\input texinfo @c {{{ Main header stuff @afourwide @paragraphindent 0 @setfilename chrony.info @settitle User guide for the chrony suite version @CHRONY_VERSION@ @c @setchapternewpage off @ifinfo @dircategory Net Utilities @direntry * chrony: (chrony). How to use chronyd and chronyc * chronyd: (chrony)Starting chronyd. Reference for chronyd * chronyc: (chrony)Running chronyc. Reference for chronyc @end direntry @end ifinfo @titlepage @sp 10 @title The chrony suite @subtitle This manual describes how to use @subtitle the programs chronyd and chronyc @author Richard P. Curnow @page @vskip 0pt plus 1filll Copyright @copyright{} 1997-1999 Richard P. Curnow Copyright @copyright{} 2009-2015 Miroslav Lichvar @end titlepage @c }}} @c {{{ Top node @node Top @top @menu * Introduction:: What the chrony suite does * Installation:: How to compile and install the software * Typical scenarios:: How to configure the software for some common cases * Usage reference:: Reference manual * GPL:: The GNU General Public License @end menu @c }}} @c {{{ Ch:Introduction @c {{{ Chapter top @node Introduction @chapter Introduction @menu * Overview:: What the programs do * Acknowledgements:: Credit where credit is due * Availability:: Where to get the software * Other time synchronisation packages:: Comparision with other software * Distribution and warranty:: There is no warranty * Bug reporting:: How to report bugs and make suggestions @end menu @c }}} @c {{{ S:Overview @node Overview @section Overview chrony is a versatile implementation of the Network Time Protocol (NTP). It can synchronize the system clock with NTP servers, reference clocks (e.g. GPS receiver), and manual input using wristwatch and keyboard. It can also operate as an NTPv4 (RFC 5905) server and peer to provide a time service to other computers in the network. It is designed to perform well in a wide range of conditions, including intermittent network connections, heavily congested networks, changing temperatures (ordinary computer clocks are sensitive to temperature), and systems that do not run continuosly, or run on a virtual machine. Typical accuracy between two machines on a LAN is in tens, or a few hundreds, of microseconds; over the Internet, accuracy is typically within a few milliseconds. With a good hardware reference clock sub-microsecond accuracy is possible. Two programs are included in chrony, @code{chronyd} is a daemon that can be started at boot time and @code{chronyc} is a command-line interface program which can be used to monitor @code{chronyd}'s performance and to change various operating parameters whilst it is running. The IP addresses from which @code{chronyc} clients may connect can be tightly controlled. The default is just the computer that @code{chronyd} itself is running on. @c }}} @c {{{ S:Acknowledgments @node Acknowledgements @section Acknowledgements The @code{chrony} suite makes use of the algorithm known as @emph{RSA Data Security, Inc. MD5 Message-Digest Algorithm} for authenticating messages between different machines on the network. In writing the @code{chronyd} program, extensive use has been made of RFC 1305 and RFC 5905, written by David Mills. The source code of the NTP reference implementation has been used to check details of the protocol. @c }}} @c {{{ S:Availability @node Availability @section Availability @menu * Getting the software:: Where can I get the software from? * Platforms:: Which platforms will it run on? @end menu @node Getting the software @subsection Getting the software Links on @uref{http://chrony.tuxfamily.org, the chrony home page} describe how to obtain the software. @node Platforms @subsection Platforms Although most of the program is portable between Unix-like systems, there are parts that have to be tailored to each specific vendor's system. These are the parts that interface with the operating system's facilities for adjusting the system clock; different operating systems may provide different function calls to achieve this, and even where the same function is used it may have different quirks in its behaviour. The software is known to work on Linux, FreeBSD, NetBSD, Mac OS X and Solaris. Closely related systems may work too. Porting the software to other systems (particularly to those supporting an @code{adjtime} or @code{ntp_adjtime} system call) should not be difficult, however it requires access to such systems to test out the driver. @c }}} @c {{{ S:Other programs @node Other time synchronisation packages @section Relationship to other software packages @menu * Comparison with ntpd:: * Comparison with timed:: @end menu @node Comparison with ntpd @subsection ntpd The `reference' implementation of the Network Time Protocol is the program @code{ntpd}, available via @uref{http://www.ntp.org/, The NTP home page}. One of the main differences between @code{ntpd} and @code{chronyd} is in how they control the computer's clock. Things @code{chronyd} can do better than @code{ntpd}: @itemize @bullet @item @code{chronyd} can perform usefully in an environment where access to the time reference is intermittent. @code{ntpd} needs regular polling of the reference to work well. @item @code{chronyd} can usually synchronise the clock faster and with better time accuracy. @item @code{chronyd} quickly adapts to sudden changes in the rate of the clock (e.g. due to changes in the temperature of the crystal oscillator). @code{ntpd} may need a long time to settle down again. @item @code{chronyd} can perform well even when the network is congested for longer periods of time. @item @code{chronyd} in the default configuration never steps the time to not upset other running programs. @code{ntpd} can be configured to never step the time too, but in that case it has to use a different means of adjusting the clock (daemon loop instead of kernel discipline), which may have a negative effect on accuracy of the clock. @item @code{chronyd} can adjust the rate of the clock in a larger range, which allows it to operate even on machines with broken or unstable clock (e.g. in some virtual machines). @item @code{chronyd} is smaller, it uses less memory and it wakes up the CPU only when necessary, which is better for power saving. @end itemize Things @code{chronyd} can do that @code{ntpd} can't: @itemize @bullet @item @code{chronyd} provides support for isolated networks whether the only method of time correction is manual entry (e.g. by the administrator looking at a clock). @code{chronyd} can look at the errors corrected at different updates to work out the rate at which the computer gains or loses time, and use this estimate to trim the computer clock subsequently. @item @code{chronyd} provides support to work out the gain or loss rate of the `real-time clock', i.e. the clock that maintains the time when the computer is turned off. It can use this data when the system boots to set the system time from a corrected version of the real-time clock. These real-time clock facilities are only available on Linux, so far. @end itemize Things @code{ntpd} can do that @code{chronyd} can't: @itemize @bullet @item @code{ntpd} supports all operating modes from RFC 5905, including broadcast, multicast, and manycast server/client. However, the broadcast and multicast modes are inherently less accurate and less secure (even with authentication) than the ordinary server/client mode and should generally be avoided. @item @code{ntpd} supports the Autokey protocol (RFC 5906) to authenticate servers with public-key cryptography. Note that the protocol has been shown to be insecure and it will be probably replaced with an implementation of the Network Time Security (NTS) specification. @item @code{ntpd} supports the orphan mode, which allows synchronisation to a common timescale in isolated networks with multiple servers. With @code{chronyd} there can be only one master and all other computers have to be directly or indirectly synchronised to it. @item @code{ntpd} has been ported to more operating systems. @item @code{ntpd} includes a large number of reference clock drivers. @code{chronyd} relies on other programs (e.g. @code{gpsd}) to access the timing data via the @code{SHM} or @code{SOCK} driver. @end itemize A comparison of NTP implementations that includes more features and also their performance is on the @uref{http://chrony.tuxfamily.org/comparison.html, chrony comparison} page. @node Comparison with timed @subsection timed @code{timed} is a program that is part of the BSD networking suite. It uses broadcast packets to find all machines running the daemon within a subnet. The machines elect a master which periodically measures the system clock offsets of the other computers using ICMP timestamps. Corrections are sent to each member as a result of this process. Problems that may arise with @code{timed} are : @itemize @bullet @item Because it uses broadcasts, it is not possible to isolate its functionality to a particular group of computers; there is a risk of upsetting other computers on the same network (e.g. where a whole company is on the same subnet but different departments are independent from the point of view of administering their computers.) @item The update period appears to be 10 minutes. Computers can build up significant offsets relative to each other in that time. If a computer can estimate its rate of drift it can keep itself closer to the other computers between updates by adjusting its clock every few seconds. @code{timed} does not seem to do this. @item @code{timed} does not have any integrated capability for feeding real-time into its estimates, or for estimating the average rate of time loss/gain of the machines relative to real-time (unless one of the computers in the group has access to an external reference and is always appointed as the `master'). @end itemize @code{timed} does have the benefit over @code{chronyd} that for isolated networks of computers, they will track the `majority vote' time. For such isolated networks, @code{chronyd} requires one computer to be the `master' with the others slaved