1.0 Introduction 1.1 ... Basic theory of operation 1.2 ... Quick build & install 2.0 Building nsd 2.1 ... Unpacking the source 2.2 ... Configuring NSD 2.3 ... Building 2.4 ... Installing 3.0 Running NSD 3.1 ... Logging 3.2 ... AXFR access 3.3 ... Using TSIG 3.4 ... Zone expiry of secondary zones 3.5 ... Diagnosing NSD log entries 3.6 ... Interfaces 3.7 ... Tuning 3.8 ... Zone verification 4.0 Support and Feedback 4.1 ... Your Support 1.0 Introduction This is NSD Name Server Daemon (NSD) version 4.9.1. The NLnet Labs Name Server Daemon (NSD) is an authoritative RFC compliant DNS nameserver. It was first conceived to allow for more genetic diversity for DNS server implementations used by the root-server system and it has been developed for operations in environments where speed, reliability, stability, and security are of high importance. NSD is currently used on root servers such as k.root-servers.net and is also in use by several top-level domain registries. NSD is a complete implementation of an authoritative DNS name server. For further information about what NSD is and what NSD is not please consult the REQUIREMENTS document which is a part of this distribution. If you are a BIND user (the named daemon) consult NSD_FOR_BIND_USERS. The source code is available for download from: http://www.nlnetlabs.nl/downloads 1.1 Basic Theory of Operation NSD consists of two programs: the zone compiler 'zonec' and the name server 'nsd' itself. The name server works with an intermediate database prepared by the zone compiler from standard zone files. For NSD operation this means that zones have to be compiled by zonec before NSD can use them. All this can be controlled via rc.d (SIGTERM, SIGHUP) or nsd-control, and uses a simple configuration file 'nsd.conf'. 1.2 Quick build and install Step 1: Unpack the source with gtar -xzvf nsd-4.9.1.tar.gz Step 2: Create user nsd or any other unprivileged user of your choice. In case of later make sure to use --with-user= while running configure. You can also set "username: " in the nsd.conf file later. Install openssl and libevent. Step 3: ./configure Step 4: make all (or simply 'make'). Step 5: make install Step 6: Create and edit /etc/nsd/nsd.conf file possibly from nsd.conf.sample template that comes with the distribution. (installed by default at /etc/nsd/nsd.conf.sample) Here you need to configure the zones you want to serve. TSIG keys used for secure zone transfers must be included. Also server parameters can be set, see nsd.conf(5) man page. If you have a NSD 2 nsd.zones config file take a look at the python script contrib/nsd.zones2nsd.conf, it will convert zone and TSIG key settings for you. Step 7: Copy necessary master zone files into appropriate directories under /etc/nsd/primary & /etc/nsd/secondary. Step 8: Run nsd-control start Step 9: Test the NSD with dig, drill or host. Step 10: If you're happy add a rc.d script to start into your OS boot up sequence. The format of the rc.d startup script depends on the platform. Also stop it in the shutdown sequence. You can use SIGTERM to stop, or nsd-control stop. Step 11: If desired add 'nsd-control write' to your superuser crontab to update the zone files with the content transferred from master servers periodically, such as once per day. Got any problems or questions with the steps above? Read the rest of this file. 2.0 Building NSD 2.1 Unpacking the source Use your favorite combination of tar and gnu zip to unpack the source, for example $ gtar -xzvf nsd-4.9.1.tar.gz will unpack the source into the ./nsd-4.9.1 directory... 2.2 Configuring NSD NSD can be configured using GNU autoconf's configure script. In addition to standard configure options, one may use the following: CC=compiler Specify the C compiler. The default is gcc or cc. The compiler must support ANSI C89. CPPFLAGS=flags Specify the C preprocessor flags. Such as -I. CFLAGS=flags Specify the C compiler flags. These include code generation, optimization, warning, and debugging flags. These flags are also passed to the linker. The default for gcc is "-g -O2". LD=linker Specify the linker (defaults to the C compiler). LDFLAGS=flags Specify linker flags. LIBS=libs Specify additional libraries to link with. --enable-root-server Configure NSD as a root server. Unless this option is specified, NSD will refuse to serve the ``.'' zone as a misconfiguration safeguard. --disable-ipv6 Disables IPv6 support in NSD. --enable-checking Enable some internal development checks. Useful if you want to modify NSD. This option enables the standard C "assert" macro and compiler