This is the reference guide for Kea version 1.0.0-beta.
Copyright © 2010-2015 Internet Systems Consortium, Inc.
Abstract
Kea is an open source implementation of the Dynamic Host Configuration Protocol (DHCP) servers, developed and maintained by Internet Systems Consortium (ISC).
This is the reference guide for Kea version 1.0.0-beta. The most up-to-date version of this document (in PDF, HTML, and plain text formats), along with other documents for Kea, can be found at http://kea.isc.org/docs.
Table of Contents
List of Tables
Kea is the next generation of DHCP software developed by ISC. It supports both DHCPv4 and DHCPv6 protocols along with their extensions, e.g. prefix delegation and dynamic updates to DNS.
Kea was initially developed as a part of the BIND 10 framework. In early 2014, ISC made the decision to discontinue active development of BIND 10 and continue development of Kea as standalone DHCP software.
This guide covers Kea version 1.0.0-beta.
Kea is officially supported on RedHat Enterprise Linux, CentOS, Fedora and FreeBSD systems. It is also likely to work on many other platforms: builds have been tested on (in no particular order) Debian GNU/Linux 6 and unstable, Ubuntu 9.10, NetBSD 5, Solaris 10 and 11, FreeBSD 7 and 8, CentOS Linux 5.3, MacOS 10.6 and 10.7, and OpenBSD 5.1. Non supported systems (especially non-Linux) are likely to have issues with directly connected DHCPv4 clients.
There are currently no plans to port Kea to Windows platforms.
Running Kea uses various extra software which may not be provided in the default installation of some operating systems, nor in the standard package collections. You may need to install this required software separately. (For the build requirements, also see Section 3.3, “Building Requirements”.)
Kea is modular. Part of this modularity is accomplished using multiple cooperating processes which, together, provide the server functionality. The following software is included with Kea:
The tools and modules are covered in full detail in this guide. In addition, manual pages are also provided in the default installation.
Kea also provides C++ libraries and programmer interfaces for DHCP. These include detailed developer documentation and code examples.
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This quickly covers the standard steps for installing and deploying Kea. For further details, full customizations, and troubleshooting, see the respective chapters in the Kea guide.
Download Kea source tarball from ISC.org downloads page or ISC ftp server.
Extract the tarball. For example:
$ tar xvzf kea-1.0.0-beta.tar.gz
Go into the source directory and run the configure script:
$cd kea-1.0.0-beta
$./configure [your extra parameters]
Build it:
$ make
Install it (by default the installation prefix is /usr/local/
,
so you likely need root privileges for that step):
# make install
Edit the configuration file which by default is installed in
[kea-install-dir]/etc/kea/kea.conf
and contains
configuration for all Kea services. Configuration choices for DHCPv4
and DHCPv6 services are described in Section 7.2, “DHCPv4 Server Configuration” and Section 8.2, “DHCPv6 Server Configuration”, respectively.
In order to start the DHCPv4 server in background, run the following command (as root):
# keactrl start -s dhcp4
Or run the following command to start DHCPv6 server instead:
# keactrl start -s dhcp6
Note that it is also possible to start both servers simultaneously:
$ keactrl start
Verify that Kea server(s) are running:
# keactrl status
If the server status is "inactive" may indicate a configuration
error. Please check a log file (by default located in
[kea-install-dir]/var/kea/kea.log
) for the
details of the error.
If the server has been started sucessfully, test that it is responding to DHCP queries and that the client receives a configuration from the server; for example, use the ISC DHCP client.
Stop running server(s):
# keactrl stop
For more system specific installation procedures, you may want to visit System specific notes, available on Kea homepage.
The details of keactrl script usage can be found in Chapter 6, Managing Kea with keactrl.
Kea servers can be started directly (without a need to use keactrl). To start DHCPv4 server run the following commmand:
# kea-dhcp4 -c /path/to/your/kea4/config/file.json
And, to start the DHCPv6 server run the following command:
# kea-dhcp6 -c /path/to/your/kea6/config/file.json
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Some operating systems or software package vendors may provide ready-to-use, pre-built software packages for Kea. Installing a pre-built package means you do not need to install build-only prerequisites and do not need to make the software.
FreeBSD ports, NetBSD pkgsrc, and Debian testing package collections provide all the prerequisite packages.
The following is the directory layout of the complete Kea installation (all directories paths are relative to the installation directory):
etc/kea/
—
configuration files.
include/
—
C++ development header files.
lib/
—
libraries.
sbin/
—
server software and commands used by the system administrator.
share/kea/
—
configuration specifications and examples.
share/doc/kea/
—
this guide, other supplementary documentation, and examples.
share/man/
—
manual pages (online documentation).
var/kea/
—
server identification, lease databases, and log files.
In addition to the run-time requirements (listed in Section 1.2, “Required Software at Run-time”), building Kea from source code requires various development include headers and program development tools.
Some operating systems have split their distribution packages into a run-time and a development package. You will need to install the development package versions, which include header files and libraries, to build Kea from the source code.
Building from source code requires the following software installed on the system:
Boost build-time headers (http://www.boost.org/). At least Boost version 1.35 is required. When header-only Boost error code is not available or wanted, the Boost system library is required too.
Botan (at least version 1.8) or OpenSSL.
log4cplus (at least version 1.0.3) development include headers.
A C++ compiler and standard development headers. Kea builds have been tested with GCC g++ 3.4.3, 4.1.2, 4.1.3, 4.2.1, 4.3.2, and 4.4.1; Clang++ 2.8; and Sun C++ 5.10.
The development tools "make".
Visit the user-contributed wiki at http://kea.isc.org/wiki/SystemSpecificNotes for system-specific installation tips.
Kea is open source software written in C++. It is freely available in source code form from ISC as a downloadable tar file or via Kea Git code revision control service. (It may also be available in pre-compiled ready-to-use packages from operating system vendors.)
The Kea release tarballs may be downloaded from: http://ftp.isc.org/isc/kea/ (using FTP or HTTP).
Downloading this "bleeding edge" code is recommended only for developers or advanced users. Using development code in a production environment is not recommended.
When building from source code retrieved via Git, additional software will be required: automake (v1.11 or later), libtoolize, and autoconf (2.59 or later). These may need to be installed.
The latest development code (together with temporary experiments and un-reviewed code) is available via the Kea code revision control system. This is powered by Git and all the Kea development is public. The leading development is done in the “master” branch.
The code can be checked out from
git://git.kea.isc.org/kea
:
$ git clone git://git.kea.isc.org/kea
The code checked out from the git repository doesn't include the
generated configure script, Makefile.in files, nor their
related build files.
They can be created by running autoreconf
with the --install
switch.
This will run autoconf,
aclocal,
libtoolize,
autoheader,
automake,
and related commands.
Kea uses the GNU Build System to discover build environment details. To generate the makefiles using the defaults, simply run:
$ ./configure
Run ./configure with the --help
switch to view the different options. Some commonly-used options are:
/usr/local
).
-Werror
compiler flag so that
compiler warnings do not result in build failures.
For additional instructions concerning the building and installation of Kea for various databases, see Section 3.6, “DHCP Database Installation and Configuration”. For additional instructions concerning the configuration backends, see Section 3.5, “Selecting the Configuration Backend”.
For example, the following command configures Kea to find the Boost headers in /usr/pkg/include, specifies that PostgreSQL support should be enabled, and sets the installation location to /opt/kea:
$ ./configure \
--with-boost-include=/usr/pkg/include \
--with-dhcp-pgsql=/usr/local/bin/pg_config \
--prefix=/opt/kea
If you have some problems with building Kea using the header-only Boost error code or you'd like to use the Boost system library (e.g., located in /usr/pkg/lib):
$ ./configure \
--with-boost-libs=-lboost_system \
--with-boost-lib-dir=/usr/pkg/lib
If the configure fails, it may be due to missing or old dependencies.
./configure
when it succeeds displays a report
with the building parameters. This report is saved into
config.report
and embedded into executable
binaries, e.g., kea-dhcp4
.
After the configure step is complete, build the executables from the C++ code and prepare the Python scripts by running the command:
$ make
To install the Kea executables, support files, and documentation, issue the command:
$ make install
Do not use any form of parallel or job server options (such as GNU make's -j option) when performing this step: doing so may cause errors.
The install step may require superuser privileges.
If required, run ldconfig as root with
/usr/local/lib
(or with ${prefix}/lib if
configured with --prefix) in
/etc/ld.so.conf
(or the relevant linker
cache configuration file for your OS):
$ ldconfig
If you do not run ldconfig where it is required, you may see errors like the following:
program: error while loading shared libraries: libkea-something.so.1: cannot open shared object file: No such file or directory
Kea 0.9 has introduced configuration backends that are switchable during the compilation phase. Only one backend, JSON, is currently supported.
Kea stores its leases in a lease database. The software has been written in a way that makes it possible to choose which database product should be used to store the lease information. At present, Kea supports three database backends: MySQL, PostgreSQL and Memfile. To limit external dependencies, both MySQL and PostgreSQL support are disabled by default and only Memfile is available. Support for the optional external database backend must be explicitly included when Kea is built. This section covers the building of Kea with MySQL and/or PostgreSQL and the creation of the lease database.
Install MySQL according to the instructions for your system. The client development libraries must be installed.
Build and install Kea as described in Chapter 3, Installation, with the following modification. To enable the MySQL database code, at the "configure" step (see Section 3.4.3, “Configure before the build”), do:
./configure [other-options] --with-dhcp-mysql
Or specify the location of the MySQL configuration program "mysql_config" if MySQL was not installed in the default location:
./configure [other-options] --with-dhcp-mysql=path-to-mysql_config
See Section 4.3.2.1, “First Time Creation of Kea Database” for details regarding MySQL database configuration.
Install PostgreSQL according to the instructions for your system. The client development libraries must be installed. Client development libraries are often packaged as "libpq".
Build and install Kea as described in Chapter 3, Installation, with the following modification. To enable the PostgreSQL database code, at the "configure" step (see Section 3.4.3, “Configure before the build”), do:
./configure [other-options] --with-dhcp-pgsql
Or specify the location of the PostgreSQL configuration program "pg_config" if PostgreSQL was not installed in the default location:
./configure [other-options] --with-dhcp-pgsql=path-to-pg_config
See Section 4.3.3.1, “Manually Create the PostgreSQL Database and the Kea User” for details regarding PostgreSQL database configuration.
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Kea stores leases in one of several supported databases. As future versions of Kea are released, the structure of those databases will change. For example, Kea currently only stores lease information: in the future, additional data - such as host reservation details - will also be stored.
A given version of Kea expects a particular structure in the database. It ensures this by checking the version of the database it is using. Separate version numbers are maintained for backend databases, independent of the version of Kea itself. It is possible that the backend database version will stay the same through several Kea revisions. Likewise, it is possible that the version of backend database may go up several revisions during a Kea upgrade. Versions for each database are independent, so an increment in the MySQL database version does not imply an increment in that of PostgreSQL.
Backend versions are specified in
a major.minor
format. The minor
number is increased when there are backward compatibile changes
introduced. For example, the addition of a new index. It is
desirable, but not mandatory to to apply such a change; you
can run on older database version if you want to. (Although, in
the example given, running without the new index may be at the
expense of a performance penalty.) On the other hand, the major
number is increased when an incompatible change is introduced,
for example an extra column is added to a table. If you try to
run Kea software on a database that is too old (as signified by
mismatched backend major version number), Kea will refuse to run:
administrative action will be required to upgrade the database.
To manage the databases, Kea provides the kea-admin tool. It is able to initialize a new database, check its version number, perform a database upgrade, and dump lease data to a text file.
kea-admin takes two mandatory parameters: command and backend. Additional, non-mandatory options may be specified. Currently supported commands are:
backend specifies the backend type. Currently supported types are:
Additional parameters may be needed, depending on your setup and specific operation: username, password and database name or the directory where specific files are located. See appropriate manual page for details (man 8 kea-admin).
There are no special initialization steps necessary for the memfile backend. During the first run, both kea-dhcp4 and kea-dhcp6 will create an empty lease file if one is not present. Necessary disk write permission is required.
There are no special steps required to upgrade memfile lease files from an earlier version of Kea to a new version of Kea. During startup the servers will check the schema version of the lease files against their own. If there is a mismatch, the servers will automatically launch the LFC process to convert the files to the server's schema version. While this mechanism is primarily meant to ease the process of upgrading to newer versions of Kea, it can also be used for downgrading should the need arise. When upgrading, any values not present in the original lease files will be assigned appropriate default values. When downgrading, any data present in the files but not in the server's schema will be dropped. If you wish to convert the files manually, prior to starting the servers you may do so by running the LFC process yourself. See Chapter 11, The LFC process for more information.
The MySQL database must be properly set up if you want Kea to store information in MySQL. This section can be safely ignored if you chose to store the data in other backends.
If you are setting the MySQL database for the first time, you need to create the database area within MySQL and set up the MySQL user ID under which Kea will access the database. This needs to be done manually: kea-admin is not able to do this for you.
To create the database:
Log into MySQL as "root":
$ mysql -u root -p
Enter password:
mysql>
Create the MySQL database:
mysql> CREATE DATABASE database-name
;
(database-name
is the name
you have chosen for the database.)
Create the user under which Kea will access the database (and give it a password), then grant it access to the database tables:
mysql>CREATE USER '
mysql>user-name
'@'localhost' IDENTIFIED BY 'password
';GRANT ALL ON
database-name
.* TO 'user-name
'@'localhost';
(user-name
and
password
are the user ID
and password you are using to allow Keas access to the
MySQL instance. All apostrophes in the command lines
above are required.)
At this point, you may elect to create the database tables. (Alternatively, you can exit MySQL and create the tables using the kea-admin tool, as explained below.) To do this:
mysql>CONNECT
mysql>database-name
;SOURCE
path-to-kea
/share/kea/scripts/mysql/dhcpdb_create.mysql
(path-to-kea
is the
location where you installed Kea.)
Exit MySQL:
mysql> quit
Bye
$
If you elected not to create the tables in step 4, you can do so now by running the kea-admin tool:
$ kea-admin lease-init mysql -u database-user
-p database-password
-n database-name
(Do not do this if you did create the tables in step 4.) kea-admin implements rudimentary checks: it will refuse to initialize a database that contains any existing tables. If you want to start from scratch, you must remove all data manually. (This process is a manual operation on purpose to avoid possibly irretrievable mistakes by kea-admin.)
Sometimes a new Kea version may use newer database schema, so there will be a need to upgrade the existing database. This can be done using the kea-admin lease-upgrade command.
To check the current version of the database, use the following command:
$ kea-admin lease-version mysql -u database-user
-p database-password
-n database-name
(See Section 4.1, “Databases and Database Version Numbers” for a discussion about versioning.) If the version does not match the minimum required for the new version of Kea (as described in the release notes), the database needs to be upgraded.
Before upgrading, please make sure that the database is backed up. The upgrade process does not discard any data but, depending on the nature of the changes, it may be impossible to subsequently downgrade to an earlier version. To perform an upgrade, issue the following command:
$ kea-admin lease-upgrade mysql -u database-user
-p database-password
-n database-name
A PostgreSQL database must be set up if you want Kea to store lease and other information in PostgreSQL. This step can be safely ignored if you are using other database backends.
The first task is to create both the lease database and the user under which the servers will access it. A number of steps are required:
Log into PostgreSQL as "root":
$ sudo -u postgres psql postgres
Enter password:
postgres=#
Create the database:
postgres=# CREATE DATABASE database-name
;
CREATE DATABASE
postgres=#
(database-name
is the name
you have chosen for the database.)
Create the user under which Kea will access the database (and give it a password), then grant it access to the database:
postgres=#CREATE USER
CREATE ROLE postgres=# postgres=#user-name
WITH PASSWORD 'password
';GRANT ALL PRIVILEGES ON DATABASE
GRANT postgres=#database-name
TOuser-name
;
Exit PostgreSQL:
postgres=# \q
Bye
$
At this point you are ready to create the database tables. This can be done using the kea-admin tool as explained in the next section (recommended), or manually. To create the tables manually enter the following command. Note that PostgreSQL will prompt you to enter the new user's password you specified in Step 3. When the command completes you will be returned to the shell prompt. You should see output similar to following:
$psql -d
Password for userdatabase-name
-Uuser-name
-fpath-to-kea
/share/kea/scripts/pgsql/dhcpdb_create.pgsqluser-name
: CREATE TABLE CREATE INDEX CREATE INDEX CREATE TABLE CREATE INDEX CREATE TABLE START TRANSACTION INSERT 0 1 INSERT 0 1 INSERT 0 1 COMMIT CREATE TABLE START TRANSACTION INSERT 0 1 COMMIT $
(path-to-kea
is the location
where you installed Kea.)
If instead you encounter an error like:
psql: FATAL: no pg_hba.conf entry for host "[local]", user "user-name
", database "database-name
", SSL off
... you will need to alter the PostgreSQL configuration.
Kea uses password authentication when connecting to
the database and must have the appropriate entries
added to PostgreSQL's pg_hba.conf file. This file is
normally located in the primary data directory for your
PostgreSQL server. The precise path may vary but the
default location for PostgreSQL 9.3 on Centos 6.5 is:
/var/lib/pgsql/9.3/data/pg_hba.conf
.
Assuming Kea is running on the same host as PostgreSQL, adding lines similar to following should be sufficient to provide password-authenticated access to Kea's database:
localdatabase-name
user-name
password hostdatabase-name
user-name
127.0.0.1/32 password hostdatabase-name
user-name
::1/128 password
These edits are primarily intended as a starting point not a definitive reference on PostgreSQL administration or database security. Please consult your PostgreSQL user manual before making these changes as they may expose other databases that you run. It may be necessary to restart PostgreSQL in order for these changes to take effect.
If you elected not to create the tables manually, you can do so now by running the kea-admin tool:
$ kea-admin lease-init pgsql -u database-user
-p database-password
-n database-name
Do not do this if you already created the tables in manually. kea-admin implements rudimentary checks: it will refuse to initialize a database that contains any existing tables. If you want to start from scratch, you must remove all data manually. (This process is a manual operation on purpose to avoid possibly irretrievable mistakes by kea-admin.)
The lease expiration time is stored in the SQL database for each lease as a timestamp value. Kea developers observed that MySQL database doesn't accept timestamps beyond 2147483647 seconds (maximum signed 32-bit number) from the beginning of the epoch. At the same time, some versions of PostgreSQL do accept greater values but the value is altered when it is read back. For this reason the lease database backends put the restriction for the maximum timestamp to be stored in the database, which is equal to the maximum signed 32-bit number. This effectively means that the current Kea version can't store the leases which expiration time is later than 2147483647 seconds since the beginning of the epoch (around year 2038).
Kea is designed to allow different methods by which it can be configured, each method being implemented by a component known as a configuration backend. At present, only one such backend is available, that allowing configuration by means of a JSON file.
JSON is the default configuration backend.
It assumes that the servers are started from the command line
(either directly or using a script, e.g. keactrl
).
The JSON backend uses certain signals to influence Kea. The
configuration file is specified upon startup using the -c parameter.
Configuration files for DHCPv4, DHCPv6 and DDNS modules are defined in an extended JSON format. Basic JSON is defined in RFC 4627. Kea components use a slightly modified JSON, in that they allow shell-style comments in the file: lines with the hash (#) character in the first column are comment lines and are ignored.
The configuration file consists of a single object (often colloquially called a map) started with a curly bracket. It comprises the "Dhcp4", "Dhcp6", "DhcpDdns" and/or "Logging" objects. It is possible to define additional elements, but they will be ignored. For example, it is possible to define Dhcp4, Dhcp6 and Logging elements in a single configuration file that can be used to start both the DHCPv4 and DHCPv6 components. When starting, the DHCPv4 component will use Dhcp4 object to configure itself and the Logging object to configure logging parameters; it will ignore the Dhcp6 object.
For example, a very simple configuration for both DHCPv4 and DHCPv6 could look like this:
# The whole configuration starts here. { # DHCPv4 specific configuration starts here. "Dhcp4": { "interfaces-config": { "interfaces": [ "eth0" ], "dhcp-socket-type": "raw" }, "valid-lifetime": 4000, "renew-timer": 1000, "rebind-timer": 2000, "subnet4": [{ "pools": [ { "pool": "192.0.2.1-192.0.2.200" } ], "subnet": "192.0.2.0/24" }], ... }, # DHCPv4 specific configuration ends here. # DHCPv6 specific configuration starts here. "Dhcp6": { "interfaces-config": { "interfaces": [ "eth1" ] }, "preferred-lifetime": 3000, "valid-lifetime": 4000, "renew-timer": 1000, "rebind-timer": 2000, "subnet6": [{ "pools": [ { "pool": "2001:db8::/80" } ], "subnet": "2001:db8::/64" }], ... }, # DHCPv6 specific configuration ends here. # Logger parameters (that could be shared among several components) start here. # This section is used by both the DHCPv4 and DHCPv6 servers. "Logging": { "loggers": [{ "name": "*", "severity": "DEBUG" }], ... } # Logger parameters end here. # The whole configuration structure ends here. }
More examples are available in the installed
share/doc/kea/examples
directory.
To avoid repetition of mostly similar structures, examples in the rest of this guide will showcase only the subset of parameters appropriate for a given context. For example, when discussing the IPv6 subnets configuration in DHCPv6, only subnet6 parameters will be mentioned. It is implied that the remaining elements (the global map that holds Dhcp6, Logging and possibly DhcpDdns) are present, but they are omitted for clarity. Usually, locations where extra parameters may appear are denoted with an ellipsis.
It is sometimes convenient to refer to a specific element in the configuration hierarchy. Each hierarchy level is separated by a slash. If there is an array, a specific instance within that array is referenced by a number in square brackets (with numbering starting at zero). For example, in the above configuration the valid-lifetime in the Dhcp6 component can be referred to as Dhcp6/valid-lifetime and the pool in the first subnet defined in the DHCPv6 configuration as Dhcp6/subnet6[0]/pool.
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keactrl is a shell script which controls the startup, shutdown and reconfiguration of the Kea servers (kea-dhcp4, kea-dhcp6 and kea-dhcp-ddns). It also provides the means for checking the current status of the servers and determining the configuration files in use.
keactrl is run as follows:
keactrl <command> [-c keactrl-config-file] [-s server[,server,..]]
<command> is the one of the commands described in Section 6.4, “Commands”.
The optional -c keactrl-config-file switch
allows specification of an alternate keactrl
configuration file. (--ctrl-config is a synonym for
-c.) In the absence of -c,
keactrl will use the default configuration
file [kea-install-dir]/etc/kea/keactrl.conf
.
The optional -s server[,server ...] switch selects the servers to which the command is issued. (--server is a synonym for -s.) If absent, the command is sent to all servers enabled in the keactrl configuration file. If multiple servers are specified, they should be separated by commas with no intervening spaces.
Depending on requirements, not all of the available servers need
be run. The keactrl configuration file sets which servers are
enabled and which are disabled. The default configuration
file is [kea-install-dir]/etc/kea/keactrl.conf
,
but this can be overridden on a per-command basis using the
-c switch.
The contents of keactrl.conf
are:
# This is a configuration file for keactrl script which controls # the startup, shutdown, reconfiguration and gathering the status # of the Kea servers. # prefix holds the location where the Kea is installed. prefix=/usr/local # Location of Kea configuration file. kea_config_file=${prefix}/etc/kea/kea.conf # Location of Kea binaries. exec_prefix=${prefix} dhcp4_srv=${exec_prefix}/sbin/kea/kea-dhcp4 dhcp6_srv=${exec_prefix}/sbin/kea/kea-dhcp6 dhcp_ddns_srv=${exec_prefix}/sbin/kea/kea-dhcp-ddns # Start DHCPv4 server? dhcp4=yes # Start DHCPv6 server? dhcp6=yes # Start DHCP DDNS server? dhcp_ddns=yes # Be verbose? kea_verbose=no
The dhcp4
, dhcp6
and
dhcp_ddns
parameters set to "yes" configure
keactrl to manage (start, reconfigure) all servers,
i.e. kea-dhcp4, kea-dhcp6 and
kea-dhcp-ddns. When any of these parameters is set to
"no" the keactrl will ignore
the corresponding server when starting or reconfiguring Kea.
By default, Kea servers managed by keactrl are
located in [kea-install-dir]/sbin
. This
should work for most installations. If the default
location needs to be altered for any reason, the paths
specified with the dhcp4_srv
,
dhcp6_srv
and dhcp_ddns_srv
parameters should be modified.
The kea_verbose
parameter specifies the verbosity
of the servers being started. When kea_verbose
is set to "yes" the logging level of the server is set to DEBUG.
Otherwise, the default logging level is used.
The verbosity for the server is set when it is started. Once
started, the verbosity can be only changed by stopping the server and
starting it again with the new value of the
kea_verbose
parameter.
The following commands are supported by keactrl to perform specific operations on the Kea servers:
Typical output from keactrl when starting the servers looks similar to the following:
$ keactrl start
INFO/keactrl: Starting kea-dhcp4 -c /usr/local/etc/kea/kea.conf -d
INFO/keactrl: Starting kea-dhcp6 -c /usr/local/etc/kea/kea.conf -d
INFO/keactrl: Starting kea-dhcp-ddns -c /usr/local/etc/kea/kea.conf -d
Kea's servers create PID files upon startup. These files are used by keactrl to deteremine whether or not a given server is running. If one or more servers are running when the start command is issued, the output will look similiar to the following:
$ keactrl start
INFO/keactrl: kea-dhcp4 appears to be running, see: PID 10918, PID file: /usr/local/var/kea/kea.kea-dhcp4.pid.
INFO/keactrl: kea-dhcp6 appears to be running, see: PID 10924, PID file: /usr/local/var/kea/kea.kea-dhcp6.pid.
INFO/keactrl: kea-dhcp-ddns appears to be running, see: PID 10930, PID file: /usr/local/var/kea/kea.kea-dhcp-ddns.pid.
During normal shutdowns these PID files are deleted. They may, however, be left over as remnants following a system crash. It is possible, though highly unlikely, that upon system restart the PIDs they contain actually refer to processes unrelated to Kea. This condition will cause keactrl to decide that the servers are running, when in fact they are not. In such a case the PID files as listed in the keactrl output must be manually deleted.
The following command stops all servers:
$ keactrl stop
INFO/keactrl: Stopping kea-dhcp4...
INFO/keactrl: Stopping kea-dhcp6...
INFO/keactrl: Stopping kea-dhcp-ddns...
Note that the stop will attempt to stop all servers
regardless of whether they are "enabled" in the keactrl.conf
.
If any of the servers are not running, an informational message
is displayed as in the stop command output below.
$ keactrl stop
INFO/keactrl: kea-dhcp4 isn't running.
INFO/keactrl: kea-dhcp6 isn't running.
INFO/keactrl: kea-dhcp-ddns isn't running.
As already mentioned, the reconfiguration of each Kea server is triggered by the SIGHUP signal. The reload command sends the SIGHUP signal to the servers that are enabled in the keactrl configuration file and are currently running. When a server receives the SIGHUP signal it re-reads its configuration file and, if the new configuration is valid, uses the new configuration. A reload is executed as follows:
$ keactrl reload
INFO/keactrl: Reloading kea-dhcp4...
INFO/keactrl: Reloading kea-dhcp6...
INFO/keactrl: Reloading kea-dhcp-ddns...
If any of the servers are not running, an informational message is displayed as in the reload command output below.
$ keactrl stop
INFO/keactrl: kea-dhcp4 isn't running.
INFO/keactrl: kea-dhcp6 isn't running.
INFO/keactrl: kea-dhcp-ddns isn't running.
Currently keactrl does not report configuration failures when the server is started or reconfigured. To check if the server's configuration succeeded the Kea log must be examined for errors. By default, this is written to the syslog file.
Sometimes it is useful to check which servers are running. The status reports this, typical output looking like:
$ keactrl status
DHCPv4 server: active
DHCPv6 server: inactive
DHCP DDNS: active
Kea configuration file: /usr/local/etc/kea/kea.conf
keactrl configuration file: /usr/local/etc/kea/keactrl.conf
The optional -s switch allows the selection of the servers to which keactrl command is issued. For example, the following instructs keactrl to stop the kea-dhcp4 and kea-dhcp6 servers and leave the kea-dhcp-ddns server running:
$ keactrl stop -s dhcp4,dhcp6
Similarly, the following will only start the kea-dhcp4 and kea-dhcp-ddns servers and not kea-dhcp6.
$ keactrl start -s dhcp4,dhcp_ddns
Note that the behavior of the -s switch with the start and reload commands is different to its behavior with the stop command. On start and reload, keactrl will check if the servers given as parameters to the -s switch are enabled in the keactrl configuration file: if not, the server will be ignored. For stop however, this check is not made: the command is applied to all listed servers, regardless of whether they have been enabled in the file.
