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unbound.conf(5) unbound 1.18.0 unbound.conf(5)

unbound.conf - Unbound configuration file.

unbound.conf

unbound.conf is used to configure unbound(8). The file format has attributes and values. Some attributes have attributes inside them. The notation is: attribute: value.

Comments start with # and last to the end of line. Empty lines are ignored as is whitespace at the beginning of a line.

The utility unbound-checkconf(8) can be used to check unbound.conf prior to usage.

There must be whitespace between keywords. Attribute keywords end with a colon ':'. An attribute is followed by a value, or its containing attributes in which case it is referred to as a clause. Clauses can be repeated throughout the file (or included files) to group attributes under the same clause.

Files can be included using the include: directive. It can appear anywhere, it accepts a single file name as argument. Processing continues as if the text from the included file was copied into the config file at that point. If also using chroot, using full path names for the included files works, relative pathnames for the included names work if the directory where the daemon is started equals its chroot/working directory or is specified before the include statement with directory: dir. Wildcards can be used to include multiple files, see glob(7).

For a more structural include option, the include-toplevel: directive can be used. This closes whatever clause is currently active (if any) and forces the use of clauses in the included files and right after this directive.

These options are part of the server: clause.

The verbosity number, level 0 means no verbosity, only errors. Level 1 gives operational information. Level 2 gives detailed operational information including short information per query. Level 3 gives query level information, output per query. Level 4 gives algorithm level information. Level 5 logs client identification for cache misses. Default is level 1. The verbosity can also be increased from the commandline, see unbound(8).
The number of seconds between printing statistics to the log for every thread. Disable with value 0 or "". Default is disabled. The histogram statistics are only printed if replies were sent during the statistics interval, requestlist statistics are printed for every interval (but can be 0). This is because the median calculation requires data to be present.
If enabled, statistics are cumulative since starting Unbound, without clearing the statistics counters after logging the statistics. Default is no.
If enabled, extended statistics are printed from unbound-control(8). Default is off, because keeping track of more statistics takes time. The counters are listed in unbound-control(8).
If enabled, selected extended statistics with a value of 0 are inhibited from printing with unbound-control(8). These are query types, query classes, query opcodes, answer rcodes (except NOERROR, FORMERR, SERVFAIL, NXDOMAIN, NOTIMPL, REFUSED) and RPZ actions. Default is on.
The number of threads to create to serve clients. Use 1 for no threading.
The port number, default 53, on which the server responds to queries.
Interface to use to connect to the network. This interface is listened to for queries from clients, and answers to clients are given from it. Can be given multiple times to work on several interfaces. If none are given the default is to listen to localhost. If an interface name is used instead of an ip address, the list of ip addresses on that interface are used. The interfaces are not changed on a reload (kill -HUP) but only on restart. A port number can be specified with @port (without spaces between interface and port number), if not specified the default port (from port) is used.
Same as interface: (for ease of compatibility with nsd.conf).
Listen on all addresses on all (current and future) interfaces, detect the source interface on UDP queries and copy them to replies. This is a lot like ip-transparent, but this option services all interfaces whilst with ip-transparent you can select which (future) interfaces Unbound provides service on. This feature is experimental, and needs support in your OS for particular socket options. Default value is no.
List the port numbers that interface-automatic listens on. If empty, the default port is listened on. The port numbers are separated by spaces in the string. Default is "".
This can be used to have interface automatic to deal with the interface, and listen on the normal port number, by including it in the list, and also https or dns over tls port numbers by putting them in the list as well.
Interface to use to connect to the network. This interface is used to send queries to authoritative servers and receive their replies. Can be given multiple times to work on several interfaces. If none are given the default (all) is used. You can specify the same interfaces in interface: and outgoing-interface: lines, the interfaces are then used for both purposes. Outgoing queries are sent via a random outgoing interface to counter spoofing.
If an IPv6 netblock is specified instead of an individual IPv6 address, outgoing UDP queries will use a randomised source address taken from the netblock to counter spoofing. Requires the IPv6 netblock to be routed to the host running Unbound, and requires OS support for unprivileged non-local binds (currently only supported on Linux). Several netblocks may be specified with multiple outgoing-interface: options, but do not specify both an individual IPv6 address and an IPv6 netblock, or the randomisation will be compromised. Consider combining with prefer-ip6: yes to increase the likelihood of IPv6 nameservers being selected for queries. On Linux you need these two commands to be able to use the freebind socket option to receive traffic for the ip6 netblock: ip -6 addr add mynetblock/64 dev lo && ip -6 route add local mynetblock/64 dev lo
Number of ports to open. This number of file descriptors can be opened per thread. Must be at least 1. Default depends on compile options. Larger numbers need extra resources from the operating system. For performance a very large value is best, use libevent to make this possible.
Permit Unbound to open this port or range of ports for use to send queries. A larger number of permitted outgoing ports increases resilience against spoofing attempts. Make sure these ports are not needed by other daemons. By default only ports above 1024 that have not been assigned by IANA are used. Give a port number or a range of the form "low-high", without spaces.
The outgoing-port-permit and outgoing-port-avoid statements are processed in the line order of the config file, adding the permitted ports and subtracting the avoided ports from the set of allowed ports. The processing starts with the non IANA allocated ports above 1024 in the set of allowed ports.
Do not permit Unbound to open this port or range of ports for use to send queries. Use this to make sure Unbound does not grab a port that another daemon needs. The port is avoided on all outgoing interfaces, both IP4 and IP6. By default only ports above 1024 that have not been assigned by IANA are used. Give a port number or a range of the form "low-high", without spaces.
Number of outgoing TCP buffers to allocate per thread. Default is 10. If set to 0, or if do-tcp is "no", no TCP queries to authoritative servers are done. For larger installations increasing this value is a good idea.
Number of incoming TCP buffers to allocate per thread. Default is 10. If set to 0, or if do-tcp is "no", no TCP queries from clients are accepted. For larger installations increasing this value is a good idea.
Number of bytes size to advertise as the EDNS reassembly buffer size. This is the value put into datagrams over UDP towards peers. The actual buffer size is determined by msg-buffer-size (both for TCP and UDP). Do not set higher than that value. Default is 1232 which is the DNS Flag Day 2020 recommendation. Setting to 512 bypasses even the most stringent path MTU problems, but is seen as extreme, since the amount of TCP fallback generated is excessive (probably also for this resolver, consider tuning the outgoing tcp number).
Maximum UDP response size (not applied to TCP response). 65536 disables the udp response size maximum, and uses the choice from the client, always. Suggested values are 512 to 4096. Default is 1232. The default value is the same as the default for edns-buffer-size.
Number of bytes size maximum to use for waiting stream buffers. Default is 4 megabytes. A plain number is in bytes, append 'k', 'm' or 'g' for kilobytes, megabytes or gigabytes (1024*1024 bytes in a megabyte). As TCP and TLS streams queue up multiple results, the amount of memory used for these buffers does not exceed this number, otherwise the responses are dropped. This manages the total memory usage of the server (under heavy use), the number of requests that can be queued up per connection is also limited, with further requests waiting in TCP buffers.
Number of bytes size of the message buffers. Default is 65552 bytes, enough for 64 Kb packets, the maximum DNS message size. No message larger than this can be sent or received. Can be reduced to use less memory, but some requests for DNS data, such as for huge resource records, will result in a SERVFAIL reply to the client.
Number of bytes size of the message cache. Default is 4 megabytes. A plain number is in bytes, append 'k', 'm' or 'g' for kilobytes, megabytes or gigabytes (1024*1024 bytes in a megabyte).
Number of slabs in the message cache. Slabs reduce lock contention by threads. Must be set to a power of 2. Setting (close) to the number of cpus is a reasonable guess.
The number of queries that every thread will service simultaneously. If more queries arrive that need servicing, and no queries can be jostled out (see jostle-timeout), then the queries are dropped. This forces the client to resend after a timeout; allowing the server time to work on the existing queries. Default depends on compile options, 512 or 1024.
Timeout used when the server is very busy. Set to a value that usually results in one roundtrip to the authority servers. If too many queries arrive, then 50% of the queries are allowed to run to completion, and the other 50% are replaced with the new incoming query if they have already spent more than their allowed time. This protects against denial of service by slow queries or high query rates. Default 200 milliseconds. The effect is that the qps for long-lasting queries is about (numqueriesperthread / 2) / (average time for such long queries) qps. The qps for short queries can be about (numqueriesperthread / 2) / (jostletimeout in whole seconds) qps per thread, about (1024/2)*5 = 2560 qps by default.
Extra delay for timeouted UDP ports before they are closed, in msec. Default is 0, and that disables it. This prevents very delayed answer packets from the upstream (recursive) servers from bouncing against closed ports and setting off all sort of close-port counters, with eg. 1500 msec. When timeouts happen you need extra sockets, it checks the ID and remote IP of packets, and unwanted packets are added to the unwanted packet counter.
Perform connect for UDP sockets that mitigates ICMP side channel leakage. Default is yes.
The wait time in msec for waiting for an unknown server to reply. Increase this if you are behind a slow satellite link, to eg. 1128. That would then avoid re-querying every initial query because it times out. Default is 376 msec.
If not 0, then set the SO_RCVBUF socket option to get more buffer space on UDP port 53 incoming queries. So that short spikes on busy servers do not drop packets (see counter in netstat -su). Default is 0 (use system value). Otherwise, the number of bytes to ask for, try "4m" on a busy server. The OS caps it at a maximum, on linux Unbound needs root permission to bypass the limit, or the admin can use sysctl net.core.rmem_max. On BSD change kern.ipc.maxsockbuf in /etc/sysctl.conf. On OpenBSD change header and recompile kernel. On Solaris ndd -set /dev/udp udp_max_buf 8388608.
If not 0, then set the SO_SNDBUF socket option to get more buffer space on UDP port 53 outgoing queries. This for very busy servers handles spikes in answer traffic, otherwise 'send: resource temporarily unavailable' can get logged, the buffer overrun is also visible by netstat -su. Default is 0 (use system value). Specify the number of bytes to ask for, try "4m" on a very busy server. The OS caps it at a maximum, on linux Unbound needs root permission to bypass the limit, or the admin can use sysctl net.core.wmem_max. On BSD, Solaris changes are similar to so-rcvbuf.
If yes, then open dedicated listening sockets for incoming queries for each thread and try to set the SO_REUSEPORT socket option on each socket. May distribute incoming queries to threads more evenly. Default is yes. On Linux it is supported in kernels >= 3.9. On other systems, FreeBSD, OSX it may also work. You can enable it (on any platform and kernel), it then attempts to open the port and passes the option if it was available at compile time, if that works it is used, if it fails, it continues silently (unless verbosity 3) without the option. At extreme load it could be better to turn it off to distribute the queries evenly, reported for Linux systems (4.4.x).
If yes, then use IP_TRANSPARENT socket option on sockets where Unbound is listening for incoming traffic. Default no. Allows you to bind to non-local interfaces. For example for non-existent IP addresses that are going to exist later on, with host failover configuration. This is a lot like interface-automatic, but that one services all interfaces and with this option you can select which (future) interfaces Unbound provides service on. This option needs Unbound to be started with root permissions on some systems. The option uses IP_BINDANY on FreeBSD systems and SO_BINDANY on OpenBSD systems.
If yes, then use IP_FREEBIND socket option on sockets where Unbound is listening to incoming traffic. Default no. Allows you to bind to IP addresses that are nonlocal or do not exist, like when the network interface or IP address is down. Exists only on Linux, where the similar ip-transparent option is also available.
The value of the Differentiated Services Codepoint (DSCP) in the differentiated services field (DS) of the outgoing IP packet headers. The field replaces the outdated IPv4 Type-Of-Service field and the IPv6 traffic class field.
Number of bytes size of the RRset cache. Default is 4 megabytes. A plain number is in bytes, append 'k', 'm' or 'g' for kilobytes, megabytes or gigabytes (1024*1024 bytes in a megabyte).
Number of slabs in the RRset cache. Slabs reduce lock contention by threads. Must be set to a power of 2.
Time to live maximum for RRsets and messages in the cache. Default is 86400 seconds (1 day). When the TTL expires, the cache item has expired. Can be set lower to force the resolver to query for data often, and not trust (very large) TTL values. Downstream clients also see the lower TTL.
Time to live minimum for RRsets and messages in the cache. Default is 0. If the minimum kicks in, the data is cached for longer than the domain owner intended, and thus less queries are made to look up the data. Zero makes sure the data in the cache is as the domain owner intended, higher values, especially more than an hour or so, can lead to trouble as the data in the cache does not match up with the actual data any more.
Time to live maximum for negative responses, these have a SOA in the authority section that is limited in time. Default is 3600. This applies to nxdomain and nodata answers.
Time to live for entries in the host cache. The host cache contains roundtrip timing, lameness and EDNS support information. Default is 900.
Number of slabs in the infrastructure cache. Slabs reduce lock contention by threads. Must be set to a power of 2.
Number of hosts for which information is cached. Default is 10000.