warnings. This will instruct NSD to be stricter when validating its input. This could lead to a reduced service level. --enable-bind8-stats Enables BIND8-like statistics. --enable-ratelimit Enables ratelimiting, based on query name, type and source. --enable-draft-rrtypes Enables draft RRtypes. --with-configdir=dir Specified, NSD configuration directory, default /etc/nsd --with-nsd_conf_file=path Pathname to the NSD configuration file, default /etc/nsd/nsd.conf --with-pidfile=path Pathname to the NSD pidfile, default is platform specific, mostly /var/run/nsd.pid --with-zonesdir=dir NSD default location for master zone files, default /etc/nsd/ --with-user=username User name or ID to answer the queries with, default is nsd --with-facility=facility Specify the syslog facility to use. The default is LOG_DAEMON. See the syslog(3) manual page for the available facilities. --with-libevent=path Specity the location of the libevent library (or libev). --with-libevent=no uses a builtin portable implementation (select()). --with-ssl=path Specify the location of the OpenSSL libraries. OpenSSL 0.9.7 or higher is required for TSIG support. --with-start_priority=number Startup priority for NSD. --with-kill_priority=number Shutdown priority for NSD. --with-tcp-timeout=number Set the default TCP timeout (in seconds). Default 120 seconds. --disable-nsec3 Disable NSEC3 support. With NSEC3 support enabled, very large zones, also non-nsec3 zones, use about 20% more memory. --disable-minimal-responses Disable minimal responses. If disabled, responses are more likely to get truncated, resulting in TCP fallback. When enabled (by default) NSD will leave out RRsets to make responses fit inside one datagram, but for shorter responses the full normal response is carried. --disable-largefile Disable large file support (64 bit file lengths). Makes off_t a 32bit length during compilation. 2.3 Building Use ``make'' to create NSD and support tools. If you get errors, try to use ``gmake'' (gnu version of make), especially on old systems. If so, do a `gmake realclean` first, to remove stuff that the make call messed up. 2.4 Installing Become a superuser (if necessary) and type ``make install'' This step should install four binaries nsd - the daemon itself nsd-control-setup - a shell script that creates keys for nsd-control. nsd-control - program that connects over SSL to nsd and gives commands. nsd-checkconf - simple C program to check nsd.conf before use. Plus the manual pages and a sample configuration file. 3.0 Running NSD Before running NSD you need to create a configuration file for it. The config file contains server settings, secret keys and zone settings. The server settings start with a line with the keyword 'server:'. In the server settings set 'database: ' with the filename of the name database that NSD will use. Set 'chroot: ' to run nsd in a chroot-jail. Make sure the zone files, database file, xfrdfile, difffile and pidfile can be accessed from the chroot-jail. Set 'username: ' to an unprivileged user, for security. For example: # This is a sample configuration server: database: "/etc/nsd/nsd.db" pidfile: "/etc/nsd/nsd.pid" chroot: "/etc/nsd/" username: nsd After the global server settings to need to make entries for the zones that you wish to serve. For each zone you need to list the zone name, the file name with the zone contents, and access control lists. zone: name: "example.com" zonefile: "example.com.zone" The zonefile needs to be filled with the correct zone information for master zones. For secondary zones an empty file will suffice, a zone transfer will be initiated to obtain the slave zone contents. Access control lists are needed for zone transfer and notifications. For a slave zone list the masters, by IP address. Below is an example of a slave zone with two master servers. If a master only supports AXFR transfers and not IXFR transfers (like NSD), specify the master as "request-xfr: AXFR ". By default, all zone transfer requests are made over TCP. If you want the IXFR request be transmitted over UDP, use "request-xfr: UDP ". zone: name: "example.com" zonefile: "example.com.zone" allow-notify: 168.192.185.33 NOKEY request-xfr: 168.192.185.33 NOKEY allow-notify: 168.192.199.2 NOKEY request-xfr: 168.192.199.2 NOKEY By default, a slave will fallback to AXFR requests if the master told us it does not support IXFR. You can configure the slave not to do AXFR fallback with: allow-axfr-fallback: "no" For a master zone, list the slave servers, by IP address or subnet. Below is an example of a master zone with two slave