The following keywords can be used with the -s command line option:
Table of Contents
It is recommended that the Kea DHCPv4 server be started and stopped using keactrl (described in Chapter 6, Managing Kea with keactrl). However, it is also possible to run the server directly: it accepts the following command-line switches:
file
-
specifies the configuration file. This is the only mandatory
switch.port
-
specifies UDP port the server will listen on. This is only
useful during testing, as the DHCPv4 server listening on
ports other than default DHCPv4 ports will not be able to
handle regular DHCPv4 queries.The -V command returns the versions of the external libraries dynamically linked.
The -W command describes the environment used
to build Kea. This command displays a copy of the
config.report
file produced by
./configure
that is embedded in the
executable binary.
The config.report
may also be accessed more
directly. The following command may be used to extract this
information. The binary path
may be found
in the install directory or in the .libs
subdirectory in the source treee. For example
kea/src/bin/dhcp4/.libs/kea-dhcp4
.
strings path
/kea-dhcp4 | sed -n 's/;;;; //p'
When running in a console, the server can be shut down by pressing ctrl-c. It detects the key combination and shuts down gracefully.
On start-up, the server will detect available network interfaces and will attempt to open UDP sockets on all interfaces mentioned in the configuration file.
Since the DHCPv4 server opens privileged ports, it requires root access. Make sure you run this daemon as root.
During startup the server will attempt to create a PID file of the form: [localstatedir]/[conf name].kea-dhcp4.pid where:
If the file already exists and contains the PID of a live process, the server will issue a DHCP4_ALREADY_RUNNING log message and exit. 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 would be necessary to manually delete the PID file.
This section explains how to configure the DHCPv4 server using the Kea configuration backend. (Kea configuration using any other backends is outside of scope of this document.) Before DHCPv4 is started, its configuration file has to be created. The basic configuration is as follows:
{ # DHCPv4 configuration starts in this line "Dhcp4": { # First we set up global values "valid-lifetime": 4000, "renew-timer": 1000, "rebind-timer": 2000, # Next we setup the interfaces to be used by the server. "interfaces-config": { "interfaces": [ "eth0" ] }, # And we specify the type of lease database "lease-database": { "type": "memfile", "persist": true, "name": "/var/kea/dhcp4.leases" }, # Finally, we list the subnets from which we will be leasing addresses. "subnet4": [ { "subnet": "192.0.2.0/24", "pools": [ { "pool": "192.0.2.1 - 192.0.2.200" } ] } ] # DHCPv4 configuration ends with this line } }
The following paragraphs provide a brief overview of the parameters in the above example and their format. Subsequent sections of this chapter go into much greater detail for these and other parameters.
The lines starting with a hash (#) are comments and are ignored by the server; they do not impact its operation in any way.
The configuration starts in the first line with the initial opening curly bracket (or brace). Each configuration consists of one or more objects. In this specific example, we have only one object called Dhcp4. This is a simplified configuration, as usually there will be additional objects, like Logging or DhcpDns, but we omit them now for clarity. The Dhcp4 configuration starts with the "Dhcp4": { line and ends with the corresponding closing brace (in the above example, the brace after the last comment). Everything defined between those lines is considered to be the Dhcp4 configuration.
In the general case, the order in which those parameters appear does not matter. There are two caveats here though. The first one is to remember that the configuration file must be well formed JSON. That means that the parameters for any given scope must be separated by a comma and there must not be a comma after the last parameter. When reordering a configuration file, keep in mind that moving a parameter to or from the last position in a given scope may also require moving the comma. The second caveat is that it is uncommon — although legal JSON — to repeat the same parameter multiple times. If that happens, the last occurrence of a given parameter in a given scope is used while all previous instances are ignored. This is unlikely to cause any confusion as there are no real life reasons to keep multiple copies of the same parameter in your configuration file.
Moving onto the DHCPv4 configuration elements, the very first few elements define some global parameters. valid-lifetime defines for how long the addresses (leases) given out by the server are valid. If nothing changes, a client that got an address is allowed to use it for 4000 seconds. (Note that integer numbers are specified as is, without any quotes around them.) renew-timer and rebind-timer are values that define T1 and T2 timers that govern when the client will begin the renewal and rebind procedures. Note that renew-timer and rebind-timer are optional. If they are not specified the client will select values for T1 and T2 timers according to the RFC 2131.
The interfaces-config map specifies the server configuration concerning the network interfaces, on which the server should listen to the DHCP messages. The interfaces parameter specifies a list of network interfaces on which the server should listen. Lists are opened and closed with square brackets, with elements separated by commas. Had we wanted to listen on two interfaces, the interfaces-config would look like this:
"interfaces-config": { "interfaces": [ "eth0", "eth1" ] },
The next couple of lines define the lease database, the place where the server stores its lease information. This particular example tells the server to use memfile, which is the simplest (and fastest) database backend. It uses an in-memory database and stores leases on disk in a CSV file. This is a very simple configuration. Usually, lease database configuration is more extensive and contains additional parameters. Note that lease-database is an object and opens up a new scope, using an opening brace. Its parameters (just one in this example -- type) follow. Had there been more than one, they would be separated by commas. This scope is closed with a closing brace. As more parameters follow, a trailing comma is present.
Finally, we need to define a list of IPv4 subnets. This is the most important DHCPv4 configuration structure as the server uses that information to process clients' requests. It defines all subnets from which the server is expected to receive DHCP requests. The subnets are specified with the subnet4 parameter. It is a list, so it starts and ends with square brackets. Each subnet definition in the list has several attributes associated with it, so it is a structure and is opened and closed with braces. At a minimum, a subnet definition has to have at least two parameters: subnet (that defines the whole subnet) and pools (which is a list of dynamically allocated pools that are governed by the DHCP server).
The example contains a single subnet. Had more than one been defined, additional elements in the subnet4 parameter would be specified and separated by commas. For example, to define three subnets, the following syntax would be used:
"subnet4": [ { "pools": [ { "pool": "192.0.2.1 - 192.0.2.200" } ], "subnet": "192.0.2.0/24" }, { "pools": [ { "pool": "192.0.3.100 - 192.0.3.200" } ], "subnet": "192.0.3.0/24" }, { "pools": [ { "pool": "192.0.4.1 - 192.0.4.254" } ], "subnet": "192.0.4.0/24" } ]
After all parameters are specified, we have two contexts open: global and Dhcp4, hence we need two closing curly brackets to close them. In a real life configuration file there most likely would be additional components defined such as Logging or DhcpDdns, so the closing brace would be followed by a comma and another object definition.
All leases issued by the server are stored in the lease database. Currently there are three database backends available: memfile (which is the default backend), MySQL and PostgreSQL.
The server is able to store lease data in different repositories. Larger deployments may elect to store leases in a database. Section 7.2.2.2, “Lease Database Configuration” describes this option. In typical smaller deployments though, the server will use a CSV file rather than a database to store lease information. As well as requiring less administration, an advantage of using a file for storage is that it eliminates a dependency on third-party database software.
The configuration of the file backend (Memfile) is controlled through
the Dhcp4/lease-database parameters. The type parameter
is mandatory and it specifies which storage for leases the server should use.
The value of "memfile"
indicates that the file should
be used as the storage. The following list presents the remaining, not mandatory
parameters, which can be used to configure the Memfile backend.
true
at all times, during the server's normal
operation. Not writing leases to disk will mean that if a server is restarted
(e.g. after a power failure), it will not know what addresses have been
assigned. As a result, it may hand out addresses to new clients that are
already in use. The value of false
is mostly useful
for performance testing purposes. The default value of the
persist parameter is true
,
which enables writing lease updates
to the lease file.
"[kea-install-dir]/var/kea/kea-leases4.csv"
.0
, which disables
the LFC.
The example configuration of the Memfile backend is presented below:
"Dhcp4": { "lease-database": {"type": "memfile"
,"persist": true
,"name": "/tmp/kea-leases4.csv",
"lfc-interval": 1800
} }
This configuration selects the /tmp/kea-leases4.csv
as
the storage for lease information and enables persistence (writing lease updates
to this file). It also configures the backend perform the periodic cleanup
of the lease files, executed every 30 minutes.
It is important to know how the lease file contents are organized to understand why the periodic lease file cleanup is needed. Every time when the server updates a lease or creates a new lease for the client, the new lease information must be recorded in the lease file. For performance reasons, the server does not supersede the existing client's lease, as it would require the lookup of the specific lease entry, but simply appends the new lease information at the end of the lease file. The previous lease entries for the client are not removed. When the server loads leases from the lease file, e.g. at the server startup, it assumes that the latest lease entry for the client is the valid one. The previous entries are discarded. This means that the server can re-construct the accurate information about the leases even though there may be many lease entries for each client. However, storing many entries for each client results in bloated lease file and impairs the performance of the server's startup and reconfiguration, as it needs to process larger number of lease entries.
The lease file cleanup removes all previous entries for each client and leaves only the latest ones. The interval at which the cleanup is performed is configurable, and it should be selected according to the frequency of lease renewals initiated by the clients. The more frequent renewals are, the lesser value of the lfc-interval should be. Note however, that the LFC takes time and thus it is possible (although unlikely) that new cleanup is started while the previous cleanup instance is still running, if the lfc-interval is too short. The server would recover from this by skipping the new cleanup when it detects that the previous cleanup is still in progress. But, this implies that the actual cleanups will be triggered more rarely than configured. Moreover, triggering a new cleanup adds an overhead to the server, which will not be able to respond to new requests for a short period of time when the new cleanup process is spawned. Therefore, it is recommended that the lfc-interval value is selected in a way that would allow for completing the cleanup before the new cleanup is triggered.
The LFC is performed by a separate process (in background) to avoid performance impact on the server process. In order to avoid the conflicts between the two processes both using the same lease files, the LFC process operates on the copy of the original lease file, rather than on the lease file used by the server to record lease updates. There are also other files being created as a side effect of the lease file cleanup. The detailed description of the LFC is located on the Kea wiki: http://kea.isc.org/wiki/LFCDesign.
Lease database access information must be configured for the DHCPv4 server, even if it has already been configured for the DHCPv6 server. The servers store their information independently, so each server can use a separate database or both servers can use the same database.
Lease database configuration is controlled through the Dhcp4/lease-database parameters. The type of the database must be set to "memfile", "mysql" or "postgresql", e.g.
"Dhcp4": { "lease-database": { "type": "mysql"
, ... }, ... }
Next, the name of the database to hold the leases must be set: this is the name used when the lease database was created (see Section 4.3.2.1, “First Time Creation of Kea Database” or Section 4.3.3.1, “Manually Create the PostgreSQL Database and the Kea User”).
"Dhcp4": { "lease-database": { "name": "database-name
"
, ... }, ... }
If the database is located on a different system to the DHCPv4 server, the database host name must also be specified (although it should be noted that this configuration may have a severe impact on server performance):
"Dhcp4": { "lease-database": { "host": remote-host-name
, ... }, ... }
The usual state of affairs will be to have the database on the same machine as the DHCPv4 server. In this case, set the value to the empty string:
"Dhcp4": { "lease-database": { "host" : ""
, ... }, ... }
Finally, the credentials of the account under which the server will access the database should be set:
"Dhcp4": { "lease-database": {"user": "
,user-name
""password": "
, ... }, ... }password
"
If there is no password to the account, set the password to the empty string "". (This is also the default.)
This feature did not undergo the regular system level testing conducted by ISC. As such, please treat it as experimental.
Kea is also able to store information about host reservations in the database. Hosts database configuration uses the same syntax as lease database. In fact, Kea server opens independent connections for each purpose, be it lease or hosts information. This gives the solution most flexibility. Kea can be used to keep leases and host reservations separately, but can also point to the same database. Currently the only supported hosts database type is MySQL.
Please note that usage of hosts storage is optional. User can define all host reservations in the configuration file. That is the recommended way if the number of reservations is small. However, with the number of reservations growing it's more convenient to use host storage. Please note that both storages (configuration file and MySQL) can be used together. If hosts are defined in both places, the definitions from configuration file are checked first and external storage is checked later, if necessary.
All hosts leases issued by the server are stored in the hosts database. Currently there is only one available backend: MySQL. Other host backends will become available in future Kea versions.
Hosts database configuration is controlled through the Dhcp4/hosts-database parameters. If enabled, the type of the database must be set to "mysql". Other hosts backends may be added in later Kea versions.
"Dhcp4": { "hosts-database": { "type": "mysql"
, ... }, ... }
Next, the name of the database to hold the leases must be set: this is the name used when the lease database was created (see Section 4.3.2.1, “First Time Creation of Kea Database”).
"Dhcp4": { "hosts-database": { "name": "database-name
"
, ... }, ... }
If the database is located on a different system to the DHCPv4 server, the database host name must also be specified (although it should be noted that this configuration may have a severe impact on server performance):
"Dhcp4": { "hosts-database": { "host": remote-host-name
, ... }, ... }
The usual state of affairs will be to have the database on the same machine as the DHCPv4 server. In this case, set the value to the empty string:
"Dhcp4": { "hosts-database": { "host" : ""
, ... }, ... }
Finally, the credentials of the account under which the server will access the database should be set:
"Dhcp4": { "hosts-database": {"user": "
,user-name
""password": "
, ... }, ... }password
"
If there is no password to the account, set the password to the empty string "". (This is also the default.)
The DHCPv4 server has to be configured to listen on specific network interfaces. The simplest network interface configuration tells the server to listen on all available interfaces:
"Dhcp4": {
"interfaces-config": {
"interfaces": [ "*"
]
}
...
},
The asterisk plays the role of a wildcard and means "listen on all interfaces". However, it is usually a good idea to explicitly specify interface names:
"Dhcp4": {
"interfaces-config": {
"interfaces": [ "eth1", "eth3"
]
},
...
}
It is possible to use wildcard interface name (asterisk) concurrently with explicit interface names:
"Dhcp4": {
"interfaces-config": {
"interfaces": [ "eth1", "eth3", "*"
]
},
...
}
It is anticipated that this form of usage will only be used when it is desired to temporarily override a list of interface names and listen on all interfaces.
Some deployments of the DHCP servers require that the servers listen on the interfaces with multiple IPv4 addresses configured. In these situations, the address to use can be selected by appending an IPv4 address to the interface name in the following manner:
"Dhcp4": {
"interfaces-config": {
"interfaces": [ "eth1/10.0.0.1", "eth3/192.0.2.3"
]
},
...
}
If it is desired that the server listens on multiple IPv4 addresses assigned to the same interface, multiple addresses can be specified for this interface as in the example below:
"Dhcp4": {
"interfaces-config": {
"interfaces": [ "eth1/10.0.0.1", "eth1/10.0.0.2"
]
},
...
}
Alternatively, if the server should listen on all addresses for the particular interface, an interface name without any address should be specified.
Kea supports responding to directly connected clients which don't have an address configured on the interface yet. This requires that the server injects the hardware address of the destination into the data link layer of the packet being sent to the client. The DHCPv4 server utilizes the raw sockets to achieve this, and builds the entire IP/UDP stack for the outgoing packets. The down side of raw socket use, however, is that incoming and outgoing packets bypass the firewalls (e.g. iptables). It is also troublesome to handle traffic on multiple IPv4 addresses assigned to the same interface, as raw sockets are bound to the interface and advanced packet filtering techniques (e.g. using the BPF) have to be used to receive unicast traffic on the desired addresses assigned to the interface, rather than capturing whole traffic reaching the interface to which the raw socket is bound. Therefore, in the deployments where the server doesn't have to provision the directly connected clients and only receives the unicast packets from the relay agents, it is desired to configure the DHCP server to utilize the IP/UDP datagram sockets, instead of raw sockets. The following configuration demonstrates how this can be achieved:
"Dhcp4": {
"interfaces-config": {
"interfaces": [ "eth1", "eth3"
],
"dhcp-socket-type": "udp"
},
...
}
The dhcp-socket-type specifies that the IP/UDP sockets will
be opened on all interfaces on which the server listens, i.e. "eth1" and
"eth3" in our case. If the dhcp-socket-type is set to
raw
, it configures the server to use raw sockets
instead. If the dhcp-socket-type value is not specified, the
default value raw
is used.
Using UDP sockets automatically disables the reception of brodcast packets from directly connected clients. This effectively means that the UDP sockets can be used for relayed traffic only. When using the raw sockets, both the traffic from the directly connected clients and the relayed traffic will be handled. Caution should be taken when configuring the server to open multiple raw sockets on the interface with several IPv4 addresses assigned. If the directly connected client sends the message to the brodcast address all sockets on this link will receive this message and multiple responses will be sent to the client. Hence, the configuration with multiple IPv4 addresses assigned to the interface should not be used when the directly connected clients are operating on that link. To use a single address on such interface, the "interface-name/address" notation should be used.
Specifying the value raw
as the socket type,
doesn't guarantee that the raw sockets will be used! The use of raw sockets
to handle the traffic from the directly connected clients is currently
supported on Linux and BSD systems only. If the raw sockets are not
supported on the particular OS, the server will issue a warning and
fall back to use the IP/UDP sockets.
The use of UDP sockets has certain benefits in deployments where the server receives only relayed traffic. These benefits are mentioned in the Section 7.2.4, “Interface configuration”. From the administrator's perspective it is often desired to be able to configure the system's firewall to filter out the unwanted traffic, and the use of UDP sockets faciliates it. However, the administrator must also be aware of the implications related to filtering certain types of traffic as it may impair the DHCP server's operation.
In this section we are focusing on the case when the server receives the DHCPINFORM message from the client via a relay. According to the RFC 2131, the server should unicast the DHCPACK response to the address carried in the 'ciaddr' field. When the UDP socket is in use, the DHCP server relies on the low level functions of an operating system to build the data link, IP and UDP layers of the outgoing message. Typically, the OS will first use ARP to obtain the client's link layer address to be inserted into the frame's header, if the address is not cached from a previous transaction that the client had with the server. When the ARP exchange is successful, the DHCP message can be unicast to the client, using the obtained address.
Some system administrators block ARP messages in their network, which causes issues for the server when it responds to the DHCPINFORM messages, because the server is unable to send the DHCPACK if the preceding ARP communication fails. Since the OS is entirely responsible for the ARP communication and then sending the DHCP packet over the wire, the DHCP server has no means to determine that the ARP exchange failed and the DHCP response message was dropped. Thus, the server does not log any error messages when the outgoing DHCP response is dropped. At the same time, all hooks pertaining to the packet sending operation will be called, even though the message never reaches its destination.
Note that the issue described in this section is not observed when the raw sockets are in use, because, in this case, the DHCP server builds all the layers of the outgoing message on its own and does not use ARP. Instead, it inserts the value carried in the 'chaddr' field of the DHCPINFORM message into the link layer.
Server administrators willing to support DHCPINFORM messages via relays should not block ARP traffic in their networks or should use raw sockets instead of UDP sockets.
The subnet identifier is a unique number associated with a particular subnet. In principle, it is used to associate clients' leases with their respective subnets. When a subnet identifier is not specified for a subnet being configured, it will be automatically assigned by the configuration mechanism. The identifiers are assigned from 1 and are monotonically increased for each subsequent subnet: 1, 2, 3 ....
If there are multiple subnets configured with auto-generated identifiers and one of them is removed, the subnet identifiers may be renumbered. For example: if there are four subnets and the third is removed the last subnet will be assigned the identifier that the third subnet had before removal. As a result, the leases stored in the lease database for subnet 3 are now associated with subnet 4, something that may have unexpected consequences. It is planned to implement a mechanism to preserve auto-generated subnet ids in a future version of Kea. However, the only remedy for this issue at present is to manually specify a unique identifier for each subnet.
The following configuration will assign the specified subnet identifier to the newly configured subnet:
"Dhcp4": {
"subnet4": [
{
"subnet": "192.0.2.0/24",
"id": 1024
,
...
}
]
}
This identifier will not change for this subnet unless the "id" parameter is removed or set to 0. The value of 0 forces auto-generation of the subnet identifier.
The essential role of DHCPv4 server is address assignment. The server has to be configured with at least one subnet and one pool of dynamic addresses to be managed. For example, assume that the server is connected to a network segment that uses the 192.0.2.0/24 prefix. The Administrator of that network has decided that addresses from range 192.0.2.10 to 192.0.2.20 are going to be managed by the Dhcp4 server. Such a configuration can be achieved in the following way:
"Dhcp4": {
"subnet4": [
{
"subnet": "192.0.2.0/24",
"pools": [
{ "pool": "192.0.2.10 - 192.0.2.20" }
],
...
}
]
}
Note that subnet is defined as a simple string, but the pools parameter is actually a list of pools: for this reason, the pools definition is enclosed in square brackets, even though only one range of addresses is specified in this example.
Each pool is a structure that contains the parameters that describe a single pool. Currently there is only one parameter, pool, which gives the range of addresses in the pool. Additional parameters will be added in future releases of Kea.
It is possible to define more than one pool in a subnet: continuing the previous example, further assume that 192.0.2.64/26 should be also be managed by the server. It could be written as 192.0.2.64 to 192.0.2.127. Alternatively, it can be expressed more simply as 192.0.2.64/26. Both formats are supported by Dhcp4 and can be mixed in the pool list. For example, one could define the following pools:
"Dhcp4": {
"subnet4": [
{
"subnet": "192.0.2.0/24",
"pools": [
{ "pool": "192.0.2.10-192.0.2.20" },
{ "pool": "192.0.2.64/26" }
]
,
...
}
],
...
}
The number of pools is not limited, but for performance reasons it is recommended to use as few as possible. White space in pool definitions is ignored, so spaces before and after the hyphen are optional. They can be used to improve readability.
The server may be configured to serve more than one subnet:
"Dhcp4": { "subnet4": [ { "subnet": "192.0.2.0/24", "pools": [ { "pool": "192.0.2.1 - 192.0.2.200" } ], ... }, { "subnet": "192.0.3.0/24", "pools": [ { "pool": "192.0.3.100 - 192.0.3.200" } ], ... }, { "subnet": "192.0.4.0/24", "pools": [ { "pool": "192.0.4.1 - 192.0.4.254" } ], ... } ] }
When configuring a DHCPv4 server using prefix/length notation, please pay attention to the boundary values. When specifying that the server can use a given pool, it will also be able to allocate the first (typically network address) and the last (typically broadcast address) address from that pool. In the aforementioned example of pool 192.0.3.0/24, both 192.0.3.0 and 192.0.3.255 addresses may be assigned as well. This may be invalid in some network configurations. If you want to avoid this, please use the "min-max" notation.
One of the major features of the DHCPv4 server is to provide configuration options to clients. Most of the options are sent by the server, only if the client explicitly requests them using the Parameter Request List option. Those that do not require being requested using the Parameter Request List option are commonly used options, e.g. "Domain Server", and options which require special behavior, e.g. "Client FQDN" is returned to the client if the client has included this option in its message to the server.
The Table 7.1, “List of standard DHCPv4 options” comprises the list of the standard DHCPv4 options, whose values can be configured using the configuration structures described in this section. This table excludes the options which require special processing and thus cannot be configured with some fixed values. The last column of this table specifies which options can be sent by the server even when they are not requested in the Parameter Request list option, and which are sent only when explicitly requested. These options are marked with the values 'true' and 'false' respectively.
The following example shows how to configure the addresses of DNS servers, which is one of the most frequently used options. Options specified in this way are considered global and apply to all configured subnets.
"Dhcp4": {
"option-data": [
{
"name": "domain-name-servers",
"code": 6,
"space": "dhcp4",
"csv-format": true,
"data": "192.0.2.1, 192.0.2.2"
},
...
]
}
The name parameter specifies the option name. For a list of currently supported names, see Table 7.1, “List of standard DHCPv4 options” below. The code parameter specifies the option code, which must match one of the values from that list. The next line specifies the option space, which must always be set to "dhcp4" as these are standard DHCPv4 options. For other option spaces, including custom option spaces, see Section 7.2.11, “Nested DHCPv4 Options (Custom Option Spaces)”. The next line specifies the format in which the data will be entered: use of CSV (comma separated values) is recommended. The sixth line gives the actual value to be sent to clients. Data is specified as normal text, with values separated by commas if more than one value is allowed.
Options can also be configured as hexadecimal values. If csv-format is set to false, option data must be specified as a hexadecimal string. The following commands configure the domain-name-servers option for all subnets with the following addresses: 192.0.3.1 and 192.0.3.2. Note that csv-format is set to false.
"Dhcp4": {
"option-data": [
{
"name": "domain-name-servers",
"code": 6,
"space": "dhcp4",
"csv-format": false,
"data": "C0 00 03 01 C0 00 03 02"
},
...
],
...
}
Most of the parameters in the "option-data" structure are optional and can be omitted in some circumstances as discussed in the Section 7.2.12, “Unspecified parameters for DHCPv4 option configuration”.
It is possible to specify or override options on a per-subnet basis. If clients connected to most of your subnets are expected to get the same values of a given option, you should use global options: you can then override specific values for a small number of subnets. On the other hand, if you use different values in each subnet, it does not make sense to specify global option values (Dhcp4/option-data), rather you should set only subnet-specific values (Dhcp4/subnet[X]/option-data[Y]).
The following commands override the global DNS servers option for a particular subnet, setting a single DNS server with address 192.0.2.3.
"Dhcp4": {
"subnet4": [
{
"option-data": [
{
"name": "domain-name-servers",
"code": 6,
"space": "dhcp4",
"csv-format": true,
"data": "192.0.2.3"
},
...
]
,
...
},
...
],
...
}
The currently supported standard DHCPv4 options are listed in Table 7.1, “List of standard DHCPv4 options” and Table 7.2, “List of standard DHCPv4 options (continued)”. The "Name" and "Code" are the values that should be used as a name in the option-data structures. "Type" designates the format of the data: the meanings of the various types is given in Table 7.3, “List of standard DHCP option types”.
Some options are designated as arrays, which means that more than one value is allowed in such an option. For example the option time-servers allows the specification of more than one IPv4 address, so allowing clients to obtain the addresses of multiple NTP servers.
The Section 7.2.9, “Custom DHCPv4 options” describes the configuration syntax to create custom option definitions (formats). It is generally not allowed to create custom definitions for standard options, even if the definition being created matches the actual option format defined in the RFCs. There is an exception from this rule for standard options for which Kea does not provide a definition yet. In order to use such options, a server administrator must create a definition as described in Section 7.2.9, “Custom DHCPv4 options” in the 'dhcp4' option space. This definition should match the option format described in the relevant RFC but the configuration mechanism will allow any option format as it has no means to validate the format at the moment.
