Table of Contents
Access Control Lists (ACLs) are address match lists that you can set up and nickname for future use in allow-notify, allow-query, allow-query-on, allow-recursion, blackhole, allow-transfer, match-clients, etc.
Using ACLs allows you to have finer control over who can access your name server, without cluttering up your config files with huge lists of IP addresses.
It is a good idea to use ACLs, and to control access to your server. Limiting access to your server by outside parties can help prevent spoofing and denial of service (DoS) attacks against your server.
ACLs match clients on the basis of up to three characteristics: 1) The client's IP address; 2) the TSIG or SIG(0) key that was used to sign the request, if any; and 3) an address prefix encoded in an EDNS Client Subnet option, if any.
Here is an example of ACLs based on client addresses:
// Set up an ACL named "bogusnets" that will block // RFC1918 space and some reserved space, which is // commonly used in spoofing attacks. acl bogusnets { 0.0.0.0/8; 192.0.2.0/24; 224.0.0.0/3; 10.0.0.0/8; 172.16.0.0/12; 192.168.0.0/16; }; // Set up an ACL called our-nets. Replace this with the // real IP numbers. acl our-nets { x.x.x.x/24; x.x.x.x/21; }; options { ... ... allow-query { our-nets; }; allow-recursion { our-nets; }; ... blackhole { bogusnets; }; ... }; zone "example.com" { type master; file "m/example.com"; allow-query { any; }; };
This allows authoritative queries for "example.com" from any address, but recursive queries only from the networks specified in "our-nets", and no queries at all from the networks specified in "bogusnets".
In addition to network addresses and prefixes, which are
matched against the source address of the DNS request, ACLs
may include key
elements, which specify the
name of a TSIG or SIG(0) key.
When BIND 9 is built with GeoIP support,
ACLs can also be used for geographic access restrictions.
This is done by specifying an ACL element of the form:
geoip [db database
] field
value
The field
indicates which field
to search for a match. Available fields are "country",
"region", "city", "continent", "postal" (postal code),
"metro" (metro code), "area" (area code), "tz" (timezone),
"isp", "asnum", and "domain".
value
is the value to search
for within the database. A string may be quoted if it
contains spaces or other special characters. An "asnum"
search for autonomous system number can be specified using
the string "ASNNNN" or the integer NNNN.
When "country" search is specified with a string is two
characters long, then it must be a standard ISO-3166-1
two-letter country code; otherwise it is interpreted as
the full name of the country. Similarly, if this is a
"region" search and the string is two characters long,
then it treated as a standard two-letter state or province
abbreviation; otherwise it treated as the full name of the
state or province.
The database
field indicates which
GeoIP database to search for a match. In most cases this is
unnecessary, because most search fields can only be found in
a single database. However, searches for "continent" or "country"
can be answered from either the "city" or "country" databases,
so for these search types, specifying a
database
will force the query to be answered from that database and no
other. If database
is not
specified, then these queries will be answered from the "city",
database if it is installed, or the "country" database if it
is installed, in that order. Valid database names are
"country", "city", "asnum", "isp", and "domain". (If using
the legacy GeoIP API, "netspeed" and "org" databases are also
available.)
Some example GeoIP ACLs:
geoip country US; geoip country JP; geoip db country country Canada; geoip region WA; geoip city "San Francisco"; geoip region Oklahoma; geoip postal 95062; geoip tz "America/Los_Angeles"; geoip org "Internet Systems Consortium";
ACLs use a "first-match" logic rather than "best-match": if an address prefix matches an ACL element, then that ACL is considered to have matched even if a later element would have matched more specifically. For example, the ACL { 10/8; !10.0.0.1; } would actually match a query from 10.0.0.1, because the first element indicated that the query should be accepted, and the second element is ignored.
When using "nested" ACLs (that is, ACLs included or referenced within other ACLs), a negative match of a nested ACL will the containing ACL to continue looking for matches. This enables complex ACLs to be constructed, in which multiple client characteristics can be checked at the same time. For example, to construct an ACL which allows queries only when it originates from a particular network and only when it is signed with a particular key, use:
allow-query { !{ !10/8; any; }; key example; };
Within the nested ACL, any address that is not in the 10/8 network prefix will be rejected, and this will terminate processing of the ACL. Any address that is in the 10/8 network prefix will be accepted, but this causes a negative match of the nested ACL, so the containing ACL continues processing. The query will then be accepted if it is signed by the key "example", and rejected otherwise. The ACL, then, will only matches when both conditions are true.
On UNIX servers, it is possible to run BIND
in a chrooted environment (using
the chroot() function) by specifying
the -t
option for named.
This can help improve system security by placing
BIND in a "sandbox", which will limit
the damage done if a server is compromised.
Another useful feature in the UNIX version of BIND is the
ability to run the daemon as an unprivileged user ( -u
user
).
We suggest running as an unprivileged user when using the chroot feature.
Here is an example command line to load BIND in a chroot sandbox, /var/named, and to run named setuid to user 202:
/usr/local/sbin/named -u 202 -t /var/named
In order for a chroot environment
to work properly in a particular directory (for example,
/var/named
), you will need to set
up an environment that includes everything
BIND needs to run. From
BIND's point of view,
/var/named
is the root of the
filesystem. You will need to adjust the values of
options like directory and
pid-file to account for this.
Unlike with earlier versions of BIND, you typically will
not need to compile named
statically nor install shared libraries under the new root.
However, depending on your operating system, you may need
to set up things like
/dev/zero
,
/dev/random
,
/dev/log
, and
/etc/localtime
.
Prior to running the named daemon, use the touch utility (to change file access and modification times) or the chown utility (to set the user id and/or group id) on files to which you want BIND to write.
If the named daemon is running as an unprivileged user, it will not be able to bind to new restricted ports if the server is reloaded.
Access to the dynamic update facility should be strictly limited. In earlier versions of BIND, the only way to do this was based on the IP address of the host requesting the update, by listing an IP address or network prefix in the allow-update zone option. This method is insecure since the source address of the update UDP packet is easily forged. Also note that if the IP addresses allowed by the allow-update option include the address of a slave server which performs forwarding of dynamic updates, the master can be trivially attacked by sending the update to the slave, which will forward it to the master with its own source IP address causing the master to approve it without question.
For these reasons, we strongly recommend that updates be cryptographically authenticated by means of transaction signatures (TSIG). That is, the allow-update option should list only TSIG key names, not IP addresses or network prefixes. Alternatively, the new update-policy option can be used.
Some sites choose to keep all dynamically-updated DNS data in a subdomain and delegate that subdomain to a separate zone. This way, the top-level zone containing critical data such as the IP addresses of public web and mail servers need not allow dynamic update at all.
BIND 9.14.11 (Stable Release)