servers. zone: name: "example.com" zonefile: "example.com.zone" notify: 168.192.133.75 NOKEY provide-xfr: 168.192.133.75 NOKEY notify: 168.192.5.44 NOKEY provide-xfr: 168.192.5.44 NOKEY You also can set the outgoing interface for notifies and zone transfer requests to satisfy access control lists at the other end: outgoing-interface: 168.192.5.69 By default, NSD will retry a notify up to 5 times. You can override that value with: notify-retry: 5 Zone transfers can be secured with TSIG keys, replace NOKEY with the name of the tsig key to use. See section 3.3. Since NSD is written to be run on the root name servers, the config file can to contain something like: zone: name: "." zonefile: "root.zone" provide-xfr: 0.0.0.0/0 NOKEY # allow axfr for everyone. provide-xfr: ::0/0 NOKEY You should only do that if you're intending to run a root server, NSD is not suited for running a . cache. Therefore if you choose to serve the . zone you have to make sure that the complete root zone is timely and fully updated. To prevent misconfiguration, NSD configure has the --enable-root-server switch, that is by default disabled. In the config file, you can use patterns. A pattern can have the same configuration statements that a zone can have. And then you can include-pattern: in a zone (or in another pattern) to apply those settings. This can be used to organise the settings. The nsd-control tool is also controlled from the nsd.conf config file. It uses SSL encrypted transport to 127.0.0.1, and if you want to use it you have to setup the keys and also edit the config file. You can leave the remote-control disabled (the secure default), or opt to turn it on: # generate keys nsd-control-setup # edit nsd.conf to add this remote-control: control-enable: yes By default nsd-control is limited to localhost, as well as encrypted, but some people may want to remotely administer their nameserver. What you then do is setup nsd-control to listen to the public IP address, with control-interface: after the control-enable statement. Furthermore, you copy the key files /etc/nsd/nsd_server.pem /etc/nsd/nsd_control.* to a remote host on the internet; on that host you can run nsd-control with -c which references same IP address control-interface and references the copies of the key files with server-cert-file, control-key-file and control-cert-file config lines after the control-enable statement. The nsd-server authenticates the nsd-control client, and also the nsd-control client authenticates the nsd-server. When you are done with the configuration file, check the syntax using nsd-checkconf The zone files are read by the daemon, which builds 'nsd.db' with their contents. You can start the daemon with nsd or with "nsd-control start" (which execs nsd again). or with nsd -c To check if the daemon is running look with ps, top, or if you enabled nsd-control, nsd-control status To reload changed zone files after you edited them, without stopping the daemon, use this to check if files are modified: kill -HUP `cat ` If you enabled nsd-control, you can reread with nsd-control reload With nsd-control you can also reread the config file (new zones, ..) nsd-control reconfig To restart the daemon /etc/rc.d/nsd restart # or your system(d) equivalent To shut it down (for example on the system shutdown) do kill -TERM or nsd-control stop NSD will automatically keep track of secondary zones and update them when needed. When primary zones are updated and reloaded notifications are sent to slave servers. The zone transfers are applied to nsd.db by the daemon. To write changed contents of the zone files for slave zones to disk in the text-based zone file format, issue nsd-control write. NSD will send notifications to slave zones if a master zone is updated. NSD will check for updates at master servers periodically and transfer the updated zone by AXFR/IXFR and reload the new zone contents. If you wish exert manual control use nsd-control notify, transfer and force_transfer commands. The transfer command will check for new versions of the secondary zones hosted by this NSD. The notify command will send notifications to the slave servers configured in 'notify:' statements. 