Table 7.1. List of standard DHCPv4 options
Name | Code | Type | Array? | Returned if not requested? |
---|---|---|---|---|
time-offset | 2 | int32 | false | false |
routers | 3 | ipv4-address | true | true |
time-servers | 4 | ipv4-address | true | false |
name-servers | 5 | ipv4-address | true | false |
domain-name-servers | 6 | ipv4-address | true | true |
log-servers | 7 | ipv4-address | true | false |
cookie-servers | 8 | ipv4-address | true | false |
lpr-servers | 9 | ipv4-address | true | false |
impress-servers | 10 | ipv4-address | true | false |
resource-location-servers | 11 | ipv4-address | true | false |
boot-size | 13 | uint16 | false | false |
merit-dump | 14 | string | false | false |
domain-name | 15 | fqdn | false | true |
swap-server | 16 | ipv4-address | false | false |
root-path | 17 | string | false | false |
extensions-path | 18 | string | false | false |
ip-forwarding | 19 | boolean | false | false |
non-local-source-routing | 20 | boolean | false | false |
policy-filter | 21 | ipv4-address | true | false |
max-dgram-reassembly | 22 | uint16 | false | false |
default-ip-ttl | 23 | uint8 | false | false |
path-mtu-aging-timeout | 24 | uint32 | false | false |
path-mtu-plateau-table | 25 | uint16 | true | false |
interface-mtu | 26 | uint16 | false | false |
all-subnets-local | 27 | boolean | false | false |
broadcast-address | 28 | ipv4-address | false | false |
perform-mask-discovery | 29 | boolean | false | false |
mask-supplier | 30 | boolean | false | false |
router-discovery | 31 | boolean | false | false |
router-solicitation-address | 32 | ipv4-address | false | false |
static-routes | 33 | ipv4-address | true | false |
trailer-encapsulation | 34 | boolean | false | false |
arp-cache-timeout | 35 | uint32 | false | false |
ieee802-3-encapsulation | 36 | boolean | false | false |
default-tcp-ttl | 37 | uint8 | false | false |
tcp-keepalive-interval | 38 | uint32 | false | false |
tcp-keepalive-garbage | 39 | boolean | false | false |
Table 7.2. List of standard DHCPv4 options (continued)
Name | Code | Type | Array? | Returned if not requested? |
---|---|---|---|---|
nis-domain | 40 | string | false | false |
nis-servers | 41 | ipv4-address | true | false |
ntp-servers | 42 | ipv4-address | true | false |
vendor-encapsulated-options | 43 | empty | false | false |
netbios-name-servers | 44 | ipv4-address | true | false |
netbios-dd-server | 45 | ipv4-address | true | false |
netbios-node-type | 46 | uint8 | false | false |
netbios-scope | 47 | string | false | false |
font-servers | 48 | ipv4-address | true | false |
x-display-manager | 49 | ipv4-address | true | false |
dhcp-option-overload | 52 | uint8 | false | false |
dhcp-message | 56 | string | false | false |
dhcp-max-message-size | 57 | uint16 | false | false |
vendor-class-identifier | 60 | binary | false | false |
nwip-domain-name | 62 | string | false | false |
nwip-suboptions | 63 | binary | false | false |
tftp-server-name | 66 | string | false | false |
boot-file-name | 67 | string | false | false |
user-class | 77 | binary | false | false |
client-system | 93 | uint16 | true | false |
client-ndi | 94 | record (uint8, uint8, uint8) | false | false |
uuid-guid | 97 | record (uint8, binary) | false | false |
subnet-selection | 118 | ipv4-address | false | false |
domain-search | 119 | binary | false | false |
vivco-suboptions | 124 | binary | false | false |
vivso-suboptions | 125 | binary | false | false |
Table 7.3. List of standard DHCP option types
Name | Meaning |
---|---|
binary | An arbitrary string of bytes, specified as a set of hexadecimal digits. |
boolean | Boolean value with allowed values true or false |
empty | No value, data is carried in suboptions |
fqdn | Fully qualified domain name (e.g. www.example.com) |
ipv4-address | IPv4 address in the usual dotted-decimal notation (e.g. 192.0.2.1) |
ipv6-address | IPv6 address in the usual colon notation (e.g. 2001:db8::1) |
record | Structured data that may comprise any types (except "record" and "empty") |
string | Any text |
uint8 | 8 bit unsigned integer with allowed values 0 to 255 |
uint16 | 16 bit unsigned integer with allowed values 0 to 65535 |
uint32 | 32 bit unsigned integer with allowed values 0 to 4294967295 |
Kea supports custom (non-standard) DHCPv4 options. Assume that we want to define a new DHCPv4 option called "foo" which will have code 222 and will convey a single unsigned 32 bit integer value. We can define such an option by using the following entry in the configuration file:
"Dhcp4": {
"option-def": [
{
"name": "foo",
"code": 222,
"type": "uint32",
"array": false,
"record-types": "",
"space": "dhcp4",
"encapsulate": ""
}, ...
],
...
}
The false value of the array parameter determines that the option does NOT comprise an array of "uint32" values but rather a single value. Two other parameters have been left blank: record-types and encapsulate. The former specifies the comma separated list of option data fields if the option comprises a record of data fields. This should be non-empty if the type is set to "record". Otherwise it must be left blank. The latter parameter specifies the name of the option space being encapsulated by the particular option. If the particular option does not encapsulate any option space it should be left blank. Note that the above set of comments define the format of the new option and do not set its values.
The name, code and type parameters are required, all others are optional. The array default value is false. The record-types and encapsulate default values are blank (i.e. ""). The default space is "dhcp4".
Once the new option format is defined, its value is set in the same way as for a standard option. For example the following commands set a global value that applies to all subnets.
"Dhcp4": {
"option-data": [
{
"name": "foo",
"code": 222,
"space": "dhcp4",
"csv-format": true,
"data": "12345"
}, ...
],
...
}
New options can take more complex forms than simple use of primitives (uint8, string, ipv4-address etc): it is possible to define an option comprising a number of existing primitives. Assume we want to define a new option that will consist of an IPv4 address, followed by an unsigned 16 bit integer, followed by a boolean value, followed by a text string. Such an option could be defined in the following way:
"Dhcp4": {
"option-def": [
{
"name": "bar",
"code": 223,
"space": "dhcp4",
"type": "record",
"array": false,
"record-types": "ipv4-address, uint16, boolean, string",
"encapsulate": ""
}, ...
],
...
}
The type is set to "record" to indicate that the option contains multiple values of different types. These types are given as a comma-separated list in the record-types field and should be those listed in Table 7.3, “List of standard DHCP option types”.
The values of the option are set as follows:
"Dhcp4": {
"option-data": [
{
"name": "bar",
"space": "dhcp4",
"code": 223,
"csv-format": true,
"data": "192.0.2.100, 123, true, Hello World"
}
],
...
}
csv-format is set to true to indicate that the data field comprises a command-separated list of values. The values in the data must correspond to the types set in the record-types field of the option definition.
In the general case, boolean values are specified as true or false, without quotes. Some specific boolean parameters may accept also "true", "false", 0, 1, "0" and "1". Future Kea versions will accept all those values for all boolean parameters.
Currently there are two option spaces defined for the DHCPv4 daemon: "dhcp4" (for the top level DHCPv4 options) and "vendor-encapsulated-options-space", which is empty by default but options can be defined in it. Those options will be carried in the Vendor Specific Information option (code 43). The following examples show how to define an option "foo", with code 1, that consists of an IPv4 address, an unsigned 16 bit integer and a string. The "foo" option is conveyed in a Vendor Specific Information option.
The first step is to define the format of the option:
"Dhcp4": {
"option-def": [
{
"name": "foo",
"code": 1,
"space": "vendor-encapsulated-options-space",
"type": "record",
"array": false,
"record-types": "ipv4-address, uint16, string",
"encapsulate": ""
}
],
...
}
(Note that the option space is set to "vendor-encapsulated-options-space".) Once the option format is defined, the next step is to define actual values for that option:
"Dhcp4": {
"option-data": [
{
"name": "foo",
"space": "vendor-encapsulated-options-space",
"code": 1,
"csv-format": true,
"data": "192.0.2.3, 123, Hello World"
}
],
...
}
We also include the Vendor Specific Information option, the option that conveys our sub-option "foo". This is required, else the option will not be included in messages sent to the client.
"Dhcp4": {
"option-data": [
{
"name": "vendor-encapsulated-options"
}
],
...
}
Alternatively, the option can be specified using its code.
"Dhcp4": {
"option-data": [
{
"code": 43
}
],
...
}
It is sometimes useful to define completely new option space. This is the case when user creates new option in the standard option space ("dhcp4") and wants this option to convey sub-options. Since they are in a separate space, sub-option codes will have a separate numbering scheme and may overlap with the codes of standard options.
Note that creation of a new option space when defining sub-options for a standard option is not required, because it is created by default if the standard option is meant to convey any sub-options (see Section 7.2.10, “DHCPv4 Vendor Specific Options”).
Assume that we want to have a DHCPv4 option called "container" with code 222 that conveys two sub-options with codes 1 and 2. First we need to define the new sub-options:
"Dhcp4": {
"option-def": [
{
"name": "subopt1",
"code": 1,
"space": "isc",
"type": "ipv4-address",
"record-types": "",
"array": false,
"encapsulate ""
},
{
"name": "subopt2",
"code": 2,
"space": "isc",
"type": "string",
"record-types": "",
"array": false,
"encapsulate": ""
}
],
...
}
Note that we have defined the options to belong to a new option space (in this case, "isc").
The next step is to define a regular DHCPv4 option with our desired code and specify that it should include options from the new option space:
"Dhcp4": {
"option-def": [
...,
{
"name": "container",
"code": 222,
"space": "dhcp4",
"type": "empty",
"array": false,
"record-types": "",
"encapsulate": "isc"
}
],
...
}
The name of the option space in which the sub-options are defined is set in the "encapsulate" field. The "type" field is set to "empty" to indicate that this option does not carry any data other than sub-options.
Finally, we can set values for the new options:
"Dhcp4": { "option-data": [ {"name": "subopt1", "code": 1, "space": "isc", "data": "192.0.2.3"
}, }"name": "subopt2", "code": 2, "space": "isc", "data": "Hello world"
}, {"name": "container", "code": 222, "space": "dhcp4"
} ], ... }
Note that it is possible to create an option which carries some data in addition to the sub-options defined in the encapsulated option space. For example, if the "container" option from the previous example was required to carry an uint16 value as well as the sub-options, the "type" value would have to be set to "uint16" in the option definition. (Such an option would then have the following data structure: DHCP header, uint16 value, sub-options.) The value specified with the "data" parameter — which should be a valid integer enclosed in quotes, e.g. "123" — would then be assigned to the uint16 field in the "container" option.
In many cases it is not required to specify all parameters for an option configuration and the default values may be used. However, it is important to understand the implications of not specifing some of them as it may result in configuration errors. The list below explains the behavior of the server when a particular parameter is not explicitly specified:
The DHCPv4 server supports the stateless client configuration whereby the client has an IP address configured (e.g. using manual configuration) and only contacts the server to obtain other configuration parameters, e.g. DNS servers' addresses. In order to obtain the stateless configuration parameters the client sends the DHCPINFORM message to the server with the "ciaddr" set to the address that the client is currently using. The server unicasts the DHCPACK message to the client that includes the stateless configuration ("yiaddr" not set).
The server will respond to the DHCPINFORM when the client is associated with the particular subnet defined in the server's configuration. The example subnet configuration will look like this:
"Dhcp4": { "subnet4": [ { "subnet": "192.0.2.0/24" "option-data": [ { "name": "domain-name-servers", "code": 6, "data": "192.0.2.200,192.0.2.201", "csv-format": true, "space": "dhcp4" } ] } ] }
This subnet specifies the single option which will be included in the DHCPACK message to the client in response to DHCPINFORM. Note that the subnet definition does not require the address pool configuration if it will be used solely for the stateless configuration.
This server will associate the subnet with the client if one of the following conditions is met:
The DHCPv4 server includes support for client classification. At the current time the capabilities of the classification process are limited but it is expected they will be expanded in the future. For a deeper discussion of the classification process see Chapter 12, Client Classification.
In certain cases it is useful to differentiate between different types of clients and treat them accordingly. It is envisaged that client classification will be used for changing the behavior of almost any part of the DHCP message processing, including the assignment of leases from different pools, the assignment of different options (or different values of the same options) etc. In the current release of the software however, there are only three mechanisms that take advantage of client classification: subnet selection, assignment of different options, and, for cable modems, there are specific options for use with the TFTP server address and the boot file field.
Kea can be instructed to limit access to given subnets based on class information. This is particularly useful for cases where two types of devices share the same link and are expected to be served from two different subnets. The primary use case for such a scenario is cable networks. There are two classes of devices: the cable modem itself, which should be handed a lease from subnet A and all other devices behind the modem that should get a lease from subnet B. That segregation is essential to prevent overly curious users from playing with their cable modems. For details on how to set up class restrictions on subnets, see Section 12.5, “Configuring Subnets With Class Information”.
The process of doing classification is conducted in three steps. The first step is to assess an incoming packet and assign it to zero or more classes. The second step is to choose a subnet, possibly based on the class information. The third step is to assign options again possibly based on the class information.
There are two methods of doing classification. The first is automatic and relies on examining the values in the vendor class options. Information from these options is extracted and a class name is constructed from it and added to the class list for the packet. The second allows you to specify an expression that is evaluated for each packet. If the result is true the packet is a member of the class.
Care should be taken with client classification as it is easy for clients that do not meet class criteria to be denied any service altogether.
The server checks whether an incoming packet includes the vendor class identifier option (60). If it does, the content of that option is prepended with "VENDOR_CLASS_" then it is interpreted as a class. For example, modern cable modems will send this option with value "docsis3.0" and as a result the packet will belong to class "VENDOR_CLASS_docsis3.0".
For clients that belong to the VENDOR_CLASS_docsis3.0 class, the siaddr field is set to the value of next-server (if specified in a subnet). If there is a boot-file-name option specified, its value is also set in the file field in the DHCPv4 packet. For eRouter1.0 class, the siaddr is always set to 0.0.0.0. That capability is expected to be moved to an external hook library that will be dedicated to cable modems.
This example shows a configuration using an automatcially generated "VENDOR_CLASS_" class. The Administrator of the network has decided that addresses from range 192.0.2.10 to 192.0.2.20 are going to be managed by the Dhcp4 server and only clients belonging to the docsis3.0 client class are allowed to use that pool.
"Dhcp4": {
"subnet4": [
{
"subnet": "192.0.2.0/24",
"pools": [ { "pool": "192.0.2.10 - 192.0.2.20" } ],
"client-class": "VENDOR_CLASS_docsis3.0"
}
],
...
}
The following example shows how to configure a class using an expression and a subnet making use of that class. This configuration defines the class named "Client_foo". It is comprised of all clients who's client ids (option 61) start with the string "foo". Members of this class will be given addresses from 192.0.2.10 to 192.0.2.20 and 192.0.2.1 and 192.0.2.2 as their domain name servers. For a deeper discussion of the classification process see Chapter 12, Client Classification.
"Dhcp4": { "client-classes": [ {"name": "Client_foo", "test": "substring(option[61].hex,0,3) == 'foo'", "option-data": [ { "name": "domain-name-servers", "code": 6, "space": "dhcp4", "csv-format": true, "data": "192.0.2.1, 192.0.2.2" } ]
}, ... ], "subnet4": [ { "subnet": "192.0.2.0/24", "pools": [ { "pool": "192.0.2.10 - 192.0.2.20" } ],"client-class": "Client_foo"
}, ... ], ... }
As mentioned earlier, kea-dhcp4 can be configured to generate requests to the DHCP-DDNS server (referred to here as "D2" ) to update DNS entries. These requests are known as NameChangeRequests or NCRs. Each NCR contains the following information:
Whether it is a request to add (update) or remove DNS entries
Whether the change requests forward DNS updates (A records), reverse DNS updates (PTR records), or both.
The FQDN, lease address, and DHCID
The parameters for controlling the generation of NCRs for submission to D2 are contained in the dhcp-ddns section of the kea-dhcp4 server configuration. The mandatory parameters for the DHCP DDNS configuration are enable-updates which is unconditionally required, and qualifying-suffix which has no default value and is required when enable-updates is set to true. The two (disabled and enabled) minimal DHCP DDNS configurations are:
"Dhcp4": {
"dhcp-ddns": {
"enable-updates": false
},
...
}
and for example:
"Dhcp4": {
"dhcp-ddns": {
"enable-updates": true,
"qualifying-suffix": "example."
},
...
}
The default values for the "dhcp-ddns" section are as follows:
In order for NCRs to reach the D2 server, kea-dhcp4 must be able to communicate with it. kea-dhcp4 uses the following configuration parameters to control how it communications with D2:
By default, kea-dhcp-ddns is assumed to be running on the same machine as kea-dhcp4, and all of the default values mentioned above should be sufficient. If, however, D2 has been configured to listen on a different address or port, these values must be altered accordingly. For example, if D2 has been configured to listen on 192.168.1.10 port 900, the following configuration would be required:
"Dhcp4": {
"dhcp-ddns": {
"server-ip": "192.168.1.10",
"server-port": 900
,
...
},
...
}
kea-dhcp4 follows the behavior prescribed for DHCP servers in RFC 4702. It is important to keep in mind that kea-dhcp4 provides the initial decision making of when and what to update and forwards that information to D2 in the form of NCRs. Carrying out the actual DNS updates and dealing with such things as conflict resolution are within the purview of D2 itself (Chapter 10, The DHCP-DDNS Server). This section describes when kea-dhcp4 will generate NCRs and the configuration parameters that can be used to influence this decision. It assumes that the "enable-updates" parameter is true.
In general, kea-dhcp4 will generate DDNS update requests when:
A new lease is granted in response to a DHCP REQUEST
An existing lease is renewed but the FQDN associated with it has changed.
An existing lease is released in response to a DHCP RELEASE
In the second case, lease renewal, two DDNS requests will be issued: one request to remove entries for the previous FQDN and a second request to add entries for the new FQDN. In the last case, a lease release, a single DDNS request to remove its entries will be made. The decision making involved when granting a new lease (the first case) is more involved and is discussed next.
When a new lease is granted, kea-dhcp4 will generate a DDNS update request if the DHCP REQUEST contains either the FQDN option (code 81) or the Host Name option (code 12). If both are present, the server will use the FQDN option. By default kea-dhcp4 will respect the FQDN N and S flags specified by the client as shown in the following table:
Table 7.4. Default FQDN Flag Behavior
Client Flags:N-S | Client Intent | Server Response | Server Flags:N-S-O |
---|---|---|---|
0-0 | Client wants to do forward updates, server should do reverse updates | Server generates reverse-only request | 1-0-0 |
0-1 | Server should do both forward and reverse updates | Server generates request to update both directions | 0-1-0 |
1-0 | Client wants no updates done | Server does not generate a request | 1-0-0 |
The first row in the table above represents "client delegation". Here the DHCP client states that it intends to do the forward DNS updates and the server should do the reverse updates. By default, kea-dhcp4 will honor the client's wishes and generate a DDNS request to the DHCP-DDNS server to update only reverse DNS data. The parameter override-client-update can be used to instruct the server to override client delegation requests. When this parameter is true, kea-dhcp4 will disregard requests for client delegation and generate a DDNS request to update both forward and reverse DNS data. In this case, the N-S-O flags in the server's response to the client will be 0-1-1 respectively.
(Note that the flag combination N=1, S=1 is prohibited according to RFC 4702. If such a combination is received from the client, the packet will be dropped by kea-dhcp4.)
To override client delegation, set the following values in your configuration file:
"Dhcp4": {
"dhcp-ddns": {
"override-client-update": true
,
...
},
...
}
The third row in the table above describes the case in which the client requests that no DNS updates be done. The parameter, override-no-update, can be used to instruct the server to disregard the client's wishes. When this parameter is true, kea-dhcp4 will generate a DDNS update request to kea-dhcp-ddns even if the client requests that no updates be done. The N-S-O flags in the server's response to the client will be 0-1-1.
To override client delegation, the following values should be set in your configuration:
"Dhcp4": {
"dhcp-ddns": {
"override-no-update": true
,
...
},
...
}
kea-dhcp4 will always generate DDNS update requests if the client request only contains the Host Name option. In addition it will include an FQDN option in the response to the client with the FQDN N-S-O flags set to 0-1-0 respectively. The domain name portion of the FQDN option will be the name submitted to D2 in the DDNS update request.
Each NameChangeRequest must of course include the fully qualified domain name whose DNS entries are to be affected. kea-dhcp4 can be configured to supply a portion or all of that name based upon what it receives from the client in the DHCP REQUEST.
The rules for determining the FQDN option are as follows:
If configured to do, so ignore the DHCPREQUEST contents and generate a FQDN using a configurable prefix and suffix.
If the DHCPREQUEST contains the client FQDN option, the candidate name is taken from there, otherwise it is taken from the Host Name option. The candidate name may then be modified:
If the candidate name is a fully qualified domain name, use it.
If the candidate name is a partial (i.e. unqualified) name then add a configurable suffix to the name and use the result as the FQDN.
If the candidate name is a empty, generate a FQDN using a configurable prefix and suffix.
To instruct kea-dhcp4 to always generate the FQDN for a client, set the parameter replace-client-name to true as follows:
"Dhcp4": {
"dhcp-ddns": {
"replace-client-name": true
,
...
},
...
}
The prefix used in the generation of a FQDN is specified by the generated-prefix parameter. The default value is "myhost". To alter its value simply set it to the desired string:
"Dhcp4": {
"dhcp-ddns": {
"generated-prefix": "another.host"
,
...
},
...
}
The suffix used when generating a FQDN or when qualifying a partial name is specified by the qualifying-suffix parameter. This parameter has no default value, thus it is mandatory when DDNS updates are enabled. To set its value simply set it to the desired string:
"Dhcp4": {
"dhcp-ddns": {
"qualifying-suffix": "foo.example.org"
,
...
},
...
}
When generating a name, kea-dhcp4 will construct name of the format:
[generated-prefix]-[address-text].[qualifying-suffix].
where address-text is simply the lease IP address converted to a hyphenated string. For example, if the lease address is 172.16.1.10, the qualifying suffix "example.com", and the default value is used for generated-prefix, the generated FQDN would be:
myhost-172-16-1-10.example.com.
In some cases, clients want to obtain configuration from the TFTP server. Although there is a dedicated option for it, some devices may use the siaddr field in the DHCPv4 packet for that purpose. That specific field can be configured using next-server directive. It is possible to define it in the global scope or for a given subnet only. If both are defined, the subnet value takes precedence. The value in subnet can be set to 0.0.0.0, which means that next-server should not be sent. It may also be set to an empty string, which means the same as if it was not defined at all, i.e. use the global value.
"Dhcp4": {"next-server": "192.0.2.123"
, ..., "subnet4": [ {"next-server": "192.0.2.234"
, ... } ] }
The original DHCPv4 specification (RFC 2131) states that the DHCPv4 server must not send back client-id options when responding to clients. However, in some cases that confused clients that did not have MAC address or client-id; see RFC 6842. for details. That behavior has changed with the publication of RFC 6842. which updated RFC 2131. That update now states that the server must send client-id if the client sent it. That is the default behaviour that Kea offers. However, in some cases older devices that do not support RFC 6842. may refuse to accept responses that include the client-id option. To enable backward compatibility, an optional configuration parameter has been introduced. To configure it, use the following configuration statement:
"Dhcp4": {
"echo-client-id": false
,
...
}
DHCP server must be able to identify the client (distinguish it from other clients) from which it receives the message. There are many reasons why this identification is required and the most important ones are listed below.
DHCPv4 makes use of two distinct identifiers which are placed by the client in the queries sent to the server and copied by the server to its responses to the client: 'chaddr' and 'client identifier'. The former was introduced as a part of the BOOTP specification and it is also used by DHCP to carry the hardware address of the interface used to send the query to the server (MAC address for the Ethernet). The latter is carried in the Client-identifier option, introduced in the RFC 2132.
The RFC 2131 indicates that the server may use both of these identifiers to identify the client but the 'client identifier', if present, takes precedence over 'chaddr'. One of the reasons for this is that 'client identifier' is independent from the hardware used by the client to communicate with the server. For example, if the client obtained the lease using one network card and then the network card is moved to another host, the server will wrongly identify this host is the one which has obtained the lease. Moreover, the RFC 4361 gives the recommendation to use DUID (see DHCPv6 specification) carried as 'client identifier' when dual stack networks are in use, to provide consistent identification information of the client, regardless of the protocol type it is using. Kea adheres to these specifications and the 'client identifier' by default takes precedence over the value carried in 'chaddr' field when the server searches, creates, updates or removes the client's lease.
When the server receives a DHCPDISCOVER or DHCPREQUEST message from the client, it will try to find out if the client already has a lease in the database and will hand out the existing lease rather than allocate a new one. Each lease in the lease database is associated with the 'client identifier' and/or 'chaddr'. The server will first use the 'client identifer' (if present) to search the lease. If the lease is found, the server will treat this lease as belonging to the client even if the current 'chaddr' and the 'chaddr' associated with the lease do not match. This facilitates the scenario when the network card on the client system has been replaced and thus the new MAC address appears in the messages sent by the DHCP client. If the server fails to find the lease using the 'client identifier' it will perform another lookup using the 'chaddr'. If this lookup returns no result, the client is considered as not having a lease and the new lease will be created.
A common problem reported by network operators is that bogus client implementations do not use stable client identifiers such as generating a new 'client identifier' each time the client connects to the network. Another well known case is when the client changes its 'client identifier' during the multi-stage boot process (PXE). In such cases, the MAC address of the client's interface remains stable and using 'chaddr' field to identify the client guarantees that the particular system is considered to be the same client, even though its 'client identifier' changes.
To address this problem, Kea includes a configuration option which enables client identification using 'chaddr' only by instructing the server to disregard server to "ignore" the 'client identifier' during lease lookups and allocations for a particular subnet. Consider the following simplified server configuration:
"Dhcp4": { ..."match-client-id": true,
... "subnet4": [ { "subnet": "192.0.10.0/24", "pools": [ { "pool": "192.0.2.23-192.0.2.87" } ],"match-client-id": false
}, { "subnet": "10.0.0.0/8", "pools": [ { "pool": "10.0.0.23-10.0.2.99" } ], } ] }
The match-client-id is a boolean value which
controls this behavior. The default value of true
indicates that the server will use the 'client identifier' for lease
lookups and 'chaddr' if the first lookup returns no results. The
false means that the server will only
use the 'chaddr' to search for client's lease. Whether the DHCID for
DNS updates is generated from the 'client identifier' or 'chaddr' is
controlled through the same parameter accordingly.
The match-client-id parameter may appear
both in the global configuration scope and/or under any subnet
declaration. In the example shown above, the effective value of the
match-client-id will be false
for the subnet 192.0.10.0/24, because the subnet specific setting
of the parameter overrides the global value of the parameter. The
effective value of the match-client-id for the subnet
10.0.0.0/8 will be set to true
because the
subnet declaration lacks this parameter and the global setting is
by default used for this subnet. In fact, the global entry for this
parameter could be omitted in this case, because
true
is the default value.
It is important to explain what happens when the client obtains
its lease for one setting of the match-client-id
and then renews when the setting has been changed. Let's first consider
the case when the client obtains the lease when the
match-client-id is set to true
.
The server will store the lease information including 'client identifier'
(if supplied) and 'chaddr' in the lease database. When the setting is
changed and the client renews the lease the server will determine that
it should use the 'chaddr' to search for the existing lease. If the
client hasn't changed its MAC address the server should successfully
find the existing lease. The 'client identifier' associated with the
returned lease is ignored and the client is allowed to use this lease.
When the lease is renewed only the 'chaddr' is recorded for this
lease according to the new server setting.
In the second case the client has the lease with only a 'chaddr'
value recorded. When the setting is changed to
match-client-id set to true
the server will first try to use the 'client identifier' to find the
existing client's lease. This will return no results because the
'client identifier' was not recorded for this lease. The server will
then use the 'chaddr' and the lease will be found. If the lease appears
to have no 'client identifier' recorded, the server will assume that
this lease belongs to the client and that it was created with the previous
setting of the match-client-id.
However, if the lease contains 'client identifier' which is different
from the 'client identifier' used by the client the lease will be
assumed to belong to another client and the new lease will be
allocated.
There are many cases where it is useful to provide a configuration on a per host basis. The most obvious one is to reserve specific, static address for exclusive use by a given client (host) ‐ returning client will receive the same address from the server every time, and other clients will generally not receive that address. Note that there may be cases when the new reservation has been made for the client for the address being currently in use by another client. We call this situation a "conflict". The conflicts get resolved automatically over time as described in the subsequent sections. Once conflict is resolved,the client will keep receiving the reserved configuration when it renews.
Another example when the host reservations are applicable is when a host that has specific requirements, e.g. a printer that needs additional DHCP options. Yet another possible use case is to define unique names for hosts. Although not all of the presented use cases are implemented yet, Kea software will support them in the near future.
Hosts reservations are defined as parameters for each subnet. Each host has to be identified by its hardware/MAC address. There is an optional reservations array in the Subnet4 element. Each element in that array is a structure, that holds information about reservrations for a single host. In particular, such a structure has to have an indentifer that uniquely identifies a host. In DHCPv4 context, such an identifier is a hardware or MAC address. In most cases, also an address will be specified. It is possible to specify a hostname. Additional capabilities are planned.
The following example shows how to reserve addresses for specific hosts:
"subnet4": [
{
"pools": [ { "pool": "192.0.2.1 - 192.0.2.200" } ],
"subnet": "192.0.2.0/24",
"interface": "eth0",
"reservations": [
{
"hw-address": "1a:1b:1c:1d:1e:1f",
"ip-address": "192.0.2.202"
},
{
"hw-address": "0a:0b:0c:0d:0e:0f",
"ip-address": "192.0.2.100",
"hostname": "alice-laptop"
}
]
}
]
The first entry reserves the 192.0.2.202 address for the client that uses MAC adress of 1a:1b:1c:1d:1e:1f. The second entry reserves the address 192.0.2.100 and the hostname of alice-laptop for client using MAC address 0a:0b:0c:0d:0e:0f. Note that if you plan to do DNS updates, it is strongly recommended for the hostnames to be unique.
Making a reservation for a mobile host that may visit multiple subnets requires a separate host definition in each subnet it is expected to visit. It is not allowed to define multiple host definitions with the same hardware address in a single subnet. It is a valid configuration, if such definitions are specified in different subnets, though.
Adding host reservation incurs a performance penalty. In principle, when the server that does not support host reservation responds to a query, it needs to check whether there is a lease for a given address being considered for allocation or renewal. The server that also supports host reservation, has to perform additional checks: not only if the address is currently used (if there is a lease for it), but also whether the address could be used by someone else (if there is a reservation for it). That additional check incurs performance penalty.
