until they are processed. Currently, all queued requests are lost if the server shuts down.
13.6. Supported Standards
The following RFCs are supported by the DHCP-DDNS server:
Secret Key Transaction Authentication for DNS (TSIG), RFC 2845: All DNS update packets sent and received by the DHCP-DDNS server can be protected by TSIG signatures.
Dynamic Updates in the Domain Name System (DNS UPDATE), RFC 2136: The complete DNS update mechanism is supported.
Resolution of Fully Qualified Domain Name (FQDN) Conflicts among Dynamic Host Configuration Protocol (DHCP) Clients, RFC 4703: DHCP-DDNS takes care of conflict resolution, for both DHCPv4 and DHCPv6 servers.
A DNS Resource Record (RR) for Encoding Dynamic Host Configuration Protocol (DHCP) Information (DHCID RR), RFC 4701: The DHCP-DDNS server uses DHCID records.