Lower limit for dynamic retransmit timeout calculation in infrastructure cache. Default is 50 milliseconds. Increase this value if using forwarders needing more time to do recursive name resolution.
Upper limit for dynamic retransmit timeout calculation in infrastructure cache. Default is 2 minutes.
If enabled the server keeps probing hosts that are down, in the one probe at a time regime. Default is no. Hosts that are down, eg. they did not respond during the one probe at a time period, are marked as down and it may take infra-host-ttl time to get probed again.
Define the tags that can be used with local-zone and access-control. Enclose the list between quotes ("") and put spaces between tags.
Enable or disable whether ip4 queries are answered or issued. Default is yes.
Enable or disable whether ip6 queries are answered or issued. Default is yes. If disabled, queries are not answered on IPv6, and queries are not sent on IPv6 to the internet nameservers. With this option you can disable the IPv6 transport for sending DNS traffic, it does not impact the contents of the DNS traffic, which may have ip4 and ip6 addresses in it.
If enabled, prefer IPv4 transport for sending DNS queries to internet nameservers. Default is no. Useful if the IPv6 netblock the server has, the entire /64 of that is not owned by one operator and the reputation of the netblock /64 is an issue, using IPv4 then uses the IPv4 filters that the upstream servers have.
If enabled, prefer IPv6 transport for sending DNS queries to internet nameservers. Default is no.
Enable or disable whether UDP queries are answered or issued. Default is yes.
Enable or disable whether TCP queries are answered or issued. Default is yes.
Maximum segment size (MSS) of TCP socket on which the server responds to queries. Value lower than common MSS on Ethernet (1220 for example) will address path MTU problem. Note that not all platform supports socket option to set MSS (TCP_MAXSEG). Default is system default MSS determined by interface MTU and negotiation between server and client.
Maximum segment size (MSS) of TCP socket for outgoing queries (from Unbound to other servers). Value lower than common MSS on Ethernet (1220 for example) will address path MTU problem. Note that not all platform supports socket option to set MSS (TCP_MAXSEG). Default is system default MSS determined by interface MTU and negotiation between Unbound and other servers.
The period Unbound will wait for a query on a TCP connection. If this timeout expires Unbound closes the connection. This option defaults to 30000 milliseconds. When the number of free incoming TCP buffers falls below 50% of the total number configured, the option value used is progressively reduced, first to 1% of the configured value, then to 0.2% of the configured value if the number of free buffers falls below 35% of the total number configured, and finally to 0 if the number of free buffers falls below 20% of the total number configured. A minimum timeout of 200 milliseconds is observed regardless of the option value used.
The period Unbound will keep TCP persistent connections open to authority servers. This option defaults to 60000 milliseconds.
The maximum number of queries that can be sent on a persistent TCP connection. This option defaults to 200 queries.
Timeout in milliseconds for TCP queries to auth servers. This option defaults to 3000 milliseconds.
Enable or disable EDNS TCP Keepalive. Default is no.
The period Unbound will wait for a query on a TCP connection when EDNS TCP Keepalive is active. If this timeout expires Unbound closes the connection. If the client supports the EDNS TCP Keepalive option, Unbound sends the timeout value to the client to encourage it to close the connection before the server times out. This option defaults to 120000 milliseconds. When the number of free incoming TCP buffers falls below 50% of the total number configured, the advertised timeout is progressively reduced to 1% of the configured value, then to 0.2% of the configured value if the number of free buffers falls below 35% of the total number configured, and finally to 0 if the number of free buffers falls below 20% of the total number configured. A minimum actual timeout of 200 milliseconds is observed regardless of the advertised timeout.
UDP queries that have waited in the socket buffer for a long time can be dropped. Default is 0, disabled. The time is set in seconds, 3 could be a good value to ignore old queries that likely the client does not need a reply for any more. This could happen if the host has not been able to service the queries for a while, i.e. Unbound is not running, and then is enabled again. It uses timestamp socket options.
Enable or disable whether the upstream queries use TCP only for transport. Default is no. Useful in tunneling scenarios. If set to no you can specify TCP transport only for selected forward or stub zones using forward-tcp-upstream or stub-tcp-upstream respectively.
Enable udp upstream even if do-udp is no. Default is no, and this does not change anything. Useful for TLS service providers, that want no udp downstream but use udp to fetch data upstream.
Enabled or disable whether the upstream queries use TLS only for transport. Default is no. Useful in tunneling scenarios. The TLS contains plain DNS in TCP wireformat. The other server must support this (see tls-service-key). If you enable this, also configure a tls-cert-bundle or use tls-win-cert or tls-system-cert to load CA certs, otherwise the connections cannot be authenticated. This option enables TLS for all of them, but if you do not set this you can configure TLS specifically for some forward zones with forward-tls-upstream. And also with stub-tls-upstream.
Alternate syntax for tls-upstream. If both are present in the config file the last is used.
If enabled, the server provides DNS-over-TLS or DNS-over-HTTPS service on the TCP ports marked implicitly or explicitly for these services with tls-port or https-port. The file must contain the private key for the TLS session, the public certificate is in the tls-service-pem file and it must also be specified if tls-service-key is specified. The default is "", turned off. Enabling or disabling this service requires a restart (a reload is not enough), because the key is read while root permissions are held and before chroot (if any). The ports enabled implicitly or explicitly via tls-port: and https-port: do not provide normal DNS TCP service. Unbound needs to be compiled with libnghttp2 in order to provide DNS-over-HTTPS.
Alternate syntax for tls-service-key.
The public key certificate pem file for the tls service. Default is "", turned off.
Alternate syntax for tls-service-pem.
The port number on which to provide TCP TLS service, default 853, only interfaces configured with that port number as @number get the TLS service.
Alternate syntax for tls-port.
If null or "", no file is used. Set it to the certificate bundle file, for example "/etc/pki/tls/certs/ca-bundle.crt". These certificates are used for authenticating connections made to outside peers. For example auth-zone urls, and also DNS over TLS connections. It is read at start up before permission drop and chroot.
Alternate syntax for tls-cert-bundle.
Add the system certificates to the cert bundle certificates for authentication. If no cert bundle, it uses only these certificates. Default is no. On windows this option uses the certificates from the cert store. Use the tls-cert-bundle option on other systems. On other systems, this option enables the system certificates.
This the same setting as the tls-win-cert setting, under a different name. Because it is not windows specific.
List portnumbers as tls-additional-port, and when interfaces are defined, eg. with the @port suffix, as this port number, they provide dns over TLS service. Can list multiple, each on a new statement.
If not "", lists files with 80 bytes of random contents that are used to perform TLS session resumption for clients using the Unbound server. These files contain the secret key for the TLS session tickets. First key use to encrypt and decrypt TLS session tickets. Other keys use to decrypt only. With this you can roll over to new keys, by generating a new first file and allowing decrypt of the old file by listing it after the first file for some time, after the wait clients are not using the old key any more and the old key can be removed. One way to create the file is dd if=/dev/random bs=1 count=80 of=ticket.dat The first 16 bytes should be different from the old one if you create a second key, that is the name used to identify the key. Then there is 32 bytes random data for an AES key and then 32 bytes random data for the HMAC key.
Set the list of ciphers to allow when serving TLS. Use "" for defaults, and that is the default.
Set the list of ciphersuites to allow when serving TLS. This is for newer TLS 1.3 connections. Use "" for defaults, and that is the default.
If enabled, TLS serviced queries that contained an EDNS Padding option will cause responses padded to the closest multiple of the size specified in pad-responses-block-size. Default is yes.
The block size with which to pad responses serviced over TLS. Only responses to padded queries will be padded. Default is 468.
If enabled, all queries sent over TLS upstreams will be padded to the closest multiple of the size specified in pad-queries-block-size. Default is yes.
The block size with which to pad queries sent over TLS upstreams. Default is 128.
Enable or disable sending the SNI extension on TLS connections. Default is yes. Changing the value requires a reload.
The port number on which to provide DNS-over-HTTPS service, default 443, only interfaces configured with that port number as @number get the HTTPS service.
The HTTP endpoint to provide DNS-over-HTTPS service on. Default "/dns-query".
Number used in the SETTINGS_MAX_CONCURRENT_STREAMS parameter in the HTTP/2 SETTINGS frame for DNS-over-HTTPS connections. Default 100.
Maximum number of bytes used for all HTTP/2 query buffers combined. These buffers contain (partial) DNS queries waiting for request stream completion. An RST_STREAM frame will be send to streams exceeding this limit. Default is 4 megabytes. A plain number is in bytes, append 'k', 'm' or 'g' for kilobytes, megabytes or gigabytes (1024*1024 bytes in a megabyte).
Maximum number of bytes used for all HTTP/2 response buffers combined. These buffers contain DNS responses waiting to be written back to the clients. An RST_STREAM frame will be send to streams exceeding this limit. Default is 4 megabytes. A plain number is in bytes, append 'k', 'm' or 'g' for kilobytes, megabytes or gigabytes (1024*1024 bytes in a megabyte).
Set TCP_NODELAY socket option on sockets used to provide DNS-over-HTTPS service. Ignored if the option is not available. Default is yes.
Disable use of TLS for the downstream DNS-over-HTTP connections. Useful for local back end servers. Default is no.
List port numbers as proxy-protocol-port, and when interfaces are defined, eg. with the @port suffix, as this port number, they support and expect PROXYv2. In this case the proxy address will only be used for the network communication and initial ACL (check if the proxy itself is denied/refused by configuration). The proxied address (if any) will then be used as the true client address and will be used where applicable for logging, ACL, DNSTAP, RPZ and IP ratelimiting. PROXYv2 is supported for UDP and TCP/TLS listening interfaces. There is no support for PROXYv2 on a DoH or DNSCrypt listening interface. Can list multiple, each on a new statement.
Enable or disable systemd socket activation. Default is no.
Enable or disable whether the Unbound server forks into the background as a daemon. Set the value to no when Unbound runs as systemd service. Default is yes.
Allow up to limit simultaneous TCP connections from the given netblock. When at the limit, further connections are accepted but closed immediately. This option is experimental at this time.
The netblock is given as an IP4 or IP6 address with /size appended for a classless network block. The action can be deny, refuse, allow, allow_setrd, allow_snoop, allow_cookie, deny_non_local or refuse_non_local. The most specific netblock match is used, if none match refuse is used. The order of the access-control statements therefore does not matter.
The deny action stops queries from hosts from that netblock.
The refuse action stops queries too, but sends a DNS rcode REFUSED error message back.
The allow action gives access to clients from that netblock. It gives only access for recursion clients (which is what almost all clients need). Nonrecursive queries are refused.
The allow action does allow nonrecursive queries to access the local-data that is configured. The reason is that this does not involve the Unbound server recursive lookup algorithm, and static data is served in the reply. This supports normal operations where nonrecursive queries are made for the authoritative data. For nonrecursive queries any replies from the dynamic cache are refused.
The allow_setrd action ignores the recursion desired (RD) bit and treats all requests as if the recursion desired bit is set. Note that this behavior violates RFC 1034 which states that a name server should never perform recursive service unless asked via the RD bit since this interferes with trouble shooting of name servers and their databases. This prohibited behavior may be useful if another DNS server must forward requests for specific zones to a resolver DNS server, but only supports stub domains and sends queries to the resolver DNS server with the RD bit cleared.
The allow_snoop action gives nonrecursive access too. This give both recursive and non recursive access. The name allow_snoop refers to cache snooping, a technique to use nonrecursive queries to examine the cache contents (for malicious acts). However, nonrecursive queries can also be a valuable debugging tool (when you want to examine the cache contents). In that case use allow_snoop for your administration host.
The allow_cookie action allows access to UDP queries that contain a valid DNS Cookie as specified in RFC 7873 and RFC 9018, when the answer-cookie option is enabled. UDP queries containing only a DNS Client Cookie and no Server Cookie, or an invalid DNS Cookie, will receive a BADCOOKIE response including a newly generated DNS Cookie, allowing clients to retry with that DNS Cookie. The allow_cookie action will also accept requests over stateful transports, regardless of the presence of an DNS Cookie and regardless of the answer-cookie setting. If ip-ratelimit is used, clients with a valid DNS Cookie will bypass the ratelimit. If a ratelimit for such clients is still needed, ip-ratelimit-cookie can be used instead.
By default only localhost is allowed, the rest is refused. The default is refused, because that is protocol-friendly. The DNS protocol is not designed to handle dropped packets due to policy, and dropping may result in (possibly excessive) retried queries.
The deny_non_local and refuse_non_local settings are for hosts that are only allowed to query for the authoritative local-data, they are not allowed full recursion but only the static data. With deny_non_local, messages that are disallowed are dropped, with refuse_non_local they receive error code REFUSED.
Assign tags to access-control elements. Clients using this access control element use localzones that are tagged with one of these tags. Tags must be defined in define-tags. Enclose list of tags in quotes ("") and put spaces between tags. If access-control-tag is configured for a netblock that does not have an access-control, an access-control element with action allow is configured for this netblock.
Set action for particular tag for given access control element. If you have multiple tag values, the tag used to lookup the action is the first tag match between access-control-tag and local-zone-tag where "first" comes from the order of the define-tag values.