In a typical scenario there is an IPv4 subnet defined, e.g. 192.0.2.0/24, with certain part of it dedicated for dynamic allocation by the DHCPv4 server. That dynamic part is referred to as a dynamic pool or simply a pool. In principle, the host reservation can reserve any address that belongs to the subnet. The reservations that specify addresses that belong to configured pools are called in-pool reservations. In contrast, those that do not belong to dynamic pools are called out-of-pool reservations. There is no formal difference in the reservation syntax. As of 0.9.1, both reservation types are handled uniformly. However, upcoming releases may offer improved performance if there are only out-of-pool reservations as the server will be able to skip reservation checks when dealing with existing leases. Therefore, system administrators are encouraged to use out-of-pool reservations, if possible.
As the reservations and lease information are stored separately, conflicts may arise. Consider the following series of events. The server has configured the dynamic pool of addresses from the range of 192.0.2.10 to 192.0.2.20. The Host A requests an address and gets 19.0.2.10. Now the system administrator decides to reserve the address for the Host B. He decides to reserve 192.0.2.10 for that purpose. In general, reserving an address that is currently assigned to someone else is not recommended, but there are valid use cases where such an operation is warranted.
The server now has a conflict to resolve. Let's analyze the situation here. If the Host B boots up and requests an address, the server is not able to assign the reserved address 192.0.2.10 for the Host B. A naive approach would to be immediately remove the existing lease for the Host A and create a new one for the Host B. That would not solve the problem, though, because as soon as the Host B gets the address, it will detect that the address is already in use by the Host A and would send the DHCPDECLINE message. Therefore, in this situation, the server has to temporarily assign a different address (not matching what has been reserved) to the Host B.
When the Host A renews its address, the server will discover that the address being renewed is now reserved for another host - the Host B. Therefore the server will inform the Host A that it is no longer allowed to use it by sending DHCPNAK message. The server will not remove the lease, though, as there's small chance that the DHCPNAK may be lost if the network is lossy. If that happens, the client will not receive any responses, so it will retransmit its DHCPREQUEST packet. Once the DHCPNAK is received by the Host A, it will then revert to the server discovery and will eventually get a different address. Besides allocating a new lease, the server will also remove the old one. As a result, the address 192.0.2.10 will be no longer used. When Host B tries to renew its temporarily assigned address, the server will detect that it has a valid lease, but there is a reservation for a different address. The server will send DHCPNAK to inform Host B that its address is no longer usable, but will keep its lease (again, the DHCPNAK may be lost, so the server will keep it, until the client returns for a new address). The Host B will revert to the server discovery phase and will eventually send a DHCPREQUEST message. This time the server will find out that there is a reservation for that host and the reserved address 192.0.2.10 is not used, so it will be granted. It will also remove the lease for the temporarily assigned address that the Host B previously obtained.
This recovery will succeed, even if other hosts will attempt to get the reserved address. Had the Host C requested address 192.0.2.10 after the reservation was made, the server will either offer a different address (when responding to DHCPDISCOVER) or would send DHCPNAK (when responding to DHCPREQUEST).
This recovery mechanism allows the server to fully recover from a case where reservations conflict with the existing leases. This procedure takes time and will roughly take as long as renew-timer value specified. The best way to avoid such recovery is to not define new reservations that conflict with existing leases. Another recommendation is to use out-of-pool reservations. If the reserved address does not belong to a pool, there is no way that other clients could get this address (note that having multiple reservations for the same address is not allowed).
When the reservation for the client includes the hostname , the server will assign this hostname to the client and send it back in the Client FQDN or Hostname option, depending on which of them the client has sent to the server. The reserved hostname always takes precedence over the hostname supplied by the client or the autogenerated (from the IPv4 address) hostname.
The server qualifies the reserved hostname with the value of the qualifying-suffix parameter. For example, the following subnet configuration:
{ "subnet4": [ { "subnet": "10.0.0.0/24", "pools": [ { "pool": "10.0.0.10-10.0.0.100" } ], "reservations": [ { "hw-address": "aa:bb:cc:dd:ee:ff", "hostname": "alice-laptop" } ] }], "dhcp-ddns": { "enable-updates": true, "qualifying-suffix": "example.isc.org." } }
will result in assigning the "alice-laptop.example.isc.org." hostname to the client using the MAC address "aa:bb:cc:dd:ee:ff". If the qualifying-suffix is not specified, the default (empty) value will be used, and in this case the value specified as a hostname will be treated as fully qualified name. Thus, by leaving the qualifying-suffix empty it is possible to qualify hostnames for the different clients with different domain names:
{ "subnet4": [ { "subnet": "10.0.0.0/24", "pools": [ { "pool": "10.0.0.10-10.0.0.100" } ], "reservations": [ { "hw-address": "aa:bb:cc:dd:ee:ff", "hostname": "alice-laptop.isc.org." }, { "hw-address": "12:34:56:78:99:AA", "hostname": "mark-desktop.example.org." } ] }], "dhcp-ddns": { "enable-updates": true, } }
Currently it is not possible to specify options in host reservation. Such a feature will be added in the upcoming Kea releases.
reservation-mode configuration parameter in DHCPv4 server is accepted, but not used in the Kea 0.9.1 beta. Full implementation will be available in the upcoming releases.
Host reservation capability introduces additional restrictions for the allocation engine during lease selection and renewal. In particular, three major checks are necessary. First, when selecting a new lease, it is not sufficient for a candidate lease to be not used by another DHCP client. It also must not be reserved for another client. Second, when renewing a lease, additional check must be performed whether the address being renewed is not reserved for another client. Finally, when a host renews an address, the server has to check whether there's a reservation for this host, so the exisiting (dynamically allocated) address should be revoked and the reserved one be used instead.
Some of those checks may be unnecessary in certain deployments. Not performing them may improve performance. The Kea server provides the reservation-mode configuration parameter to select the types of reservations allowed for the particular subnet. Each reservation type has different constraints for the checks to be performed by the server when allocating or renewing a lease for the client. Allowed values are:
An example configuration that disables reservation looks like follows:
"Dhcp4": {
"subnet4": [
{
"subnet": "192.0.2.0/24",
"reservation-mode": "disabled"
,
...
}
]
}
The DHCPv4 protocol uses a "server identifier" to allow clients to discriminate between several servers present on the same link: this value is an IPv4 address of the server. The server chooses the IPv4 address of the interface on which the message from the client (or relay) has been received. A single server instance will use multiple server identifiers if it is receiving queries on multiple interfaces.
Currently there is no mechanism to override the default server identifiers by an administrator. In the future, the configuration mechanism will be used to specify the custom server identifier.
The DHCPv4 server differentiates between the directly connected clients, clients trying to renew leases and clients sending their messages through relays. For the directly connected clients the server will check the configuration for the interface on which the message has been received, and if the server configuration doesn't match any configured subnet the message is discarded.
Assuming that the server's interface is configured with the IPv4 address 192.0.2.3, the server will only process messages received through this interface from a directly connected client if there is a subnet configured to which this IPv4 address belongs, e.g. 192.0.2.0/24. The server will use this subnet to assign IPv4 address for the client.
The rule above does not apply when the client unicasts its message, i.e. is trying to renew its lease. Such a message is accepted through any interface. The renewing client sets ciaddr to the currently used IPv4 address. The server uses this address to select the subnet for the client (in particular, to extend the lease using this address).
If the message is relayed it is accepted through any interface. The giaddr set by the relay agent is used to select the subnet for the client.
It is also possible to specify a relay IPv4 address for a given subnet. It can be used to match incoming packets into a subnet in uncommon configurations, e.g. shared subnets. See Section 7.5.1, “Using a Specific Relay Agent for a Subnet” for details.
The subnet selection mechanism described in this section is based on the assumption that client classification is not used. The classification mechanism alters the way in which a subnet is selected for the client, depending on the classes to which the client belongs.
The relay has to have an interface connected to the link on which the clients are being configured. Typically the relay has an IPv4 address configured on that interface that belongs to the subnet from which the server will assign addresses. In the typical case, the server is able to use the IPv4 address inserted by the relay (in the giaddr field of the DHCPv4 packet) to select the appropriate subnet.
However, that is not always the case. In certain uncommon — valid — deployments, the relay address may not match the subnet. This usually means that there is more than one subnet allocated for a given link. The two most common examples where this is the case are long lasting network renumbering (where both old and new address space is still being used) and a cable network. In a cable network both cable modems and the devices behind them are physically connected to the same link, yet they use distinct addressing. In such a case, the DHCPv4 server needs additional information (the IPv4 address of the relay) to properly select an appropriate subnet.
The following example assumes that there is a subnet 192.0.2.0/24 that is accessible via a relay that uses 10.0.0.1 as its IPv4 address. The server will be able to select this subnet for any incoming packets that came from a relay that has an address in 192.0.2.0/24 subnet. It will also select that subnet for a relay with address 10.0.0.1.
"Dhcp4": {
"subnet4": [
{
"subnet": "192.0.2.0/24",
"pools": [ { "pool": "192.0.2.10 - 192.0.2.20" } ],
"relay": {
"ip-address": "10.0.0.1"
}
,
...
}
],
...
}
In certain cases, it is useful to mix relay address information, introduced in Section 7.5.1, “Using a Specific Relay Agent for a Subnet” with client classification, explained in Chapter 12, Client Classification. One specific example is cable network, where typically modems get addresses from a different subnet than all devices connected behind them.
Let's assume that there is one CMTS (Cable Modem Termination System) with one CM MAC (a physical link that modems are connected to). We want the modems to get addresses from the 10.1.1.0/24 subnet, while everything connected behind modems should get addresses from another subnet (192.0.2.0/24). The CMTS that acts as a relay uses address 10.1.1.1. The following configuration can serve that configuration:
"Dhcp4": { "subnet4": [ { "subnet": "10.1.1.0/24", "pools": [ { "pool": "10.1.1.2 - 10.1.1.20" } ],"client-class" "docsis3.0", "relay": { "ip-address": "10.1.1.1" }
}, { "subnet": "192.0.2.0/24", "pools": [ { "pool": "192.0.2.10 - 192.0.2.20" } ],"relay": { "ip-address": "10.1.1.1" }
} ], ... }
The DHCPv4 server is configured with a certain pool of addresses that it is expected to hand out to the DHCPv4 clients. It is assumed that the server is authoritative and has complete jurisdiction over those addresses. However, due to various reasons, such as misconfiguration or a faulty client implemetation that retains its address beyond the valid lifetime, there may be devices connected that use those addresses without the server's approval or knowledge.
Such an unwelcome event can be detected by legitimate clients (using ARP or ICMP Echo Request mechanisms) and reported to the DHCPv4 server using a DHCPDECLINE message. The server will do a sanity check (if the client declining an address really was supposed to use it), and then will conduct a clean up operation. Any DNS entries related to that address will be removed, the fact will be logged and hooks will be triggered. After that is done, the address will be marked as declined (which indicates that it is used by an unknown entity and thus not available for assignment to anyone) and a probation time will be set on it. Unless otherwise configured, the probation period lasts 24 hours. After that period, the server will recover the lease, i.e. put it back into the available state. The address will be available for assignment again. It should be noted that if the underlying issue of a misconfigured device is not resolved, the duplicate address scenario will repeat. On the other hand, it provides an opportunity to recover from such an event automatically, without any sysadmin intervention.
To configure the decline probation period to a value different than the default, the following syntax can be used:
"Dhcp4": {
"decline-probation-period": 3600
,
"subnet4": [ ... ],
...
}
The parameter is expressed in seconds, so the example above will instruct the server to recycle declined leases after an hour.
There are several statistics and hook points associated with the Decline handling procedure. The lease4_decline hook is triggered after the incoming DHCPDECLINE message has been sanitized and the server is about to decline the lease. The declined-addresses statistic is increased after the hook returns (both global and subnet specific variants).
Once the probation time elapses, the declined lease is recovered using the standard expired lease reclaimation procedure, with several additional steps. In particular, both declined-addresses statistics (global and subnet specific) are decreased. At the same time, reclaimed-declined-addresses statistics (again in two variants, global and subnet specific) are increased.
Note about statistics: The server does not decrease assigned-addresses statistics when a DHCPDECLINE is received and processed successfully. While technically a declined address is no longer assigned, the primary usage of the assigned-addresses statistic is to monitor pool utilization. Most people would forget to include declined-addresses in the calculation, and simply do assigned-addresses/total-addresses. This would have a bias towards under-representing pool utilization. As this has a potential for major issues, we decided not to decrease assigned addresses immediately after receiving DHCPDECLINE, but to do it later when we recover the address back to the available pool.
This section describes DHCPv4-specific statistics. For a general overview and usage of statistics, see Chapter 14, Statistics.
The DHCPv4 server supports the following statistics:
Table 7.5. DHCPv4 Statistics
Statistic | Data Type | Description |
---|---|---|
pkt4-received | integer | Number of DHCPv4 packets received. This includes all packets: valid, bogus, corrupted, rejected etc. This statistic is expected to grow rapidly. |
pkt4-discover-received | integer | Number of DHCPDISCOVER packets received. This statistic is expected to grow. Its increase means that clients that just booted started their configuration process and their initial packets reached your server. |
pkt4-offer-received | integer | Number of DHCPOFFER packets received. This statistic is expected to remain zero at all times, as DHCPOFFER packets are sent by the server and the server is never expected to receive them. Non-zero value indicates an error. One likely cause would be a misbehaving relay agent that incorrectly forwards DHCPOFFER messages towards the server, rather back to the clients. |
pkt4-request-received | integer | Number of DHCPREQUEST packets received. This statistic is expected to grow. Its increase means that clients that just booted received server's response (DHCPOFFER), accepted it and now requesting an address (DHCPREQUEST). |
pkt4-ack-received | integer | Number of DHCPACK packets received. This statistic is expected to remain zero at all times, as DHCPACK packets are sent by the server and the server is never expected to receive them. Non-zero value indicates an error. One likely cause would be a misbehaving relay agent that incorrectly forwards DHCPACK messages towards the server, rather back to the clients. |
pkt4-nak-received | integer | Number of DHCPNAK packets received. This statistic is expected to remain zero at all times, as DHCPNAK packets are sent by the server and the server is never expected to receive them. Non-zero value indicates an error. One likely cause would be a misbehaving relay agent that incorrectly forwards DHCPNAK messages towards the server, rather back to the clients. |
pkt4-release-received | integer | Number of DHCPRELEASE packets received. This statistic is expected to grow. Its increase means that clients that had an address are shutting down or stop using their addresses. |
pkt4-decline-received | integer | Number of DHCPDECLINE packets received. This statistic is expected to remain close to zero. Its increase means that a client that leased an address, but discovered that the address is currently used by an unknown device in your network. |
pkt4-inform-received | integer | Number of DHCPINFORM packets received. This statistic is expected to grow. Its increase means that there are clients that either do not need an address or already have an address and are interested only in getting additional configuration parameters. |
pkt4-unknown-received | integer | Number of packets received of an unknown type. Non-zero value of this statistic indicates that the server received a packet that it wasn't able to recognize: either with unsupported type or possibly malformed (without message type option). |
pkt4-sent | integer | Number of DHCPv4 packets sent. This statistic is expected to grow every time the server transmits a packet. In general, it should roughly match pkt4-received, as most incoming packets cause server to respond. There are exceptions (e.g. DHCPRELEASE), so do not worry, if it is lesser than pkt4-received. |
pkt4-offer-sent | integer | Number of DHCPOFFER packets sent. This statistic is expected to grow in most cases after a DHCPDISCOVER is processed. There are certain uncommon, but valid cases where incoming DHCPDISCOVER is dropped, but in general this statistic is expected to be close to pkt4-discover-received. |
pkt4-ack-sent | integer | Number of DHCPACK packets sent. This statistic is expected to grow in most cases after a DHCPREQUEST is processed. There are certain cases where DHCPNAK is sent instead. In general, the sum of pkt4-ack-sent and pkt4-nak-sent should be close to pkt4-request-received. |
pkt4-nak-sent | integer | Number of DHCPNAK packets sent. This statistic is expected to grow when the server choses to not honor the address requested by a client. In general, the sum of pkt4-ack-sent and pkt4-nak-sent should be close to pkt4-request-received. |
pkt4-parse-failed | integer | Number of incoming packets that could not be parsed. Non-zero value of this statistic indicates that the server received malformed or truncated packet. This may indicate problems in your network, faulty clients or server code bug. |
pkt4-receive-drop | integer | Number of incoming packets that were dropped. Exact reason for dropping packets is logged, but the most common reasons may be: an unacceptable packet type, direct responses are forbidden, or the server-id sent by the client does not match the server's server-id. |
subnet[id].total-addresses | integer | The total number of addresses available for the DHCPv4 management. In other words, this is the sum of all addresses in all configured pools. This statistic changes only during configuration changes. Note it does not take into account any addresses that may be reserved due to host reservation. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. This statistic is reset during reconfiguration event. |
subnet[id].assigned-addresses | integer | This statistic shows the number of assigned addresses in a given subnet. This statistic increases every time a new lease is allocated (as a result of receiving a DHCPREQUEST message) and is decreased every time a lease is released (a DHCPRELEASE message is received) or expires. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. This statistic is reset during reconfiguration event. |
declined-addresses | integer | This statistic shows the number of IPv4 adresses that are currently declined. This statistic counts the number of leases currently unavailable. Once a lease is recovered, this statistic will be decreased. Ideally, this statistic should be zero. If this statistic is non-zero (or worse increasing), a network administrator should investigate if there is a misbehaving device in his network. This is a global statistic that covers all subnets. |
subnet[id].declined-addresses | integer | This statistic shows the number of IPv4 adresses that are currently declined in a given subnet. This statistic counts the number of leases currently unavailable. Once a lease is recovered, this statistic will be decreased. Ideally, this statistic should be zero. If this statistic is non-zero (or worse increasing), a network administrator should investigate if there is a misbehaving device in his network. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. |
reclaimed-declined-addresses | integer | This statistic shows the number of IPv4 adresses that were declined, but have now been recovered. Unlike declined-addresses, this statistic never decreases. It can be used as a long term indicator of how many actual valid Declines were processed and recovered from. This is a global statistic that covers all subnets. |
subnet[id].reclaimed-declined-addresses | integer | This statistic shows the number of IPv4 adresses that were declined, but have now been recovered. Unlike declined-addresses, this statistic never decreases. It can be used as a long term indicator of how many actual valid Declines were processed and recovered from. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. |
Management API has been introduced in Kea 0.9.2-beta. It allows issuing specific management commands, like statistics retrieval, reconfiguration or shutdown. For more details, see Chapter 15, Management API. Currently the only supported communication channel type is 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:
"Dhcp4": {
"control-socket": {
"socket-type": "unix",
"socket-name": "/path/to/the/unix/socket"
},
"subnet4": [
...
],
...
}
The length of the path specified by the socket-name parameter is restricted by the maximum length for the unix socket name on your 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. The typical values are 107 on Linux and 103 on FreeBSD.
Communication over control channel is conducted using JSON structures. See the Control Channel section in the Kea Developer's Guide for more details.
DHCPv4 server supports statistic-get, statistic-reset, statistic-remove, statistic-get-all, statistic-reset-all and statistic-remove-all, specified in Section 14.3, “Commands for Manipulating Statistics”. It also supports list-commands and shutdown, specified in Section 15.3.2, “list-commands command” and Section 15.3.3, “shutdown command”, respectively.
The following standards are currently supported:
These are the current limitations of the DHCPv4 server software. Most of them are reflections of the current stage of development and should be treated as “not implemented yet”, rather than actual limitations. However, some of them are implications of the design choices made. Those are clearly marked as such.
Table of Contents
It is recommended that the Kea DHCPv6 server be started and stopped using keactrl (described in Chapter 6, Managing Kea with keactrl). However, it is also possible to run the server directly: it accepts the following command-line switches:
file
-
specifies the configuration file. This is the only mandatory
switch.port
-
specifies UDP port on which the server will listen. This is only
useful during testing, as a DHCPv6 server listening on
ports other than default DHCPv6 ports will not be able to
handle regular DHCPv6 queries.The -V command returns the versions of the external libraries dynamically linked.
The -W command describes the environment used
to build Kea. This command displays a copy of the
config.report
file produced by
./configure
that is embedded in the
executable binary.
The config.report
may also be accessed more
directly. The following command may be used to extract this
information. The binary path
may be found
in the install directory or in the .libs
subdirectory in the source treee. For example
kea/src/bin/dhcp6/.libs/kea-dhcp6
.
strings path
/kea-dhcp6 | sed -n 's/;;;; //p'
When running in a console, the server can be shut down by pressing ctrl-c. It detects the key combination and shuts down gracefully.
On start-up, the server will detect available network interfaces and will attempt to open UDP sockets on all interfaces mentioned in the configuration file.
Since the DHCPv6 server opens privileged ports, it requires root access. Make sure you run this daemon as root.
During startup the server will attempt to create a PID file of the form: [localstatedir]/[conf name].kea-dhcp6.pid where:
If the file already exists and contains the PID of a live process, the server will issue a DHCP6_ALREADY_RUNNING log message and exit. 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 would be necessary to manually delete the PID file.
This section explains how to configure the DHCPv6 server using the Kea configuration backend. (Kea configuration using any other backends is outside of scope of this document.) Before DHCPv6 is started, its configuration file has to be created. The basic configuration looks as follows:
{ # DHCPv6 configuration starts on the next line "Dhcp6": { # First we set up global values "renew-timer": 1000, "rebind-timer": 2000, "preferred-lifetime": 3000, "valid-lifetime": 4000, # Next we setup the interfaces to be used by the server. "interfaces-config": { "interfaces": [ "eth0" ] }, # And we specify the type of a lease database "lease-database": { "type": "memfile", "persist": true, "name": "/var/kea/dhcp6.leases" }, # Finally, we list the subnets from which we will be leasing addresses. "subnet6": [ { "subnet": "2001:db8:1::/64", "pools": [ { "pool": "2001:db8:1::1-2001:db8:1::ffff" } ] } ] # DHCPv6 configuration ends with the next line } }
The following paragraphs provide a brief overview of the parameters in the above example and their format. Subsequent sections of this chapter go into much greater detail for these and other parameters.
The lines starting with a hash (#) are comments and are ignored by the server; they do not impact its operation in any way.
The configuration starts in the first line with the initial opening curly bracket (or brace). Each configuration consists of one or more objects. In this specific example, we have only one object called Dhcp6. This is a simplified configuration, as usually there will be additional objects, like Logging or DhcpDns, but we omit them now for clarity. The Dhcp6 configuration starts with the "Dhcp6": { line and ends with the corresponding closing brace (in the above example, the brace after the last comment). Everything defined between those lines is considered to be the Dhcp6 configuration.
In the general case, the order in which those parameters appear does not matter. There are two caveats here though. The first one is to remember that the configuration file must be well formed JSON. That means that parameters for any given scope must be separated by a comma and there must not be a comma after the last parameter. When reordering a configuration file, keep in mind that moving a parameter to or from the last position in a given scope may require moving the comma as well. The second caveat is that it is uncommon — although legal JSON — to repeat the same parameter multiple times. If that happens, the last occurrence of a given parameter in a given scope is used while all previous instances are ignored. This is unlikely to cause any confusion as there are no real life reasons to keep multiple copies of the same parameter in your configuration file.
Moving onto the DHCPv6 configuration elements, the very first few elements define some global parameters. valid-lifetime defines for how long the addresses (leases) given out by the server are valid. If nothing changes, a client that got an address is allowed to use it for 4000 seconds. (Note that integer numbers are specified as is, without any quotes around them.) The address will become deprecated in 3000 seconds (clients are allowed to keep old connections, but can't use this address for creating new connections). renew-timer and rebind-timer are values that define T1 and T2 timers that govern when the client will begin the renewal and rebind procedures.
The interfaces-config map specifies the server configuration concerning the network interfaces, on which the server should listen to the DHCP messages. The interfaces parameter specifies a list of network interfaces on which the server should listen. Lists are opened and closed with square brackets, with elements separated by commas. Had we wanted to listen on two interfaces, the interfaces-config would look like this:
"interfaces-config": { "interfaces": [ "eth0", "eth1" ] },
The next couple of lines define the lease database, the place where the server stores its lease information. This particular example tells the server to use memfile, which is the simplest (and fastest) database backend. It uses an in-memory database and stores leases on disk in a CSV file. This is a very simple configuration. Usually, lease database configuration is more extensive and contains additional parameters. Note that lease-database is an object and opens up a new scope, using an opening brace. Its parameters (just one in this example -- type) follow. Had there been more than one, they would be separated by commas. This scope is closed with a closing brace. As more parameters follow, a trailing comma is present.
Finally, we need to define a list of IPv6 subnets. This is the most important DHCPv6 configuration structure as the server uses that information to process clients' requests. It defines all subnets from which the server is expected to receive DHCP requests. The subnets are specified with the subnet6 parameter. It is a list, so it starts and ends with square brackets. Each subnet definition in the list has several attributes associated with it, so it is a structure and is opened and closed with braces. At minimum, a subnet definition has to have at least two parameters: subnet (that defines the whole subnet) and pool (which is a list of dynamically allocated pools that are governed by the DHCP server).
The example contains a single subnet. Had more than one been defined, additional elements in the subnet6 parameter would be specified and separated by commas. For example, to define two subnets, the following syntax would be used:
"subnet6": [ { "pools": [ { "pool": "2001:db8:1::/112" } ], "subnet": "2001:db8:1::/64" }, { "pools": [ { "pool": "2001:db8:2::1-2001:db8:2::ffff" } ], "subnet": "2001:db8:2::/64", "interface": "eth0" } ]
Note that indentation is optional and is used for aesthetic purposes only. In some cases in may be preferable to use more compact notation.
After all parameters are specified, we have two contexts open: global and Dhcp6, hence we need two closing curly brackets to close them. In a real life configuration file there most likely would be additional components defined such as Logging or DhcpDdns, so the closing brace would be followed by a comma and another object definition.
All leases issued by the server are stored in the lease database. Currently there are three database backends available: memfile (which is the default backend), MySQL and PostgreSQL.
The server is able to store lease data in different repositories. Larger deployments may elect to store leases in a database. Section 8.2.2.2, “Lease Database Configuration” describes this option. In typical smaller deployments though, the server will use a CSV file rather than a database to store lease information. As well as requiring less administration, an advantage of using a file for storage is that it eliminates a dependency on third-party database software.
The configuration of the file backend (Memfile) is controlled through
the Dhcp6/lease-database parameters. The type parameter
is mandatory and it specifies which storage for leases the server should use.
The value of "memfile"
indicates that the file should
be used as the storage. The following list presents the remaining, not mandatory
parameters, which can be used to configure the Memfile backend.
true
at all times, during the server's normal
operation. Not writing leases to disk will mean that if a server is restarted
(e.g. after a power failure), it will not know what addresses have been
assigned. As a result, it may hand out addresses to new clients that are
already in use. The value of false
is mostly useful
for performance testing purposes. The default value of the
persist parameter is true
,
which enables writing lease updates
to the lease file.
"[kea-install-dir]/var/kea/kea-leases6.csv"
.0
, which disables
the LFC.
The example configuration of the Memfile backend is presented below:
"Dhcp6": { "lease-database": {"type": "memfile"
,"persist": true
,"name": "/tmp/kea-leases6.csv"
,"lfc-interval": 1800
} }
It is important to know how the lease file contents are organized to understand why the periodic lease file cleanup is needed. Every time when the server updates a lease or creates a new lease for the client, the new lease information must be recorded in the lease file. For performance reasons, the server does not supersede the existing client's lease, as it would require the lookup of the specific lease entry, but simply appends the new lease information at the end of the lease file. The previous lease entries for the client are not removed. When the server loads leases from the lease file, e.g. at the server startup, it assumes that the latest lease entry for the client is the valid one. The previous entries are discarded. This means that the server can re-construct the accurate information about the leases even though there may be many lease entries for each client. However, storing many entries for each client results in bloated lease file and impairs the performance of the server's startup and reconfiguration, as it needs to process larger number of lease entries.
The lease file cleanup removes all previous entries for each client and leaves only the latest ones. The interval at which the cleanup is performed is configurable, and it should be selected according to the frequency of lease renewals initiated by the clients. The more frequent renewals are, the lesser value of the lfc-interval should be. Note however, that the LFC takes time and thus it is possible (although unlikely) that new cleanup is started while the previous cleanup instance is still running, if the lfc-interval is too short. The server would recover from this by skipping the new cleanup when it detects that the previous cleanup is still in progress. But, this implies that the actual cleanups will be triggered more rarely than configured. Moreover, triggering a new cleanup adds an overhead to the server, which will not be able to respond to new requests for a short period of time when the new cleanup process is spawned. Therefore, it is recommended that the lfc-interval value is selected in a way that would allow for completing the cleanup before the new cleanup is triggered.