to it. If the master has a particular defective clock, the whole set of computers will tend to slip relative to real time (but they @emph{will} stay accurate relative to one another). @c }}} @c {{{ S:Rights + warranty @node Distribution and warranty @section Distribution rights and (lack of) warranty Chrony may be distributed in accordance with the GNU General Public License version 2, reproduced in @xref{GPL}. @c }}} @c {{{ S:Bug reporting + suggestions @node Bug reporting @section Bug reporting and suggestions If you think you've found a bug in chrony, or have a suggestion, please let us know. You can join chrony users mailing list by sending a message with the subject subscribe to @email{chrony-users-request@@chrony.tuxfamily.org}. Only subscribers can post to the list. When you are reporting a bug, please send us all the information you can. Unfortunately, chrony has proven to be one of those programs where it is very difficult to reproduce bugs in a different environment. So we may have to interact with you quite a lot to obtain enough extra logging and tracing to pin-point the problem in some cases. Please be patient and plan for this! Of course, if you can debug the problem yourself and send us a source code patch to fix it, we will be very grateful! @c }}} @c }}} @c {{{ Ch:Installation @node Installation @chapter Installation @c {{{ main introduction text The software is distributed as source code which has to be compiled. The source code is supplied in the form of a gzipped tar file, which unpacks to a subdirectory identifying the name and version of the program. After unpacking the source code, change directory into it, and type @example ./configure @end example This is a shell script that automatically determines the system type. There is a single optional parameter, @code{--prefix} which indicates the directory tree where the software should be installed. For example, @example ./configure --prefix=/opt/free @end example will install the @code{chronyd} daemon into /opt/free/sbin and the @code{chronyc} control program into /opt/free/bin. The default value for the prefix is /usr/local. The configure script assumes you want to use gcc as your compiler. If you want to use a different compiler, you can configure this way: @example CC=cc CFLAGS=-O ./configure --prefix=/opt/free @end example for Bourne-family shells, or @example setenv CC cc setenv CFLAGS -O ./configure --prefix=/opt/free @end example for C-family shells. If the software cannot (yet) be built on your system, an error message will be shown. Otherwise, @file{Makefile} will be generated. If editline or readline library is available, chronyc will be built with line editing support. If you don't want this, specify the --disable-readline flag to configure. Please refer to @pxref{line editing support} for more information. If a @file{timepps.h} header is available (e.g. from the @uref{http://linuxpps.org/, LinuxPPS project}), @code{chronyd} will be built with PPS API reference clock driver. If the header is installed in a location that isn't normally searched by the compiler, you can add it to the searched locations by setting @code{CPPFLAGS} variable to @code{-I/path/to/timepps}. Now type @example make @end example to build the programs. If you want to build the manual in plain text, HTML and info versions, type @example make docs @end example Once the programs have been successfully compiled, they need to be installed in their target locations. This step normally needs to be performed by the superuser, and requires the following command to be entered. @example make install @end example This will install the binaries and manpages. To install the plain text, HTML and info versions of the manual, enter the command @example make install-docs @end example If you want chrony to appear in the top level info directory listing, you need to run the @command{install-info} command manually after this step. @command{install-info} takes 2 arguments. The first is the path to the @file{chrony.info} file you have just installed. This will be the argument you gave to --prefix when you configured (@file{/usr/local} by default), with @file{/share/info/chrony.info} on the end. The second argument is the location of the file called @file{dir}. This will typically be @file{/usr/share/info/dir}. So the typical command line would be @example install-info /usr/local/share/info/chrony.info /usr/share/info/dir @end example Now that the software is successfully installed, the next step is to set up a configuration file. The default location of the file is @file{@SYSCONFDIR@/chrony.conf}. Several examples of configuration with comments are included in the examples directory. Suppose you want to use public NTP servers from the pool.ntp.org project as your time reference. A minimal useful configuration file could be @example pool pool.ntp.org iburst makestep 1.0 3 rtcsync @end example Then, @code{chronyd} can be run. @c }}} @menu * line editing support:: If libraries are in a non-standard place * package builders:: Extra options useful to package builders @end menu @c {{{ line editing support @node line editing support @section Support for line editing libraries Chronyc can be built with support for line editing, this allows you to use the cursor keys to replay and edit old commands. Two libraries are supported which provide such functionality, editline and GNU readline. Please note that readline since version 6.0 is licensed under GPLv3+ which is incompatible with chrony's license GPLv2. You should use editline instead if you don't want to use older readline versions. The configure script will automatically enable the line editing support if one of the supported libraries is available. If they are both available, the editline library will be used. If you don't want to use it (in which case chronyc will use a minimal command line interface), invoke configure like this: @example ./configure --disable-readline other-options... @end example If you have editline, readline or ncurses installed in locations that aren't normally searched by the compiler and linker, you need to use extra options: @table @samp @item --with-readline-includes=directory_name This defines the name of the directory above the one where @file{readline.h} is. @file{readline.h} is assumed to be in @file{editline} or @file{readline} subdirectory of the named directory. @item --with-readline-library=directory_name This defines the directory containing the @file{libedit.a} or @file{libedit.so} file, or @file{libreadline.a} or @file{libreadline.so} file. @item --with-ncurses-library=directory_name This defines the directory containing the @file{libncurses.a} or @file{libncurses.so} file. @end table @c }}} @c {{{ @node package builders @section Extra options for package builders The configure and make procedures have some extra options that may be useful if you are building a distribution package for chrony. The --infodir=DIR option to configure specifies an install directory for the info files. This overrides the @file{info} subdirectory of the argument to the --prefix option. For example, you might use @example ./configure --prefix=/usr --infodir=/usr/share/info @end example The --mandir=DIR option to configure specifies an install directory for the man pages. This overrides the @file{man} subdirectory of the argument to the --prefix option. @example ./configure --prefix=/usr --infodir=/usr/share/info --mandir=/usr/share/man @end example to set both options together. The final option is the DESTDIR option to the make command. For example, you could use the commands @example ./configure --prefix=/usr --infodir=/usr/share/info --mandir=/usr/share/man make all docs make install DESTDIR=./tmp cd tmp tar cvf - . | gzip -9 > chrony.tar.gz @end example to build a package. When untarred within the root directory, this will install the files to the intended final locations. @c }}} @c }}} @c {{{ Ch:Typical operating scenarios @c {{{ Chapter top @node Typical scenarios @chapter Typical operating scenarios @menu * Computers on the net:: Your computer is on the Internet most of the time (or on a private network with NTP servers) * Infrequent connection:: You connect to the Internet sometimes (e.g. via a modem) * Isolated networks:: You have an isolated network with no reference clocks * Dial-up home PCs:: Additional considerations if you turn your computer off when it's not in use * Configuration options overview:: Overview of some configuration options @end menu @c }}} @c {{{ S:Permanent connection @node Computers on the net @section Computers connected to the internet In this section we discuss how to configure chrony for computers that are connected to the Internet (or to any network containing true NTP servers which ultimately derive their time from a reference clock) permanently or most of the time. To operate in this mode, you will need to know the names of the NTP server machines you wish to use. You may be able to find names of suitable servers by one of the following methods: @itemize @bullet @item Your institution may already operate servers on its network. Contact your system administrator to find out. @item Your ISP probably has one or more NTP servers available for its customers. @item Somewhere under the NTP homepage there is a list of public stratum 1 and stratum 2 servers. You should find one or more servers that are near to you --- check that their access policy allows you to use their facilities. @item Use public servers from @uref{http://www.pool.ntp.org/, the pool.ntp.org project}. @end itemize Assuming that you have found some servers, you need to set up a configuration file to run chrony. The (compiled-in) default location for this file is @file{@SYSCONFDIR@/chrony.conf}. Assuming that your NTP servers are called @code{foo.example.net}, @code{bar.example.net} and @code{baz.example.net}, your @file{chrony.conf} file could contain as a minimum @example server foo.example.net server bar.example.net server baz.example.net @end example However, you will probably want to include some