Set redirect data for particular tag for given access control element.
Set view for given access control element.
Similar to access-control: but for interfaces.
The action is the same as the ones defined under access-control:. Interfaces are refused by default. By default only localhost (the IP netblock, not the loopback interface) is allowed through the default access-control: behavior.
Note that the interface needs to be already specified with interface: and that any access-control*: setting overrides all interface-*: settings for targeted clients.
Similar to access-control-tag: but for interfaces.
Note that the interface needs to be already specified with interface: and that any access-control*: setting overrides all interface-*: settings for targeted clients.
Similar to access-control-tag-action: but for interfaces.
Note that the interface needs to be already specified with interface: and that any access-control*: setting overrides all interface-*: settings for targeted clients.
Similar to access-control-tag-data: but for interfaces.
Note that the interface needs to be already specified with interface: and that any access-control*: setting overrides all interface-*: settings for targeted clients.
Similar to access-control-view: but for interfaces.
Note that the interface needs to be already specified with interface: and that any access-control*: setting overrides all interface-*: settings for targeted clients.
If chroot is enabled, you should pass the configfile (from the commandline) as a full path from the original root. After the chroot has been performed the now defunct portion of the config file path is removed to be able to reread the config after a reload.
All other file paths (working dir, logfile, roothints, and key files) can be specified in several ways: as an absolute path relative to the new root, as a relative path to the working directory, or as an absolute path relative to the original root. In the last case the path is adjusted to remove the unused portion.
The pidfile can be either a relative path to the working directory, or an absolute path relative to the original root. It is written just prior to chroot and dropping permissions. This allows the pidfile to be /var/run/unbound.pid and the chroot to be /var/unbound, for example. Note that Unbound is not able to remove the pidfile after termination when it is located outside of the chroot directory.
Additionally, Unbound may need to access /dev/urandom (for entropy) from inside the chroot.
If given a chroot is done to the given directory. By default chroot is enabled and the default is "/var/unbound". If you give "" no chroot is performed.
If given, after binding the port the user privileges are dropped. Default is "_unbound". If you give username: "" no user change is performed.
If this user is not capable of binding the port, reloads (by signal HUP) will still retain the opened ports. If you change the port number in the config file, and that new port number requires privileges, then a reload will fail; a restart is needed.
Sets the working directory for the program. Default is "/var/unbound/etc". On Windows the string "%EXECUTABLE%" tries to change to the directory that unbound.exe resides in. If you give a server: directory: dir before include: file statements then those includes can be relative to the working directory.
If "" is given, logging goes to stderr, or nowhere once daemonized. The logfile is appended to, in the following format:
[seconds since 1970] unbound[pid:tid]: type: message.
If this option is given, the use-syslog is option is set to "no". The logfile is reopened (for append) when the config file is reread, on SIGHUP.
Sets Unbound to send log messages to the syslogd, using syslog(3). The log facility LOG_DAEMON is used, with identity "unbound". The logfile setting is overridden when use-syslog is turned on. The default is to log to syslog.
If "" is given (default), then the name of the executable, usually "unbound" is used to report to the log. Enter a string to override it with that, which is useful on systems that run more than one instance of Unbound, with different configurations, so that the logs can be easily distinguished against.
Sets logfile lines to use a timestamp in UTC ascii. Default is no, which prints the seconds since 1970 in brackets. No effect if using syslog, in that case syslog formats the timestamp printed into the log files.
Prints one line per query to the log, with the log timestamp and IP address, name, type and class. Default is no. Note that it takes time to print these lines which makes the server (significantly) slower. Odd (nonprintable) characters in names are printed as '?'.
Prints one line per reply to the log, with the log timestamp and IP address, name, type, class, return code, time to resolve, from cache and response size. Default is no. Note that it takes time to print these lines which makes the server (significantly) slower. Odd (nonprintable) characters in names are printed as '?'.
Prints the word 'query' and 'reply' with log-queries and log-replies. This makes filtering logs easier. The default is off (for backwards compatibility).
Print log lines to inform about local zone actions. These lines are like the local-zone type inform prints out, but they are also printed for the other types of local zones.
Print log lines that say why queries return SERVFAIL to clients. This is separate from the verbosity debug logs, much smaller, and printed at the error level, not the info level of debug info from verbosity.
The process id is written to the file. Default is to not write to a file.
Read the root hints from this file. Default is nothing, using builtin hints for the IN class. The file has the format of zone files, with root nameserver names and addresses only. The default may become outdated, when servers change, therefore it is good practice to use a root-hints file.
If enabled id.server and hostname.bind queries are refused.
Set the identity to report. If set to "", the default, then the hostname of the server is returned.
If enabled version.server and version.bind queries are refused.
Set the version to report. If set to "", the default, then the package version is returned.
If enabled the HTTP header User-Agent is not set. Use with caution as some webserver configurations may reject HTTP requests lacking this header. If needed, it is better to explicitly set the http-user-agent below.
Set the HTTP User-Agent header for outgoing HTTP requests. If set to "", the default, then the package name and version are used.
Add the specified nsid to the EDNS section of the answer when queried with an NSID EDNS enabled packet. As a sequence of hex characters or with ascii_ prefix and then an ascii string.
If enabled trustanchor.unbound queries are refused.
Set the target fetch policy used by Unbound to determine if it should fetch nameserver target addresses opportunistically. The policy is described per dependency depth.
The number of values determines the maximum dependency depth that Unbound will pursue in answering a query. A value of -1 means to fetch all targets opportunistically for that dependency depth. A value of 0 means to fetch on demand only. A positive value fetches that many targets opportunistically.
Enclose the list between quotes ("") and put spaces between numbers. The default is "3 2 1 0 0". Setting all zeroes, "0 0 0 0 0" gives behaviour closer to that of BIND 9, while setting "-1 -1 -1 -1 -1" gives behaviour rumoured to be closer to that of BIND 8.
Very small EDNS buffer sizes from queries are ignored. Default is on, as described in the standard.
Very large queries are ignored. Default is off, since it is legal protocol wise to send these, and could be necessary for operation if TSIG or EDNS payload is very large.
Will trust glue only if it is within the servers authority. Default is yes.
Require DNSSEC data for trust-anchored zones, if such data is absent, the zone becomes bogus. If turned off, and no DNSSEC data is received (or the DNSKEY data fails to validate), then the zone is made insecure, this behaves like there is no trust anchor. You could turn this off if you are sometimes behind an intrusive firewall (of some sort) that removes DNSSEC data from packets, or a zone changes from signed to unsigned to badly signed often. If turned off you run the risk of a downgrade attack that disables security for a zone. Default is yes.
From RFC 8020 (with title "NXDOMAIN: There Really Is Nothing Underneath"), returns nxdomain to queries for a name below another name that is already known to be nxdomain. DNSSEC mandates noerror for empty nonterminals, hence this is possible. Very old software might return nxdomain for empty nonterminals (that usually happen for reverse IP address lookups), and thus may be incompatible with this. To try to avoid this only DNSSEC-secure nxdomains are used, because the old software does not have DNSSEC. Default is yes. The nxdomain must be secure, this means nsec3 with optout is insufficient.
Harden the referral path by performing additional queries for infrastructure data. Validates the replies if trust anchors are configured and the zones are signed. This enforces DNSSEC validation on nameserver NS sets and the nameserver addresses that are encountered on the referral path to the answer. Default no, because it burdens the authority servers, and it is not RFC standard, and could lead to performance problems because of the extra query load that is generated. Experimental option. If you enable it consider adding more numbers after the target-fetch-policy to increase the max depth that is checked to.
Harden against algorithm downgrade when multiple algorithms are advertised in the DS record. If no, allows the weakest algorithm to validate the zone. Default is no. Zone signers must produce zones that allow this feature to work, but sometimes they do not, and turning this option off avoids that validation failure.
Harden against unknown records in the authority section and additional section. Default is no. If no, such records are copied from the upstream and presented to the client together with the answer. If yes, it could hamper future protocol developments that want to add records.
Use 0x20-encoded random bits in the query to foil spoof attempts. This perturbs the lowercase and uppercase of query names sent to authority servers and checks if the reply still has the correct casing. Disabled by default. This feature is an experimental implementation of draft dns-0x20.
Exempt the domain so that it does not receive caps-for-id perturbed queries. For domains that do not support 0x20 and also fail with fallback because they keep sending different answers, like some load balancers. Can be given multiple times, for different domains.
Alternate syntax for caps-exempt.
Send minimum amount of information to upstream servers to enhance privacy. Only send minimum required labels of the QNAME and set QTYPE to A when possible. Best effort approach; full QNAME and original QTYPE will be sent when upstream replies with a RCODE other than NOERROR, except when receiving NXDOMAIN from a DNSSEC signed zone. Default is yes.
QNAME minimisation in strict mode. Do not fall-back to sending full QNAME to potentially broken nameservers. A lot of domains will not be resolvable when this option in enabled. Only use if you know what you are doing. This option only has effect when qname-minimisation is enabled. Default is no.
Aggressive NSEC uses the DNSSEC NSEC chain to synthesize NXDOMAIN and other denials, using information from previous NXDOMAINs answers. Default is yes. It helps to reduce the query rate towards targets that get a very high nonexistent name lookup rate.
Give IPv4 of IPv6 addresses or classless subnets. These are addresses on your private network, and are not allowed to be returned for public internet names. Any occurrence of such addresses are removed from DNS answers. Additionally, the DNSSEC validator may mark the answers bogus. This protects against so-called DNS Rebinding, where a user browser is turned into a network proxy, allowing remote access through the browser to other parts of your private network. Some names can be allowed to contain your private addresses, by default all the local-data that you configured is allowed to, and you can specify additional names using private-domain. No private addresses are enabled by default. We consider to enable this for the RFC1918 private IP address space by default in later releases. That would enable private addresses for 10.0.0.0/8 172.16.0.0/12 192.168.0.0/16 169.254.0.0/16 fd00::/8 and fe80::/10, since the RFC standards say these addresses should not be visible on the public internet. Turning on 127.0.0.0/8 would hinder many spamblocklists as they use that. Adding ::ffff:0:0/96 stops IPv4-mapped IPv6 addresses from bypassing the filter.
Allow this domain, and all its subdomains to contain private addresses. Give multiple times to allow multiple domain names to contain private addresses. Default is none.
If set, a total number of unwanted replies is kept track of in every thread. When it reaches the threshold, a defensive action is taken and a warning is printed to the log. The defensive action is to clear the rrset and message caches, hopefully flushing away any poison. A value of 10 million is suggested. Default is 0 (turned off).
Do not query the given IP address. Can be IP4 or IP6. Append /num to indicate a classless delegation netblock, for example like 10.2.3.4/24 or 2001::11/64.
If yes, localhost is added to the do-not-query-address entries, both IP6 ::1 and IP4 127.0.0.1/8. If no, then localhost can be used to send queries to. Default is yes.
If yes, message cache elements are prefetched before they expire to keep the cache up to date. Default is no. Turning it on gives about 10 percent more traffic and load on the machine, but popular items do not expire from the cache.
If yes, fetch the DNSKEYs earlier in the validation process, when a DS record is encountered. This lowers the latency of requests. It does use a little more CPU. Also if the cache is set to 0, it is no use. Default is no.
If yes, deny queries of type ANY with an empty response. Default is no. If disabled, Unbound responds with a short list of resource records if some can be found in the cache and makes the upstream type ANY query if there are none.
If yes, Unbound rotates RRSet order in response (the random number is taken from the query ID, for speed and thread safety). Default is yes.
If yes, Unbound does not insert authority/additional sections into response messages when those sections are not required. This reduces response size significantly, and may avoid TCP fallback for some responses. This may cause a slight speedup. The default is yes, even though the DNS protocol RFCs mandate these sections, and the additional content could be of use and save roundtrips for clients. Because they are not used, and the saved roundtrips are easier saved with prefetch, whilst this is faster.
If true, disables the DNSSEC lameness check in the iterator. This check sees if RRSIGs are present in the answer, when dnssec is expected, and retries another authority if RRSIGs are unexpectedly missing. The validator will insist in RRSIGs for DNSSEC signed domains regardless of this setting, if a trust anchor is loaded.
Module configuration, a list of module names separated by spaces, surround the string with quotes (""). The modules can be respip, validator, or iterator (and possibly more, see below). Setting this to just "iterator" will result in a non-validating server. Setting this to "validator iterator" will turn on DNSSEC validation. The ordering of the modules is significant, the order decides the order of processing. You must also set trust-anchors for validation to be useful. Adding respip to the front will cause RPZ processing to be done on all queries. The default is "validator iterator".