3.1 Logging NSD doesn't do any logging. We believe that logging is a separate task and has to be done independently from the core operation. This consciously is not part of nsd itself in order to keep nsd focused and minimize its complexity. It is better to leave logging and tracing to separate dedicated tools. dnsstat can also easily be configured and/or modified to suit local statistics requirements without any danger of affecting the name server itself. We have run dnsstat on the same machine as nsd, we would recommend using a multiprocessor if performance is an issue. Of course it can also run on a separate machine that has MAC layer access to the network of the server. The nsd-control tool can output some statistics, with nsd-control stats and nsd-control stats_noreset. In contrib/nsd_munin_ there is a munin grapher plugin that uses it. The output of nsd-control stats is easy to read (text only) with scripts. The output values are documented on the nsd-control man page. The CAIDA dnsstat tool referenced is recommended to nsd operators as a means of keeping statistics and check on abnormal query loads. http://www.caida.org/tools/utilities/dnsstat/dnsstat-3.5.1a.tar.gz Another tool is the dnstop, that displays DNS statistics on your network. http://dns.measurement-factory.com/tools/dnstop/src/dnstop-20060517.tar.gz A sample invocation of dnsstat: /usr/local/Coral/bin/crl_dnsstat -D -Ci=60 -Cd=240 -C'filter dst 10.1.1.3' -h -u if:fxp1 A sample output of a slightly modified version: # dnsstat output version: 0.2 "dfk" # begin trace interval at 1025267664.859043, duration 15.000000 # DNS messages: 74973 (4998.200000/s); DNS queries: 151983 (10132.200000/s) # print threshold: 30 messages/sec #src op type class queries msgs rd notes 208.18.162.10 - - - 533 533 0 " 0 MX IN 6 " 0 A IN 264 " 0 ANY IN 263 209.11.18.248 - - - 661 661 0 " 0 A IN 655 " 0 MX IN 6 210.117.65.137 - - - 745 745 0 " 0 A IN 745 216.54.221.131 - - - 477 477 0 " 0 A IN 477 193.97.205.80 - - - 681 681 0 " 0 A IN 3 " 0 ANY IN 678 168.30.240.11 - - - 685 685 0 " 0 A IN 405 " 0 MX IN 280 210.94.6.67 - - - 742 742 0 " 0 A IN 742 63.66.68.237 - - - 1375 1375 0 " 0 A IN 1375 168.30.240.12 - - - 493 493 0 " 0 A IN 493 139.142.205.225 - - - 5579 5579 0 " 0 A IN 3006 " 0 MX IN 2573 210.117.65.2 - - - 700 700 0 " 0 A IN 700 # end trace interval 3.2 AXFR access The access list for AXFR should be set with provide-xfr: in the nsd config file. This is per zone. See nsd.conf(5). For example to grant zone 'example.com' AXFR right to localhost for IPv4 and IPv6, use the below config options. zone: name: "example.com" provide-xfr: 127.0.0.1 NOKEY provide-xfr: ::1 NOKEY You can use dig @localhost example.com axfr to test this. 3.3 Using TSIG NSD supports TSIG for any query to the server, for zone transfer and for notify sending and receiving. TSIG keys are based on shared secrets. These must be configured in the config file. To keep the secret in a separate file use include: "filename" to include that file. An example tsig key named sec1_key. key: name: "sec1_key" algorithm: hmac-md5 secret: "6KM6qiKfwfEpamEq72HQdA==" This key can then be used for any query to the NSD server. NSD will check if the signature is valid, and if so, return a signed answer. Unsigned queries will be given unsigned replies. The key can be used to restrict the access control lists, for example to only allow zone transfer with the key, by listing the key name on the access control line. # provides AXFR to the subnet when TSIG is used. provide-xfr: 10.11.12.0/24 sec1_key # allow only notifications that are signed allow-notify: 192.168.0.0/16 sec1_key If the TSIG key name is used in notify or request-xfr lines, the key is used to sign the request/notification messages. 3.4 Zone expiry of secondary zones NSD will keep track of the status of secondary zones, according to the timing values in the SOA record for the zone. When the refresh time of a zone is reached, the serial number is checked and a zone transfer is started if the zone has changed. Each master server is tried in turn. Master zones cannot expire. They are always served. Zones are master zones if they have no 'request-xfr:' statements in the config file. After the expire timeout (from the SOA record at the zone apex) is reached, the zone becomes expired. NSD will return SERVFAIL for expired zones, and will attempt to perform a zone transfer from any of the masters. After a zone transfer succeeds, or if the master indicates that the SOA serial number is still the same, the zone will be OK again. In contrast with e.g. BIND, the inception time for a slave zone is stored on disk (in the xfrdfile: "xfrd.state"), together with timeouts. If a slave zone acquisition time is recent enough, this means that NSD can start serving a zone immediately on loading, without querying the master server. If your slave zone has expired, and no masters can be reached, but you still want NSD to serve the zone. (i.e. ''My network