The LFC is performed by a separate process (in background) to avoid performance impact on the server process. In order to avoid the conflicts between the two processes both using the same lease files, the LFC process operates on the copy of the original lease file, rather than on the lease file used by the server to record lease updates. There are also other files being created as a side effect of the lease file cleanup. The detailed description of the LFC is located on the Kea wiki: http://kea.isc.org/wiki/LFCDesign.
Lease database access information must be configured for the DHCPv6 server, even if it has already been configured for the DHCPv4 server. The servers store their information independently, so each server can use a separate database or both servers can use the same database.
Lease database configuration is controlled through the Dhcp6/lease-database parameters. The type of the database must be set to "memfile", "mysql" or "postgresql", e.g.
"Dhcp6": { "lease-database": { "type": "mysql"
, ... }, ... }
Next, the name of the database is to hold the leases must be set: this is the name used when the lease database was created (see Section 4.3.2.1, “First Time Creation of Kea Database” or Section 4.3.3.1, “Manually Create the PostgreSQL Database and the Kea User”).
"Dhcp6": { "lease-database": { "name": "database-name
"
, ... }, ... }
If the database is located on a different system than the DHCPv6 server, the database host name must also be specified (although it should be noted that this configuration may have a severe impact on server performance):
"Dhcp6": { "lease-database": { "host": remote-host-name
, ... }, ... }
The usual state of affairs will be to have the database on the same machine as the DHCPv6 server. In this case, set the value to the empty string:
"Dhcp6": { "lease-database": { "host" : ""
, ... }, ... }
Finally, the credentials of the account under which the server will access the database should be set:
"Dhcp6": { "lease-database": {"user": "
,user-name
""password": "
, ... }, ... }password
"
If there is no password to the account, set the password to the empty string "". (This is also the default.)
The DHCPv6 server has to be configured to listen on specific network interfaces. The simplest network interface configuration instructs the server to listen on all available interfaces:
"Dhcp6": {
"interfaces-config": {
"interfaces": [ "*"
]
}
...
}
The asterisk plays the role of a wildcard and means "listen on all interfaces". However, it is usually a good idea to explicitly specify interface names:
"Dhcp6": {
"interfaces-config": {
"interfaces": [ "eth1", "eth3"
]
},
...
}
It is possible to use wildcard interface name (asterisk) concurrently with the actual interface names:
"Dhcp6": {
"interfaces-config": {
"interfaces": [ "eth1", "eth3", "*"
]
},
...
}
It is anticipated that this will form of usage only be used where it is desired to temporarily override a list of interface names and listen on all interfaces.
The subnet identifier is a unique number associated with a particular subnet. In principle, it is used to associate clients' leases with respective subnets. When the subnet identifier is not specified for a subnet being configured, it will be automatically assigned by the configuration mechanism. The identifiers are assigned from 1 and are monotonically increased for each subsequent subnet: 1, 2, 3 ....
If there are multiple subnets configured with auto-generated identifiers and one of them is removed, the subnet identifiers may be renumbered. For example: if there are four subnets and the third is removed the last subnet will be assigned the identifier that the third subnet had before removal. As a result, the leases stored in the lease database for subnet 3 are now associated with subnet 4, which may have unexpected consequences. In the future it is planned to implement a mechanism to preserve auto-generated subnet ids upon removal of one of the subnets. Currently, the only remedy for this issue is to manually specify a unique subnet identifier for each subnet.
The following configuration will assign the specified subnet identifier to the newly configured subnet:
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"id": 1024
,
...
}
]
}
This identifier will not change for this subnet unless the "id" parameter is removed or set to 0. The value of 0 forces auto-generation of the subnet identifier.
When the DHCPv6 server starts, by default it listens to the DHCP traffic sent to multicast address ff02::1:2 on each interface that it is configured to listen on (see Section 8.2.3, “Interface selection”). In some cases it is useful to configure a server to handle incoming traffic sent to the global unicast addresses as well. The most common reason for that is to have relays send their traffic to the server directly. To configure the server to listen on a specific unicast address, the notation to specify interfaces has been extended. An interface name can be optionally followed by a slash, followed by the global unicast address on which the server should listen. This will be done in addition to normal link-local binding + listening on ff02::1:2 address. The sample configuration below shows how to listen on 2001:db8::1 (a global address) configured on the eth1 interface.
"Dhcp6": {
"interfaces-config": {
"interfaces": [ "eth1/2001:db8::1"
]
},
...
}
This configuration will cause the server to listen on eth1 on link-local address, multicast group (ff02::1:2) and 2001:db8::1.
It is possible to mix interface names, wildcards and interface name/addresses on the list of interfaces. It is not possible to specify more than one unicast address on a given interface.
Care should be taken to specify proper unicast addresses. The server will attempt to bind to those addresses specified, without any additional checks. This approach is selected on purpose, so the software can be used to communicate over uncommon addresses if the administrator so desires.
The essential role of a DHCPv6 server is address assignment. For this, the server has to be configured with at least one subnet and one pool of dynamic addresses to be managed. For example, assume that the server is connected to a network segment that uses the 2001:db8:1::/64 prefix. The Administrator of that network has decided that addresses from range 2001:db8:1::1 to 2001:db8:1::ffff are going to be managed by the Dhcp6 server. Such a configuration can be achieved in the following way:
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"pools": [
{
"pool": "2001:db8:1::1-2001:db8:1::ffff"
}
],
...
}
]
}
Note that subnet is defined as a simple string, but the pool parameter is actually a list of pools: for this reason, the pool definition is enclosed in square brackets, even though only one range of addresses is specified.
Each pool is a structure that contains the parameters that describe a single pool. Currently there is only one parameter, pool, which gives the range of addresses in the pool. Additional parameters will be added in future releases of Kea.
It is possible to define more than one pool in a subnet: continuing the previous example, further assume that 2001:db8:1:0:5::/80 should also be managed by the server. It could be written as 2001:db8:1:0:5:: to 2001:db8:1::5:ffff:ffff:ffff, but typing so many 'f's is cumbersome. It can be expressed more simply as 2001:db8:1:0:5::/80. Both formats are supported by Dhcp6 and can be mixed in the pool list. For example, one could define the following pools:
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"pools": [
{ "pool": "2001:db8:1::1-2001:db8:1::ffff" },
{ "pool": "2001:db8:1:05::/80" }
]
,
...
}
]
}
The number of pools is not limited, but for performance reasons it is recommended to use as few as possible.
The server may be configured to serve more than one subnet. To add a second subnet, use a command similar to the following:
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"pools": [
{ "pool": "2001:db8:1::1-2001:db8:1::ffff" }
]
},
{
"subnet": "2001:db8:2::/64",
"pools": [
{ "pool": "2001:db8:2::/64" }
]
},
...
]
}
In this example, we allow the server to dynamically assign all addresses available in the whole subnet. Although rather wasteful, it is certainly a valid configuration to dedicate the whole /64 subnet for that purpose. Note that the Kea server does not preallocate the leases, so there is no danger in using gigantic address pools.
When configuring a DHCPv6 server using prefix/length notation, please pay attention to the boundary values. When specifying that the server can use a given pool, it will also be able to allocate the first (typically network address) address from that pool. For example for pool 2001:db8:2::/64 the 2001:db8:2:: address may be assigned as well. If you want to avoid this, use the "min-max" notation.
Subnets may also be configured to delegate prefixes, as defined in RFC 3633. A subnet may have one or more prefix delegation pools. Each pool has a prefixed address, which is specified as a prefix and a prefix length, as well as a delegated prefix length. delegated-len must not be shorter (that is it must be numerically greater or equal) than prefix-len. If both delegated-len and prefix-len are equal, the server will be able to delegate only one prefix. The delegated prefix does not have to match the subnet prefix.
Below is a sample subnet configuration which enables prefix delegation for the subnet:
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:d8b:1::/64",
"pd-pools": [
{
"prefix": "3000:1::",
"prefix-len": 64,
"delegated-len": 96
}
]
}
],
...
}
One of the major features of a DHCPv6 server is to provide configuration options to clients. Although there are several options that require special behavior, most options are sent by the server only if the client explicitly requests them. The following example shows how to configure DNS servers, which is one of the most frequently used options. Numbers in the first column are added for easier reference and will not appear on screen. Options specified in this way are considered global and apply to all configured subnets.
"Dhcp6": {
"option-data": [
{
"name": "dns-servers",
"code": 23,
"space": "dhcp6",
"csv-format": true,
"data": "2001:db8::cafe, 2001:db8::babe"
},
...
]
}
The option-data> line creates a new entry in the option-data table. This table contains information on all global options that the server is supposed to configure in all subnets. The name line specifies the option name. (For a complete list of currently supported names, see Table 8.1, “List of standard DHCPv6 options”.) The next line specifies the option code, which must match one of the values from that list. The line beginning with space specifies the option space, which must always be set to "dhcp6" as these are standard DHCPv6 options. For other name spaces, including custom option spaces, see Section 8.2.11, “Nested DHCPv6 options (custom option spaces)”. The next line specifies the format in which the data will be entered: use of CSV (comma separated values) is recommended. The data line gives the actual value to be sent to clients. Data is specified as normal text, with values separated by commas if more than one value is allowed.
Options can also be configured as hexadecimal values. If "csv-format" is set to false, the option data must be specified as a string of hexadecimal numbers. The following commands configure the DNS-SERVERS option for all subnets with the following addresses: 2001:db8:1::cafe and 2001:db8:1::babe.
"Dhcp6": {
"option-data": [
{
"name": "dns-servers",
"code": 23,
"space": "dhcp6",
"csv-format": false,
"data": "2001 0DB8 0001 0000 0000 0000 0000 CAFE
2001 0DB8 0001 0000 0000 0000 0000 BABE"
},
...
]
}
The value for the setting of the "data" element is split across two lines in this document for clarity: when entering the command, the whole string should be entered on the same line. Care should be taken to use proper encoding when using hexadecimal format as Kea's ability to validate data correctness in hexadecimal is limited.
Most of the parameters in the "option-data" structure are optional and can be omitted in some circumstances as discussed in the Section 8.2.12, “Unspecified parameters for DHCPv6 option configuration”.
It is possible to override options on a per-subnet basis. If clients connected to most of your subnets are expected to get the same values of a given option, you should use global options: you can then override specific values for a small number of subnets. On the other hand, if you use different values in each subnet, it does not make sense to specify global option values (Dhcp6/option-data), rather you should set only subnet-specific values (Dhcp6/subnet[X]/option-data[Y]).
The following commands override the global DNS servers option for a particular subnet, setting a single DNS server with address 2001:db8:1::3.
"Dhcp6": {
"subnet6": [
{
"option-data": [
{
"name": "dns-servers",
"code": 23,
"space": "dhcp6",
"csv-format": true,
"data": "2001:db8:1::3"
},
...
]
,
...
},
...
],
...
}
The currently supported standard DHCPv6 options are listed in Table 8.1, “List of standard DHCPv6 options”. The "Name" and "Code" are the values that should be used as a name in the option-data structures. "Type" designates the format of the data: the meanings of the various types is given in Table 7.3, “List of standard DHCP option types”.
Experimental options (like standard options but with a code which was not assigned by IANA) are listed in Table 8.2, “List of experimental DHCPv6 options”.
Some options are designated as arrays, which means that more than one value is allowed in such an option. For example the option dns-servers allows the specification of more than one IPv6 address, allowing clients to obtain the addresses of multiple DNS servers.
The Section 8.2.9, “Custom DHCPv6 options” describes the configuration syntax to create custom option definitions (formats). It is generally not allowed to create custom definitions for standard options, even if the definition being created matches the actual option format defined in the RFCs. There is an exception from this rule for standard options for which Kea does not provide a definition yet. In order to use such options, a server administrator must create a definition as described in Section 8.2.9, “Custom DHCPv6 options” in the 'dhcp6' option space. This definition should match the option format described in the relevant RFC but the configuration mechanism would allow any option format as it has no means to validate the format at the moment.
Table 8.1. List of standard DHCPv6 options
Name | Code | Type | Array? |
---|---|---|---|
preference | 7 | uint8 | false |
vendor-opts | 17 | uint32 | false |
sip-server-dns | 21 | fqdn | true |
sip-server-addr | 22 | ipv6-address | true |
dns-servers | 23 | ipv6-address | true |
domain-search | 24 | fqdn | true |
nis-servers | 27 | ipv6-address | true |
nisp-servers | 28 | ipv6-address | true |
nis-domain-name | 29 | fqdn | true |
nisp-domain-name | 30 | fqdn | true |
sntp-servers | 31 | ipv6-address | true |
information-refresh-time | 32 | uint32 | false |
bcmcs-server-dns | 33 | fqdn | true |
bcmcs-server-addr | 34 | ipv6-address | true |
geoconf-civic | 36 | record (uint8, uint16, binary) | false |
remote-id | 37 | record (uint32, binary) | false |
subscriber-id | 38 | binary | false |
client-fqdn | 39 | record (uint8, fqdn) | false |
pana-agent | 40 | ipv6-address | true |
new-posix-timezone | 41 | string | false |
new-tzdb-timezone | 42 | string | false |
ero | 43 | uint16 | true |
lq-query | 44 | record (uint8, ipv6-address) | false |
client-data | 45 | empty | false |
clt-time | 46 | uint32 | false |
lq-relay-data | 47 | record (ipv6-address, binary) | false |
lq-client-link | 48 | ipv6-address | true |
bootfile-url | 59 | string | false |
bootfile-param | 60 | binary | false |
client-arch-type | 61 | uint16 | true |
nii | 62 | record (uint8, uint8, uint8) | false |
erp-local-domain-name | 65 | fqdn | false |
rsoo | 66 | empty | false |
client-linklayer-addr | 79 | binary | false |
dhcp4o6-server-addr | 88 | ipv6-address | true |
Table 8.2. List of experimental DHCPv6 options
Name | Code | Type | Array? |
---|---|---|---|
public-key | 701 | binary | false |
certificate | 702 | binary | false |
signature | 703 | record (uint8, uint8, binary) | false |
timestamp | 704 | binary | false |
It is also possible to define options other than the standard ones. Assume that we want to define a new DHCPv6 option called "foo" which will have code 100 and will convey a single unsigned 32 bit integer value. We can define such an option by using the following commands:
"Dhcp6": {
"option-def": [
{
"name": "foo",
"code": 100,
"type": "uint32",
"array": false,
"record-types": "",
"space": "dhcp6",
"encapsulate": ""
}, ...
],
...
}
The "false" value of the "array" parameter determines that the option does NOT comprise an array of "uint32" values but rather a single value. Two other parameters have been left blank: "record-types" and "encapsulate". The former specifies the comma separated list of option data fields if the option comprises a record of data fields. The "record-fields" value should be non-empty if the "type" is set to "record". Otherwise it must be left blank. The latter parameter specifies the name of the option space being encapsulated by the particular option. If the particular option does not encapsulate any option space it should be left blank. Note that the above set of comments define the format of the new option and do not set its values.
The name, code and type parameters are required, all others are optional. The array default value is false. The record-types and encapsulate default values are blank (i.e. ""). The default space is "dhcp6".
Once the new option format is defined, its value is set in the same way as for a standard option. For example the following commands set a global value that applies to all subnets.
"Dhcp6": {
"option-data": [
{
"name": "foo",
"code": 100,
"space": "dhcp6",
"csv-format": true,
"data": "12345"
}, ...
],
...
}
New options can take more complex forms than simple use of primitives (uint8, string, ipv6-address etc): it is possible to define an option comprising a number of existing primitives.
Assume we want to define a new option that will consist of an IPv6 address, followed by an unsigned 16 bit integer, followed by a boolean value, followed by a text string. Such an option could be defined in the following way:
"Dhcp6": {
"option-def": [
{
"name": "bar",
"code": 101,
"space": "dhcp6",
"type": "record",
"array": false,
"record-types": "ipv6-address, uint16, boolean, string",
"encapsulate": ""
}, ...
],
...
}
The "type" is set to "record" to indicate that the option contains multiple values of different types. These types are given as a comma-separated list in the "record-types" field and should be those listed in Table 7.3, “List of standard DHCP option types”.
The values of the option are set as follows:
"Dhcp6": {
"option-data": [
{
"name": "bar",
"space": "dhcp6",
"code": 101,
"csv-format": true,
"data": "2001:db8:1::10, 123, false, Hello World"
}
],
...
}
csv-format is set true to indicate that the data field comprises a command-separated list of values. The values in the "data" must correspond to the types set in the "record-types" field of the option definition.
In the general case, boolean values are specified as true or false, without quotes. Some specific boolean parameters may accept also "true", "false", 0, 1, "0" and "1". Future Kea versions will accept all those values for all boolean parameters.
Currently there are two option spaces defined for the DHCPv6 daemon: "dhcp6" (for top level DHCPv6 options) and "vendor-opts-space", which is empty by default, but options can be defined in it. Those options will be carried in the Vendor-specific Information option (code 17). The following examples show how to define an option "foo" with code 1 that consists of an IPv6 address, an unsigned 16 bit integer and a string. The "foo" option is conveyed in a Vendor-specific Information option. This option comprises a single uint32 value that is set to "12345". The sub-option "foo" follows the data field holding this value.
"Dhcp6": {
"option-def": [
{
"name": "foo",
"code": 1,
"space": "vendor-opts-space",
"type": "record",
"array": false,
"record-types": "ipv6-address, uint16, string",
"encapsulate": ""
}
],
...
}
(Note that the option space is set to vendor-opts-space.) Once the option format is defined, the next step is to define actual values for that option:
"Dhcp6": {
"option-data": [
{
"name": "foo",
"space": "vendor-opts-space",
"data": "2001:db8:1::10, 123, Hello World"
},
...
],
...
}
We should also define a value (enterprise-number) for the Vendor-specific Information option, that conveys our option "foo".
"Dhcp6": {
"option-data": [
...,
{
"name": "vendor-opts",
"data": "12345"
}
],
...
}
Alternatively, the option can be specified using its code.
"Dhcp6": {
"option-data": [
...,
{
"code": 17,
"data": "12345"
}
],
...
}
It is sometimes useful to define completely new option spaces. This is useful if the user wants his new option to convey sub-options that use a separate numbering scheme, for example sub-options with codes 1 and 2. Those option codes conflict with standard DHCPv6 options, so a separate option space must be defined.
Note that it is not required to create a new option space when defining sub-options for a standard option because it is created by default if the standard option is meant to convey any sub-options (see Section 8.2.10, “DHCPv6 vendor specific options”).
Assume that we want to have a DHCPv6 option called "container" with code 102 that conveys two sub-options with codes 1 and 2. First we need to define the new sub-options:
"Dhcp6": { "option-def": [ {"name": "subopt1", "code": 1, "space": "isc", "type": "ipv6-address", "record-types": "", "array": false, "encapsulate": ""
}, {"name": "subopt2", "code": 2, "space": "isc", "type": "string", "record-types": "", "array": false "encapsulate": ""
} ], ... }
Note that we have defined the options to belong to a new option space (in this case, "isc").
The next step is to define a regular DHCPv6 option and specify that it should include options from the isc option space:
"Dhcp6": {
"option-def": [
...,
{
"name": "container",
"code": 102,
"space": "dhcp6",
"type": "empty",
"array": false,
"record-types": "",
"encapsulate": "isc"
}
],
...
}
The name of the option space in which the sub-options are defined is set in the encapsulate field. The type field is set to empty which limits this option to only carrying data in sub-options.
Finally, we can set values for the new options:
"Dhcp6": { "option-data": [ {"name": "subopt1", "code": 1, "space": "isc", "data": "2001:db8::abcd"
}, }"name": "subopt2", "code": 2, "space": "isc", "data": "Hello world"
}, {"name": "container", "code": 102, "space": "dhcp6"
} ], ... }
Note that it is possible to create an option which carries some data in addition to the sub-options defined in the encapsulated option space. For example, if the "container" option from the previous example was required to carry an uint16 value as well as the sub-options, the "type" value would have to be set to "uint16" in the option definition. (Such an option would then have the following data structure: DHCP header, uint16 value, sub-options.) The value specified with the "data" parameter — which should be a valid integer enclosed in quotes, e.g. "123" — would then be assigned to the uint16 field in the "container" option.
In many cases it is not required to specify all parameters for an option configuration and the default values can be used. However, it is important to understand the implications of not specifing some of them as it may result in configuration errors. The list below explains the behavior of the server when a particular parameter is not explicitly specified:
The DHCPv6 server may receive requests from local (connected to the same subnet as the server) and remote (connecting via relays) clients. As the server may have many subnet configurations defined, it must select an appropriate subnet for a given request.
The server can not assume which of the configured subnets are local. In IPv4 it is possible as there is a reasonable expectation that the server will have a (global) IPv4 address configured on the interface, and can use that information to detect whether a subnet is local or not. That assumption is not true in IPv6, the DHCPv6 server must be able to operate while only having link-local addresses. Therefore an optional "interface" parameter is available within a subnet definition to designate that a given subnet is local, i.e. reachable directly over the specified interface. For example the server that is intended to serve a local subnet over eth0 may be configured as follows:
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:beef::/48",
"pools": [
{
"pool": "2001:db8:beef::/48"
}
],
"interface": "eth0"
}
],
...
}
The Rapid Commit option, described in RFC 3315, is supported by the Kea DHCPv6 server. However, support is disabled by default for all subnets. It can be enabled for a particular subnet using the rapid-commit parameter as shown below:
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:beef::/48",
"rapid-commit": true
,
"pools": [
{
"pool": "2001:db8:beef::1-2001:db8:beef::10"
}
],
}
],
...
}
This setting only affects the subnet for which the rapid-commit is set to true. For clients connected to other subnets, the server will ignore the Rapid Commit option sent by the client and will follow the 4-way exchange procedure, i.e. respond with the Advertise for the Solicit containing Rapid Commit option.
A DHCPv6 server with multiple subnets defined must select the appropriate subnet when it receives a request from a client. For clients connected via relays, two mechanisms are used:
The first uses the linkaddr field in the RELAY_FORW message. The name of this field is somewhat misleading in that it does not contain a link-layer address: instead, it holds an address (typically a global address) that is used to identify a link. The DHCPv6 server checks if the address belongs to a defined subnet and, if it does, that subnet is selected for the client's request.
The second mechanism is based on interface-id options. While forwarding a client's message, relays may insert an interface-id option into the message that identifies the interface on the relay that received the message. (Some relays allow configuration of that parameter, but it is sometimes hardcoded and may range from the very simple (e.g. "vlan100") to the very cryptic: one example seen on real hardware was "ISAM144|299|ipv6|nt:vp:1:110"). The server can use this information to select the appropriate subnet. The information is also returned to the relay which then knows the interface to use to transmit the response to the client. In order for this to work successfully, the relay interface IDs must be unique within the network and the server configuration must match those values.
When configuring the DHCPv6 server, it should be noted that two similarly-named parameters can be configured for a subnet:
The two are mutually exclusive: a subnet cannot be both reachable locally (direct traffic) and via relays (remote traffic). Specifying both is a configuration error and the DHCPv6 server will refuse such a configuration.
To specify interface-id with value "vlan123", the following commands can be used:
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:beef::/48",
"pools": [
{
"pool": "2001:db8:beef::/48"
}
],
"interface-id": "vlan123"
}
],
...
}
RFC 6422 defines a mechanism called Relay-Supplied DHCP Options. In certain cases relay agents are the only entities that may have specific information. They can insert options when relaying messages from the client to the server. The server will then do certain checks and copy those options to the response that will be sent to the client.
There are certain conditions that must be met for the option to be included. First, the server must not provide the option by itself. In other words, if both relay and server provide an option, the server always takes precedence. Second, the option must be RSOO-enabled. IANA mantains a list of RSOO-enabled options here. However, there may be cases when system administrators want to echo other options. Kea can be instructed to treat other options as RSOO-enabled. For example, to mark options 110, 120 and 130 as RSOO-enabled, the following syntax should be used:
"Dhcp6": {
"relay-supplied-options": [ "110", "120", "130" ],
...
}
As of March 2015, only option 65 is RSOO-enabled by IANA. This option will always be treated as such and there's no need to explicitly mark it. Also, when enabling standard options, it is possible to use their names, rather than option code, e.g. (e.g. use dns-servers instead of 23). See Table 8.1, “List of standard DHCPv6 options” for the names. In certain cases it could also work for custom options, but due to the nature of the parser code this may be unreliable and should be avoided.
The DHCPv6 server includes support for client classification. At the current time the capabilities of the classification process are limited but it is expected they will be expanded in the future. For a deeper discussion of the classification process see Chapter 12, Client Classification.
In certain cases it is useful to differentiate between different types of clients and treat them accordingly. It is envisaged that client classification will be used for changing the behavior of almost any part of the DHCP message processing, including the assignement of leases from different pools, the assigment of different options (or different values of the same options) etc. In the current release of the sofware however, there are only two mechanisms that take advantage of client classification: subnet selection and assignment of differnet options.
Kea can be instructed to limit access to given subnets based on class information. This is particularly useful for cases where two types of devices share the same link and are expected to be served from two different subnets. The primary use case for such a scenario is cable networks. There are two classes of devices: the cable modem itself, which should be handed a lease from subnet A and all other devices behind the modem that should get a lease from subnet B. That segregation is essential to prevent overly curious users from playing with their cable modems. For details on how to set up class restrictions on subnets, see Section 12.5, “Configuring Subnets With Class Information”.
The process of doing classification is conducted in three steps. The first step is to assess an incoming packet and assign it to zero or more classes. The second step is to choose a subnet, possibly based on the class information. The third step is to assign options again possibly based on the class information.
There are two methods of doing classification. The first is automatic and relies on examining the values in the vendor class options. Information from these options is extracted and a class name is constructed from it and added to the class list for the packet. The second allows you to specify an expression that is evaluated for each packet. If the result is true the packet is a member of the class.
Care should be taken with client classification as it is easy for clients that do not meet class criteria to be denied any service altogether.
The following example shows how to configure a class using an expression and a subnet making use of that class. This configuration defines the class named "Client_enterprise". It is comprised of all clients who's client identifiers start with the given hex string (which would indicate a DUID based on an enterprise id of 0xAABBCCDD). They will be given an address from 2001:db8:1::0 to 2001:db8:1::FFFF and 2001:db8:0::1 and 2001:db8:2::1 for their domain name servers. For a deeper discussion of the classification process see Chapter 12, Client Classification.
"Dhcp6": { "client-classes": [ {"name": "Client_enterprise", "test": "substring(option[2].hex,0,6) == 0x0002AABBCCDD'", "option-data": [ { "name": "dns-servers", "code": 23, "space": "dhcp6", "csv-format": true, "data": "2001:db8:0::1, 2001:db8:2::1" } ]
}, ... ], "subnet6": [ { "subnet": "2001:db8:1::/64", "pools": [ { "pool": "2001:db8:1::-2001:db8:1::ffff" } ],"client-class": "Client_enterprise"
} ], ... }
This example shows a configuration using an automatcially generated "VENDOR_CLASS_" class. The Administrator of the network has decided that addresses from range 2001:db8:1::1 to 2001:db8:1::ffff are going to be managed by the Dhcp6 server and only clients belonging to the eRouter1.0 client class are allowed to use that pool.
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"pools": [
{
"pool": "2001:db8:1::-2001:db8:1::ffff"
}
],
"client-class": "VENDOR_CLASS_eRouter1.0"
}
],
...
}
As mentioned earlier, kea-dhcp6 can be configured to generate requests to the DHCP-DDNS server (referred to here as "D2") to update DNS entries. These requests are known as NameChangeRequests or NCRs. Each NCR contains the following information:
Whether it is a request to add (update) or remove DNS entries
Whether the change requests forward DNS updates (AAAA records), reverse DNS updates (PTR records), or both.
The FQDN, lease address, and DHCID
The parameters controlling the generation of NCRs for submission to D2 are contained in the "dhcp-ddns" section of kea-dhcp6 configuration. The mandatory parameters for the DHCP DDNS configuration are enable-updates which is unconditionally required, and qualifying-suffix which has no default value and is required when enable-updates is set to true. The two (disabled and enabled) minimal DHCP DDNS configurations are:
"Dhcp6": {
"dhcp-ddns": {
"enable-updates": false
},
...
}
and for example:
"Dhcp6": {
"dhcp-ddns": {
"enable-updates": true,
"qualifying-suffix": "example."
},
...