When the server is built with EDNS client subnet support the default is "subnetcache validator iterator". Most modules that need to be listed here have to be listed at the beginning of the line. The subnetcachedb module has to be listed just before the iterator. The python module can be listed in different places, it then processes the output of the module it is just before. The dynlib module can be listed pretty much anywhere, it is only a very thin wrapper that allows dynamic libraries to run in its place.
File with trusted keys for validation. Both DS and DNSKEY entries can appear in the file. The format of the file is the standard DNS Zone file format. Default is "", or no trust anchor file.
File with trust anchor for one zone, which is tracked with RFC5011 probes. The probes are run several times per month, thus the machine must be online frequently. The initial file can be one with contents as described in trust-anchor-file. The file is written to when the anchor is updated, so the Unbound user must have write permission. Write permission to the file, but also to the directory it is in (to create a temporary file, which is necessary to deal with filesystem full events), it must also be inside the chroot (if that is used).
A DS or DNSKEY RR for a key to use for validation. Multiple entries can be given to specify multiple trusted keys, in addition to the trust-anchor-files. The resource record is entered in the same format as 'dig' or 'drill' prints them, the same format as in the zone file. Has to be on a single line, with "" around it. A TTL can be specified for ease of cut and paste, but is ignored. A class can be specified, but class IN is default.
File with trusted keys for validation. Specify more than one file with several entries, one file per entry. Like trust-anchor-file but has a different file format. Format is BIND-9 style format, the trusted-keys { name flag proto algo "key"; }; clauses are read. It is possible to use wildcards with this statement, the wildcard is expanded on start and on reload.
Send RFC8145 key tag query after trust anchor priming. Default is no.
Root key trust anchor sentinel. Default is yes.
Sets domain name to be insecure, DNSSEC chain of trust is ignored towards the domain name. So a trust anchor above the domain name can not make the domain secure with a DS record, such a DS record is then ignored. Can be given multiple times to specify multiple domains that are treated as if unsigned. If you set trust anchors for the domain they override this setting (and the domain is secured).
This can be useful if you want to make sure a trust anchor for external lookups does not affect an (unsigned) internal domain. A DS record externally can create validation failures for that internal domain.
Default is "" or "0", which disables this debugging feature. If enabled by giving a RRSIG style date, that date is used for verifying RRSIG inception and expiration dates, instead of the current date. Do not set this unless you are debugging signature inception and expiration. The value -1 ignores the date altogether, useful for some special applications.
Minimum number of seconds of clock skew to apply to validated signatures. A value of 10% of the signature lifetime (expiration - inception) is used, capped by this setting. Default is 3600 (1 hour) which allows for daylight savings differences. Lower this value for more strict checking of short lived signatures.
Maximum number of seconds of clock skew to apply to validated signatures. A value of 10% of the signature lifetime (expiration - inception) is used, capped by this setting. Default is 86400 (24 hours) which allows for timezone setting problems in stable domains. Setting both min and max very low disables the clock skew allowances. Setting both min and max very high makes the validator check the signature timestamps less strictly.
The maximum number the validator should restart validation with another authority in case of failed validation. Default is 5.
The time to live for bogus data. This is data that has failed validation; due to invalid signatures or other checks. The TTL from that data cannot be trusted, and this value is used instead. The value is in seconds, default 60. The time interval prevents repeated revalidation of bogus data.
Instruct the validator to remove data from the additional section of secure messages that are not signed properly. Messages that are insecure, bogus, indeterminate or unchecked are not affected. Default is yes. Use this setting to protect the users that rely on this validator for authentication from potentially bad data in the additional section.
Have the validator print validation failures to the log. Regardless of the verbosity setting. Default is 0, off. At 1, for every user query that fails a line is printed to the logs. This way you can monitor what happens with validation. Use a diagnosis tool, such as dig or drill, to find out why validation is failing for these queries. At 2, not only the query that failed is printed but also the reason why Unbound thought it was wrong and which server sent the faulty data.
Instruct the validator to mark bogus messages as indeterminate. The security checks are performed, but if the result is bogus (failed security), the reply is not withheld from the client with SERVFAIL as usual. The client receives the bogus data. For messages that are found to be secure the AD bit is set in replies. Also logging is performed as for full validation. The default value is "no".
Instruct Unbound to ignore the CD flag from clients and refuse to return bogus answers to them. Thus, the CD (Checking Disabled) flag does not disable checking any more. This is useful if legacy (w2008) servers that set the CD flag but cannot validate DNSSEC themselves are the clients, and then Unbound provides them with DNSSEC protection. The default value is "no".
If enabled, Unbound attempts to serve old responses from cache with a TTL of serve-expired-reply-ttl in the response without waiting for the actual resolution to finish. The actual resolution answer ends up in the cache later on. Default is "no".
Limit serving of expired responses to configured seconds after expiration. 0 disables the limit. This option only applies when serve-expired is enabled. A suggested value per RFC 8767 is between 86400 (1 day) and 259200 (3 days). The default is 0.
Set the TTL of expired records to the serve-expired-ttl value after a failed attempt to retrieve the record from upstream. This makes sure that the expired records will be served as long as there are queries for it. Default is "no".
TTL value to use when replying with expired data. If serve-expired-client-timeout is also used then it is RECOMMENDED to use 30 as the value (RFC 8767). The default is 30.
Time in milliseconds before replying to the client with expired data. This essentially enables the serve-stale behavior as specified in RFC 8767 that first tries to resolve before immediately responding with expired data. A recommended value per RFC 8767 is 1800. Setting this to 0 will disable this behavior. Default is 0.
If enabled, Unbound will always return the original TTL as received from the upstream name server rather than the decrementing TTL as stored in the cache. This feature may be useful if Unbound serves as a front-end to a hidden authoritative name server. Enabling this feature does not impact cache expiry, it only changes the TTL Unbound embeds in responses to queries. Note that enabling this feature implicitly disables enforcement of the configured minimum and maximum TTL, as it is assumed users who enable this feature do not want Unbound to change the TTL obtained from an upstream server. Thus, the values set using cache-min-ttl and cache-max-ttl are ignored. Default is "no".
List of keysize and iteration count values, separated by spaces, surrounded by quotes. Default is "1024 150 2048 150 4096 150". This determines the maximum allowed NSEC3 iteration count before a message is simply marked insecure instead of performing the many hashing iterations. The list must be in ascending order and have at least one entry. If you set it to "1024 65535" there is no restriction to NSEC3 iteration values. This table must be kept short; a very long list could cause slower operation.
If enabled the ZONEMD verification failures are only logged and do not cause the zone to be blocked and only return servfail. Useful for testing out if it works, or if the operator only wants to be notified of a problem without disrupting service. Default is no.
Instruct the auto-trust-anchor-file probe mechanism for RFC5011 autotrust updates to add new trust anchors only after they have been visible for this time. Default is 30 days as per the RFC.
Instruct the auto-trust-anchor-file probe mechanism for RFC5011 autotrust updates to remove revoked trust anchors after they have been kept in the revoked list for this long. Default is 30 days as per the RFC.
Instruct the auto-trust-anchor-file probe mechanism for RFC5011 autotrust updates to remove missing trust anchors after they have been unseen for this long. This cleans up the state file if the target zone does not perform trust anchor revocation, so this makes the auto probe mechanism work with zones that perform regular (non-5011) rollovers. The default is 366 days. The value 0 does not remove missing anchors, as per the RFC.
Debug option that allows the autotrust 5011 rollover timers to assume very small values. Default is no.
Number of bytes size of the key cache. Default is 4 megabytes. A plain number is in bytes, append 'k', 'm' or 'g' for kilobytes, megabytes or gigabytes (1024*1024 bytes in a megabyte).
Number of slabs in the key cache. Slabs reduce lock contention by threads. Must be set to a power of 2. Setting (close) to the number of cpus is a reasonable guess.
Number of bytes size of the aggressive negative cache. Default is 1 megabyte. A plain number is in bytes, append 'k', 'm' or 'g' for kilobytes, megabytes or gigabytes (1024*1024 bytes in a megabyte).
Default is disabled. If enabled, then for private address space, the reverse lookups are no longer filtered. This allows Unbound when running as dns service on a host where it provides service for that host, to put out all of the queries for the 'lan' upstream. When enabled, only localhost, 127.0.0.1 reverse and ::1 reverse zones are configured with default local zones. Disable the option when Unbound is running as a (DHCP-) DNS network resolver for a group of machines, where such lookups should be filtered (RFC compliance), this also stops potential data leakage about the local network to the upstream DNS servers.
Default is disabled. If enabled, then reverse lookups in private address space are not validated. This is usually required whenever unblock-lan-zones is used.
Configure a local zone. The type determines the answer to give if there is no match from local-data. The types are deny, refuse, static, transparent, redirect, nodefault, typetransparent, inform, inform_deny, inform_redirect, always_transparent, block_a, always_refuse, always_nxdomain, always_null, noview, and are explained below. After that the default settings are listed. Use local-data: to enter data into the local zone. Answers for local zones are authoritative DNS answers. By default the zones are class IN.
If you need more complicated authoritative data, with referrals, wildcards, CNAME/DNAME support, or DNSSEC authoritative service, setup a stub-zone for it as detailed in the stub zone section below. A stub-zone can be used to have unbound send queries to another server, an authoritative server, to fetch the information. With a forward-zone, unbound sends queries to a server that is a recursive server to fetch the information. With an auth-zone a zone can be loaded from file and used, it can be used like a local-zone for users downstream, or the auth-zone information can be used to fetch information from when resolving like it is an upstream server. The forward-zone and auth-zone options are described in their sections below. If you want to perform filtering of the information that the users can fetch, the local-zone and local-data statements allow for this, but also the rpz functionality can be used, described in the RPZ section.
deny
Do not send an answer, drop the query. If there is a match from local data, the query is answered.
refuse
Send an error message reply, with rcode REFUSED. If there is a match from local data, the query is answered.
static
If there is a match from local data, the query is answered. Otherwise, the query is answered with nodata or nxdomain. For a negative answer a SOA is included in the answer if present as local-data for the zone apex domain.
transparent
If there is a match from local data, the query is answered. Otherwise if the query has a different name, the query is resolved normally. If the query is for a name given in localdata but no such type of data is given in localdata, then a noerror nodata answer is returned. If no local-zone is given local-data causes a transparent zone to be created by default.
typetransparent
If there is a match from local data, the query is answered. If the query is for a different name, or for the same name but for a different type, the query is resolved normally. So, similar to transparent but types that are not listed in local data are resolved normally, so if an A record is in the local data that does not cause a nodata reply for AAAA queries.
redirect
The query is answered from the local data for the zone name. There may be no local data beneath the zone name. This answers queries for the zone, and all subdomains of the zone with the local data for the zone. It can be used to redirect a domain to return a different address record to the end user, with local-zone: "example.com." redirect and local-data: "example.com. A 127.0.0.1" queries for www.example.com and www.foo.example.com are redirected, so that users with web browsers cannot access sites with suffix example.com.
inform
The query is answered normally, same as transparent. The client IP address (@portnumber) is printed to the logfile. The log message is: timestamp, unbound-pid, info: zonename inform IP@port queryname type class. This option can be used for normal resolution, but machines looking up infected names are logged, eg. to run antivirus on them.
inform_deny
The query is dropped, like 'deny', and logged, like 'inform'. Ie. find infected machines without answering the queries.
inform_redirect
The query is redirected, like 'redirect', and logged, like 'inform'. Ie. answer queries with fixed data and also log the machines that ask.
always_transparent
Like transparent, but ignores local data and resolves normally.
block_a
Like transparent, but ignores local data and resolves normally all query types excluding A. For A queries it unconditionally returns NODATA. Useful in cases when there is a need to explicitly force all apps to use IPv6 protocol and avoid any queries to IPv4.
always_refuse
Like refuse, but ignores local data and refuses the query.
always_nxdomain
Like static, but ignores local data and returns nxdomain for the query.
always_nodata
Like static, but ignores local data and returns nodata for the query.
always_deny
Like deny, but ignores local data and drops the query.
always_null
Always returns 0.0.0.0 or ::0 for every name in the zone. Like redirect with zero data for A and AAAA. Ignores local data in the zone. Used for some block lists.
noview
Breaks out of that view and moves towards the global local zones for answer to the query. If the view first is no, it'll resolve normally. If view first is enabled, it'll break perform that step and check the global answers. For when the view has view specific overrides but some zone has to be answered from global local zone contents.
nodefault
Used to turn off default contents for AS112 zones. The other types also turn off default contents for the zone. The 'nodefault' option has no other effect than turning off default contents for the given zone. Use nodefault if you use exactly that zone, if you want to use a subzone, use transparent.