is in shambles, but serve the zone dangit!''). You can delete the file 'xfrd.state', but leave the zonefile for the zone intact. Make sure to stop nsd before you delete the file, as NSD writes it on exit. Upon loading NSD will treat the zonefile that you as operator have provided as recent and will serve the zone. Even though NSD will start to serve the zone immediately, the zone will expire after the timeout is reached again. NSD will also attempt to confirm that you have provided the correct data by polling the masters. So when the master servers come back up, it will transfer the updated zone within seconds. In general it is possible to provide zone files for both master and slave zones manually (say from email or rsync). Reload with SIGHUP or nsd-control reload to read the new zonefile contents into the name database. When this is done the new zone will be served. For master zones, NSD will issue notifications to all configured 'notify:' targets. For slave zones the above happens; NSD attempts to validate the zone from the master (checking its SOA serial number). 3.5 Diagnosing NSD log entries NSD will print log messages to the system log (or 'logfile:' configuration entry). Some of these messages are discussed below. These messages can get extra support if errors happen. - "Reload process failed with status , continuing with old database" This log message indicates the reload process of NSD has failed for some reason. The reason can be anything from a missing database file to internal errors. If this happens often, please let us know, this error message can be caught in the code, and appropriate action could be taken. We are as of yet not sure what action is appropriate, if any. - "snipping off trailing partial part of " Please let us know if, and how often, this happens. What happens is the file ixfr.db contains only part of expected data. The corruption is removed by snipping off the trailing part. - "memory recyclebin holds bytes" This is printed for every reload. NSD allocates and deallocates memory to service IXFR updates. The recyclebin holds deallocated memory ready for future use. If the number grows too large, a restart resets it. - "xfrd: max number of tcp connections (32) reached." This line is printed when more than 32 zones need a zone transfer at the same time. The value is a compile constant (xfrd-tcp.h), but if this happens often for you, we could make this a config option. NSD will reuse existing TCP connections to the same master (determined by IP address) to transfer up to 64k zones from that master. Thus this error should only happen with more than 32 masters or more than 64*32=2M zones that need to be updated at the same time. If this happens, more zones have to wait until a zone transfer completes (or is aborted) before they can have a zone transfer too. This waiting list has no size limit. - "error: NSEC3PARAM entry has unknown hash algo " This error means that the zone has NSEC3 chain(s) with hash algorithms that are not supported by this version of NSD, and thus cannot be served by NSD. If there are also no NSECs or NSEC3 chain(s) with known hash algorithms, NSD will not be able to serve DNSSEC authenticated denials for the zone. 3.6 Interfaces NSD will by default bind itself to the system default interface and service ip4 and if available also ip6. It is possible to service only ip4 or ip6 using the -4, -6 commandline options, or the ip4-only and ip6-only config file options. The commandline option -a and config file option ip-address can be given to bind to specific interfaces. Multiple interfaces can be specified. This is useful for two reasons: o The specific interface bound will result in the OS bypassing routing tables for the interface selection. This results in a small performance gain. It is not the performance gain that is the problem, sometimes the routing tables can give the wrong answer, see the next point. o The answer will be routed via the interface the query came from. This makes sure that the return address on the DNS replies is the same as the query was sent to. Many resolvers require the source address of the replies to be correct. The ip-address: option is easier than configuring the OS routing table to return the DNS replies via the correct interface. The above means that even for systems with multiple interfaces where you intend to provide DNS service to all interfaces, it is prudent to specify all the interfaces as ip-address config file options. With the config file option ip-transparent you can allow NSD to bind to non local addresses. 