}
The default values for the "dhcp-ddns" section are as follows:
In order for NCRs to reach the D2 server, kea-dhcp6 must be able to communicate with it. kea-dhcp6 uses the following configuration parameters to control how it communications with D2:
By default, kea-dhcp-ddns is assumed to running on the same machine as kea-dhcp6, and all of the default values mentioned above should be sufficient. If, however, D2 has been configured to listen on a different address or port, these values must altered accordingly. For example, if D2 has been configured to listen on 2001:db8::5 port 900, the following commands would be required:
"Dhcp6": {
"dhcp-ddns": {
"server-ip": "2001:db8::5",
"server-port": 900
,
...
},
...
}
kea-dhcp6 follows the behavior prescribed for DHCP servers in RFC 4704. It is important to keep in mind that kea-dhcp6 provides the initial decision making of when and what to update and forwards that information to D2 in the form of NCRs. Carrying out the actual DNS updates and dealing with such things as conflict resolution are the purview of D2 (Chapter 10, The DHCP-DDNS Server).
This section describes when kea-dhcp6 will generate NCRs and the configuration parameters that can be used to influence this decision. It assumes that the "enable-updates" parameter is true.
Currently the interface between kea-dhcp6 and D2 only supports requests which update DNS entries for a single IP address. If a lease grants more than one address, kea-dhcp6 will create the DDNS update request for only the first of these addresses. Support for multiple address mappings may be provided in a future release.
In general, kea-dhcp6 will generate DDNS update requests when:
A new lease is granted in response to a DHCP REQUEST
An existing lease is renewed but the FQDN associated with it has changed.
An existing lease is released in response to a DHCP RELEASE
In the second case, lease renewal, two DDNS requests will be issued: one request to remove entries for the previous FQDN and a second request to add entries for the new FQDN. In the last case, a lease release, a single DDNS request to remove its entries will be made. The decision making involved when granting a new lease is more involved and is discussed next.
kea-dhcp6 will generate a DDNS update request only if the DHCP REQUEST contains the FQDN option (code 39). By default kea-dhcp6 will respect the FQDN N and S flags specified by the client as shown in the following table:
Table 8.3. Default FQDN Flag Behavior
Client Flags:N-S | Client Intent | Server Response | Server Flags:N-S-O |
---|---|---|---|
0-0 | Client wants to do forward updates, server should do reverse updates | Server generates reverse-only request | 1-0-0 |
0-1 | Server should do both forward and reverse updates | Server generates request to update both directions | 0-1-0 |
1-0 | Client wants no updates done | Server does not generate a request | 1-0-0 |
The first row in the table above represents "client delegation". Here the DHCP client states that it intends to do the forward DNS updates and the server should do the reverse updates. By default, kea-dhcp6 will honor the client's wishes and generate a DDNS request to D2 to update only reverse DNS data. The parameter, "override-client-update", can be used to instruct the server to override client delegation requests. When this parameter is true, kea-dhcp6 will disregard requests for client delegation and generate a DDNS request to update both forward and reverse DNS data. In this case, the N-S-O flags in the server's response to the client will be 0-1-1 respectively.
(Note that the flag combination N=1, S=1 is prohibited according to RFC 4702. If such a combination is received from the client, the packet will be dropped by kea-dhcp6.)
To override client delegation, issue the following commands:
"Dhcp6": {
"dhcp-ddns": {
"override-client-update": true
,
...
},
...
}
The third row in the table above describes the case in which the client requests that no DNS updates be done. The parameter, "override-no-update", can be used to instruct the server to disregard the client's wishes. When this parameter is true, kea-dhcp6 will generate DDNS update requests to kea-dhcp-ddns even if the client requests no updates be done. The N-S-O flags in the server's response to the client will be 0-1-1.
To override client delegation, issue the following commands:
"Dhcp6": {
"dhcp-ddns": {
"override-no-update": true
,
...
},
...
}
Each NameChangeRequest must of course include the fully qualified domain name whose DNS entries are to be affected. kea-dhcp6 can be configured to supply a portion or all of that name based upon what it receives from the client in the DHCP REQUEST.
The rules for determining the FQDN option are as follows:
If configured to do so ignore the REQUEST contents and generate a FQDN using a configurable prefix and suffix.
Otherwise, using the domain name value from the client FQDN option as the candidate name:
If the candidate name is a fully qualified domain name then use it.
If the candidate name is a partial (i.e. unqualified) name then add a configurable suffix to the name and use the result as the FQDN.
If the candidate name is a empty then generate a FQDN using a configurable prefix and suffix.
To instruct kea-dhcp6 to always generate a FQDN, set the parameter "replace-client-name" to true:
"Dhcp6": {
"dhcp-ddns": {
"replace-client-name": true
,
...
},
...
}
The prefix used when generating a FQDN is specified by the "generated-prefix" parameter. The default value is "myhost". To alter its value, simply set it to the desired string:
"Dhcp6": {
"dhcp-ddns": {
"generated-prefix": "another.host"
,
...
},
...
}
The suffix used when generating a FQDN or when qualifying a partial name is specified by the qualifying-suffix parameter. This parameter has no default value, thus it is mandatory when DDNS updates are enabled. To set its value simply set it to the desired string:
"Dhcp6": {
"dhcp-ddns": {
"qualifying-suffix": "foo.example.org"
,
...
},
...
}
When qualifying a partial name, kea-dhcp6 will construct a name with the format:
[candidate-name].[qualifying-suffix].
where candidate-name is the partial name supplied in the REQUEST. For example, if FQDN domain name value was "some-computer" and qualifying-suffix "example.com", the generated FQDN would be:
some-computer.example.com.
When generating the entire name, kea-dhcp6 will construct name of the format:
[generated-prefix]-[address-text].[qualifying-suffix].
where address-text is simply the lease IP address converted to a hyphenated string. For example, if lease address is 3001:1::70E, the qualifying suffix "example.com", and the default value is used for generated-prefix, the generated FQDN would be:
myhost-3001-1--70E.example.com.
There are many cases where it is useful to provide a configuration on a per host basis. The most obvious one is to reserve specific, static IPv6 address or/and prefix for exclusive use by a given client (host) ‐ returning client will get the same address or/and prefix every time and other clients will never get that address. Note that there may be cases when the new reservation has been made for the client for the address or prefix being currently in use by another client. We call this situation a "conflict". The conflicts get resolved automatically over time as described in the subsequent sections. Once conflict is resolved, the client will keep receiving the reserved configuration when it renews.
Another example when the host reservations are applicable is when a host that has specific requirements, e.g. a printer that needs additional DHCP options or a cable modem needs specific parameters. Yet another possible use case for host reservation is to define unique names for hosts. Although not all of the presented use cases are are implemented yet, Kea software will support them in the near future.
Hosts reservations are defined as parameters for each subnet. Each host can be identified by either DUID or its hardware/MAC address. See Section 8.9, “MAC/Hardware addresses in DHCPv6” for details. There is an optional reservations array in the Subnet6 structure. Each element in that array is a structure, that holds information about a single host. In particular, such a structure has to have an indentifer that uniquely identifies a host. In DHCPv6 context, such an identifier is a hardware (MAC) address or a DUID. Also, either one or more addresses or prefixes should be specified. It is possible to specify a hostname. Additional capabilities are planned.
The following example shows how to reserve addresses and prefixes for specific hosts:
"subnet6": [
{
"subnet": "2001:db8:1::/48",
"pools": [ { "pool": "2001:db8:1::/80" } ],
"pd-pools": [
{
"prefix": "2001:db8:1:8000::",
"prefix-len": 56,
"delegated-len": 64
}
],
"reservations": [
{
"duid": "01:02:03:04:05:0A:0B:0C:0D:0E",
"ip-addresses": [ "2001:db8:1::100" ]
},
{
"hw-address": "00:01:02:03:04:05",
"ip-addresses": [ "2001:db8:1::101" ]
},
{
"duid": "01:02:03:04:05:06:07:08:09:0A",
"ip-addresses": [ "2001:db8:1::102" ],
"prefixes": [ "2001:db8:2:abcd::/64" ],
"hostname": "foo.example.com"
}
]
}
]
This example makes 3 reservations. The first one reserves 2001:db8:1::100 address for the client using DUID 01:02:03:04:05:0A:0B:0C:0D:0E. The second one also reserves an address, but does so using MAC or hardware address, rather than DUID. The third example is most advanced. It reserves an address, a prefix and a hostname at the same time.
Note that DHCPv6 allows for a single client to lease multiple addresses and multiple prefixes at the same time. In the upcoming Kea releases, it will be possible to have multiple addresses and prefixes reserved for a single host. Therefore ip-addresses and prefixes are plural and are actually arrays. As of 0.9.1 having more than one IPv6 address or prefix is only partially supported.
Making a reservation for a mobile host that may visit multiple subnets requires a separate host definition in each subnet it is expected to visit. It is not allowed to define multiple host definitions with the same hardware address in a single subnet. It is a valid configuration, if such definitions are specified in different subnets, though. The reservation for a given host should include only one identifier, either DUID or hwardware address. Defining both for the same host is considered a configuration error, but as of 0.9.1 beta, it is not rejected.
Adding host reservation incurs a performance penalty. In principle, when the server that does not support host reservation responds to a query, it needs to check whether there is a lease for a given address being considered for allocation or renewal. The server that also supports host reservation, has to perform additional checks: not only if the address is currently used (if there is a lease for it), but also whether the address could be used by someone else (if there is a reservation for it). That additional check incurs performance penalty.
In a typical scenario there's an IPv6 subnet defined with a certain part of it dedicated for dynamic address allocation by the DHCPv6 server. There may be an additional address space defined for prefix delegation. Those dynamic parts are referred to as dynamic pools, address and prefix pools or simply pools. In principle, the host reservation can reserve any address or prefix that belongs to the subnet. The reservations that specify an address that belongs to configured pools are called in-pool reservations. In contrast, those that do not belong to dynamic pools are called out-of-pool reservations. There is no formal difference in the reservation syntax. As of 0.9.1, both reservation types are handled uniformly. However, upcoming releases may offer improved performance if there are only out-of-pool reservations as the server will be able to skip reservation checks when dealing with existing leases. Therefore, system administrators are encouraged to use out-of-pool reservations, if possible.
As reservations and lease information are stored in different places, conflicts may arrise. Consider the following series of events. The server has configured the dynamic pool of addresses from the range of 2001:db8::10 to 2001:db8::20. Host A requests an address and gets 2001:db8::10. Now the system administrator decides to reserve an address for host B. He decides to reserve 2001:db8::10 for that purpose. In general, reserving an address that is currently assigned to someone else is not recommended, but there are valid use cases where such an operation is warranted.
The server now has a conflict to resolve. Let's analyze the situation here. If host B boots up and request an address, the server is not able to assign the reserved address 2001:db8::10. A naive approach would to be immediately remove the lease for host A and create a new one for host B. That would not solve the problem, though, because as soon as host B get the address, it will detect that the address is already in use by someone else (host A) and would send Decline. Therefore in this situation, the server has to temporarily assign a different address from the dynamic pool (not matching what has been reserved) to host B.
When the host A renews its address, the server will discover that the address being renewed is now reserved for someone else (host B). Therefore the server will remove the lease for 2001:db8::10 and select a new address and will create a new lease for it. It will send two addresses in its response: the old address with lifetimes set to 0 to explicitly indicate that it is no longer valid and a new address with non-zero lifetimes. When the host B renews its temporarily assigned address, the server will detect that the existing lease does not match reservation, so it will release the current address host B has and will create a new lease matching the reservation. Similar as before, the server will send two addresses: the temporarily assigned one with zeroed lifetimes, and the new one that matches reservation with proper lifetimes set.
This recovery will succeed, even if other hosts will attempt to get the reserved address. Had the host C requested address 2001:db8::10 after the reservation was made, the server will propose a different address.
This recovery mechanism allows the server to fully recover from a case where reservations conflict with existing leases. This procedure takes time and will roughly take as long as renew-timer value specified. The best way to avoid such recovery is to not define new reservations that conflict with existing leases. Another recommendation is to use out-of-pool reservations. If the reserved address does not belong to a pool, there is no way that other clients could get this address (note that having multiple reservations for the same address is not allowed).
When the reservation for the client includes the hostname , the server will assign this hostname to the client and send it back in the Client FQDN, if the client sent the FQDN option to the the server. The reserved hostname always takes precedence over the hostname supplied by the client (via the FQDN option) or the autogenerated (from the IPv6 address) hostname.
The server qualifies the reserved hostname with the value of the qualifying-suffix parameter. For example, the following subnet configuration:
"subnet6": [ { "subnet": "2001:db8:1::/48", "pools": [ { "pool": "2001:db8:1::/80" } ], "reservations": [ { "duid": "01:02:03:04:05:0A:0B:0C:0D:0E", "ip-addresses": [ "2001:db8:1::100" ] "hostname": "alice-laptop" } ] } ], "dhcp-ddns": { "enable-updates": true, "qualifying-suffix": "example.isc.org." }
will result in assigning the "alice-laptop.example.isc.org." hostname to the client using the DUID "01:02:03:04:05:0A:0B:0C:0D:0E". If the qualifying-suffix is not specified, the default (empty) value will be used, and in this case the value specified as a hostname will be treated as fully qualified name. Thus, by leaving the qualifying-suffix empty it is possible to qualify hostnames for the different clients with different domain names:
"subnet6": [ { "subnet": "2001:db8:1::/48", "pools": [ { "pool": "2001:db8:1::/80" } ], "reservations": [ { "duid": "01:02:03:04:05:0A:0B:0C:0D:0E", "ip-addresses": [ "2001:db8:1::100" ] "hostname": "mark-desktop.example.org." } ] } ], "dhcp-ddns": { "enable-updates": true, }
will result in assigning the "mark-desktop.example.org." hostname to the client using the DUID "01:02:03:04:05:0A:0B:0C:0D:0E".
Currently it is not possible to specify options in host reservation. Such a feature will be added in the upcoming Kea releases.
reservation-mode in the DHCPv6 server is implemented in Kea 0.9.1 beta, but has not been tested and is considered experimental.
Host reservation capability introduces additional restrictions for the allocation engine during lease selection and renewal. In particular, three major checks are necessary. First, when selecting a new lease, it is not sufficient for a candidate lease to be not used by another DHCP client. It also must not be reserved for another client. Second, when renewing a lease, additional check must be performed whether the address being renewed is not reserved for another client. Finally, when a host renews an address or a prefix, the server has to check whether there's a reservation for this host, so the existing (dynamically allocated) address should be revoked and the reserved one be used instead.
Some of those checks may be unnecessary in certain deployments. Not performing them may improve performance. The Kea server provides the reservation-mode configuration parameter to select the types of reservations allowed for the particular subnet. Each reservation type has different constraints for the checks to be performed by the server when allocating or renewing a lease for the client. Allowed values are:
An example configuration that disables reservation looks like follows:
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"reservation-mode": "disabled"
,
...
}
]
}
The DHCPv6 protocol uses a "server identifier" (also known as a DUID) for clients to be able to discriminate between several servers present on the same link. RFC 3315 defines three DUID types: DUID-LLT, DUID-EN and DUID-LL. RFC 6355 also defines DUID-UUID. Future specifications may introduce new DUID types.
Kea DHCPv6 server generates a server identifier once, upon the first startup, and stores it in a file. This identifier isn't modified across restarts of the server (stable identifier).
Kea follows recommendation from RFC 3315 to use DUID-LLT as a default server identifier. However, we have received reports that some deployments require different DUID types, and there is a need to administratively select both DUID type and/or its contents.
The server identifier can be configured using parameters within the server-id map element in the global scope of the Kea configuration file. The following example demonstrates how to select DUID-EN as a server identifier:
"Dhcp6": { "server-id": { "type": "EN" }, ... }
Currently supported values for type parameter are: "LLT", "EN" and "LL", for DUID-LLT, DUID-EN and DUID-LL respectively.
When a new DUID type is selected the server will generate its value and replace any existing DUID in the file. The server will use the new server identifier in all future interactions with the clients.
If the new server identifier is created after some clients have obtained their leases, the clients using old identifier will not be able to renew the leases. The server will ignore messages containing the old server identifier. Clients will continue sending Renew until they transition to rebinding state. In this state they will start sending Rebind messages to multicast address and without a server identifier. The server will respond to the Rebind messages with a new server identifier and the clients will associate the new server identifier with their leases. Although the clients will be able to keep their leases and will eventually learn the new server identifier, this will be at the cost of increased number of renewals and multicast traffic due to a need to rebind. Therefore it is recommended to avoid modification of the server identifier type and its value if the server has already assigned leases and these leases are still valid.
There are cases when an administrator needs to explicitly specify a DUID value, rather than allow the server to generate it. The following example demonstrates how to explicitly set all components of a DUID-LLT.
"Dhcp6": { "server-id": { "type": "LLT", "htype": 8, "identifier": "A65DC7410F05", "time": 2518920166 }, ... }
where:
The hexadecimal representation of the DUID generated as a result of the configuration specified above will be:
00:01:00:08:96:23:AB:E6:A6:5D:C7:41:0F:05 ------------------------------------------ |type|htype| time | identifier |
It is allowed to use special value of 0 for "htype" and "time", which indicates that the server should use ANY value for these components. If the server already uses a DUID-LLT it will use the values from this DUID. If the server uses a DUID of a different type or doesn't use any DUID yet, it will generate these values. Similarly, if the "identifier" is assigned an empty string, the value of the identifier will be generated. Omitting any of these parameters is equivalent to setting them to those special values.
For example, the following configuration:
"Dhcp6": { "server-id": { "type": "LLT", "htype": 0, "identifier": "", "time": 2518920166 }, ... }
indicates that the server should use ANY link layer address and hardware type. If the server is already using DUID-LLT it will use link layer address and hardware type from the existing DUID. If the server is not using any DUID yet, it will use link layer address and hardware type from one of the available network interfaces. The server will use explicit value of time. If it is different than a time value present in the currently used DUID, this value will be replaced. This will effectively cause modification of the current server identifier.
The following example demonstrates an explicit configuration of a DUID-EN:
"Dhcp6": { "server-id": { "type": "EN", "enterprise-id": 2495, "identifier": "87ABEF7A5BB545" }, ... }
where:
The hexadecimal representation of the DUID-EN created accoring to the configuration above is:
00:02:00:00:09:BF:87:AB:EF:7A:5B:B5:45 -------------------------------------- |type| ent-id | identifier |
As in the case of the DUID-LLT, special values can be used for the configuration of the DUID-EN. If the "enterprise-id" is 0, the server will use a value from the existing DUID-EN. If the server is not using any DUID or the existing DUID has a different type, the ISC enterprise id will be used. When an empty string is used for "identifier", the identifier from the existing DUID-EN will be used. If the server is not using any DUID-EN the new 6-bytes long identifier will be generated.
DUID-LL is configured in the same way as DUID-LLT with an exception that the time parameter has no effect for DUID-LL, because this DUID type only comprises a hardware type and link layer address. The following example demonstrates how to configure DUID-LL:
"Dhcp6": { "server-id": { "type": "LL", "htype": 8, "identifier": "A65DC7410F05" }, ... }
which will result in the following server identifier:
00:03:00:08:A6:5D:C7:41:0F:05 ------------------------------ |type|htype| identifier |
Server stores a generated server identifier in the following
location: [kea-install-dir]/var/kea/kea-dhcp6-serverid
.
In some uncommon deployments where no stable storage is available, it is desired to configure the server to not try to store the server identifier on the stable storage. It is controlled by the value of persist boolean parameter:
"Dhcp6": { "server-id": { "type": "EN", "enterprise-id": 2495, "identifier": "87ABEF7A5BB545", "persist": false }, ... }
The default value of the "persist" parameter is true which configures the server to store the server identifier on a disk.
In the example above, the server is configured to not store the generated server identifier on a disk. But, if the server identifier is not modified in the configuration the same value will be used after server restart, because entire server identifier is explicitly specified in a configuration.
Typically DHCPv6 is used to assign both addresses and options. These assignments (leases) have state that changes over time, hence their name, stateful. DHCPv6 also supports a stateless mode, where clients request configuration options only. This mode is considered lightweight from the server perspective, as it does not require any state tracking; hence its name.
The Kea server supports stateless mode. Clients can send Information-Request messages and the server will send back answers with the requested options (providing the options are available in the server configuration). The server will attempt to use per-subnet options first. If that fails - for whatever reason - it will then try to provide options defined in the global scope.
Stateless and stateful mode can be used together. No special configuration directives are required to handle this. Simply use the configuration for stateful clients and the stateless clients will get just options they requested.
This usage of global options allows for an interesting case. It is possible to run a server that provides just options and no addresses or prefixes. If the options have the same value in each subnet, the configuration can define required options in the global scope and skip subnet definitions altogether. Here's a simple example of such a configuration:
"Dhcp6": {
"interfaces-config": {
"interfaces": [ "ethX" ]
},
"option-data": [ {
"name": "dns-servers",
"data": "2001:db8::1, 2001:db8::2"
} ]
,
"lease-database": { "type": "memfile" }
}
This very simple configuration will provide DNS server information to all clients in the network, regardless of their location. Note the specification of the memfile lease database: this is required since, as of version 0.9.1, Kea requires a lease database to be specified even if it is not used.
The RFC 7550 has introduced some changes to the DHCPv6 protocol to resolve a few issues with the coexistence of multiple stateful options in the messages sent between the clients and servers.
The typical example is when the client, such as a requesting router, requests an allocation of both addresses and prefixes when it performs the 4-way (SARR) exchange with the server. If the server is not configured to allocate any prefixes but it can allocate some addresses, it will respond with the IA_NA(s) containing allocated addresses and the IA_PD(s) containing the NoPrefixAvail status code. If the client can operate without prefixes it may transition to the 'bound' state when it sends Renew/Rebind messages to the server, according to the T1 and T2 times, to extend the lifetimes of the allocated addresses. If the client is still interested in obtaining prefixes from the server it may also include IA_PD in the Renew/Rebind to request allocation of the prefixes. If the server still cannot allocate the prefixes, it will respond with the IA_PD(s) containing NoPrefixAvail status code. However, if the server can now allocate the prefixes it will do so, and send them in the IA_PD(s) to the client. Allocation of leases during the Renew/Rebind was not supported in the RFC 3315 and RFC 3633, and has been introduced in RFC 7550. Kea supports this new behavior and it doesn't provide any configuration mechanisms to disable it.
The following are the other behaviors specified in the RFC 7550 supported by the Kea DHCPv6 server:
The relay has to have an interface connected to the link on which the clients are being configured. Typically the relay has a global IPv6 address configured on the interface that belongs to the subnet from which the server will assign addresses. In the typical case, the server is able to use the IPv6 address inserted by the relay (in the link-addr field in RELAY-FORW message) to select the appropriate subnet.
However, that is not always the case. The relay address may not match the subnet in certain deployments. This usually means that there is more than one subnet allocated for a given link. The two most common examples where this is the case are long lasting network renumbering (where both old and new address space is still being used) and a cable network. In a cable network both cable modems and the devices behind them are physically connected to the same link, yet they use distinct addressing. In such case, the DHCPv6 server needs additional information (like the value of interface-id option or IPv6 address inserted in the link-addr field in RELAY-FORW message) to properly select an appropriate subnet.
The following example assumes that there is a subnet 2001:db8:1::/64 that is accessible via relay that uses 3000::1 as its IPv6 address. The server will be able to select this subnet for any incoming packets that came from a relay that has an address in 2001:db8:1::/64 subnet. It will also select that subnet for a relay with address 3000::1.
"Dhcp6": {
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"pools": [
{
"pool": "2001:db8:1::1-2001:db8:1::ffff"
}
],
"relay": {
"ip-address": "3000::1"
}
}
]
}
In certain cases, it is useful to mix relay address information, introduced in Section 8.7, “Using specific relay agent for a subnet” with client classification, explained in Chapter 12, Client Classification. One specific example is a cable network, where typically modems get addresses from a different subnet than all devices connected behind them.
Let's assume that there is one CMTS (Cable Modem Termination System) with one CM MAC (a physical link that modems are connected to). We want the modems to get addresses from the 3000::/64 subnet, while everything connected behind modems should get addresses from another subnet (2001:db8:1::/64). The CMTS that acts as a relay an uses address 3000::1. The following configuration can serve that configuration:
"Dhcp6": { "subnet6": [ { "subnet": "3000::/64", "pools": [ { "pool": "3000::2 - 3000::ffff" } ],"client-class": "VENDOR_CLASS_docsis3.0", "relay": { "ip-address": "3000::1" }
}, { "subnet": "2001:db8:1::/64", "pools": [ { "pool": "2001:db8:1::1-2001:db8:1::ffff" } ],"relay": { "ip-address": "3000::1" }
} ] }
MAC/hardware addesses are available in DHCPv4 messages from the clients and administrators frequently use that information to perform certain tasks, like per host configuration, address reserveration for specific MAC addresses and other. Unfortunately, the DHCPv6 protocol does not provide any completely reliable way to retrieve that information. To mitigate that issue a number of mechanisms have been implemented in Kea that attempt to gather that information. Each of those mechanisms works in certain cases, but may fail in other cases. Whether the mechanism works or not in the particular deployment is somewhat dependent on the network topology and the technologies used.
Kea allows for configuration which of the supported methods should be used and in which order. This configuration may be considered a fine tuning of the DHCP deployment. In a typical deployment the default value of "any" is sufficient and there is no need to select specific methods. Changing the value of this parameter is the most useful in cases when an administrator wants to disable certain method, e.g. if the administrator trusts the network infrastructure more than the information provided by the clients themselves, the administrator may prefer information provided by the relays over that provided by the clients. The format of this parameter is as follows:
"Dhcp6": {
"mac-sources": [ "method1", "method2", "method3", ... ]
,
"subnet6": [ ... ],
...
}
When not specified, a special value of any is used, which instructs the server to attempt to use all the methods in sequence and use value returned by the first one that succeeds.
Supported methods are:
The DHCPv6 server is configured with a certain pool of addresses that it is expected to hand out to the DHCPv6 clients. It is assumed that the server is authoritative and has complete jurisdiction over those addresses. However, due to various reasons, such as misconfiguration or a faulty client implenetation that retains its address beyond the valid lifetime, there may be devices connected that use those addresses without the server's approval or knowledge.
Such an unwelcome event can be detected by legitimate clients (using Duplicate Address Detection) and reported to the DHCPv6 server using a DECLINE message. The server will do a sanity check (if the client declining an address really was supposed to use it), then will a conduct clean up operation and confirm it by sending back a REPLY message. Any DNS entries related to that address will be removed, the fact will be logged and hooks will be triggered. After that is done, the address will be marked as declined (which indicates that it is used by an unknown entity and thus not available for assignment to anyone) and a probation time will be set on it. Unless otherwise configured, the probation period lasts 24 hours. After that period, the server will recover the lease, i.e. put it back into the available state. The address will be available for assignment again. It should be noted that if the underlying issue of a misconfigured device is not resolved, the duplicate address scenario will repeat. On the other hand, it provides an opportunity to recover from such an event automatically, without any sysadmin intervention.
To configure the decline probation period to a value different than the default, the following syntax can be used:
"Dhcp6": {
"decline-probation-period": 3600
,
"subnet6": [ ... ],
...
}
The parameter is expressed in seconds, so the example above will instruct the server to recycle declined leases after an hour.
There are several statistics and hook points associated with the Decline handling procedure. The lease6_decline hook is triggered after the incoming Decline message has been sanitized and the server is about to decline the lease. The declined-addresses statistic is increased after the hook returns (both global and subnet specific variants).
Once the probation time elapses, the declined lease is recovered using the standard expired lease reclaimation procedure, with several additional steps. In particular, both declined-addresses statistics (global and subnet specific) are decreased. At the same time, reclaimed-declined-addresses statistics (again in two variants, global and subnet specific) are increased.
Note about statistics: The server does not decrease assigned-addresses statistics when a DECLINE message is received and processed successfully. While technically a declined address is no longer assigned, the primary usage of the assigned-addresses statistic is to monitor pool utilization. Most people would forget to include declined-addresses in the calculation, and simply do assigned-addresses/total-addresses. This would have a bias towards under-representing pool utilization. As this has a potential for major issues, we decided not to decrease assigned addresses immediately after receiving Decline, but to do it later when we recover the address back to the available pool.
This section describes DHCPv6-specific statistics. For a general overview and usage of statistics, see Chapter 14, Statistics.