of the other directives described later. The following directives may be particularly useful : @code{driftfile}, @code{makestep}, @code{rtcsync}. Also, the @code{iburst} server option is useful to speed up the initial synchronization. The smallest useful configuration file would look something like @example server foo.example.net iburst server bar.example.net iburst server baz.example.net iburst driftfile @CHRONYVARDIR@/drift makestep 1.0 3 rtcsync @end example When using a pool of NTP servers (one name is used for multiple servers which may change over time), it's better to specify them with the @code{pool} directive instead of multiple @code{server} directives. The configuration file could in this case look like @example pool pool.ntp.org iburst driftfile @CHRONYVARDIR@/drift makestep 1.0 3 rtcsync @end example @c }}} @c {{{ S:Infrequent connection @node Infrequent connection @section Infrequent connection to true NTP servers In this section we discuss how to configure chrony for computers that have occasional connections to the internet. @menu * Configuration for infrequent connections:: How to set up the @code{@SYSCONFDIR@/chrony.conf} file * Advising chronyd of internet availability:: How to tell chronyd when the link is available @end menu @node Configuration for infrequent connections @subsection Setting up the configuration file for infrequent connections As in the previous section, you will need access to NTP servers on the internet. The same remarks apply for how to find them. In this case, you will need some additional configuration to tell @code{chronyd} when the connection to the internet goes up and down. This saves the program from continuously trying to poll the servers when they are inaccessible. Again, assuming that your NTP servers are called @code{foo.example.net}, @code{bar.example.net} and @code{baz.example.net}, your @file{chrony.conf} file would need to contain something like @example server foo.example.net server bar.example.net server baz.example.net @end example However, your computer will keep trying to contact the servers to obtain timestamps, even whilst offline. If you operate a dial-on-demand system, things are even worse, because the link to the internet will keep getting established. For this reason, it would be better to specify this part of your configuration file in the following way: @example server foo.example.net offline server bar.example.net offline server baz.example.net offline @end example The @code{offline} keyword indicates that the servers start in an offline state, and that they should not be contacted until @code{chronyd} receives notification from @code{chronyc} that the link to the internet is present. The smallest useful configuration file would look something like @example server foo.example.net offline server bar.example.net offline server baz.example.net offline driftfile @CHRONYVARDIR@/drift makestep 1.0 3 rtcsync @end example The next section describes how to tell @code{chronyd} when the internet link goes up and down. @node Advising chronyd of internet availability @subsection How to tell chronyd when the internet link is available. To tell @code{chronyd} when to start and finish sampling the servers, the @code{online} and @code{offline} commands of @code{chronyc} need to be used. To give an example of their use, we assume that @code{pppd} is the program being used to connect to the internet, and that @code{chronyc} has been installed at its default location @file{@BINDIR@/chronyc}. In the file @file{/etc/ppp/ip-up} we add the command sequence @example @BINDIR@/chronyc online @end example and in the file @file{/etc/ppp/ip-down} we add the sequence @example @BINDIR@/chronyc offline @end example @code{chronyd's} polling of the servers will now only occur whilst the machine is actually connected to the Internet. @c }}} @c {{{ S:Isolated networks @node Isolated networks @section Isolated networks In this section we discuss how to configure chrony for computers that never have network conectivity to any computer which ultimately derives its time from a reference clock. In this situation, one computer is selected to be the master timeserver. The other computers are either direct clients of the master, or clients of clients. The rate value in the master's drift file needs to be set to the average rate at which the master gains or loses time. @code{chronyd} includes support for this, in the form of the @code{manual} directive in the configuration file and the @code{settime} command in the @code{chronyc} program. The @code{smoothtime} directive (@pxref{smoothtime directive}) is useful when the clocks of the clients need to stay close together when the local time is adjusted by the @code{settime} command. The smoothing process needs to be activated by the @code{smoothtime activate} command when the local time is ready to be served. After that point, any adjustments will be smoothed out. A typical configuration file for the master (called @code{master}) might be (assuming the clients are in the 192.168.165.x subnet) @example driftfile @CHRONYVARDIR@/drift local stratum 8 manual allow 192.168.165 smoothtime 400 0.01 @end example For the clients the configuration file might be @example server master iburst driftfile @CHRONYVARDIR@/drift logdir /var/log/chrony log measurements statistics tracking @end example @c }}} @c {{{ S:Dial-up home PCs @node Dial-up home PCs @section The home PC with a dial-up connection @menu * Dial-up overview:: General discussion of how the software operates in this mode * Dial-up configuration:: Typical configuration files @end menu @node Dial-up overview @subsection Assumptions/how the software works This section considers the home computer which has a dial-up connection. It assumes that Linux is run exclusively on the computer. Dual-boot systems may work; it depends what (if anything) the other system does to the system's real-time clock. Much of the configuration for this case is discussed earlier (@pxref{Infrequent connection}). This section addresses specifically the case of a computer which is turned off between 'sessions'. In this case, @code{chronyd} relies on the computer's real-time clock (RTC) to maintain the time between the periods when it is powered up. The arrangement is shown in the figure below. @example @group trim if required PSTN +---------------------------+ +----------+ | | | | v | | | +---------+ +-------+ +-----+ +---+ | System's| measure error/ |chronyd| |modem| |ISP| |real-time|------------------->| |-------| | | | | clock | drift rate +-------+ +-----+ +---+ +---------+ ^ | | | | +---------------------------+ --o-----o--- set time at boot up | +----------+ |NTP server| +----------+ @end group @end example When the computer is connected to the Internet (via the modem), @code{chronyd} has access to external NTP servers which it makes measurements from. These measurements are saved, and straight-line fits are performed on them to provide an estimate of the computer's time error and rate of gaining/losing time. When the computer is taken offline from the Internet, the best estimate of the gain/loss rate is used to free-run the computer until it next goes online. Whilst the computer is running, @code{chronyd} makes measurements of the real-time clock (RTC) (via the @file{/dev/rtc} interface, which must be compiled into the kernel). An estimate is made of the RTC error at a particular RTC second, and the rate at which the RTC gains or loses time relative to true time. On 2.6 and later kernels, if your motherboard has a HPET, you need to enable the @samp{HPET_EMULATE_RTC} option in your kernel configuration. Otherwise, chrony will not be able to interact with the RTC device and will give up using it. When the computer is powered down, the measurement histories for all the NTP servers are saved to files (if the @code{dumponexit} directive is specified in the configuration file), and the RTC tracking information is also saved to a file (if the @code{rtcfile} directive has been specified). These pieces of information are also saved if the @code{dump} and @code{writertc} commands respectively are issued through @code{chronyc}. When the computer is rebooted, @code{chronyd} reads the current RTC time and the RTC information saved at the last shutdown. This information is used to set the system clock to the best estimate of what its time would have been now, had it been left running continuously. The measurement histories for the servers are then reloaded. The next time the computer goes online, the previous sessions' measurements can contribute to the line-fitting process, which gives a much better estimate of the computer's gain/loss rate. One problem with saving the measurements and RTC data when the machine is shut down is what happens if there is a power failure; the most recent data will not be saved. Although @code{chronyd} is robust enough to cope with this, some performance may be lost. (The main danger arises if the RTC has been changed during the session, with the @code{trimrtc} command in @code{chronyc}. Because of this, @code{trimrtc} will make sure that a meaningful RTC file is saved out after the change is completed). The easiest protection against power failure is to put the @code{dump} and @code{writertc} commands in the same place as the @code{offline} command is issued to take @code{chronyd} offline; because @code{chronyd} free-runs between online sessions, no parameters will change significantly between going offline from the Internet and any power failure. A final point regards home computers which are left running for extended periods and where it is desired to spin down the hard disc when it is not in use (e.g. when not accessed for 15 minutes). @code{chronyd} has been planned so it supports such operation; this is the reason why the RTC tracking parameters are not saved to disc after every update, but only when the user requests such a write, or during the shutdown sequence. The only other facility that will generate periodic writes to the disc is the @code{log rtc} facility