The default zones are localhost, reverse 127.0.0.1 and ::1, the home.arpa, the onion, test, invalid and the AS112 zones. The AS112 zones are reverse DNS zones for private use and reserved IP addresses for which the servers on the internet cannot provide correct answers. They are configured by default to give nxdomain (no reverse information) answers. The defaults can be turned off by specifying your own local-zone of that name, or using the 'nodefault' type. Below is a list of the default zone contents.

localhost
The IP4 and IP6 localhost information is given. NS and SOA records are provided for completeness and to satisfy some DNS update tools. Default content:
local-zone: "localhost." redirect
local-data: "localhost. 10800 IN NS localhost."
local-data: "localhost. 10800 IN

SOA localhost. nobody.invalid. 1 3600 1200 604800 10800" local-data: "localhost. 10800 IN A 127.0.0.1" local-data: "localhost. 10800 IN AAAA ::1"
reverse IPv4 loopback
Default content:
local-zone: "127.in-addr.arpa." static
local-data: "127.in-addr.arpa. 10800 IN NS localhost."
local-data: "127.in-addr.arpa. 10800 IN

SOA localhost. nobody.invalid. 1 3600 1200 604800 10800" local-data: "1.0.0.127.in-addr.arpa. 10800 IN
PTR localhost."
reverse IPv6 loopback
Default content:
local-zone: "1.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.

0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.ip6.arpa." static local-data: "1.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.ip6.arpa. 10800 IN
NS localhost." local-data: "1.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.ip6.arpa. 10800 IN
SOA localhost. nobody.invalid. 1 3600 1200 604800 10800" local-data: "1.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.ip6.arpa. 10800 IN
PTR localhost."
home.arpa (RFC 8375)
Default content:
local-zone: "home.arpa." static
local-data: "home.arpa. 10800 IN NS localhost."
local-data: "home.arpa. 10800 IN

SOA localhost. nobody.invalid. 1 3600 1200 604800 10800"
onion (RFC 7686)
Default content:
local-zone: "onion." static
local-data: "onion. 10800 IN NS localhost."
local-data: "onion. 10800 IN

SOA localhost. nobody.invalid. 1 3600 1200 604800 10800"
test (RFC 6761)
Default content:
local-zone: "test." static
local-data: "test. 10800 IN NS localhost."
local-data: "test. 10800 IN

SOA localhost. nobody.invalid. 1 3600 1200 604800 10800"
invalid (RFC 6761)
Default content:
local-zone: "invalid." static
local-data: "invalid. 10800 IN NS localhost."
local-data: "invalid. 10800 IN

SOA localhost. nobody.invalid. 1 3600 1200 604800 10800"
reverse RFC1918 local use zones
Reverse data for zones 10.in-addr.arpa, 16.172.in-addr.arpa to 31.172.in-addr.arpa, 168.192.in-addr.arpa. The local-zone: is set static and as local-data: SOA and NS records are provided.
reverse RFC3330 IP4 this, link-local, testnet and broadcast
Reverse data for zones 0.in-addr.arpa, 254.169.in-addr.arpa, 2.0.192.in-addr.arpa (TEST NET 1), 100.51.198.in-addr.arpa (TEST NET 2), 113.0.203.in-addr.arpa (TEST NET 3), 255.255.255.255.in-addr.arpa. And from 64.100.in-addr.arpa to 127.100.in-addr.arpa (Shared Address Space).
reverse RFC4291 IP6 unspecified
Reverse data for zone
0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.ip6.arpa.
reverse RFC4193 IPv6 Locally Assigned Local Addresses
Reverse data for zone D.F.ip6.arpa.
reverse RFC4291 IPv6 Link Local Addresses
Reverse data for zones 8.E.F.ip6.arpa to B.E.F.ip6.arpa.
reverse IPv6 Example Prefix
Reverse data for zone 8.B.D.0.1.0.0.2.ip6.arpa. This zone is used for tutorials and examples. You can remove the block on this zone with:

local-zone: 8.B.D.0.1.0.0.2.ip6.arpa. nodefault
You can also selectively unblock a part of the zone by making that part transparent with a local-zone statement. This also works with the other default zones.
Configure local data, which is served in reply to queries for it. The query has to match exactly unless you configure the local-zone as redirect. If not matched exactly, the local-zone type determines further processing. If local-data is configured that is not a subdomain of a local-zone, a transparent local-zone is configured. For record types such as TXT, use single quotes, as in local-data: 'example. TXT "text"'.
If you need more complicated authoritative data, with referrals, wildcards, CNAME/DNAME support, or DNSSEC authoritative service, setup a stub-zone for it as detailed in the stub zone section below.
Configure local data shorthand for a PTR record with the reversed IPv4 or IPv6 address and the host name. For example "192.0.2.4 www.example.com". TTL can be inserted like this: "2001:DB8::4 7200 www.example.com"
Assign tags to localzones. Tagged localzones will only be applied when the used access-control element has a matching tag. Tags must be defined in define-tags. Enclose list of tags in quotes ("") and put spaces between tags. When there are multiple tags it checks if the intersection of the list of tags for the query and local-zone-tag is non-empty.
Override the localzone type for queries from addresses matching netblock. Use this localzone type, regardless the type configured for the local-zone (both tagged and untagged) and regardless the type configured using access-control-tag-action.
This requires use of the "respip" module.
If the IP address in an AAAA or A RR in the answer section of a response matches the specified IP netblock, the specified action will apply. <action> has generally the same semantics as that for access-control-tag-action, but there are some exceptions.
Actions for response-ip are different from those for local-zone in that in case of the former there is no point of such conditions as "the query matches it but there is no local data". Because of this difference, the semantics of response-ip actions are modified or simplified as follows: The static, refuse, transparent, typetransparent, and nodefault actions are invalid for response-ip. Using any of these will cause the configuration to be rejected as faulty. The deny action is non-conditional, i.e. it always results in dropping the corresponding query. The resolution result before applying the deny action is still cached and can be used for other queries.
This requires use of the "respip" module.
This specifies the action data for response-ip with action being to redirect as specified by "resource record string". "Resource record string" is similar to that of access-control-tag-action, but it must be of either AAAA, A or CNAME types. If the IP-netblock is an IPv6/IPv4 prefix, the record must be AAAA/A respectively, unless it is a CNAME (which can be used for both versions of IP netblocks). If it is CNAME there must not be more than one response-ip-data for the same IP-netblock. Also, CNAME and other types of records must not coexist for the same IP-netblock, following the normal rules for CNAME records. The textual domain name for the CNAME does not have to be explicitly terminated with a dot ("."); the root name is assumed to be the origin for the name.
This requires use of the "respip" module.
Assign tags to response IP-netblocks. If the IP address in an AAAA or A RR in the answer section of a response matches the specified IP-netblock, the specified tags are assigned to the IP address. Then, if an access-control-tag is defined for the client and it includes one of the tags for the response IP, the corresponding access-control-tag-action will apply. Tag matching rule is the same as that for access-control-tag and local-zones. Unlike local-zone-tag, response-ip-tag can be defined for an IP-netblock even if no response-ip is defined for that netblock. If multiple response-ip-tag options are specified for the same IP-netblock in different statements, all but the first will be ignored. However, this will not be flagged as a configuration error, but the result is probably not what was intended.
Actions specified in an access-control-tag-action that has a matching tag with response-ip-tag can be those that are "invalid" for response-ip listed above, since access-control-tag-actions can be shared with local zones. For these actions, if they behave differently depending on whether local data exists or not in case of local zones, the behavior for response-ip-data will generally result in NOERROR/NODATA instead of NXDOMAIN, since the response-ip data are inherently type specific, and non-existence of data does not indicate anything about the existence or non-existence of the qname itself. For example, if the matching tag action is static but there is no data for the corresponding response-ip configuration, then the result will be NOERROR/NODATA. The only case where NXDOMAIN is returned is when an always_nxdomain action applies.
Enable ratelimiting of queries sent to nameserver for performing recursion. If 0, the default, it is disabled. This option is experimental at this time. The ratelimit is in queries per second that are allowed. More queries are turned away with an error (servfail). This stops recursive floods, eg. random query names, but not spoofed reflection floods. Cached responses are not ratelimited by this setting. The zone of the query is determined by examining the nameservers for it, the zone name is used to keep track of the rate. For example, 1000 may be a suitable value to stop the server from being overloaded with random names, and keeps Unbound from sending traffic to the nameservers for those zones. Configured forwarders are excluded from ratelimiting.
Give the size of the data structure in which the current ongoing rates are kept track in. Default 4m. In bytes or use m(mega), k(kilo), g(giga). The ratelimit structure is small, so this data structure likely does not need to be large.
Give power of 2 number of slabs, this is used to reduce lock contention in the ratelimit tracking data structure. Close to the number of cpus is a fairly good setting.
Set the amount of queries to rate limit when the limit is exceeded. If set to 0, all queries are dropped for domains where the limit is exceeded. If set to another value, 1 in that number is allowed through to complete. Default is 10, allowing 1/10 traffic to flow normally. This can make ordinary queries complete (if repeatedly queried for), and enter the cache, whilst also mitigating the traffic flow by the factor given.
If enabled, the ratelimit is treated as a hard failure instead of the default maximum allowed constant rate. When the limit is reached, traffic is ratelimited and demand continues to be kept track of for a 2 second rate window. No traffic is allowed, except for ratelimit-factor, until demand decreases below the configured ratelimit for a 2 second rate window. Useful to set ratelimit to a suspicious rate to aggressively limit unusually high traffic. Default is off.
Override the global ratelimit for an exact match domain name with the listed number. You can give this for any number of names. For example, for a top-level-domain you may want to have a higher limit than other names. A value of 0 will disable ratelimiting for that domain.
Override the global ratelimit for a domain name that ends in this name. You can give this multiple times, it then describes different settings in different parts of the namespace. The closest matching suffix is used to determine the qps limit. The rate for the exact matching domain name is not changed, use ratelimit-for-domain to set that, you might want to use different settings for a top-level-domain and subdomains. A value of 0 will disable ratelimiting for domain names that end in this name.
Enable global ratelimiting of queries accepted per IP address. This option is experimental at this time. The ratelimit is in queries per second that are allowed. More queries are completely dropped and will not receive a reply, SERVFAIL or otherwise. IP ratelimiting happens before looking in the cache. This may be useful for mitigating amplification attacks. Default is 0 (disabled).
Enable global ratelimiting of queries accepted per IP address with a valid DNS Cookie. This option is experimental at this time. The ratelimit is in queries per second that are allowed. More queries are completely dropped and will not receive a reply, SERVFAIL or otherwise. IP ratelimiting happens before looking in the cache. This option could be useful in combination with allow_cookie in an attempt to mitigate other amplification attacks than UDP reflections (e.g., attacks targeting Unbound itself) which are already handled with DNS Cookies. If used, the value is suggested to be higher than ip-ratelimit e.g., tenfold. Default is 0 (disabled).
Give the size of the data structure in which the current ongoing rates are kept track in. Default 4m. In bytes or use m(mega), k(kilo), g(giga). The ip ratelimit structure is small, so this data structure likely does not need to be large.
Give power of 2 number of slabs, this is used to reduce lock contention in the ip ratelimit tracking data structure. Close to the number of cpus is a fairly good setting.
Set the amount of queries to rate limit when the limit is exceeded. If set to 0, all queries are dropped for addresses where the limit is exceeded. If set to another value, 1 in that number is allowed through to complete. Default is 10, allowing 1/10 traffic to flow normally. This can make ordinary queries complete (if repeatedly queried for), and enter the cache, whilst also mitigating the traffic flow by the factor given.
If enabled, the ratelimit is treated as a hard failure instead of the default maximum allowed constant rate. When the limit is reached, traffic is ratelimited and demand continues to be kept track of for a 2 second rate window. No traffic is allowed, except for ip-ratelimit-factor, until demand decreases below the configured ratelimit for a 2 second rate window. Useful to set ip-ratelimit to a suspicious rate to aggressively limit unusually high traffic. Default is off.
The number of retries, per upstream nameserver in a delegation, that Unbound will attempt in case a throwaway response is received. No response (timeout) contributes to the retry counter. If a forward/stub zone is used, this is the number of retries per nameserver in the zone. Default is 5.
Hard limit on the number of outgoing queries Unbound will make while resolving a name, making sure large NS sets do not loop. Results in SERVFAIL when reached. It resets on query restarts (e.g., CNAME) and referrals. Default is 32.
Hard limit on the number of times Unbound is allowed to restart a query upon encountering a CNAME record. Results in SERVFAIL when reached. Changing this value needs caution as it can allow long CNAME chains to be accepted, where Unbound needs to verify (resolve) each link individually. Default is 11.
Specify how many times out of 1000 to pick from the set of fastest servers. 0 turns the feature off. A value of 900 would pick from the fastest servers 90 percent of the time, and would perform normal exploration of random servers for the remaining time. When prefetch is enabled (or serve-expired), such prefetches are not sped up, because there is no one waiting for it, and it presents a good moment to perform server exploration. The fast-server-num option can be used to specify the size of the fastest servers set. The default for fast-server-permil is 0.
Set the number of servers that should be used for fast server selection. Only use the fastest specified number of servers with the fast-server-permil option, that turns this on or off. The default is to use the fastest 3 servers.
If enabled, Unbound will answer to requests containing DNS Cookies as specified in RFC 7873 and RFC 9018. Default is no.
Server's secret for DNS Cookie generation. Useful to explicitly set for servers in an anycast deployment that need to share the secret in order to verify each other's Server Cookies. An example hex string would be "000102030405060708090a0b0c0d0e0f". Default is a 128 bits random secret generated at startup time.
Include an EDNS0 option containing configured ascii string in queries with destination address matching the configured IP netblock. This configuration option can be used multiple times. The most specific match will be used.
EDNS0 option code for the edns-client-string option, from 0 to 65535. A value from the `Reserved for Local/Experimental` range (65001-65534) should be used. Default is 65001.
If enabled, Unbound will respond with Extended DNS Error codes (RFC8914). These EDEs attach informative error messages to a response for various errors. Default is "no".