The DHCPv6 server supports the following statistics:
Table 8.4. DHCPv6 Statistics
Statistic | Data Type | Description |
---|---|---|
pkt6-received | integer | Number of DHCPv6 packets received. This includes all packets: valid, bogus, corrupted, rejected etc. This statistic is expected to grow rapidly. |
pkt6-receive-drop | integer | Number of incoming packets that were dropped. Exact reason for dropping packets is logged, but the most common reasons may be: an unacceptable or not supported packet type, direct responses are forbidden, the server-id sent by the client does not match the server's server-id or the packet is malformed. |
pkt6-parse-failed | integer | Number of incoming packets that could not be parsed. A non-zero value of this statistic indicates that the server received a malformed or truncated packet. This may indicate problems in your network, faulty clients, faulty relay agents or server code bug. |
pkt6-solicit-received | integer | Number of SOLICIT packets received. This statistic is expected to grow. Its increase means that clients that just booted started their configuration process and their initial packets reached your server. |
pkt6-advertise-received | integer | Number of ADVERTISE packets received. Advertise packets are sent by the server and the server is never expected to receive them. A non-zero value of this statistic indicates an error ocurring in the network. One likely cause would be a misbehaving relay agent that incorrectly forwards ADVERTISE messages towards the server, rather back to the clients. |
pkt6-request-received | integer | Number of REQUEST packets received. This statistic is expected to grow. Its increase means that clients that just booted received the server's response (ADVERTISE), accepted it and are now requesting an address (REQUEST). |
pkt6-reply-received | integer | Number of REPLY packets received. This statistic is expected to remain zero at all times, as REPLY packets are sent by the server and the server is never expected to receive them. A non-zero value indicates an error. One likely cause would be a misbehaving relay agent that incorrectly forwards REPLY messages towards the server, rather back to the clients. |
pkt6-renew-received | integer | Number of RENEW packets received. This statistic is expected to grow. Its increase means that clients received their addresses and prefixes and are trying to renew them. |
pkt6-rebind-received | integer | Number of REBIND packets received. A non-zero value indicates that clients didn't receive responses to their RENEW messages (regular lease renewal mechanism) and are attempting to find any server that is able to take over their leases. It may mean that some server's REPLY messages never reached the clients. |
pkt6-release-received | integer | Number of RELEASE packets received. This statistic is expected to grow when a device is being shut down in the network. It indicates that the address or prefix assigned is reported as no longer needed. Note that many devices, especially wireless, do not send RELEASE, because of design choice or due to moving out of range. |
pkt6-decline-received | integer | Number of DECLINE packets received. This statistic is expected to remain close to zero. Its increase means that a client leased an address, but discovered that the address is currently used by an unknown device in your network. If this statistic is growing, it may indicate misconfigured server or devices that have statically assigned conflicting addresses. |
pkt6-infrequest-received | integer | Number of INFORMATION-REQUEST packets received. This statistic is expected to grow if there are devices that are using stateless DHCPv6. INFORMATION-REQUEST messages are used by clients that request stateless configuration, i.e. options and parameters other than addresses or prefixes. |
pkt6-unknown-received | integer | Number of packets received of an unknown type. Non-zero value of this statistic indicates that the server received a packet that it wasn't able to recognize: either with unsupported type or possibly malformed. |
pkt6-sent | integer | Number of DHCPv6 packets sent. This statistic is expected to grow every time the server transmits a packet. In general, it should roughly match pkt6-received, as most incoming packets cause the server to respond. There are exceptions (e.g. server receiving a REQUEST with server-id matching other server), so do not worry, if it is lesser than pkt6-received. |
pkt6-advertise-sent | integer | Number of ADVERTISE packets sent. This statistic is expected to grow in most cases after a SOLICIT is processed. There are certain uncommon, but valid cases where incoming SOLICIT is dropped, but in general this statistic is expected to be close to pkt6-solicit-received. |
pkt6-reply-sent | integer | Number of REPLY packets sent. This statistic is expected to grow in most cases after a SOLICIT (with rapid-commit), REQUEST, RENEW, REBIND, RELEASE, DECLINE or INFORMATION-REQUEST is processed. There are certain cases where there is no response. |
subnet[id].total-nas | integer | This statistic shows the total number of NA addresses available for DHCPv6 management for a given subnet. In other words, this is the sum of all addresses in all configured pools. This statistic changes only during configuration changes. Note it does not take into account any addresses that may be reserved due to host reservation. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. This statistic is reset during a reconfiguration event. |
subnet[id].assigned-nas | integer | This statistic shows the number of NA addresses in a given subnet that are assigned. This statistic increases every time a new lease is allocated (as a result of receiving a REQUEST message) and is decreased every time a lease is released (a RELEASE message is received) or expires. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. This statistic is reset during a reconfiguration event. |
subnet[id].total-pds | integer | This statistic shows the total number of PD prefixes available for DHCPv6 management for a given subnet. In other words, this is the sum of all prefixes in all configured pools. This statistic changes only during configuration changes. Note it does not take into account any prefixes that may be reserved due to host reservation. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. This statistic is reset during a reconfiguration event. |
subnet[id].assigned-pds | integer | This statistic shows the number of PD prefixes in a given subnet that are assigned. This statistic increases every time a new lease is allocated (as a result of receiving a REQUEST message) and is decreased every time a lease is released (a RELEASE message is received) or expires. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. This statistic is reset during a reconfiguration event. |
declined-addresses | integer | This statistic shows the number of IPv6 adresses that are currently declined. This statistic counts the number of leases currently unavailable. Once a lease is recovered, this statistic will be decreased. Ideally, this statistic should be zero. If this statistic is non-zero (or worse increasing), a network administrator should investigate if there is a misbehaving device in his network. This is a global statistic that covers all subnets. |
subnet[id].declined-addresses | integer | This statistic shows the number of IPv6 adresses that are currently declined in a given subnet. This statistic counts the number of leases currently unavailable. Once a lease is recovered, this statistic will be decreased. Ideally, this statistic should be zero. If this statistic is non-zero (or worse increasing), a network administrator should investigate if there is a misbehaving device in his network. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. |
reclaimed-declined-addresses | integer | This statistic shows the number of IPv6 adresses that were declined, but have now been recovered. Unlike declined-addresses, this statistic never decreases. It can be used as a long term indicator of how many actual valid Declines were processed and recovered from. This is a global statistic that covers all subnets. |
subnet[id].reclaimed-declined-addresses | integer | This statistic shows the number of IPv6 adresses that were declined, but have now been recovered. Unlike declined-addresses, this statistic never decreases. It can be used as a long term indicator of how many actual valid Declines were processed and recovered from. The id is the subnet-id of a given subnet. This statistic is exposed for each subnet separately. |
Management API has been introduced in Kea 0.9.2-beta. It allows issuing specific management commands, like statistics retrieval, reconfiguration or shutdown. For more details, see Chapter 15, Management API. Currently the only supported communication channel type is 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:
"Dhcp6": {
"control-socket": {
"socket-type": "unix",
"socket-name": "/path/to/the/unix/socket"
},
"subnet6": [
...
],
...
}
The length of the path specified by the socket-name parameter is restricted by the maximum length for the unix socket name on your 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. The typical values are 107 on Linux and 103 on FreeBSD.
Communication over control channel is conducted using JSON structures. See the Control Channel section in the Kea Developer's Guide for more details.
DHCPv6 server supports statistic-get, statistic-reset, statistic-remove, statistic-get-all, statistic-reset-all and statistic-remove-all, specified in Section 14.3, “Commands for Manipulating Statistics”. It also supports list-commands and shutdown, specified in Section 15.3.2, “list-commands command” and Section 15.3.3, “shutdown command”, respectively.
The following standards are currently supported:
These are the current limitations and known problems with the DHCPv6 server software. Most of them are reflections of the early stage of development and should be treated as “not implemented yet”, rather than actual limitations.
On-line configuration has some limitations. Adding new subnets or modifying existing ones work, as is removing the last subnet from the list. However, removing non-last (e.g. removing subnet 1,2 or 3 if there are 4 subnets configured) will cause issues. The problem is caused by simplistic subnet-id assignment. The subnets are always numbered, starting from 1. That subnet-id is then used in leases that are stored in the lease database. Removing non-last subnet will cause the configuration information to mismatch data in the lease database. It is possible to manually update subnet-id fields in MySQL or PostgreSQL database, but it is awkward and error prone process. A better reconfiguration support is planned.
Table of Contents
The primary role of the DHCP server is to assign addresses and/or delegate prefixes to DHCP clients. These addresses and prefixes are often referred to as 'leases'. Leases are typically assigned to clients for a finite amount of time, known as 'valid lifetime'. DHCP clients who wish to continue using their assigned leases, will periodically renew them by sending the appropriate message to the DHCP server. The DHCP server records the time when these leases are renewed and calculates new expiration times for them.
If the client does not renew a lease before its valid lifetime elapses, the lease is considered expired. There are many situations when the client may cease lease renewals. A common scenario is when the machine running the client shuts down for an extended period of time.
The process through which the DHCP server makes expired leases available for reassignment is referred to as "lease reclamation" and expired leases returned to availability through this process are referred to as "reclaimed". The DHCP server should reclaim an expired lease as soon as it detects that it has expired. One way in which the server may detect expiration is when it is trying to allocate a lease to a client and finds this lease already present in the database but expired. Another way the server detects expired leases is by periodically querying the lease database for them. Regardless of how an expired lease is detected, before it my assigned to a client, it must be reclaimed. This chapter explains how to configure the server to periodically query for the expired leases and how to minimize the impact of the periodic leases reclamation process on the server's responsiveness. Finally, 'lease affinity', which provides the means to assign the same lease to the returning client after its lease has expired, is explained.
Although, all configuration examples in this section are provided for the DHCPv4 server, the same parameters may be used for the DHCPv6 server configuration.
Lease reclamation is the process through which an expired lease becomes available for assignment to the same or a different client. This process involves the following steps for each reclaimed lease:
Please refer to Chapter 10, The DHCP-DDNS Server to see how to configure DNS updates in Kea, and to Chapter 13, Hooks Libraries for information about using hooks libraries.
Kea can be configured to periodically detect and reclaim expired leases. During this process the lease entries in the database are modified or removed. Therefore the server will not process incoming DHCP messages to avoid issues with concurrent access to database information. As a result, the server will be unresponsive while lease reclamation is performed. DHCP queries will accumulate and responses will be sent once the leases reclamation cycle is complete.
In deployments where response time is critical, administrators may wish to minimize the interruptions in service caused by lease reclamation. Toward this end, Kea provides configuration parameters to control: the frequency of lease reclamation cycles, the maximum number of leases processed in a single reclamation cycle, and the maximum amount of time a single reclamation cycle is allowed to run before being interrupted. The following examples demonstrate how these parameters can be used:
"Dhcp4": { ... "expired-leases-processing": { "reclaim-timer-wait-time": 5, "max-reclaim-leases": 0, "max-reclaim-time": 0, "flush-reclaimed-timer-wait-time": 0, }, ... }
The first parameter is expressed in seconds and specifies an interval between the two consecutive lease reclamation cycles. This is explained on the following diagram.
| c1 | | c2 | |c3| | c4 | |<---->|<---------->|<-->|<---------->|<>|<---------->|<-->| ----------------------------------------------------------------> | | 5s | | 5s | | 5s | | time
This diagram shows 4 leases reclamation cycles of variable duration. Note that the duration of the reclamation cycle depends on the number of expired leases detected and processed in the particular cycle. This duration is also usually significantly shorter than the interval between the cycles.
According to the reclamim-timer-wait-time the server keeps fixed intervals of 5 seconds between the end of one cycle and the start of the next cycle. This guarantees the presence of 5s long periods during which the server remains responsive to DHCP queries and does not perform leases reclamation. The max-reclaim-leases and max-reclaim-time are set to 0, which implies that there is no restriction on the maximum number of leases reclaimed in the particular cycle, or the maximum duration of each cycle.
In deployments with high lease pool utilization, relatively short valid lifetimes, and frequently disconnecting clients which allow leases to expire; the number of expired leases requiring reclamation at any given time may rise significantly. In this case it is often desirable to apply restrictions on the maximum duration of a reclamation cycle or the maximum number of leases reclaimed in a cycle. The following configuration demonstrates how this can be done:
"Dhcp4": { ... "expired-leases-processing": { "reclaim-timer-wait-time": 3, "max-reclaim-leases": 100, "max-reclaim-time": 50, "unwarned-reclaim-cycles": 10, "flush-reclaimed-timer-wait-time": 0, }, ... }
The max-reclaim-leases parameter limits the number of leases reclaimed in a single cycle to 100. The max-reclaim-time limits the maximum duration of each cycle to 50ms. The lease reclamation cycle will be interrupted if either of these limitations is reached. The reclamation of all unreclaimed leases will be attempted in subsequent cycles.
The following diagram illustrates the behavior of the system in the presence of many expired leases, when the limits are applied for the reclamation cycles.
| c1 | | c2 | | c3 | | c4 | |<-->|<-------------->|<-->|<-------------->|<-->|<-------------->|<-->|<-- ------------------------------------------------------------------------------> |50ms| 3s |50ms| 3s |50ms| 3s |50ms| time
The diagram demonstrates the case when each reclamation cycle would take more than 50ms, and thus is interrupted according to the value of the max-reclaim-time. This results in equal durations of all reclamation cycles over time. Note that in this example the limitation of maximum 100 leases is not reached. This may be the case when database transactions are slow or callouts in the hook libraries attached to the server are slow. Regardless, the choosing values for either the maximum number of leases or a maximum cycle time strongly depends on the particular deployment, lease database backend being used, and any hooks libraries etc. Administrators may need to experiment to tune the system to suit the dynamics of their deployment.
It is important to realize that with the use of these limits, there is a risk that expired leases will accumulate faster than the server can reclaim them. This should not be the problem if the server is dealing with a temporary burst of expirations, because it should be able to eventually deal with them over time. However, if leases expire at the high rate for a longer period of time, the unreclaimed leases will pile up in the database. In order to notify the administrator that the current configuration does not satisfy the needs for reclamation of expired leases, the server issues a warning message in the log, if it was unable to reclaim all leases within the last couple of reclamation cycles. The number of cycles after which such warning is issued is specified with the unwarned-reclaim-cycles configuration parameter.
Setting the reclaim-timer-wait-time to 0 disables periodic reclamation of the expired leases.
Suppose that a laptop goes to a sleep mode after a period of user inactivity. While the laptop is in sleep mode, its DHCP client will not renew leases obtained from the server and these leases will eventually expire. When the laptop wakes up, it is often desired that it continue using its previous assigned IP addresses. In order to facilitate this, the server needs to correlate returning clients with their expired leases When the client returns, the server will first check for those leases and re-assign them if they have not assigned to another client. The ability of the server to re-assign the same lease to a returning client is referred to as 'lease affinity'.
When lease affinity is enabled, the server will still reclaim leases according to the parameters described in Section 9.2, “Configuring Leases Reclamation”, but the reclaimed leases will be held in the database (rather than removed) for the specified amount of time. When the client returns, the server will first check if there are any reclaimed leases associated with this client and re-assign them if possible. However, it is important to note that any reclaimed lease may be assigned to another client if that client specifically asks for it. Therefore, the lease affinity does not guarantee that the reclaimed lease will be available for the client who used it before. It merely increases the chances for the client to be assigned the same lease. If the lease pool is small (mostly applies to DHCPv4 for which address space is small), there is an increased likelihood that the expired lease will be hijacked by another client.
Consider the following configuration:
"Dhcp4": { ... "expired-leases-processing": { "reclaim-timer-wait-time": 3, "hold-reclaimed-time": 1800, "flush-reclaimed-timer-wait-time": 5 }, ... }
The hold-reclaim-time specifies how many seconds after an expiration a reclaimed lease should be held in the database for re-assignment to the same client. In the example given above, reclaimed leases will be held for 30 minutes (1800s) after their expiration. During this time, the server will likely be able to re-assign the same lease to the returning client, unless another client requests this lease and the server assigns it.
The server must periodically remove reclaimed leases for which the time indicated by hold-reclaim-time has elapsed. The flush-reclaimed-timer-wait-time controls how often the server removes such leases. In the example provided above, the server will initiate removal of such leases 5 seconds after the previous removal attempt was completed. Setting this value to 0 disables lease affinity, in which case leases will be removed from the lease database when they are reclaimed. If lease affinity is enabled, it is recommended that hold-reclaim-time be set to a value significantly higher than the reclaim-timer-wait-time, as timely removal of expired-reclaimed leases is less critical while the removal process may impact server responsiveness.
The following list presents all configuration parameters pertaining to processing expired leases with their default values:
The default value for any parameter is used when this parameter not explicitly specified in the configuration. Also, the expired-leases-processing map may be omitted entirely in the configuration, in which case the default values are used for all parameters listed above.
The leases-reclaim command can be used to trigger leases reclamation at any time. Please consult the Section 15.3.1, “leases-reclaim command” for the details about using this command.
Table of Contents
The DHCP-DDNS Server (kea-dhcp-ddns, known informally as D2) conducts the client side of the DDNS protocol (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 upon DHCP lease change events and then post these to D2. D2 attempts to match each such request to the appropriate DNS server(s) and carry out the necessary conversation with those servers to update the DNS data.
In order 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 will compare the FQDN in the request against the name of each forward DDNS Domain. 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 will simply disregard the forward update portion of requests.
When conducting reverse domain matching, D2 constructs a reverse FQDN from the lease address in the request and compare 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, it is possible to 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. Finally, if there are no reverse DDNS Domains defined, D2 will simply disregard the reverse update portion of requests.
kea-dhcp-ddns is the Kea DHCP-DDNS server and, due to the nature of DDNS, it is run alongside either the DHCPv4 or DHCPv6 components (or both). Like other parts of Kea, it is a separate binary that can be run on its own or through keactrl (see Chapter 6, 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:
file
-
specifies the configuration file. This is the only mandatory
switch.The -V command returns the versions of the external libraries dynamically linked.
The -W command describes the environment used
to build Kea. This command displays a copy of the
config.report
file produced by
./configure
that is embedded in the
executable binary.
The config.report
may also be accessed more
directly. The following command may be used to extract this
information. The binary path
may be found
in the install directory or in the .libs
subdirectory in the source treee. For example
kea/src/bin/d2/.libs/kea-dhcp-ddns
.
strings path
/kea-dhcp-ddns | sed -n 's/;;;; //p'
Upon start up the module will load its configuration and begin listening for NCRs based on that configuration.
During startup the server will attempt to create a PID file of the form: [localstatedir]/[conf name].kea-dhcp-ddns.pid where:
If the file already exists and contains the PID of a live process, the server will issue a DHCP_DDNS_ALREADY_RUNNING log message and exit. 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 would be necessary to manually delete the PID file.
Before starting kea-dhcp-ddns module for the first time, a configuration file needs to be created. The following default configuration is a template that can be customised to your 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 as follows, each of which is described in its own section:
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,
...
}
}
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, but note that local users may still communicate with the DHCP-DDNS server. A future version of Kea will implement authentication to guard against such attacks.
If the ip-address and port are changed, it will be necessary to change the corresponding values in the DHCP servers' "dhcp-ddns" configuration section.
A DDNS protocol exchange can be conducted with or without 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 will use 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 will be 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:
As an example, suppose that a domain D2 will be updating is maintained by a BIND9 DNS server which requires dynamic updates to be secured with TSIG. Suppose further that the entry for the TSIG key in BIND9'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": [ ]
,
...
}
We must extend the list with a new key:
"DhcpDdns": {
"tsig-keys": [
{
"name": "key.four.example.com.",
"algorithm": "HMAC-SHA224",
"secret": "bZEG7Ow8OgAUPfLWV3aAUQ=="
}
],
...
}
These steps would be repeated for each TSIG key needed. Note that the same TSIG key can be used with more than one domain.
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 will cause the server to ignore the forward update portions of requests.
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. You will need one forward DDNS Domain for each zone you wish to service. It may very well be that some or all of your zones are maintained by the same servers. You will still need one DDNS Domain per 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:
To create a new forward DDNS Domain, one must add a new domain element and set its parameters:
"DhcpDdns": {
"forward-ddns": {
"ddns-domains": [
{
"name": "other.example.com.",
"key-name": "",
"dns-servers": [
]
}
]
}
}
It is permissible to add a domain without any servers. If that domain should be matched to a request, however, the request will fail. In order to make the domain useful though, we must add at least one DNS server to it.
This section describes how to add DNS servers to a Forward DDNS Domain. Repeat them for as many servers as desired for a 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:
To create a new forward DNS Server, one must add a new server element to the domain and fill in its parameters. If for example the service is running at "172.88.99.10", then set it as follows:
"DhcpDdns": {
"forward-ddns": {
"ddns-domains": [
{
"name": "other.example.com.",
"key-name": "",
"dns-servers": [
{
"hostname": "",
"ip-address": "172.88.99.10",
"port": 53
}
]
}
]
}
}
As stated earlier, "hostname" is not yet supported so, the parameter "ip-address" must be set to the address of the DNS server.
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 will cause the server to ignore the reverse update portions of requests.
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. You will need one reverse DDNS Domain for each zone you wish to service. It may very well be that some or all of your zones are maintained by the same servers; even then, you will still need one DDNS Domain entry 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:
To create a new reverse DDNS Domain, one must add a new domain element and set its parameters. 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 permissible to add a domain without any servers. If that domain should be matched to a request, however, the request will fail. In order to make the domain useful though, we must add at least one DNS server to it.
This section describes how to add DNS servers to a Reverse DDNS Domain. Repeat them for as many servers as desired for each domain.
Reverse DNS Server entries represents a actual DNS servers which support the server side of the DDNS protocol. Each Reverse DNS Server has the following parameters:
To create a new reverse DNS Server, one must first add a new server element to the domain and fill in its parameters. 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": [
{
"hostname": "",
"ip-address": "172.88.99.10",
"port": 53
}
]
}
]
}
}
As stated earlier, "hostname" is not yet supported so, the parameter "ip-address" must be set to the address of the DNS server.
This section provides an example DHCP-DDNS server configuration based on a small example network. Let's suppose our example network has three domains, each with their own subnet.
Table 10.1. Our example network
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:
Table 10.2. Forward DDNS Domains Needed
# | DDNS Domain Name | DNS Servers |
---|---|---|
1. | four.example.com. | 172.16.1.5, 172.16.2.5 |
2. | six.example.com. | 3001:1::50 |
3. | 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.", will match the first
domain ("four.example.com") while "admin.example.com." will match the
third domain ("example.com"). The
FQDN, "other.example.net." will fail to match any domain and would
be rejected.
The following example configuration specified the Forward DDNS Domains.
"DhcpDdns": {
"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" }
]
},
]
}
}
Similarly, we need to construct the three reverse DDNS Domains:
Table 10.3. Reverse DDNS Domains Needed
# | DDNS Domain Name | DNS Servers |
---|---|---|
1. | 2.0.192.in-addr.arpa. | 172.16.1.5, 172.16.2.5 |
2. | 1.0.0.0.8.d.b.0.1.0.0.2.ip6.arpa. | 3001:1::50 |
3. | 0.182.in-addr.arpa. | 172.16.2.5 |
An address of "192.0.2.150" will match the first domain,
"2001:db8:1::10" will match the second domain, and "192.0.50.77"
the third domain.
These Reverse DDNS Domains are specified as follows:
"DhcpDdns": {
"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" }
]
}
]
}
}
Table of Contents
kea-lfc is a service process that removes redundant infomation from the files used to provide persistent storage for the memfile data base backend. This service is written to run as a stand alone process.
While kea-lfc can be started externally, there is usually no need to do this. kea-lfc is run on a periodic basis by the Kea DHCP servers.
The process operates on a set of files, using them for input and output of the lease entries and to indicate where it is in the process in case of an interruption. Currently the caller must supply names for all of the files, in the future this requirement may be relaxed with the process getting the names from either the config file or from defaults.
kea-lfc is run as follows:
kea-lfc [-4 | -6] -c config-file -p pid-file -x previous-file -i copy-file -o output-file -f finish-file
The argument -4 or -6 selects the protocol version of the lease files.
The -c argument specifies the configuration file. This is required, but not currently used by the process.
The -p argument specifies the PID file. When the kea-lfc process starts it attempts to determine if another instance of the process is already running by examining the pid file. If one is already running the new process is terminated. If one isn't running it writes its pid into the pid file.
The other filenames specify where the kea-lfc process should look for input, write its output and use for bookkeeping.
There are several additional arguments mostly for debugging purposes. -d Sets the logging level to debug. -v and -V print out version stamps with -V providing a longer form. -h prints out the usage string.
Table of Contents
In certain cases it is useful to differentiate between different types of clients and treat them accordingly. Common reasons include:
The clients represent different pieces of topology, e.g. a cable modem is different to the clients behind that modem.
The clients have different behavior, e.g.a smart phone behaves differently to a lapttop.
The clients require different values for some options, e.g. a docsis3.0 cable modem requires different settings to docsis2.0 cable modem.
It is envisaged that client classification will be used for changing the behavior of almost any part of the DHCP message processing, including the assignment of leases from different pools, the assignment of different options (or different values of the same options) etc. In the current release of the software however, there are only three mechanisms that take advantage of client classification: subnet selection, assignment of different options and, for DHCPv4 cable modems, the setting of specific options for use with the TFTP server address and the boot file field.
The process of doing classification is conducted in three steps:
Assess an incoming packet and assign it to zero or more classes.
Choose a subnet, possibly based on the class information.
Assign options, again possibly based on the class information.
When determining which options to include in the response the server will examine the union of options from all of the assigned classes. In the case two or more classes include the same option, the value from the first class examined will be used. When choosing a subnet the server will iterate over all of the subnets that are feasible given the information found in the packet (client address, relay address etc). It will use the first subnet it finds that either doesn't have a class associated with it or that has a class which matches one of the packet's classes. In the future the processing order of the various classes may be specified but for now it is being left unspecified and may change in future releases.
As an example, imagine two classes. Class "foo" defines values for an NTP server (option 42 in DHCPv4) and an SMTP server (option 69 in DHCPv4) while class "bar" defines values for an NTP server and a POP3 server (option 70 in DHCPv4). The server will examine the three options NTP, SMTP and POP3 and return any of them that the client requested. As the NTP server was defined twice the server will choose only one of the values for the reply: the class from which the value is obtained is unspecified.
There are two methods of doing classification. The first is automatic and relies on examining the values in the vendor class options. Information from these options is extracted and a class name is constructed from it and added to the class list for the packet. The second allows you to specify an expression that is evaluated for each packet. If the result is true, the packet is a member of the class.
Care should be taken with client classification as it is easy for clients that do not meet class criteria to be denied any service altogether.
The server checks whether an incoming DHCPv4 packet includes the vendor class identifier option (60) or an incoming DHCPv6 packet includes the vendor class option (16). If it does, the content of that option is prepended with "VENDOR_CLASS_" and the result is interpreted as a class. For example, modern cable modems will send this option with value "docsis3.0" and so the packet will belong to class "VENDOR_CLASS_docsis3.0".
The expression portion of classification contains operators and values. All values are currently strings and operators take a string or strings and return another string. When all the operations have completed the result should be a value of "true" or "false". The packet belongs to the class (and the class name is added to the list of classes) if the result is "true". Expressions are written in standard format and can be nested.
Expressions are pre-processed during the parsing of the configuration file and converted to an internal representation. This allows certain types of errors to be caught and logged during parsing. Examples of these errors include incorrect number or types of arguments to an operator. The evaluation code will also check for this class of error and generally throw an exception, though they should not occur in a normally functioning system.
Other issues, for example the starting position of a substring being outside of the substring or an option not existing in the packet, result in the operator returning an empty string.
Expressions are a work in progress and the supported operators and values are limited. The expectation is that additional operators and values will be added over time, however it is expected the basic mechanisms will remain the same.
Table 12.1. List of Classification Values
Name | Example | Description |
---|---|---|
String | 'example' | A string |
Hex String | 0XABCD | A hexadecimal string |
Integer | 123 | An integer value |
Option Hex | option[code].hex | The value of the option with code "code" from the packet as hex |
Hex Strings are converted into a string as expected. The starting "0X" or
"0x" is removed and if the string is an odd number of characters a
"0" is prepended to it.
Integers in the expression are converted to strings when the expression is read into Kea.
"option[code].hex" extracts the value of the option with the given code from the incoming packet. If the packet doesn't contain the option, it returns the empty string. The string is presented as a byte string of the option payload without the type code or length fields.
Table 12.2. List of Classification Expressions
Name | Example | Description |
---|---|---|
Equal | 'foo' == 'bar' | Compare the two values and return "true" or "false" |
Substring | substring('foobar',0,3) | Return the requested substring |
substring('foobar', 0, 6) == 'foobar' substring('foobar', 3, 3) == 'bar' substring('foobar', 3, all) == 'bar' substring('foobar', 1, 4) == 'ooba' substring('foobar', -5, 4) == 'ooba' substring('foobar', -1, -3) == 'oba' substring('foobar', 4, -2) == 'ob' substring('foobar', 10, 2) == ''
The expression for each class is executed on each packet received. If the expressions are overly complex, the time taken to execute them may impact the performance of the server. If you need complex or time consuming expressions you should write a hook to perform the necessary work.