3.7 Tuning NSD is performant by design and most users will have little need for tuning it. For setups that do require every ounce of performance, NSD offers a number of configuration options. cpu-affinity, server--cpu-affinity and xfrd-cpu-affinity Modern computer systems have many cores available. By default the operating system's scheduling-algorithm determines which core a given task is allocated to. Processors build up state, like keeping frequently accessed data in cache memory, for the task (process/thread) that it is currently running. Whenever, a task switches cores, performance is degraded because the core it switched to has yet to build up said state. The cpu-affinity configuration options can be used to bind NSD to one or more cores. cpu-affinity can be used to designate a set of cores onto which NSD processes are scheduled. server--cpu-affinity and xfrd-cpu-affinity can be used to designate a specific core to each individual process. This improves L1/L2 cache hits and reduces pipeline stalls/flushes. For example, a name server configured to fork two NSD servers that must run on dedicated cores 0 and 2, while the transfer daemon (xfrd) must run on core 1, the configuration becomes. server: server-count: 2 cpu-affinity: 0 1 2 server-1-cpu-affinity: 0 server-2-cpu-affinity: 2 xfrd-cpu-affinity: 1 ip-address: x.x.x.x servers= ip-address options can be configured per (set of) server(s). Sockets that are configured for a specific server are closed by other servers on startup. This improves select/poll performance and avoids waking up multiple servers when a packet comes in. ip-address: x.x.x.x bindtodevice=yes ip-address: x.x.x.x setfib= The bindtodevice attribute on Linux and the setfib ip-address attribute on FreeBSD can be used to skip the interface selection process in the kernel. This improves performance, and ensures responses written to the socket are pushed out the same interface the corresponding query came in on when multiple interfaces are configured to listen on the same subnet. The aforementioned options all complement eachother and best performance is achieved by assigning a socket to a single server that runs on a dedicated core and line that up with a dedicated network interface. Network interface interrupts are best handled by a core not designated to any NSD servers. server: server-count: 3 cpu-affinity: 0 1 2 4 server-1-cpu-affinity: 0 server-2-cpu-affinity: 1 server-3-cpu-affinity: 2 xfrd-cpu-affinity: 4 ip-address: 1.2.3.11 servers=1 setfib=1 bindtodevice=yes ip-address: 1.2.3.12 servers=2 setfib=2 bindtodevice=yes ip-address: 1.2.3.13 servers=3 setfib=3 bindtodevice=yes The number of NSD servers to fork and which cores are best used depends entirely on the hardware. cpu-affinity options are supported on Linux and FreeBSD. 3.8 Zone verification NSD can be configured to verify a zone is correct before publishing it. This feature is primarily aimed at fortifying DNSSEC in the DNS notify/transfer-chain, but can be used to carry out any checks desired. An external verifier can be configured per zone. When a zone with verification enabled is received or updated via an (incremental) zone transfer, it will be submitted to the verifier for evaluation. If the verifier deems the updated zone correct (indicated with exit status 0), the zone will be served. NSD will discard the update and continue to serve the zone before the update if the exit status of the verifier is non-zero. Verifier options can be configured globally in the "verify:" clause, or specifically for a zone/pattern in the respective "zone:" and "pattern:" clauses. The global values are applied by default. The zone can be provided to the verifier in two ways. 1. The complete zone can be fed to the standard input of the verifier. This modus operandi is enabled by default and can be configured with the "verifier-feed-zone:" option. Examples for verifiers that read from the standard input are: "ldns-verify-zone -V2" (-V2 to suppress copying to stdout) or "validns -" (don't forget the dash (-) to read the zone from stdin). 