When the val-log-level option is also set to 2, responses with Extended DNS Errors concerning DNSSEC failures that are not served from cache, will also contain a descriptive text message about the reason for the failure.

If enabled, Unbound will attach an Extended DNS Error (RFC8914) Code 3 - Stale Answer as EDNS0 option to the expired response. Note that this will not attach the EDE code without setting the global ede option to "yes" as well. Default is "no".

In the remote-control: clause are the declarations for the remote control facility. If this is enabled, the unbound-control(8) utility can be used to send commands to the running Unbound server. The server uses these clauses to setup TLSv1 security for the connection. The unbound-control(8) utility also reads the remote-control section for options. To setup the correct self-signed certificates use the unbound-control-setup(8) utility.

The option is used to enable remote control, default is "no". If turned off, the server does not listen for control commands.
Give IPv4 or IPv6 addresses or local socket path to listen on for control commands. If an interface name is used instead of an ip address, the list of ip addresses on that interface are used. By default localhost (127.0.0.1 and ::1) is listened to. Use 0.0.0.0 and ::0 to listen to all interfaces. If you change this and permissions have been dropped, you must restart the server for the change to take effect.
If you set it to an absolute path, a unix domain socket is used. This socket does not use the certificates and keys, so those files need not be present. To restrict access, Unbound sets permissions on the file to the user and group that is configured, the access bits are set to allow the group members to access the control socket file. Put users that need to access the socket in the that group. To restrict access further, create a directory to put the control socket in and restrict access to that directory.
The port number to listen on for IPv4 or IPv6 control interfaces, default is 8953. If you change this and permissions have been dropped, you must restart the server for the change to take effect.
For localhost control-interface you can disable the use of TLS by setting this option to "no", default is "yes". For local sockets, TLS is disabled and the value of this option is ignored.
Path to the server private key, by default unbound_server.key. This file is generated by the unbound-control-setup utility. This file is used by the Unbound server, but not by unbound-control.
Path to the server self signed certificate, by default unbound_server.pem. This file is generated by the unbound-control-setup utility. This file is used by the Unbound server, and also by unbound-control.
Path to the control client private key, by default unbound_control.key. This file is generated by the unbound-control-setup utility. This file is used by unbound-control.
Path to the control client certificate, by default unbound_control.pem. This certificate has to be signed with the server certificate. This file is generated by the unbound-control-setup utility. This file is used by unbound-control.

There may be multiple stub-zone: clauses. Each with a name: and zero or more hostnames or IP addresses. For the stub zone this list of nameservers is used. Class IN is assumed. The servers should be authority servers, not recursors; Unbound performs the recursive processing itself for stub zones.

The stub zone can be used to configure authoritative data to be used by the resolver that cannot be accessed using the public internet servers. This is useful for company-local data or private zones. Setup an authoritative server on a different host (or different port). Enter a config entry for Unbound with stub-addr: <ip address of host[@port]>. The Unbound resolver can then access the data, without referring to the public internet for it.

This setup allows DNSSEC signed zones to be served by that authoritative server, in which case a trusted key entry with the public key can be put in config, so that Unbound can validate the data and set the AD bit on replies for the private zone (authoritative servers do not set the AD bit). This setup makes Unbound capable of answering queries for the private zone, and can even set the AD bit ('authentic'), but the AA ('authoritative') bit is not set on these replies.

Consider adding server: statements for domain-insecure: and for local-zone: name nodefault for the zone if it is a locally served zone. The insecure clause stops DNSSEC from invalidating the zone. The local zone nodefault (or transparent) clause makes the (reverse-) zone bypass Unbound's filtering of RFC1918 zones.

Name of the stub zone. This is the full domain name of the zone.
Name of stub zone nameserver. Is itself resolved before it is used. To use a nondefault port for DNS communication append '@' with the port number. If tls is enabled, then you can append a '#' and a name, then it'll check the tls authentication certificates with that name. If you combine the '@' and '#', the '@' comes first. If only '#' is used the default port is the configured tls-port.
IP address of stub zone nameserver. Can be IP 4 or IP 6. To use a nondefault port for DNS communication append '@' with the port number. If tls is enabled, then you can append a '#' and a name, then it'll check the tls authentication certificates with that name. If you combine the '@' and '#', the '@' comes first. If only '#' is used the default port is the configured tls-port.
This option is by default no. If enabled it performs NS set priming, which is similar to root hints, where it starts using the list of nameservers currently published by the zone. Thus, if the hint list is slightly outdated, the resolver picks up a correct list online.
If enabled, a query is attempted without the stub clause if it fails. The data could not be retrieved and would have caused SERVFAIL because the servers are unreachable, instead it is tried without this clause. The default is no.
Enabled or disable whether the queries to this stub use TLS for transport. Default is no.
Alternate syntax for stub-tls-upstream.
If it is set to "yes" then upstream queries use TCP only for transport regardless of global flag tcp-upstream. Default is no.
Default is no. If enabled, data inside the stub is not cached. This is useful when you want immediate changes to be visible.

There may be multiple forward-zone: clauses. Each with a name: and zero or more hostnames or IP addresses. For the forward zone this list of nameservers is used to forward the queries to. The servers listed as forward-host: and forward-addr: have to handle further recursion for the query. Thus, those servers are not authority servers, but are (just like Unbound is) recursive servers too; Unbound does not perform recursion itself for the forward zone, it lets the remote server do it. Class IN is assumed. CNAMEs are chased by Unbound itself, asking the remote server for every name in the indirection chain, to protect the local cache from illegal indirect referenced items. A forward-zone entry with name "." and a forward-addr target will forward all queries to that other server (unless it can answer from the cache).

Name of the forward zone. This is the full domain name of the zone.
Name of server to forward to. Is itself resolved before it is used. To use a nondefault port for DNS communication append '@' with the port number. If tls is enabled, then you can append a '#' and a name, then it'll check the tls authentication certificates with that name. If you combine the '@' and '#', the '@' comes first. If only '#' is used the default port is the configured tls-port.
IP address of server to forward to. Can be IP 4 or IP 6. To use a nondefault port for DNS communication append '@' with the port number. If tls is enabled, then you can append a '#' and a name, then it'll check the tls authentication certificates with that name. If you combine the '@' and '#', the '@' comes first. If only '#' is used the default port is the configured tls-port.
At high verbosity it logs the TLS certificate, with TLS enabled. If you leave out the '#' and auth name from the forward-addr, any name is accepted. The cert must also match a CA from the tls-cert-bundle.
If a forwarded query is met with a SERVFAIL error, and this option is enabled, Unbound will fall back to normal recursive resolution for this query as if no query forwarding had been specified. The default is "no".
Enabled or disable whether the queries to this forwarder use TLS for transport. Default is no. If you enable this, also configure a tls-cert-bundle or use tls-win-cert to load CA certs, otherwise the connections cannot be authenticated.
Alternate syntax for forward-tls-upstream.
If it is set to "yes" then upstream queries use TCP only for transport regardless of global flag tcp-upstream. Default is no.
Default is no. If enabled, data inside the forward is not cached. This is useful when you want immediate changes to be visible.

Authority zones are configured with auth-zone:, and each one must have a name:. There can be multiple ones, by listing multiple auth-zone clauses, each with a different name, pertaining to that part of the namespace. The authority zone with the name closest to the name looked up is used. Authority zones can be processed on two distinct, non-exclusive, configurable stages.

With for-downstream: yes (default), authority zones are processed after local-zones and before cache. When used in this manner, Unbound responds like an authority server with no further processing other than returning an answer from the zone contents. A notable example, in this case, is CNAME records which are returned verbatim to downstream clients without further resolution.

With for-upstream: yes (default), authority zones are processed after the cache lookup, just before going to the network to fetch information for recursion. When used in this manner they provide a local copy of an authority server that speeds up lookups for that data during resolving.

If both options are enabled (default), client queries for an authority zone are answered authoritatively from Unbound, while internal queries that require data from the authority zone consult the local zone data instead of going to the network.

An interesting configuration is for-downstream: no, for-upstream: yes that allows for hyperlocal behavior where both client and internal queries consult the local zone data while resolving. In this case, the aforementioned CNAME example will result in a thoroughly resolved answer.

Authority zones can be read from zonefile. And can be kept updated via AXFR and IXFR. After update the zonefile is rewritten. The update mechanism uses the SOA timer values and performs SOA UDP queries to detect zone changes.

If the update fetch fails, the timers in the SOA record are used to time another fetch attempt. Until the SOA expiry timer is reached. Then the zone is expired. When a zone is expired, queries are SERVFAIL, and any new serial number is accepted from the primary (even if older), and if fallback is enabled, the fallback activates to fetch from the upstream instead of the SERVFAIL.