in the configuration file; this option should not be used if you want your disc to spin down. @node Dial-up configuration @subsection Typical configuration files. To illustrate how a dial-up home computer might be configured, example configuration files are shown in this section. For the @file{@SYSCONFDIR@/chrony.conf} file, the following can be used as an example. @example server foo.example.net maxdelay 0.4 offline server bar.example.net maxdelay 0.4 offline server baz.example.net maxdelay 0.4 offline logdir /var/log/chrony log statistics measurements tracking driftfile @CHRONYVARDIR@/drift makestep 1.0 3 maxupdateskew 100.0 dumponexit dumpdir @CHRONYVARDIR@ rtcfile @CHRONYVARDIR@/rtc @end example @code{pppd} is used for connecting to the internet. This runs two scripts @file{/etc/ppp/ip-up} and @file{/etc/ppp/ip-down} when the link goes online and offline respectively. The relevant part of the @file{/etc/ppp/ip-up} file is @example @BINDIR@/chronyc online @end example and the relevant part of the @file{/etc/ppp/ip-down} script is @example @BINDIR@/chronyc -m offline dump writertc @end example To start @code{chronyd} during the boot sequence, the following is in @file{/etc/rc.d/rc.local} (this is a Slackware system) @example if [ -f @SBINDIR@/chronyd -a -f @SYSCONFDIR@/chrony.conf ]; then @SBINDIR@/chronyd -r -s echo "Start chronyd" fi @end example The placement of this command may be important on some systems. In particular, @code{chronyd} may need to be started before any software that depends on the system clock not jumping or moving backwards, depending on the directives in @code{chronyd's} configuration file. For the system shutdown, @code{chronyd} should receive a SIGTERM several seconds before the final SIGKILL; the SIGTERM causes the measurement histories and RTC information to be saved out. @c }}} @c {{{ S:Other config options @node Configuration options overview @section Other important configuration options The most common option to include in the configuration file is the @code{driftfile} option. One of the major tasks of @code{chronyd} is to work out how fast or how slow the system clock runs relative to real time - e.g. in terms of seconds gained or lost per day. Measurements over a long period are usually required to refine this estimate to an acceptable degree of accuracy. Therefore, it would be bad if @code{chronyd} had to work the value out each time it is restarted, because the system clock would not run so accurately whilst the determination is taking place. To avoid this problem, @code{chronyd} allows the gain or loss rate to be stored in a file, which can be read back in when the program is restarted. This file is called the drift file, and might typically be stored in @file{@CHRONYVARDIR@/drift}. By specifying an option like the following @example driftfile @CHRONYVARDIR@/drift @end example in the configuration file (@file{@SYSCONFDIR@/chrony.conf}), the drift file facility will be activated. @c }}} @c }}} @c {{{ Ch:Usage reference @node Usage reference @chapter Usage reference @c {{{ Chapter top @menu * Starting chronyd:: Command line options for the daemon * Configuration file:: Format of the configuration file * Running chronyc:: The run-time configuration program @end menu @c }}} @c {{{ S:Starting chronyd @node Starting chronyd @section Starting chronyd If @code{chronyd} has been installed to its default location @file{@SBINDIR@/chronyd}, starting it is simply a matter of entering the command @example @SBINDIR@/chronyd @end example Information messages and warnings will be logged to syslog. If no configuration commands are specified on the command line, @code{chronyd} will read the commands from the configuration file (default @file{@SYSCONFDIR@/chrony.conf}). The command line options supported are as follows: @table @code @item -n When run in this mode, the program will not detach itself from the terminal. @item -d When run in this mode, the program will not detach itself from the terminal, and all messages will be sent to the terminal instead of to syslog. When @code{chronyd} was compiled with debugging support, this option can be used twice to print also debugging messages. @item -f This option can be used to specify an alternate location for the configuration file (default @file{@SYSCONFDIR@/chrony.conf}). @item -r This option will reload sample histories for each of the servers and refclocks being used. These histories are created by using the @code{dump} command in @code{chronyc}, or by setting the @code{dumponexit} directive in the configuration file. This option is useful if you want to stop and restart @code{chronyd} briefly for any reason, e.g. to install a new version. However, it should be used only on systems where the kernel can maintain clock compensation whilst not under @code{chronyd's} control (i.e. Linux, FreeBSD, NetBSD and Solaris). @item -R When this option is used, the @code{initstepslew} directive and the @code{makestep} directive used with a positive limit will be ignored. This option is useful when restarting @code{chronyd} and can be used in conjunction with the `-r' option. @item -s This option will set the system clock from the computer's real-time clock or to the last modification time of the file specified by the @code{driftfile} directive. Real-time clocks are supported only on Linux. If used in conjunction with the `-r' flag, @code{chronyd} will attempt to preserve the old samples after setting the system clock from the real time clock (RTC). This can be used to allow @code{chronyd} to perform long term averaging of the gain or loss rate across system reboots, and is useful for dial-up systems that are shut down when not in use. For this to work well, it relies on @code{chronyd} having been able to determine accurate statistics for the difference between the RTC and system clock last time the computer was on. If the last modification time of the drift file is later than the current time and the RTC time, the system time will be set to it to restore the time when @code{chronyd} was previously stopped. This is useful on computers that have no RTC or the RTC is broken (e.g. it has no battery). @item -u This option sets the name of the system user to which @code{chronyd} will switch after start in order to drop root privileges. It overrides the @code{user} directive (default @code{@DEFAULT_USER@}). It may be set to a non-root user only when @code{chronyd} is compiled with support for Linux capabilities (libcap) or on NetBSD with the @code{/dev/clockctl} device. @item -F This option configures a system call filter when @code{chronyd} is compiled with support for the Linux secure computing (seccomp) facility. In level 1 the process is killed when a forbidden system call is made, in level -1 the SYSSIG signal is thrown instead and in level 0 the filter is disabled (default 0). @item -q When run in this mode, @code{chronyd} will set the system clock once and exit. It will not detach from the terminal. @item -Q This option is similar to `-q', but it will only print the offset and not correct the clock. @item -v This option displays @code{chronyd's} version number to the terminal and exits. @item -P On Linux, this option will select the SCHED_FIFO real-time scheduler at the specified priority (which must be between 0 and 100). On Mac OS X, this option must have either a value of 0 (the default) to disable the thread time constraint policy or 1 for the policy to be enabled. Other systems do not support this option. @item -m This option will lock chronyd into RAM so that it will never be paged out. This mode is only supported on Linux. @item -4 With this option hostnames will be resolved only to IPv4 addresses and only IPv4 sockets will be created. @item -6 With this option hostnames will be resolved only to IPv6 addresses and only IPv6 sockets will be created. @end table On systems that support an @file{/etc/rc.local} file for starting programs at boot time, @code{chronyd} can be started from there. On systems with a System V style initialisation, a suitable start/stop script might be as shown below. This might be placed in the file @file{/etc/rc2.d/S83chrony}. @example @group #!/bin/sh # This file should have uid root, gid sys and chmod 744 # killproc() @{ # kill the named process(es) pid=`/usr/bin/ps -e | /usr/bin/grep -w $1 | /usr/bin/sed -e 's/^ *//' -e 's/ .*//'` [ "$pid" != "" ] && kill $pid @} case "$1" in 'start') if [ -f /opt/free/sbin/chronyd -a -f @SYSCONFDIR@/chrony.conf ]; then /opt/free/sbin/chronyd fi ;; 'stop') killproc chronyd ;; *) echo "Usage: /etc/rc2.d/S83chrony @{ start | stop @}" ;; esac @end group @end example (In both cases, you may want to bear in mind that @code{chronyd} can step the time when it starts. There may be other programs started at boot time that could be upset by this, so you may need to consider the ordering carefully. However, @code{chronyd} will need to start after daemons providing services that it may require, e.g. the domain name service.) @c }}} @c {{{ S:chronyd configuration file @node Configuration file @section The chronyd configuration file @c {{{ section top The configuration file is normally called @file{@SYSCONFDIR@/chrony.conf}; in fact, this is the compiled-in default. However, other locations can be specified with a command line option. Each command in the configuration file is placed on a separate line. The following sections describe each of the commands in turn. The directives can occur in any order in the file and they are not case-sensitive. The configuration commands can also be specified directly on the @code{chronyd} command line, each argument is parsed as a line and the configuration file is ignored. @menu * comments in config file:: How to write a comment * acquisitionport directive:: Set NTP client port * allow directive:: Give access to NTP clients * bindacqaddress directive:: Limit network interface used by NTP client * bindaddress directive:: Limit network interface used by NTP server * bindcmdaddress directive:: Limit network interface used for commands * broadcast