2. The zone can be served to the verifier. This is disabled by default and can be enabled by configuring ip- addresses, with the "ip-address:" option in the "verify:" clause, on which the zone to be assessed will be served. Addresses can contain a port number to override the default, which is 5347 by default, but can be overridden with the "port:" option in the verify clause. For example to validate the SOA of a zone example.com by querying, with a certain DS record as the trust anchor (in file example.com.ds), the "verifier:" option could have the following value: "drill -S -k example.com.ds @localhost -p 5347 example.com SOA" A verifier is informed about the domain name of the zone to be verified and the accessibility of the system submitting the zone via environment variables. VERIFY_ZONE Domain name of the zone to be verified. VERIFY_ZONE_ON_STDIN Contains "yes" if the zone is fed over standard input, otherwise "no". VERIFY_IP_ADDRESSES Contains a list of @s on which the zone to be verified can be queried. VERIFY_IPV6_ADDRESS and VERIFY_IPV6_PORT Contains the first configured IPv6 address and port. VERIFY_IPV4_ADDRESS and VERIFY_IPV4_PORT Contains the first configured IPv4 address and port. VERIFY_IP_ADDRESS and VERIFY_PORT Contains the first configured address and port. IPv6 is preferred over IPv4. For each zone one verifier will be run at the same time, but when multiple to-be-verified zones are received, multiple verifiers may be run simultaneously. The number of verifiers that may be run simultaneously is configured with the "verifier-count:" option in the "verify:" clause and defaults to 1. The time a verifier may take can be configured with the "verifier-timeout:" option in the "verify:" clause (to make the general default) or in the "zone:" or "pattern:" clause to set it for a specific zone. When the time the verifier takes exceeds the timeout value, the zone to be verified will be considered bad. By default the value is 0, which means that the verifier may take as long as it needs. To enable verification for all zones. verify: enable: yes verifier: To enable verification only for a specific zone. verify: enable: yes verify-zones: no zone: name: example.com verify-zone: yes 4.0 Support and Feedback NLnet Labs is committed to support NSD and its other software products on a best effort basis, free of charge. This form of community support is offered through a mailing lists and the 'bugzilla' web interface. http://www.nlnetlabs.nl/bugs/ If for any reason NLnet Labs would stop community support of NSD such would be announced on our web pages at least two years in advance. The community mailing list nsd-users@lists.NLnetLabs.nl can be used to discuss issues with other users of NSD. Subscribe here http://lists.nlnetlabs.nl/mailman/listinfo/nsd-users NLnet Labs recognizes that in some corporate environments this commitment to community support is not sufficient and that support needs to be codified. We therefore offer paid support contracts that come in 3 varieties. More information about these support varieties can be found at https://nlnetlabs.nl/services/contracts/ Support goes two ways. By acquiring one of the support contracts you also support NLnet Labs to continue to participate in the development of the Internet architecture. We do this through our participation in the (IETF) standards process and by developing and maintaining reference implementations of standards and tools to support operation and deployment of new and existing Internet technology. We are interested in our users and in the environment you use NSD. Please drop us a mail when you use NSD at users@NLnetLabs.nl. Indicate in what kind of operation you deploy NSD and let us know what your positive and negative experiences are. 4.1 Your Support NLnet Labs offers all of its software products as open source, most are published under a BSD license. You can download them, not only from the NLnet Labs website but also through the various OS distributions for which NSD, ldns, and Unbound are packaged. We therefore have little idea who uses our software in production environments and have no direct ties with 'our customers'. Therefore, we ask you to contact us at users@NLnetLabs.nl and tell us whether you use one of our products in your production environment, what that environment looks like, and maybe even share some praise. We would like to refer to the fact that your organization is using our products. We will only do that if you explicitly allow us. In all other cases we will keep the information you share with us to ourselves. In addition to the moral support you can also support us financially. NLnet Labs is a recognized not-for-profit charity foundation that is chartered to develop open-source software and open-standards for the Internet. If you use our software to satisfaction please express that by giving us a donation. For small donations PayPal can be used. For larger and regular donations please contact us at users@NLnetLabs.nl. Also see http://www.nlnetlabs.nl/labs/contributors/. $Id: README,v 1.8 2024/04/12 15:53:34 florian Exp $