Name of the authority zone.
Where to download a copy of the zone from, with AXFR and IXFR. Multiple primaries can be specified. They are all tried if one fails. To use a nondefault port for DNS communication append '@' with the port number. You can append a '#' and a name, then AXFR over TLS can be used and the tls authentication certificates will be checked with that name. If you combine the '@' and '#', the '@' comes first. If you point it at another Unbound instance, it would not work because that does not support AXFR/IXFR for the zone, but if you used url: to download the zonefile as a text file from a webserver that would work. If you specify the hostname, you cannot use the domain from the zonefile, because it may not have that when retrieving that data, instead use a plain IP address to avoid a circular dependency on retrieving that IP address.
Alternate syntax for primary.
Where to download a zonefile for the zone. With http or https. An example for the url is "http://www.example.com/example.org.zone". Multiple url statements can be given, they are tried in turn. If only urls are given the SOA refresh timer is used to wait for making new downloads. If also primaries are listed, the primaries are first probed with UDP SOA queries to see if the SOA serial number has changed, reducing the number of downloads. If none of the urls work, the primaries are tried with IXFR and AXFR. For https, the tls-cert-bundle and the hostname from the url are used to authenticate the connection. If you specify a hostname in the URL, you cannot use the domain from the zonefile, because it may not have that when retrieving that data, instead use a plain IP address to avoid a circular dependency on retrieving that IP address. Avoid dependencies on name lookups by using a notation like "http://192.0.2.1/unbound-primaries/example.com.zone", with an explicit IP address.
With allow-notify you can specify additional sources of notifies. When notified, the server attempts to first probe and then zone transfer. If the notify is from a primary, it first attempts that primary. Otherwise other primaries are attempted. If there are no primaries, but only urls, the file is downloaded when notified. The primaries from primary: and url: statements are allowed notify by default.
Default no. If enabled, Unbound falls back to querying the internet as a resolver for this zone when lookups fail. For example for DNSSEC validation failures.
Default yes. If enabled, Unbound serves authority responses to downstream clients for this zone. This option makes Unbound behave, for the queries with names in this zone, like one of the authority servers for that zone. Turn it off if you want Unbound to provide recursion for the zone but have a local copy of zone data. If for-downstream is no and for-upstream is yes, then Unbound will DNSSEC validate the contents of the zone before serving the zone contents to clients and store validation results in the cache.
Default yes. If enabled, Unbound fetches data from this data collection for answering recursion queries. Instead of sending queries over the internet to the authority servers for this zone, it'll fetch the data directly from the zone data. Turn it on when you want Unbound to provide recursion for downstream clients, and use the zone data as a local copy to speed up lookups.
Enable this option to check ZONEMD records in the zone. Default is disabled. The ZONEMD record is a checksum over the zone data. This includes glue in the zone and data from the zone file, and excludes comments from the zone file. When there is a DNSSEC chain of trust, DNSSEC signatures are checked too.
Enable this option to reject the absence of the ZONEMD record. Without it, when zonemd is not there it is not checked. It is useful to enable for a nonDNSSEC signed zone where the operator wants to require the verification of a ZONEMD, hence a missing ZONEMD is a failure. The action upon failure is controlled by the zonemd-permissive-mode option, for log only or also block the zone. The default is no.
Without the option absence of a ZONEMD is only a failure when the zone is DNSSEC signed, and we have a trust anchor, and the DNSSEC verification of the absence of the ZONEMD fails. With the option enabled, the absence of a ZONEMD is always a failure, also for nonDNSSEC signed zones.
The filename where the zone is stored. If not given then no zonefile is used. If the file does not exist or is empty, Unbound will attempt to fetch zone data (eg. from the primary servers).

There may be multiple view: clauses. Each with a name: and zero or more local-zone and local-data elements. Views can also contain view-first, response-ip, response-ip-data and local-data-ptr elements. View can be mapped to requests by specifying the view name in an access-control-view element. Options from matching views will override global options. Global options will be used if no matching view is found, or when the matching view does not have the option specified.

Name of the view. Must be unique. This name is used in access-control-view elements.
View specific local-zone elements. Has the same types and behaviour as the global local-zone elements. When there is at least one local-zone specified and view-first is no, the default local-zones will be added to this view. Defaults can be disabled using the nodefault type. When view-first is yes or when a view does not have a local-zone, the global local-zone will be used including it's default zones.
View specific local-data elements. Has the same behaviour as the global local-data elements.
View specific local-data-ptr elements. Has the same behaviour as the global local-data-ptr elements.
If enabled, it attempts to use the global local-zone and local-data if there is no match in the view specific options. The default is no.

The python: clause gives the settings for the python(1) script module. This module acts like the iterator and validator modules do, on queries and answers. To enable the script module it has to be compiled into the daemon, and the word "python" has to be put in the module-config: option (usually first, or between the validator and iterator). Multiple instances of the python module are supported by adding the word "python" more than once.

If the chroot: option is enabled, you should make sure Python's library directory structure is bind mounted in the new root environment, see mount(8). Also the python-script: path should be specified as an absolute path relative to the new root, or as a relative path to the working directory.

The script file to load. Repeat this option for every python module instance added to the module-config: option.

The dynlib: clause gives the settings for the dynlib module. This module is only a very small wrapper that allows dynamic modules to be loaded on runtime instead of being compiled into the application. To enable the dynlib module it has to be compiled into the daemon, and the word "dynlib" has to be put in the module-config: option. Multiple instances of dynamic libraries are supported by adding the word "dynlib" more than once.

The dynlib-file: path should be specified as an absolute path relative to the new path set by chroot: option, or as a relative path to the working directory.

The dynamic library file to load. Repeat this option for every dynlib module instance added to the module-config: option.

The dns64 module must be configured in the module-config: "dns64 validator iterator" directive and be compiled into the daemon to be enabled. These settings go in the server: section.

This sets the DNS64 prefix to use to synthesize AAAA records with. It must be /96 or shorter. The default prefix is 64:ff9b::/96.
Debug option, default no. If enabled, synthesize all AAAA records despite the presence of actual AAAA records.
List domain for which the AAAA records are ignored and the A record is used by dns64 processing instead. Can be entered multiple times, list a new domain for which it applies, one per line. Applies also to names underneath the name given.

NAT64 operation allows using a NAT64 prefix for outbound requests to IPv4-only servers. It is controlled by two options in the server: section:

Use NAT64 to reach IPv4-only servers. Consider also enabling prefer-ip6 to prefer native IPv6 connections to nameservers. Default no.
Use a specific NAT64 prefix to reach IPv4-only servers. Defaults to using the prefix configured in dns64-prefix, which in turn defaults to 64:ff9b::/96. The prefix length must be one of /32, /40, /48, /56, /64 or /96.

The dnscrypt: clause gives the settings of the dnscrypt channel. While those options are available, they are only meaningful if Unbound was compiled with --enable-dnscrypt. Currently certificate and secret/public keys cannot be generated by Unbound. You can use dnscrypt-wrapper to generate those: https://github.com/cofyc/dnscrypt-wrapper/blob/master/README.md#usage

Whether or not the dnscrypt config should be enabled. You may define configuration but not activate it. The default is no.
On which port should dnscrypt should be activated. Note that you should have a matching interface option defined in the server section for this port.
The provider name to use to distribute certificates. This is of the form: 2.dnscrypt-cert.example.com.. The name MUST end with a dot.
Path to the time limited secret key file. This option may be specified multiple times.
Path to the certificate related to the dnscrypt-secret-keys. This option may be specified multiple times.
Path to a certificate that we should be able to serve existing connection from but do not want to advertise over dnscrypt-provider's TXT record certs distribution. A typical use case is when rotating certificates, existing clients may still use the client magic from the old cert in their queries until they fetch and update the new cert. Likewise, it would allow one to prime the new cert/key without distributing the new cert yet, this can be useful when using a network of servers using anycast and on which the configuration may not get updated at the exact same time. By priming the cert, the servers can handle both old and new certs traffic while distributing only one. This option may be specified multiple times.
Give the size of the data structure in which the shared secret keys are kept in. Default 4m. In bytes or use m(mega), k(kilo), g(giga). The shared secret cache is used when a same client is making multiple queries using the same public key. It saves a substantial amount of CPU.
Give power of 2 number of slabs, this is used to reduce lock contention in the dnscrypt shared secrets cache. Close to the number of cpus is a fairly good setting.
Give the size of the data structure in which the client nonces are kept in. Default 4m. In bytes or use m(mega), k(kilo), g(giga). The nonce cache is used to prevent dnscrypt message replaying. Client nonce should be unique for any pair of client pk/server sk.
Give power of 2 number of slabs, this is used to reduce lock contention in the dnscrypt nonce cache. Close to the number of cpus is a fairly good setting.

The ECS module must be configured in the module-config: "subnetcache validator iterator" directive and be compiled into the daemon to be enabled. These settings go in the server: section.

If the destination address is allowed in the configuration Unbound will add the EDNS0 option to the query containing the relevant part of the client's address. When an answer contains the ECS option the response and the option are placed in a specialized cache. If the authority indicated no support, the response is stored in the regular cache.

Additionally, when a client includes the option in its queries, Unbound will forward the option when sending the query to addresses that are explicitly allowed in the configuration using send-client-subnet. The option will always be forwarded, regardless the allowed addresses, if client-subnet-always-forward is set to yes. In this case the lookup in the regular cache is skipped.

The maximum size of the ECS cache is controlled by 'msg-cache-size' in the configuration file. On top of that, for each query only 100 different subnets are allowed to be stored for each address family. Exceeding that number, older entries will be purged from cache.

This module does not interact with the serve-expired* and prefetch: options.

Send client source address to this authority. Append /num to indicate a classless delegation netblock, for example like 10.2.3.4/24 or 2001::11/64. Can be given multiple times. Authorities not listed will not receive edns-subnet information, unless domain in query is specified in client-subnet-zone.
Send client source address in queries for this domain and its subdomains. Can be given multiple times. Zones not listed will not receive edns-subnet information, unless hosted by authority specified in send-client-subnet.
Specify whether the ECS address check (configured using send-client-subnet) is applied for all queries, even if the triggering query contains an ECS record, or only for queries for which the ECS record is generated using the querier address (and therefore did not contain ECS data in the client query). If enabled, the address check is skipped when the client query contains an ECS record. And the lookup in the regular cache is skipped. Default is no.
Specifies the maximum prefix length of the client source address we are willing to expose to third parties for IPv6. Defaults to 56.
Specifies the maximum prefix length of the client source address we are willing to expose to third parties for IPv4. Defaults to 24.
Specifies the minimum prefix length of the IPv6 source mask we are willing to accept in queries. Shorter source masks result in REFUSED answers. Source mask of 0 is always accepted. Default is 0.
Specifies the minimum prefix length of the IPv4 source mask we are willing to accept in queries. Shorter source masks result in REFUSED answers. Source mask of 0 is always accepted. Default is 0.
Specifies the maximum number of subnets ECS answers kept in the ECS radix tree. This number applies for each qname/qclass/qtype tuple. Defaults to 100.
Specifies the maximum number of subnets ECS answers kept in the ECS radix tree. This number applies for each qname/qclass/qtype tuple. Defaults to 100.

The IPsec module must be configured in the module-config: "ipsecmod validator iterator" directive and be compiled into Unbound by using --enable-ipsecmod to be enabled. These settings go in the server: section.

When Unbound receives an A/AAAA query that is not in the cache and finds a valid answer, it will withhold returning the answer and instead will generate an IPSECKEY subquery for the same domain name. If an answer was found, Unbound will call an external hook passing the following arguments:

QNAME
Domain name of the A/AAAA and IPSECKEY query. In string format.
IPSECKEY TTL
TTL of the IPSECKEY RRset.
A/AAAA
String of space separated IP addresses present in the A/AAAA RRset. The IP addresses are in string format.
IPSECKEY
String of space separated IPSECKEY RDATA present in the IPSECKEY RRset. The IPSECKEY RDATA are in DNS presentation format.

The A/AAAA answer is then cached and returned to the client. If the external hook was called the TTL changes to ensure it doesn't surpass ipsecmod-max-ttl.

The same procedure is also followed when prefetch: is used, but the A/AAAA answer is given to the client before the hook is called. ipsecmod-max-ttl ensures that the A/AAAA answer given from cache is still relevant for opportunistic IPsec.