A class contains three items: a name, a test expression and option data. The name must exist and must be unique amongst all classes. The test expression and option data are optional.
The test expression is a string containing the logical expression used to determine membership in the class. The entire expression is in double quotes.
The option data is a list which defines any options that should be assigned to members of this class.
In the following example the class named "Client_foo" is defined. It is comprised of all clients who's client ids (option 61) start with the string "foo". Members of this class will be given 192.0.2.1 and 192.0.2.2 as their domain name servers.
"Dhcp4": {
"client-classes": [
{
"name": "Client_foo",
"test": "substring(option[61].hex,0,3) == 'foo'",
"option-data": [
{
"name": "domain-name-servers",
"code": 6,
"space": "dhcp4",
"csv-format": true,
"data": "192.0.2.1, 192.0.2.2"
}
]
},
...
],
...
}
This example shows a client class being defined for use by the DHCPv6 server. In it the class named "Client_enterprise" is defined. It is comprised of all clients who's client identifiers start with the given hex string (which would indicate a DUID based on an enterprise id of 0xAABBCCDD). Members of this class will be given an 2001:db8:0::1 and 2001:db8:2::1 as their domain name servers.
"Dhcp6": {
"client-classes": [
{
"name": "Client_enterprise",
"test": "substring(option[2].hex,0,6) == 0x0002AABBCCDD'",
"option-data": [
{
"name": "dns-servers",
"code": 23,
"space": "dhcp6",
"csv-format": true,
"data": "2001:db8:0::1, 2001:db8:2::1"
}
]
},
...
],
...
}
In certain cases it beneficial to restrict access to certain subnets only to clients that belong to a given class using the "client-class" keyword when defining the subnet.
Let's assume that the server is connected to a network segment that uses the 192.0.2.0/24 prefix. The Administrator of that network has decided that addresses from range 192.0.2.10 to 192.0.2.20 are going to be managed by the DHCP4 server. Only clients belonging to client class Client_foo are allowed to use this subnet. Such a configuration can be achieved in the following way:
"Dhcp4": {
"client-classes": [
{
"name": "Client_foo",
"test": "substring(option[61].hex,0,3) == 'foo'",
"option-data": [
{
"name": "domain-name-servers",
"code": 6,
"space": "dhcp4",
"csv-format": true,
"data": "192.0.2.1, 192.0.2.2"
}
]
},
...
],
"subnet4": [
{
"subnet": "192.0.2.0/24",
"pools": [ { "pool": "192.0.2.10 - 192.0.2.20" } ],
"client-class": "Client_foo"
},
...
],
,
...
}
The following example shows restricting access to a DHCPv6 subnet. This configuration will restrict use of the addresses 2001:db8:1::1 to 2001:db8:1::FFFF to members of the "Client_enterprise" class.
"Dhcp6": {
"client-classes": [
{
"name": "Client_enterprise",
"test": "substring(option[2].hex,0,6) == 0x0002AABBCCDD'",
"option-data": [
{
"name": "dns-servers",
"code": 23,
"space": "dhcp6",
"csv-format": true,
"data": "2001:db8:0::1, 2001:db8:2::1"
}
]
},
...
],
"subnet6": [
{
"subnet": "2001:db8:1::/64",
"pools": [ { "pool": "2001:db8:1::-2001:db8:1::ffff" } ],
"client-class": "Client_enterprise"
}
],
...
}
Currently classes can be used for two functions. They can supply options to the members of the class and they can be used to choose a subnet from which an address will be assigned to the class member.
When supplying options, options defined as part of the class definition are considered "class globals". They will override any global options that may be defined and in turn will be overridden by any options defined for an individual subnet.
You may use a hook to classify your packets. This may be useful if the expression would either be complex or time consuming and be easier or better to write as code. Once the hook has added the proper class name to the packet the rest of the classification system will work as normal in choosing a subnet and selecting options. For a description of the hooks see Chapter 13, Hooks Libraries, for a description on configuring he classes see Section 12.4, “Configuring Classes” and Section 12.5, “Configuring Subnets With Class Information”.
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Although Kea offers a lot of flexibility, there may be cases where its behavior needs customisation. To accommodate this possibility, Kea includes the idea of "Hooks". This feature lets Kea load one or more dynamically-linked libraries (known as "hooks libraries") and, at various points in its processing ("hook points"), call functions in them. Those functions perform whatever custom processing is required.
Hooks libraries are attached to individual Kea processes, not to Kea as a whole. This means (for example) that it is possible to associate one set of libraries with the DHCP4 server and a different set to the DHCP6 server.
Another point to note is that it is possible for a process to load multiple libraries. When processing reaches a hook point, Kea calls the hooks library functions attached to it. If multiple libraries have attached a function to a given hook point, Kea calls all of them, in the order in which the libraries are specified in the configuration file. The order may be important: consult the documentation of the libraries to see if this is the case.
The next section describes how to configure hooks libraries. If you are interested in writing your own hooks library, information can be found in the Kea Developer's Guide.
The hooks libraries for a given process are configured using the hooks-libraries keyword in the configuration for that process. (Note that the word "hooks" is plural). The value of the keyword is an array of map structures, each structure corresponding to a hooks library. For example, to set up two hooks libraries for the DHCPv4 server, the configuration would be:
"Dhcp4": {
:
"hooks-libraries": [
{
"library": "/opt/charging.so"
},
{
"library": "/opt/local/notification.so"
}
]
:
}
This is a change to the syntax used in Kea 0.9.2 and earlier, where hooks-libraries was a list of strings, each string being the name of a library. The change has been made in Kea 1.0 to facilitate the specification of library-specific parameters, a feature that will be added to a future version of Kea.
Notes:
The full path to each library should be given.
As noted above, order may be important - consult the documentation for each library.
An empty list has the same effect as omitting the hooks-libraries configuration element all together.
There is one case where this is not true: if Kea is running with a configuration that contains a hooks-libraries item, and that item is removed and the configuration reloaded, the removal will be ignored and the libraries remain loaded. As a workaround, instead of removing the hooks-libraries item, change it to an empty list. This will be fixed in a future version of Kea.
At the present time, only the kea-dhcp4 and kea-dhcp6 processes support hooks libraries.
Table of Contents
Both Kea DHCP servers support statistics gathering since 0.9.2-beta version. A working DHCP server encounters various events that can cause certain statistics to be collected. For example, a DHCPv4 server may receive a packet (pkt4-received statistic increases by one) that after parsing was identifier as DHCPDISCOVER (pkt4-discover-received). The Server processed it and decided to send DHCPOFFER representing its answer (pkt4-offer-sent and pkt4-sent statistics increase by one). Such events happen frequently, so it is not uncommon for the statistics to have values in high thousands. They can serve as an easy and powerful tool for observing a server's and network's health. For example, if pkt4-received statistic stops growing, it means that the clients' packets are not reaching the server.
There are four types of statistics:
During normal operation, DHCPv4 and DHCPv6 servers gather statistics. For a list of DHCPv4 and DHCPv6 statistics, see Section 7.7, “Statistics in DHCPv4 server” and Section 8.11, “Statistics in DHCPv6 server”, respectively.
To extract data from the statistics module, the control channel can be used. See Chapter 15, Management API for details. It is possible to retrieve a single or all statistics, reset statistics (i.e. set to neutral value, typically zero) or even remove completely a single or all statistics. See section Section 14.3, “Commands for Manipulating Statistics” for a list of statistic oriented commands.
It is useful to understand how the Statistics Manager module works. When the server starts operation, the manager is empty and does not have any statistics. When statistic-get-all is executed, an empty list is returned. Once the server performs an operation that causes a statistic to change, the related statistic will be created. In the general case once a statistic is recorded even once, it is kept in the manager, until explicitly removed, by statistic-remove or statistic-remove-all being called or the server is shut down. Per subnet statistics are explicitly removed when reconfiguration takes place.
Statistics are considered run-time properties, so they are not retained after server restart.
Removing a statistic that is updated frequently makes little sense as it will be re-added when the server code next records that statistic. The statistic-remove and statistic-remove-all commands are intended to remove statistics that are not expected to be observed in the near future. For example, a misconfigured device in a network may cause clients to report duplicate addresses, so the server will report increasing values of pkt4-decline-received. Once the problem is found and the device is removed, the system administrator may want to remove the pkt4-decline-received statistic, so it won't be reported anymore. If a duplicate address is detected ever again, the server will add this statistic back.
There are several commands defined that can be used for accessing (-get), resetting to zero or neutral value (-reset) or even removing a statistic completely (-remove). The difference between reset and remove is somewhat subtle. The reset command sets the value of the statistic to zero or neutral value. After this operation, the statistic will have a value of 0 (integer), 0.0 (float), 0h0m0s0us (duration) or "" (string). When asked for, a statistic with the values mentioned will be returned. Remove removes a statistic completely, so the statistic will not be reported anymore. Please note that the server code may add it back if there's a reason to record it.
statistic-get command retrieves a single statistic. It takes a single string parameter called name that specifies the statistic name. An example command may look like this:
{
"command": "statistic-get",
"arguments": {
"name": "pkt4-received
"
}
}
The server will respond with details of the requested statistic, with result set to 0 indicating success and the specified statistic as the value of "arguments" parameter. If the requested statistic is not found, the response will contain an empty map, i.e. only { } as argument, but the status code will still be set to success (0).
statistic-reset command sets the specified statistic to its neutral value: 0 for integer, 0.0 for float, 0h0m0s0us for time duration and "" for string type. It takes a single string parameter called name that specifies the statistic name. An example command may look like this:
{
"command": "statistic-reset",
"arguments": {
"name": "pkt4-received
"
}
}
If the specific statistic is found and reset was successful, the server will respond with a status of 0, indicating success and an empty parameters field. If an error is encountered (e.g. requested statistic was not found), the server will return a status code of 1 (error) and the text field will contain the error description.
statistic-remove command attempts to delete a single statistic. It takes a single string parameter called name that specifies the statistic name. An example command may look like this:
{
"command": "statistic-remove",
"arguments": {
"name": "pkt4-received
"
}
}
If the specific statistic is found and its removal was successful, the server will respond with a status of 0, indicating success and an empty parameters field. If an error is encountered (e.g. requested statistic was not found), the server will return a status code of 1 (error) and the text field will contain the error description.
statistic-get-all command retrieves all statistics recorded. An example command may look like this:
{ "command": "statistic-get-all", "arguments": { } }
The server will respond with details of all recorded statistics, with result set to 0 indicating that it iterated over all statistics (even when the total number of statistics is zero).
statistic-reset command sets all statistics to their neutral values: 0 for integer, 0.0 for float, 0h0m0s0us for time duration and "" for string type. An example command may look like this:
{ "command": "statistic-reset-all", "arguments": { } }
If the operation is successful, the server will respond with a status of 0, indicating success and an empty parameters field. If an error is encountered, the server will return a status code of 1 (error) and the text field will contain the error description.
statistic-remove-all command attempts to delete all statistics. An example command may look like this:
{ "command": "statistic-remove-all", "arguments": { } }
If the removal of all statistics was successful, the server will respond with a status of 0, indicating success and an empty parameters field. If an error is encountered, the server will return a status code of 1 (error) and the text field will contain the error description.
Table of Contents
A classic approach to daemon configuration assumes that the server's configuration is stored in the configuration files and when the configuration is changed, the daemon is restarted. This approach has the significant disadvantage of introducing periods of downtime, when client traffic is not handled. Another risk is that if the new configuration is invalid for whatever reason, the server may refuse to start, which will further extend the downtime period, until the issue is resolved.
To avoid such problems, both DHCPv4 and DHCPv6 servers introduced support for a mechanism that will allow on-line reconfiguration, without requiring server shutdown. Both servers can be instructed to open control sockets, which is a communication channel. The server is able to receive commands on that channel, act on them and report back status. While the set of commands supported in Kea 1.0 is limited, the number is expected to grow over time.
Currently the only supported type of control channel is UNIX stream socket. For details how to configure it, see Section 7.8, “Management API for the DHCPv4 server” and Section 8.12, “Management API for the DHCPv6 server”. It is likely that support for other control channel types will be added in the future.
Communication over control channel is conducted using JSON structures. If configured, Kea will open a socket and will listen for any incoming connections. A process connecting to this socket is expected to send JSON commands structured as follows:
{ "command": "foo", "arguments": { "param1": "value1", "param2": "value2", ... } }
command is the name of command to execute and is mandatory. arguments is a map of parameters required to carry out the given command. The exact content and format is command specific.
The server will process the incoming command and then send a response of the form:
{ "result": 0|1, "text": "textual description", "arguments": { "argument1": "value1", "argument2": "value2", ... } }
result indicates the outcome of the command. A value of 0 means success while any non-zero value designates an error. Currently 1 is used as a generic error, but additional error codes may be added in the future.text field typically appears when result is non-zero and contains a description of the error encountered, but it may also appear for successful results. That's command specific. arguments is a map of additional data values returned by the server, specific to the command issued. The map is always present, even if it contains no data values.
ISC does not provide a client for using control channel. The primary reason for that is the expectation is that the entity using control channel is typically an IPAM or similar network management/monitoring software which may have quite varied expectations regarding the client and is even likely to be written in languages different than C or C++. Therefore we only provide examples how one can take advantage of the API.
The easiest way is to use a tool called socat, a tool available from socat homepage, but it is also widely available in Linux and BSD distributions. Once Kea is started, one could connect to the control interface using the following command:
$ socat UNIX:/path/to/the/kea/socket -
where /path/to/the/kea/socket is the path specified in the Dhcp4/control-socket/socket-name parameter in the Kea configuration file.
It is also easy to open UNIX socket programmatically. An example of such a simplistic client written in C is available in the Kea Developer's Guide, chapter Control Channel Overview, section Using Control Channel.
leases-reclaim command instructs the server to reclaim all expired leases immediately. The command has the following JSON syntax:
{ "command": "leases-reclaim", "arguments": { "remove": true } }
The remove boolean parameter is mandatory and it indicates whether the reclaimed leases should be removed from the lease database (if true), or they should be left in the expired-reclaimed state (if false). The latter facilitates lease affinity, i.e. ability to re-assign expired lease to the same client which used this lease before. See Section 9.3, “Configuring Lease Affinity” for the details. Also, see Section 9.1, “Lease Reclamation” for the general information about the processing of expired leases (leases reclamation).
list-commands command retrieves a list of all commands supported by the server. It does not take any arguments. An example command may look like this:
{ "command": "list-commands", "arguments": { } }
The server will respond with a list of all supported commands. The arguments element will be a list of strings. Each string will convey one supported command.
shutdown command instructs the server to initiate its shutdown procedure. It is the equivalent of sending a SIGTERM singal to the process. This command does not take any arguments. An example command may look like this:
{ "command": "shutdown", "arguments": { } }
The server will respond with a confirmation that the shutdown procedure has been initiated.
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libdhcp++ is a common library written in C++ that handles many DHCP-related tasks, including:
While this library is currently used by Kea, it is designed to be a portable, universal library, useful for any kind of DHCP-related software.
Both the DHCPv4 and DHCPv6 components share network interface detection routines. Interface detection is currently supported on Linux, all BSD family (FreeBSD, NetBSD, OpenBSD), Mac OS X and Solaris 11 systems.
DHCPv4 requires special raw socket processing to send and receive packets from hosts that do not have IPv4 address assigned yet. Support for this operation is implemented on Linux, FreeBSD, NetBSD and OpenBSD. It is likely that DHCPv4 component will not work in certain cases on other systems.
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During its operation Kea may produce many messages. They differ in severity (some are more important than others) and source (some are produced by specific components, e.g. hooks). It is useful to understand which log messages are needed and which are not and configure your logging appropriately. For example, debug level messages can be safely ignored in a typical deployment. They are, however, very useful when debugging a problem.
The logging system in Kea is configured through the
Logging
structure in your configuration
file. All daemons (e.g. DHCPv4 and DHCPv6 servers) will use the
configuration in the Logging
structure to see
what should be logged and to where. This allows for sharing identical
logging configuration between daemons.
Within Kea, a message is logged through an entity called a "logger". Different components log messages through different loggers, and each logger can be configured independently of one another. Some components, in particular the DHCP server processes, may use multiple loggers to log messages pertaining to different logical functions of the component. For example, the DHCPv4 server is using one logger for messages pertaining to packet reception and transmission, another logger for messages related to lease allocation and so on. Some of the libraries used by the Kea servers, e.g. libdhcpsrv or libhooks library, use their own loggers.
Users implementing hooks libraries (code attached to the server at runtime) are responsible for creating the loggers used by those libraries. Such loggers should have unique names, different from the logger names used by Kea. In this way the messages emitted from the hooks library can be distingued from messages issued by the core Kea code. Unique names also allow the loggers to be configured independently of loggers used by Kea. Whenever it makes sense, a hook library can use multiple loggers to log messages pertaining to different logical parts of the library.
In the “Logging” structure of a configuration file you can specify the configuration for zero or more loggers (including loggers used by the proprietary hooks libraries). If there are no loggers specified, the code will use default values which cause Kea to log messages on at least INFO severity to standard output.
The three most important elements of a logger configuration
are the name
(the component that is
generating the messages), the severity
(what to log), and the output_options
(where to log).
Each logger in the system has a name, the name being that of the component binary file using it to log messages. For instance, if you want to configure logging for the DHCPv4 server, you add an entry for a logger named “kea-dhcp4”. This configuration will then be used by the loggers in the DHCPv4 server, and all the libraries used by it (unless a library defines its own logger and there is specific logger configuration that applies to that logger).
When diagnosing the problem with the server's operation, it is often desired to use the DEBUG logging level to obtain the verbose output from the server and libraries it uses. However, high verbosity may be an overkill for the logging system in cases when the server is processing high volume traffic. To mitigate this problem, Kea is using multiple loggers, which can be configured independently and which are responsible for logging messages from different functional parts of the server. If the user, trying to diagnose the problem, has a reasonably high confidence that the problem origins in a specific function of the server, or the problem is related to the specific type of operation, he may enable high verbosity only for the relevant logger, thus limiting the debug messages to the required minimum.
The loggers are associated with a particular library or binary of Kea. However, each library or binary may (and usually does) include multiple loggers. For example, the DHCPv4 server binary contains separate loggers for: packet parsing, for dropped packets, for callouts etc. Each logger "derives" its configuration from the root logger. In the typical case, the root logger configuration is the only logging configuration specified in the configuration file. Creating a specific configuration for the selected logger, thus overriding the configuration settings specified in the root logger configuration, requires putting its configuration aside of the root logger's configuration with some of the parameters modified.
To illustrate this, suppose you are using the DHCPv4 server with the root logger “kea-dhcp4” logging at the INFO level. In order to enable DEBUG verbosity for the DHCPv4 packet drops, you must create configuration entry for the logger called “kea-dhcp4.bad-packets” and specify severity DEBUG for this logger. All other configuration parameters may be omited for this logger if the logger should use the default values specified in the root logger's configuration.
If there are multiple logger specifications in the configuration that might match a particular logger, the specification with the more specific logger name takes precedence. For example, if there are entries for both “kea-dhcp4” and “kea-dhcp4.dhcpsrv”, the DHCPv4 server — and all libraries it uses that are not dhcpsrv — will log messages according to the configuration in the first entry (“kea-dhcp4”).
Currently defined loggers are:
Note that user-defined hook libraries should not use any of those loggers, and should define new loggers with names that correspond to the libraries using them. Suppose that the user created the library called “libpacket-capture” to dump packets received and transmitted by the server to the file. The appropriate name for the logger could be kea-dhcp4.packet-capture. Note that the hook library implementor only specifies the second part of this name, i.e. “packet-capture”. The first part is a root logger name and is prepended by the Kea logging system. It is also important to note that since this new logger is a child of a root logger, it inherits the configuration from the root logger, unless there is a separate configuration entry for the child logger which overrides the default configuration.
The list of loggers above excludes any loggers implemented in hooks libraries. Please consult the documentation of the specific hooks libraries for the names of loggers they define.
Additional loggers may be defined in the future. The easiest way to find out the logger name is to configure all logging to go to a single destination and look for specific logger names. See Section 17.2, “Logging Message Format” for details.
This specifies the category of messages logged. Each message is logged with an associated severity which may be one of the following (in descending order of severity):
When the severity of a logger is set to one of these values, it will only log messages of that severity, and the severities above it. The severity may also be set to NONE, in which case all messages from that logger are inhibited.
Each logger can have zero or more
output_options
. These specify where log
messages are sent. These are explained in detail below.
The other options for a logger are:
The main settings for an output option are the
destination
and a value called
output
, the meaning of which depends on
the destination that is set.
The destination is the type of output. It can be one of:
This value determines the type of output. There are several special values allowed here: stdout (messages are printed on standard output), stderr (messages are printed on stderr), syslog (messages are logged to syslog using default name, syslog:name (messages are logged to syslog using specified name). Any other value is interpreted as a filename that the logs should be written to.
The other options for output_options
are:
Flush buffers after each log message. Doing this will reduce performance but will ensure that if the program terminates abnormally, all messages up to the point of termination are output. Default is true.
Only relevant when destination is file, this is maximum file size of output files in bytes. When the maximum size is reached, the file is renamed and a new file opened. (For example, a ".1" is appended to the name — if a ".1" file exists, it is renamed ".2", etc.)
If this is 0, no maximum file size is used.
Due to a limitation of the underlying logging library (log4cplus), rolling over the log files (from ".1" to ".2", etc) may show odd results: There can be multiple small files at the timing of roll over. This can happen when multiple processes try to roll over the files simultaneously. Version 1.1.0 of log4cplus solved this problem, so if this or higher version of log4cplus is used to build Kea, it shouldn't happen. Even for older versions it is normally expected to happen rarely unless the log messages are produced very frequently by multiple different processes.
In this example we want to set the global logging to write to the console using standard output.
"Logging": {
"loggers": [
{
"name": "kea-dhcp4",
"output_options": [
{
"output": "stdout"
}
],
"severity": "WARN"
}
]
}
In this second example, we want to store debug log messages in a file that is at most 2MB and keep up to 8 copies of old logfiles. Once the logfile grows to 2MB, it will be renamed and a new file file be created.
"Logging": {
"loggers": [
{
"name": "kea-dhcp6",
"output_options": [
{
"output": "/var/log/kea-debug.log",
"maxver": 8,
"maxsize": 204800,
"flush": true
}
],
"severity": "DEBUG",
"debuglevel": 99
}
]
}
Each message written to the configured logging destinations comprises a number of components that identify the origin of the message and, if the message indicates a problem, information about the problem that may be useful in fixing it.
Consider the message below logged to a file:
2014-04-11 12:58:01.005 INFO [kea-dhcp4.dhcpsrv/27456] DHCPSRV_MEMFILE_DB opening memory file lease database: type=memfile universe=4
Note: the layout of messages written to the system logging file (syslog) may be slightly different. This message has been split across two lines here for display reasons; in the logging file, it will appear on one line.
The log message comprises a number of components:
The date and time at which the message was generated.
The severity of the message.
The source of the message. This comprises two elements: the Kea process generating the message (in this case, kea-dhcp4) and the component within the program from which the message originated (which is the name of the common library used by DHCP server implementations). The number after the slash is a process id (pid).
The message identification. Every message in Kea has a unique identification, which can be used as an index into the Kea Messages Manual (http://kea.isc.org/docs/kea-messages.html) from which more information can be obtained.
A brief description. Within this text, information relating to the condition that caused the message to be logged will be included. In this example, the information is logged that the in-memory lease database backend will be used to store DHCP leases.
The logging configuration is specified in the configuration file. However, when Kea starts, the file is not read until some way into the initialization process. Prior to that, the logging settings are set to default values, although it is possible to modify some aspects of the settings by means of environment variables. Note that in the absence of any logging configuration in the configuration file, the settings of (possibly modified) default configuration will persist while the program is running.
The following environment variables can be used to control the behavio of logging during startup:
Specifies a directory where the logging system should create its
lock file. If not specified, it is
prefix
/var/run/kea, where
prefix
defaults to /usr/local.
This variable must not end
with a slash. There is one special value: "none", which
instructs Kea to not create lock file at all. This may cause
issues if several processes log to the same file.
Specifies logging output. There are several special values.
Log to standard output.
Log to standard error.
fac
]
Log via syslog. The optional
fac
(which is
separated from the word "syslog" by a colon)
specifies the
facility to be used for the log messages. Unless
specified, messages will be logged using the
facility "local0".
Any other value is treated as a name of the output file. If not specified otherwise, Kea will log to standard output.
Table of Contents
This chapter contains a number of frequently asked questions and troubleshooting tips. It currently lacks content, but it is expected to grow over time.
Kea is the name of a high mountain parrot living in New Zealand. See this https://lists.isc.org/pipermail/kea-users/2014-October/000032.html for an extended answer.
Kea is developed by a small team of engineers. Our resources are limited, so we need to prioritize requests. The complexity of a new feature (how difficult it is to implement a feature and how likely it would break something that already works), amount of work required and expected popularity (i.e., how many users would actually benefit from it) are three leading factors. We sometimes also have contractual obligations.
Simply stating that you'd like feature X is useful. We try to implement features that are actively requested first, but the reality is that we have more requests than we can handle, so some of them must be postponed, at least in the near future. So is your request likely to be rejected? Not at all. You can do many things to greatly improve the chances of your request being fulfilled. First, it helps to explain why you need a feature. If your explanation is reasonable and there are likely other users that would benefit from it, the chances for Kea developers to put this task on a roadmap is better. Saying that you are willing to participate in tests (e.g., test engineering drops when they become available) is also helpful.
Another thing you can do to greatly improve the chances of a feature to appear is to actually develop it on your own and submit a patch. That's an avenue that people often forget about. Kea is open source software and we do accept patches. There are certain requirements, like code quality, comments, unit-tests, documentation, etc., but we have accepted a significant number of patches in the past, so it's doable. Accepted contributions range from minor documentation corrections to significant new features, like support for a new database type. Before considering writing and submitting a patch, make sure you read the Contributor's Guide in Kea Developer's Guide.
Kea is developed by ISC, which is a non-profit organization. You may consider signing a development contract with us. In the past we did implement certain features due to contractual obligations. With additional funds we are able to put extra engineering efforts into Kea development. We can reshuffle our schedule or add extra hands to the team if needed. Please keep in mind that Kea is open source software and its principle goal is to provide a good DHCP solution that can be used by everyone. In other words, we may refuse a contract that would tie the solution to specific proprietary technology or make it unusable for other users. Also, we strive to make Kea a reference implementation, so if your proposal significantly violates a RFC, we may have a problem with that. Nevertheless, please talk to us and we may be able to find a solution.
Finally, Kea has a public roadmap, with releases happening several times each year. We tend to not modify plans for the current milestone, unless there are very good reasons to do so. Therefore "I'd like a feature X in 6 months" is much better received than "I'd like a feature X now".
Any DHCPv4 server must be able to receive from and send traffic to hosts that don't have an IPv4 address assigned yet. That is typically not possible with regular UDP sockets, therefore the Kea DHCPv4 server uses raw sockets by default. Raw sockets mean that the incoming packets are received as raw Ethernet frames, thus bypassing the whole kernel IP stack, including any firewalling rules your kernel may provide.
If you do not want the server to use raw sockets, it is possible to configure the Kea DHCPv4 server to use UDP sockets instead. See dhcp-socket-type described in Section 7.2.4, “Interface configuration”. However, using UDP sockets has certain limitations. In particular, they may not allow for sending responses directly to clients without IPv4 addresses assigned. That's ok, if all your traffic is coming through relay agents.
Please check whether your OS has any IPv6 filtering rules. Many operating systems are shipped with firewalls that discard incoming IPv6 traffic by default. In particular, many Linux distributions do that. Please check the output of the following command:
# ip6tables -L -n
One common mistake in this area is to use iptables tool, which lists IPv4 firewall rules only.
Kea is primarily designed, developed, and maintained by Internet Systems Consortium, Inc. It is an open source project and contributions are welcomed.
Support for the development of the DHCPv4, DHCPv6 and DHCP-DDNS components was provided by Comcast.
Kea was initially implemented as a collection of applications within the BIND 10 framework. Hence, Kea development would not be possible without the generous support of past BIND 10 project sponsors.
JPRS and CIRA were Patron Level BIND 10 sponsors.
AFNIC, CNNIC, CZ.NIC, DENIC eG, Google, RIPE NCC, Registro.br, .nz Registry Services, and Technical Center of Internet were past BIND 10 sponsors.
Afilias, IIS.SE, Nominet, and SIDN were founding sponsors of the BIND 10 project.