directive:: Make chronyd act as an NTP broadcast server * clientloglimit directive:: Set client log memory limit * cmdallow directive:: Give monitoring access to chronyc on other computers * cmddeny directive:: Deny monitoring access to chronyc on other computers * cmdport directive:: Set port to use for runtime monitoring * combinelimit directive:: Limit sources included in combining algorithm * corrtimeratio directive:: Set correction time ratio * deny directive:: Deny access to NTP clients * driftfile directive:: Specify location of file containing drift data * dumpdir directive:: Specify directory for dumping measurements * dumponexit directive:: Dump measurements when daemon exits * fallbackdrift directive:: Specify fallback drift intervals * hwclockfile directive:: Specify location of hwclock's adjtime file * include directive:: Include a configuration file * initstepslew directive:: Trim the system clock on boot-up * keyfile directive:: Specify location of file containing keys * leapsecmode directive:: Select leap second handling mode * leapsectz directive:: Read leap second data from tz database * local directive:: Allow unsynchronised machine to act as server * lock_all directive:: Require that chronyd be locked into RAM * log directive:: Make daemon log certain sets of information * logbanner directive:: Specify how often is banner written to log files * logchange directive:: Generate syslog messages if large offsets occur * logdir directive:: Specify directory for logging * mailonchange directive:: Send email if a clock correction above a threshold occurs * makestep directive:: Step system clock if large correction is needed * manual directive:: Allow manual entry using chronyc's settime cmd * maxchange directive:: Set maximum allowed offset * maxclockerror directive:: Set maximum frequency error of local clock * maxdistance directive:: Set maximum allowed distance of sources * maxsamples directive:: Set maximum number of samples per source * maxslewrate directive:: Set maximum slew rate * maxupdateskew directive:: Stop bad estimates upsetting machine clock * minsamples directive:: Set minimum number of samples per source * minsources directive:: Set minimum number of selectable sources to update clock * noclientlog directive:: Prevent chronyd from gathering data about clients * peer directive:: Specify an NTP peer * pidfile directive:: Specify the file where chronyd's pid is written * pool directive:: Specify an NTP pool * port directive:: Set NTP server port * refclock directive:: Specify a reference clock * reselectdist directive:: Set improvement in distance needed to reselect a source * rtcautotrim directive:: Specify threshold at which RTC is trimmed automatically * rtcdevice directive:: Specify name of enhanced RTC device (if not /dev/rtc) * rtcfile directive:: Specify the file where real-time clock data is stored * rtconutc directive:: Specify that the real time clock keeps UTC not local time * rtcsync directive:: Specify that RTC should be automatically synchronised by kernel * sched_priority directive:: Require real-time scheduling and specify a priority for it * server directive:: Specify an NTP server * smoothtime directive:: Smooth served time to keep clients close together * stratumweight directive:: Specify how important is stratum when selecting source * tempcomp directive:: Specify temperature sensor and compensation coefficients * user directive:: Specify user for dropping root privileges @end menu @c }}} @c {{{ comments in config file @node comments in config file @subsection Comments in the configuration file The configuration file may contain comment lines. A comment line is any line that starts with zero or more spaces followed by any one of the following characters: @itemize @item ! @item ; @item # @item % @end itemize Any line with this format will be ignored. @c }}} @c {{{ acquisitionport directive @node acquisitionport directive @subsection acquisitionport By default, @code{chronyd} uses a separate client socket for each configured server and their source port is chosen arbitrarily by the operating system. However, you can use the @code{acquisitionport} directive to explicitly specify a port and use only one socket (per IPv4/IPv6 address family) for all configured servers. This may be useful for getting through firewalls. If set to 0, the source port of the socket will be chosen arbitrarily. It may be set to the same port as used by the NTP server (@pxref{port directive}) to use only one socket for all NTP packets. An example of the @code{acquisitionport} command is @example acquisitionport 1123 @end example This would change the source port used for client requests to udp/1123. You could then persuade the firewall administrator to let that port through. @c }}} @c {{{ allow @node allow directive @subsection allow The @code{allow} command is used to designate a particular subnet from which NTP clients are allowed to access the computer as an NTP server. The default is that no clients are allowed access, i.e. @code{chronyd} operates purely as an NTP client. If the @code{allow} directive is used, @code{chronyd} will be both a client of its servers, and a server to other clients. Examples of use of the command are as follows: @example allow foo.example.net allow 1.2 allow 3.4.5 allow 6.7.8/22 allow 6.7.8.9/22 allow 2001:db8::/32 allow 0/0 allow ::/0 allow @end example The first command allows the named node to be an NTP client of this computer. The second command allows any node with an IPv4 address of the form 1.2.x.y (with x and y arbitrary) to be an NTP client of this computer. Likewise, the third command allows any node with an IPv4 address of the form 3.4.5.x to have client NTP access. The fourth and fifth forms allow access from any node with an IPv4 address of the form 6.7.8.x, 6.7.9.x, 6.7.10.x or 6.7.11.x (with x arbitrary), i.e. the value 22 is the number of bits defining the specified subnet. (In the fifth form, the final byte is ignored). The sixth form is used for IPv6 addresses. The seventh and eighth forms allow access by any IPv4 and IPv6 node respectively. The ninth forms allows access by any node (IPv4 or IPv6). A second form of the directive, @code{allow all}, has a greater effect, depending on the ordering of directives in the configuration file. To illustrate the effect, consider the two examples @example allow 1.2.3.4 deny 1.2.3 allow 1.2 @end example and @example allow 1.2.3.4 deny 1.2.3 allow all 1.2 @end example In the first example, the effect is the same regardles of what order the three directives are given in. So the 1.2.x.y subnet is allowed access, except for the 1.2.3.x subnet, which is denied access, however the host 1.2.3.4 is allowed access. In the second example, the @code{allow all 1.2} directives overrides the effect of @emph{any} previous directive relating to a subnet within the specified subnet. Within a configuration file this capability is probably rather moot; however, it is of greater use for reconfiguration at run-time via @code{chronyc} (@pxref{allow all command}). Note, if the @code{initstepslew} directive (@pxref{initstepslew directive}) is used in the configuration file, each of the computers listed in that directive must allow client access by this computer for it to work. @c }}} @c {{{ bindacqaddress @node bindacqaddress directive @subsection bindacqaddress The @code{bindacqaddress} directive sets the network interface to which will @code{chronyd} bind its NTP client sockets. The syntax is similar to the @code{bindaddress} and @code{bindcmdaddress} directives. For each of IPv4 and IPv6 protocols, only one @code{bindacqaddress} directive can be specified. @c }}} @c {{{ bindaddress @node bindaddress directive @subsection bindaddress The @code{bindaddress} directive allows you to restrict the network interface to which @code{chronyd} will listen for NTP requests. This provides an additional level of access restriction above that available through the @code{deny} mechanism. Suppose you have a local ethernet with addresses in the 192.168.1.0 subnet together with an internet connection. The ethernet interface's IP address is 192.168.1.1. Suppose you want to block all access through the internet connection. You could add the line @example bindaddress 192.168.1.1 @end example to the configuration file. For each of IPv4 and IPv6 protocols, only one @code{bindaddress} directive can be specified. Therefore, it's not useful on computers which should serve NTP on multiple network interfaces. @c }}} @c {{{ bindcmdaddress @node bindcmdaddress directive @subsection bindcmdaddress The @code{bindcmdaddress} directive allows you to specify the network interface to which @code{chronyd} will listen for monitoring command packets (issued by @code{chronyc}). This provides an additional level of access restriction above that available through @code{cmddeny} mechanism. This directive can also change the path of the Unix domain command socket, which is used by @code{chronyc} to send configuration commands. The socket must be in a directory that is accessible only by the root or chrony user. The directory will be created on start if it doesn't exist. The default path of the socket is @code{@CHRONYSOCKDIR@/chronyd.sock}. By default, @code{chronyd} binds to the loopback interface (with addresses @code{127.0.0.1} and @code{::1}). This blocks all access except from localhost. To listen for command packets on all interfaces, you can add the lines @example bindcmdaddress 0.0.0.0 bindcmdaddress :: @end example to the configuration file. For each of IPv4 and IPv6 protocols, only one @code{bindcmdaddress} directive can be specified. An example that sets the path of the Unix domain command socket is @example bindcmdaddress /var/run/chrony/chronyd.sock @end example @c }}} @c {{{ broadcast directive @node broadcast directive @subsection broadcast The @code{broadcast} directive is used to declare a broadcast address to which chronyd should send packets in NTP broadcast mode (i.e. make chronyd act as a broadcast server). Broadcast clients