Specifies whether the IPsec module is enabled or not. The IPsec module still needs to be defined in the module-config: directive. This option facilitates turning on/off the module without restarting/reloading Unbound. Defaults to yes.
Specifies the external hook that Unbound will call with system(3). The file can be specified as an absolute/relative path. The file needs the proper permissions to be able to be executed by the same user that runs Unbound. It must be present when the IPsec module is defined in the module-config: directive.
If enabled Unbound requires the external hook to return a success value of 0. Failing to do so Unbound will reply with SERVFAIL. The A/AAAA answer will also not be cached. Defaults to no.
Time to live maximum for A/AAAA cached records after calling the external hook. Defaults to 3600.
Specifies the behaviour of Unbound when the IPSECKEY answer is bogus. If set to yes, the hook will be called and the A/AAAA answer will be returned to the client. If set to no, the hook will not be called and the answer to the A/AAAA query will be SERVFAIL. Mainly used for testing. Defaults to no.
Allow the ipsecmod functionality for the domain so that the module logic will be executed. Can be given multiple times, for different domains. If the option is not specified, all domains are treated as being allowed (default).
Alternate syntax for ipsecmod-allow.

The Cache DB module must be configured in the module-config: "validator cachedb iterator" directive and be compiled into the daemon with --enable-cachedb. If this module is enabled and configured, the specified backend database works as a second level cache: When Unbound cannot find an answer to a query in its built-in in-memory cache, it consults the specified backend. If it finds a valid answer in the backend, Unbound uses it to respond to the query without performing iterative DNS resolution. If Unbound cannot even find an answer in the backend, it resolves the query as usual, and stores the answer in the backend.

This module interacts with the serve-expired-* options and will reply with expired data if Unbound is configured for that. Currently the use of serve-expired-client-timeout: and serve-expired-reply-ttl: is not consistent for data originating from the external cache as these will result in a reply with 0 TTL without trying to update the data first, ignoring the configured values.

If Unbound was built with --with-libhiredis on a system that has installed the hiredis C client library of Redis, then the "redis" backend can be used. This backend communicates with the specified Redis server over a TCP connection to store and retrieve cache data. It can be used as a persistent and/or shared cache backend. It should be noted that Unbound never removes data stored in the Redis server, even if some data have expired in terms of DNS TTL or the Redis server has cached too much data; if necessary the Redis server must be configured to limit the cache size, preferably with some kind of least-recently-used eviction policy. Additionally, the redis-expire-records option can be used in order to set the relative DNS TTL of the message as timeout to the Redis records; keep in mind that some additional memory is used per key and that the expire information is stored as absolute Unix timestamps in Redis (computer time must be stable). This backend uses synchronous communication with the Redis server based on the assumption that the communication is stable and sufficiently fast. The thread waiting for a response from the Redis server cannot handle other DNS queries. Although the backend has the ability to reconnect to the server when the connection is closed unexpectedly and there is a configurable timeout in case the server is overly slow or hangs up, these cases are assumed to be very rare. If connection close or timeout happens too often, Unbound will be effectively unusable with this backend. It's the administrator's responsibility to make the assumption hold.

The cachedb: clause gives custom settings of the cache DB module.

Specify the backend database name. The default database is the in-memory backend named "testframe", which, as the name suggests, is not of any practical use. Depending on the build-time configuration, "redis" backend may also be used as described above.
Specify a seed to calculate a hash value from query information. This value will be used as the key of the corresponding answer for the backend database and can be customized if the hash should not be predictable operationally. If the backend database is shared by multiple Unbound instances, all instances must use the same secret seed. This option defaults to "default".

The following cachedb options are specific to the redis backend.

The IP (either v6 or v4) address or domain name of the Redis server. In general an IP address should be specified as otherwise Unbound will have to resolve the name of the server every time it establishes a connection to the server. This option defaults to "127.0.0.1".
The TCP port number of the Redis server. This option defaults to 6379.
The unix socket path to connect to the redis server. Off by default, and it can be set to "" to turn this off. Unix sockets may have better throughput than the IP address option.
The Redis AUTH password to use for the redis server. Only relevant if Redis is configured for client password authorisation. Off by default, and it can be set to "" to turn this off.
The period until when Unbound waits for a response from the Redis sever. If this timeout expires Unbound closes the connection, treats it as if the Redis server does not have the requested data, and will try to re-establish a new connection later. This option defaults to 100 milliseconds.
If Redis record expiration is enabled. If yes, Unbound sets timeout for Redis records so that Redis can evict keys that have expired automatically. If Unbound is configured with serve-expired and serve-expired-ttl is 0, this option is internally reverted to "no". Redis SETEX support is required for this option (Redis >= 2.0.0). This option defaults to no.

DNSTAP support, when compiled in by using --enable-dnstap, is enabled in the dnstap: section. This starts an extra thread (when compiled with threading) that writes the log information to the destination. If Unbound is compiled without threading it does not spawn a thread, but connects per-process to the destination.

If dnstap is enabled. Default no. If yes, it connects to the dnstap server and if any of the dnstap-log-..-messages options is enabled it sends logs for those messages to the server.
Use frame streams in bidirectional mode to transfer DNSTAP messages. Default is yes.
Sets the unix socket file name for connecting to the server that is listening on that socket. Default is "".
If "", the unix socket is used, if set with an IP address (IPv4 or IPv6) that address is used to connect to the server.
Set this to use TLS to connect to the server specified in dnstap-ip. The default is yes. If set to no, TCP is used to connect to the server.
The TLS server name to authenticate the server with. Used when dnstap-tls is enabled. If "" it is ignored, default "".
The pem file with certs to verify the TLS server certificate. If "" the server default cert bundle is used, or the windows cert bundle on windows. Default is "".
The client key file for TLS client authentication. If "" client authentication is not used. Default is "".
The client cert file for TLS client authentication. Default is "".
If enabled, the server identity is included in the log messages. Default is no.
If enabled, the server version if included in the log messages. Default is no.
The identity to send with messages, if "" the hostname is used. Default is "".
The version to send with messages, if "" the package version is used. Default is "".
Enable to log resolver query messages. Default is no. These are messages from Unbound to upstream servers.
Enable to log resolver response messages. Default is no. These are replies from upstream servers to Unbound.
Enable to log client query messages. Default is no. These are client queries to Unbound.
Enable to log client response messages. Default is no. These are responses from Unbound to clients.
Enable to log forwarder query messages. Default is no.
Enable to log forwarder response messages. Default is no.

Response Policy Zones are configured with rpz:, and each one must have a name:. There can be multiple ones, by listing multiple rpz clauses, each with a different name. RPZ clauses are applied in order of configuration. The respip module needs to be added to the module-config, e.g.: module-config: "respip validator iterator".

QNAME, Response IP Address, nsdname, nsip and clientip triggers are supported. Supported actions are: NXDOMAIN, NODATA, PASSTHRU, DROP, Local Data, tcp-only and drop. RPZ QNAME triggers are applied after local-zones and before auth-zones.

The rpz zone is formatted with a SOA start record as usual. The items in the zone are entries, that specify what to act on (the trigger) and what to do (the action). The trigger to act on is recorded in the name, the action to do is recorded as the resource record. The names all end in the zone name, so you could type the trigger names without a trailing dot in the zonefile.

An example RPZ record, that answers example.com with NXDOMAIN

	example.com CNAME .

The triggers are encoded in the name on the left

	name                          query name
	netblock.rpz-client-ip        client IP address
	netblock.rpz-ip               response IP address in the answer
	name.rpz-nsdname              nameserver name
	netblock.rpz-nsip             nameserver IP address
The netblock is written as <netblocklen>.<ip address in reverse>. For IPv6 use 'zz' for '::'. Specify individual addresses with scope length of 32 or 128. For example, 24.10.100.51.198.rpz-ip is 198.51.100.10/24 and 32.10.zz.db8.2001.rpz-ip is 2001:db8:0:0:0:0:0:10/32.

The actions are specified with the record on the right

	CNAME .                      nxdomain reply
	CNAME *.                     nodata reply
	CNAME rpz-passthru.          do nothing, allow to continue
	CNAME rpz-drop.              the query is dropped
	CNAME rpz-tcp-only.          answer over TCP
	A 192.0.2.1                  answer with this IP address
Other records like AAAA, TXT and other CNAMEs (not rpz-..) can also be used to answer queries with that content.

The RPZ zones can be configured in the config file with these settings in the rpz: block.

Name of the authority zone.
Where to download a copy of the zone from, with AXFR and IXFR. Multiple primaries can be specified. They are all tried if one fails. To use a nondefault port for DNS communication append '@' with the port number. You can append a '#' and a name, then AXFR over TLS can be used and the tls authentication certificates will be checked with that name. If you combine the '@' and '#', the '@' comes first. If you point it at another Unbound instance, it would not work because that does not support AXFR/IXFR for the zone, but if you used url: to download the zonefile as a text file from a webserver that would work. If you specify the hostname, you cannot use the domain from the zonefile, because it may not have that when retrieving that data, instead use a plain IP address to avoid a circular dependency on retrieving that IP address.
Alternate syntax for primary.
Where to download a zonefile for the zone. With http or https. An example for the url is "http://www.example.com/example.org.zone". Multiple url statements can be given, they are tried in turn. If only urls are given the SOA refresh timer is used to wait for making new downloads. If also primaries are listed, the primaries are first probed with UDP SOA queries to see if the SOA serial number has changed, reducing the number of downloads. If none of the urls work, the primaries are tried with IXFR and AXFR. For https, the tls-cert-bundle and the hostname from the url are used to authenticate the connection.
With allow-notify you can specify additional sources of notifies. When notified, the server attempts to first probe and then zone transfer. If the notify is from a primary, it first attempts that primary. Otherwise other primaries are attempted. If there are no primaries, but only urls, the file is downloaded when notified. The primaries from primary: and url: statements are allowed notify by default.
The filename where the zone is stored. If not given then no zonefile is used. If the file does not exist or is empty, Unbound will attempt to fetch zone data (eg. from the primary servers).
Always use this RPZ action for matching triggers from this zone. Possible action are: nxdomain, nodata, passthru, drop, disabled and cname.
The CNAME target domain to use if the cname action is configured for rpz-action-override.
Log all applied RPZ actions for this RPZ zone. Default is no.
Specify a string to be part of the log line, for easy referencing.
Signal when a query is blocked by the RPZ with NXDOMAIN with an unset RA flag. This allows certain clients, like dnsmasq, to infer that the domain is externally blocked. Default is no.
If enabled the zone is authoritatively answered for and queries for the RPZ zone information are answered to downstream clients. This is useful for monitoring scripts, that can then access the SOA information to check if the rpz information is up to date. Default is no.
Limit the policies from this RPZ clause to clients with a matching tag. Tags need to be defined in define-tag and can be assigned to client addresses using access-control-tag. Enclose list of tags in quotes ("") and put spaces between tags. If no tags are specified the policies from this clause will be applied for all clients.

In the example config settings below memory usage is reduced. Some service levels are lower, notable very large data and a high TCP load are no longer supported. Very large data and high TCP loads are exceptional for the DNS. DNSSEC validation is enabled, just add trust anchors. If you do not have to worry about programs using more than 3 Mb of memory, the below example is not for you. Use the defaults to receive full service, which on BSD-32bit tops out at 30-40 Mb after heavy usage.

# example settings that reduce memory usage
server:
	num-threads: 1
	outgoing-num-tcp: 1	# this limits TCP service, uses less buffers.
	incoming-num-tcp: 1
	outgoing-range: 60	# uses less memory, but less performance.
	msg-buffer-size: 8192   # note this limits service, 'no huge stuff'.
	msg-cache-size: 100k
	msg-cache-slabs: 1
	rrset-cache-size: 100k
	rrset-cache-slabs: 1
	infra-cache-numhosts: 200
	infra-cache-slabs: 1
	key-cache-size: 100k
	key-cache-slabs: 1
	neg-cache-size: 10k
	num-queries-per-thread: 30
	target-fetch-policy: "2 1 0 0 0 0"
	harden-large-queries: "yes"
	harden-short-bufsize: "yes"

/var/unbound/etc
default Unbound working directory.
/var/unbound
default chroot(2) location.
/var/unbound/etc/unbound.conf
Unbound configuration file.
Unbound log file. default is to log to syslog(3).

unbound(8), unbound-checkconf(8).

Unbound was written by NLnet Labs. Please see CREDITS file in the distribution for further details.

August 30, 2023 NLnet Labs