on that subnet will be able to synchronise. The syntax is as follows @example broadcast 30 192.168.1.255 broadcast 60 192.168.2.255 12123 broadcast 60 ff02::101 @end example In the first example, the destination port defaults to 123/udp (the normal NTP port). In the second example, the destionation port is specified as 12123. The first parameter in each case (30 or 60 respectively) is the interval in seconds between broadcast packets being sent. The second parameter in each case is the broadcast address to send the packet to. This should correspond to the broadcast address of one of the network interfaces on the computer where chronyd is running. You can have more than 1 @code{broadcast} directive if you have more than 1 network interface onto which you wish to send NTP broadcast packets. @code{chronyd} itself cannot currently act as a broadcast client; it must always be configured as a point-to-point client by defining specific NTP servers and peers. This broadcast server feature is intended for providing a time source to other NTP software (e.g. various MS Windows clients). If ntpd is used as the broadcast client, it will try to use a point-to-point client/server NTP access to measure the round-trip delay. Thus, the broadcast subnet should also be the subject of an @code{allow} directive (@pxref{allow directive}). @c }}} @c {{{ clientloglimit @node clientloglimit directive @subsection clientloglimit This directive specifies the maximum size of the memory allocated to log client accesses. When the limit is reached, only information for clients that have already been logged will be updated. If 0 is specified, the memory size will be unlimited. The default is 524288 bytes. An example of the use of this directive is @example clientloglimit 1048576 @end example @c }}} @c {{{ cmdallow @node cmdallow directive @subsection cmdallow This is similar to the @code{allow} directive (@pxref{allow directive}), except that it allows monitoring access (rather than NTP client access) to a particular subnet or host. (By 'monitoring access' is meant that @code{chronyc} can be run on those hosts and retrieve monitoring data from @code{chronyd} on this computer.) The syntax is identical to the @code{allow} directive. There is also a @code{cmdallow all} directive with similar behaviour to the @code{allow all} directive (but applying to monitoring access in this case, of course). Note that @code{chronyd} has to be configured with the @code{bindcmdaddress} directive to not listen only on the loopback interface to actually allow remote access. @c }}} @c {{{ cmddeny @node cmddeny directive @subsection cmddeny This is similar to the @code{cmdallow} directive (@pxref{cmdallow directive}), except that it denies monitoring access to a particular subnet or host, rather than allowing it. The syntax is identical. There is also a @code{cmddeny all} directive with similar behaviour to the @code{cmdallow all} directive. @c }}} @c {{{ cmdport @node cmdport directive @subsection cmdport The @code{cmdport} directive allows the port that is used for run-time monitoring (via the @code{chronyc} program) to be altered from its default (323/udp). If set to 0, @code{chronyd} will not open the port, this is useful to disable the @code{chronyc} access from the internet. (It does not disable the Unix domain command socket.) An example shows the syntax @example cmdport 257 @end example This would make @code{chronyd} use 257/udp as its command port. (@code{chronyc} would need to be run with the @code{-p 257} switch to inter-operate correctly). @c }}} @c {{{ combinelimit @node combinelimit directive @subsection combinelimit When @code{chronyd} has multiple sources available for synchronization, it has to select one source as the synchronization source. The measured offsets and frequencies of the system clock relative to the other sources, however, can be combined with the selected source to improve the accuracy of the system clock. The @code{combinelimit} directive limits which sources are included in the combining algorithm. Their synchronization distance has to be shorter than the distance of the selected source multiplied by the value of the limit. Also, their measured frequencies have to be close to the frequency of the selected source. By default, the limit is 3. Setting the limit to 0 effectively disables the source combining algorithm and only the selected source will be used to control the system clock. The syntax is @example combinelimit @end example @c }}} @c {{{ corrtimeratio @node corrtimeratio directive @subsection corrtimeratio When @code{chronyd} is slewing the system clock to correct an offset, the rate at which it is slewing adds to the frequency error of the clock. On Linux, FreeBSD, NetBSD and Solaris this rate can be controlled. The @code{corrtimeratio} directive sets the ratio between the duration in which the clock is slewed for an average correction according to the source history and the interval in which the corrections are done (usually the NTP polling interval). Corrections larger than the average take less time and smaller corrections take more time, the amount of the correction and the correction time are inversely proportional. Increasing @code{corrtimeratio} improves the overall frequency error of the system clock, but increases the overall time error as the corrections take longer. By default, the ratio is set to 3, the time accuracy of the clock is preferred over its frequency accuracy. The syntax is @example corrtimeratio 100 @end example The maximum allowed slew rate can be set by the @code{maxslewrate} directive (@pxref{maxslewrate directive}. The current remaining correction is shown in the @code{tracking} report (@pxref{tracking command}) as the @code{System time} value. @c }}} @c {{{ deny @node deny directive @subsection deny This is similar to the @code{allow} directive (@pxref{allow directive}), except that it denies NTP client access to a particular subnet or host, rather than allowing it. The syntax is identical. There is also a @code{deny all} directive with similar behaviour to the @code{allow all} directive. @c }}} @c {{{ driftfile @node driftfile directive @subsection driftfile One of the main activities of the @code{chronyd} program is to work out the rate at which the system clock gains or loses time relative to real time. Whenever @code{chronyd} computes a new value of the gain/loss rate, it is desirable to record it somewhere. This allows @code{chronyd} to begin compensating the system clock at that rate whenever it is restarted, even before it has had a chance to obtain an equally good estimate of the rate during the new run. (This process may take many minutes, at least). The driftfile command allows a file to be specified into which @code{chronyd} can store the rate information. Two parameters are recorded in the file. The first is the rate at which the system clock gains or loses time, expressed in parts per million, with gains positive. Therefore, a value of 100.0 indicates that when the system clock has advanced by a second, it has gained 100 microseconds on reality (so the true time has only advanced by 999900 microseconds). The second is an estimate of the error bound around the first value in which the true rate actually lies. An example of the driftfile command is @example driftfile @CHRONYVARDIR@/drift @end example @c }}} @c {{{ dumpdir @node dumpdir directive @subsection dumpdir To compute the rate of gain or loss of time, @code{chronyd} has to store a measurement history for each of the time sources it uses. Certain systems (Linux, FreeBSD, NetBSD, Solaris) have operating system support for setting the rate of gain or loss to compensate for known errors. (On Mac OS X, @code{chronyd} must simulate such a capability by periodically slewing the system clock forwards or backwards by a suitable amount to compensate for the error built up since the previous slew). For such systems, it is possible to save the measurement history across restarts of @code{chronyd} (assuming no changes are made to the system clock behaviour whilst it is not running). If this capability is to be used (via the dumponexit command in the configuration file, or the dump command in chronyc), the dumpdir command should be used to define the directory where the measurement histories are saved. An example of the command is @example dumpdir @CHRONYVARDIR@ @end example A source whose reference id (the IP address for IPv4 sources) is 1.2.3.4 would have its measurement history saved in the file @file{/var/lib/chrony/1.2.3.4.dat}. @c }}} @c {{{ dumponexit @node dumponexit directive @subsection dumponexit If this command is present, it indicates that @code{chronyd} should save the measurement history for each of its time sources recorded whenever the program exits. (See the dumpdir command above). @c }}} @c {{{ fallbackdrift @node fallbackdrift directive @subsection fallbackdrift Fallback drifts are long-term averages of the system clock drift calculated over exponentially increasing intervals. They are used when the clock is no longer synchronised to avoid quickly drifting away from true time if there was a short-term deviation in the drift before the synchronisation was lost. The directive specifies the minimum and maximum interval since last clock update to switch between fallback drifts. They are defined as a power of 2 (in seconds). The syntax is as follows @example fallbackdrift 16 19 @end example In this example, the minimum interval is 16 (18 hours) and maximum interval is 19 (6 days). The system clock frequency will be set to the first fallback 18 hours after last clock update, to the second after 36 hours, etc. This might be a good setting to cover daily and weekly temperature fluctuations. By default (or if the specified maximum or minimum is 0), no fallbacks are used and the clock frequency changes only with new measurements from NTP, reference clocks or manual input. @c }}} @c {{{ hwclockfile @node hwclockfile directive @subsection hwclockfile The @code{hwclockfile} directive sets the location of the adjtime file which is used by the @file{/sbin/hwclock} program on Linux. @code{chronyd} parses the file to find out if the RTC keeps local time or UTC. It overrides the @code{rtconutc} directive (@pxref{rtconutc directive}). The default value is @file{@DEFAULT_HWCLOCK_FILE@}. An example of the command is @example hwclockfile /etc/adjtime @end example @c }}} @c {{{ include @node include directive @subsection include The @code{include} directive includes a specified configuration file or multiple configuration files when a wildcard pattern is specified. This can be useful when maintaining configuration on multiple hosts to keep the differences in separate files. An example of the command is @example include @SYSCONFDIR@/chrony.d/*.conf @end example @c }}} @c {{{ initstepslew @node initstepslew directive @subsection initstepslew In normal operation, @code{chronyd} slews the time when it needs to adjust the system clock. For example, to correct a system clock which is 1 second slow, @code{chronyd} slightly increases the amount by which the system clock is advanced on each clock interrupt, until the error is removed. (Actually, this is done by calling the @code{adjtime()} or similar system function which does it for us.) Note that at no time does time run backwards with this method. On most Unix systems it is not desirable to step the system clock, because many programs rely on time advancing monotonically forwards. When the @code{chronyd} daemon is initially started, it is possible that the system clock is considerably in error. Attempting to correct such an error by slewing may not be sensible, since it may take several hours to correct the error by this means. The purpose of the @code{initstepslew} directive is to allow @code{chronyd} to make a rapid measurement of the system clock error at boot time, and to correct the system clock by stepping before normal operation begins. Since this would normally be performed only at an appropriate point in the system boot sequence, no other software should be adversely affected by the step. If the correction required is less than a specified threshold, a slew is used instead. This makes it easier to restart @code{chronyd} whilst the system is in normal operation. The @code{initstepslew} directive takes a threshold and a list of NTP servers as arguments. Each of the servers is rapidly polled several times, and a majority voting mechanism used to find the most likely range of system clock error that is present. A step (or slew) is applied to the system clock to correct this error. @code{chronyd} then enters its normal operating mode. An example of use of the command is @example initstepslew 30 foo.example.net bar.example.net @end example where 2 NTP servers are used to make the measurement. The @code{30} indicates that if the system's error is found to be 30 seconds or less, a slew will be used to correct it; if the error is above 30 seconds, a step will be used. The @code{initstepslew} directive can also be used in an isolated LAN environment, where the clocks are set manually. The most stable computer is chosen as the master, and the other computers are slaved to it. If each of the slaves is configured with the local option (see below), the master can be set up with an @code{initstepslew} directive which references some or all of the slaves. Then, if the master machine has to be rebooted, the slaves can be relied on to 'flywheel' the time for the master. The @code{initstepslew} directive is functionally similar to a combination of the @code{makestep} and @code{server} directives with the @code{iburst} option. The main difference is that the @code{initstepslew} servers are used only before normal operation begins and that the foreground @code{chronyd} process waits for @code{initstepslew} to finish before exiting. This is useful to prevent programs started in the boot sequence after @code{chronyd} from reading the clock before it's stepped. @c }}} @c {{{ keyfile @node keyfile directive @subsection keyfile This command is used to specify the location of the file containing ID/key pairs for authentication of NTP packets. The format of the command is shown in the example below @example keyfile @SYSCONFDIR@/chrony.keys @end example The argument is simply the name of the file containing the ID/key pairs. The format of the file is shown below @example 10 tulip 11 hyacinth 20 MD5 ASCII:crocus 25 SHA1 HEX:1dc764e0791b11fa67efc7ecbc4b0d73f68a070c ... @end example Each line consists of an ID, a name of authentication hash function (optional) and a password. The ID can be any unsigned integer in the range 1 through 2**32-1. The hash function is MD5 by default, depending on how was @code{chronyd} compiled, other allowed hash functions may be SHA1, SHA256, SHA384, SHA512, RMD128, RMD160, RMD256, RMD320, TIGER and WHIRLPOOL. The password can be encoded as a string of characters not containing a space with optional @code{ASCII:} prefix or as a hexadecimal number with @code{HEX:} prefix. The password is used with the hash function to generate and verify a message authentication code (MAC) in NTP packets. For maximum security, it's recommended to use SHA1 or stronger hash function. The passwords should be random and they should be as long as the output size of the configured hash function, e.g. 160 bits with SHA1. These shell commands can be used to generate random MD5 and SHA1 keys on systems which have the @code{/dev/urandom} device: @example echo "1 MD5 HEX:$(tr -d -c '[:xdigit:]' < /dev/urandom | head -c 32)" echo "1 SHA1 HEX:$(tr -d -c '[:xdigit:]' < /dev/urandom | head -c 40)" @end example @c }}} @c {{{ leapsecmode @node leapsecmode directive @subsection leapsecmode A leap second is an adjustment that is occasionally applied to UTC to keep it close to the mean solar time. When a leap second is inserted, the last day of June or December has an extra second 23:59:60. For computer clocks that is a problem. The Unix time is defined as number of seconds since 00:00:00 UTC on 1 January 1970 without leap seconds. The system clock cannot have time 23:59:60, every minute has 60 seconds and every day has 86400 seconds by definition. The inserted leap second is skipped and the clock is suddenly ahead of UTC by one second. The @code{leapsecmode} directive selects how that error is corrected. There are four options: @table @code @item system When inserting a leap second, the kernel steps the system clock backwards by one second when the clock gets to 00:00:00 UTC. When deleting a leap second, it steps forward by one second when the clock gets to 23:59:59 UTC. This is the default mode when the system driver supports leap seconds (i.e. on Linux, FreeBSD, NetBSD and Solaris). @item step This is similar to the @code{system} mode, except the clock is stepped by @code{chronyd} instead of the kernel. It can be useful to avoid bugs in the kernel code that would be executed in the @code{system} mode. This is the default mode when the system driver doesn't support leap seconds. @item slew The clock is corrected by slewing started at 00:00:00 UTC when a leap second is inserted or 23:59:59 UTC when a leap second is deleted. This may be preferred over the @code{system} and @code{step} modes when applications running on the system are sensitive to jumps in the system time and it's acceptable that the clock will be off for a longer time. On Linux with the default @code{maxslewrate} value (@pxref{maxslewrate directive}) the correction takes 12 seconds. @item ignore No correction is applied to the clock for the leap second. The clock will be corrected later in normal operation when new measurements are made and the estimated offset includes the one second error. @end table An example of the command is @example leapsecmode slew @end example When serving time to NTP clients that can't be configured to correct their clocks for a leap second by slewing or they would correct them at slightly different rates when it's necessary to keep them close together, the @code{slew} mode can be combined with the @code{smoothtime} directive (@pxref{smoothtime directive}) to enable a server leap smear. When smearing a leap second, the leap status is suppressed on the server and the served time is corrected slowly be slewing instead of stepping. The clients don't need any special configuration as they don't know there is any leap second and they follow the server time which eventually brings them back to UTC. Care must be taken to ensure they use for synchronization only NTP servers which smear the leap second in exactly the same way. This feature needs to be used carefully, because the server is intentionally not serving its best estimate of the true time. A recommended configuration to enable a server leap smear is: @example leapsecmode slew maxslewrate 1000 smoothtime 400 0.001 leaponly @end example The first directive is necessary to disable the clock step which would reset the smoothing process. The second directive limits the slewing rate of the local clock to 1000 ppm, which improves the stability of the smoothing process when the local correction starts and ends. The third directive enables the server time smoothing process. It will start when the clock gets to 00:00:00 UTC and it will take 17 hours 34 minutes to finish. The frequency offset will be changing by 0.001 ppm per second and will reach maximum of 31.623 ppm. The @code{leaponly} option makes the duration of the leap smear constant and allows the clients to safely synchronise with multiple identically configured leap smearing servers. @c }}} @c {{{ leapsectz @node leapsectz directive @subsection leapsectz This directive is used to set the name of the timezone in the system tz database which @code{chronyd} can use to find out when will the next leap second occur. It will periodically check if the times 23:59:59 and 23:59:60 are valid on Jun 30 and Dec 31 in the timezone. A useful timezone is @code{right/UTC}. This is mainly useful with reference clocks which don't provide the leap second information. It is not necessary to restart @code{chronyd} if the tz database is updated with a new leap second at least 12 hours before the event. An example of the command is @example leapsectz right/UTC @end example The following shell command verifies that the timezone contains leap seconds and can be used with this directive @example $ TZ=right/UTC date -d 'Dec 31 2008 23:59:60' Wed Dec 31 23:59:60 UTC 2008 @end example @c }}} @c {{{ local @node local directive @subsection local The local keyword is used to allow @code{chronyd} to appear synchronised to real time (from the viewpoint of clients polling it), even if it has no current synchronisation source. This option is normally used on computers in an isolated network, where several computers are required to synchronise to one other, this being the "master" which is kept vaguely in line with real time by manual input. An example of the command is @example local stratum 10 @end example The value 10 may be substituted with other values in the range 1 through 15. Stratum 1 indicates a computer that has a true real-time reference directly connected to it (e.g. GPS, atomic clock etc) – such computers are expected to be very close to real time. Stratum 2 computers are those which have a stratum 1 server; stratum 3 computers have a stratum 2 server and so on. A large value of 10 indicates that the clock is so many hops away from a reference clock that its time is fairly unreliable. Put another way, if the computer ever has access to another computer which is ultimately synchronised to a reference clock, it will almost certainly be at a stratum less than 10. Therefore, the choice of a high value like 10 for the local command prevents the machine's own time from ever being confused with real time, were it ever to leak out to clients that have visibility of real servers. @c }}} @c {{{ lock_all @node lock_all directive @subsection lock_all The @code{lock_all} directive will lock chronyd into RAM so that it will never be paged out. This mode is only supported on Linux. This directive uses the Linux mlockall() system call to prevent @code{chronyd} from ever being swapped out. This should result in lower and more consistent latency. It should not have significant impact on performance as @code{chronyd's} memory usage is modest. The mlockall man page has more details. @c }}} @c {{{ log @node log directive @subsection log @c {{{ section top The log command indicates that certain information is to be logged. @table @code @item measurements This option logs the raw NTP measurements and related information to a file called measurements.log. @item statistics This option logs information about the regression processing to a file called statistics.log. @item tracking This option logs changes to the estimate of the system's gain or loss rate, and any slews made, to a file called tracking.log. @item rtc This option logs information about the system's real-time clock. @item refclocks This option logs the raw and filtered reference clock measurements to a file called refclocks.log. @item tempcomp This option logs the temperature measurements and system rate compensations to a file called tempcomp.log. @end table The files are written to the directory specified by the logdir command. An example of the command is @example log measurements statistics tracking @end example @menu * measurements log:: The format of the measurements log * statistics log:: The format of the statistics log * tracking log:: The format of the tracking log * RTC log:: The format of the RTC log * refclocks log:: The format of the refclocks log * tempcomp log:: The format of the tempcomp log @end menu @c }}} @c {{{ measurements.log @node measurements log @subsubsection Measurements log file format An example line (which actually appears as a single line in the file) from the measurements log file is shown below. @example 2014-10-13 05:40:50 158.152.1.76 N 2 111 111 1111 10 10 1.0 \ -4.966e-03 2.296e-01 1.577e-05 1.615e-01 7.446e-03 @end example The columns are as follows (the quantities in square brackets are the values from the example line above) : @enumerate 1 @item Date [2014-10-13] @item Hour:Minute:Second [05:40:50]. Note that the date/time pair is expressed in UTC, not the local time zone. @item IP address of server/peer from which measurement comes [158.152.1.76] @item Leap status (@code{N} means normal, @code{+} means that the last minute of the current month has 61 seconds, @code{-} means that the last minute of the month has 59 seconds, @code{?} means the remote computer is not currently synchronised.) [N] @item Stratum of remote computer. [2] @item RFC 5905 tests 1 through 3 (1=pass, 0=fail) [111] @item RFC 5905 tests 5 through 7 (1=pass, 0=fail) [111] @item Tests for maximum delay, maximum delay ratio and maximum delay dev ratio, against defined parameters, and a test for synchronisation loop (1=pass, 0=fail) [1111] @item Local poll [10] @item Remote poll [10] @item `Score' (an internal score within each polling level used to decide when to increase or decrease the polling level. This is adjusted based on number of measurements currently being used for the regression algorithm). [1.0] @item The estimated local clock error (`theta' in RFC 5905). Positive indicates that the local clock is slow of the remote source. [-4.966e-03]. @item The peer delay (`delta' in RFC 5905). [2.296e-01] @item The peer dispersion (`epsilon' in RFC 5905). [1.577e-05] @item The root delay (`DELTA' in RFC 5905). [1.615e-01] @item The root dispersion (`EPSILON' in RFC 5905). [7.446e-03] @end enumerate A banner is periodically written to the log file to indicate the meanings of the columns. @c }}} @c {{{ statistics.log @node statistics log @subsubsection Statistics log file format An example line (which actually appears as a single line in the file) from the statistics log file is shown below. @example 1998-07-22 05:40:50 158.152.1.76 6.261e-03 -3.247e-03 \ 2.220e-03 1.874e-06 1.080e-06 7.8e-02 16 0 8 @end example The columns are as follows (the quantities in square brackets are the values from the example line above) : @enumerate 1 @item Date [1998-07-22] @item Hour:Minute:Second [05:40:50]. Note that the date/time pair is expressed in UTC, not the local time zone. @item IP address of server/peer from which measurement comes [158.152.1.76] @item The estimated standard deviation of the measurements from the source (in seconds). [6.261e-03] @item The estimated offset of the source (in seconds, positive means the local clock is estimated to be fast, in this case). [-3.247e-03] @item The estimated standard deviation of the offset estimate (in seconds). [2.220e-03] @item The estimated rate at which the local clock is gaining or losing time relative to the source (in seconds per second, positive means the local clock is gaining). This is relative to the compensation currently being applied to the local clock, @emph{not} to the local clock without any compensation. [1.874e-06] @item The estimated error in the rate value (in seconds per second). [1.080e-06]. @item The ration of |old_rate - new_rate| / old_rate_error. Large values indicate the statistics are not modelling the source very well. [7.8e-02] @item The number of measurements currently being used for the regression algorithm. [16] @item The new starting index (the oldest sample has index 0; this is the method used to prune old samples when it no longer looks like the measurements fit a linear model). [0, i.e. no samples discarded this time] @item The number of runs. The number of runs of regression residuals with the same sign is computed. If this is too small it indicates that the measurements are no longer represented well by a linear model and that some older samples need to be discarded. The number of runs for the data that is being retained is tabulated. Values of approximately half the number of samples are expected. [8] @end enumerate A banner is periodically written to the log file to indicate the meanings of the columns. @c }}} @c {{{ tracking.log @node tracking log @subsubsection Tracking log file format An example line (which actually appears as a single line in the file) from the tracking log file is shown below. @example 2012-02-23 05:40:50 158.152.1.76 3 340.529 1.606 1.046e-03 N \ 4 6.849e-03 -4.670e-04 @end example The columns are as follows (the quantities in square brackets are the values from the example line above) : @enumerate 1 @item Date [2012-02-03] @item Hour:Minute:Second [05:40:50]. Note that the date/time pair is expressed in UTC, not the local time zone. @item The IP address of the server/peer to which the local system is synchronised. [158.152.1.76] @item The stratum of the local system. [3] @item The local system frequency (in ppm, positive means the local system runs fast of UTC). [340.529] @item The error bounds on the frequency (in ppm) [1.606] @item The estimated local offset at the epoch (which is rapidly corrected by slewing the local clock. (In seconds, positive indicates the local system is fast of UTC). [1.046e-3] @item Leap status (@code{N} means normal, @code{+} means that the last minute of this month has 61 seconds, @code{-} means that the last minute of the month has 59 seconds, @code{?} means the clock is not currently synchronised.) [N] @item The number of combined sources. [4] @item The estimated standard deviation of the combined offset (in seconds). [6.849e-03] @item The remaining offset correction from the previous update (in seconds, positive means the system clock is slow of UTC). [-4.670e-04] @end enumerate A banner is periodically written to the log file to indicate the meanings of the columns. @c }}} @c {{{ rtc.log @node RTC log @subsubsection Real-time clock log file format An example line (which actually appears as a single line in the file) from the measurements log file is shown below. @example 1998-07-22 05:40:50 -0.037360 1 -0.037434\ -37.948 12 5 120 @end example The columns are as follows (the quantities in square brackets are the values from the example line above) : @enumerate 1 @item Date [1998-07-22] @item Hour:Minute:Second [05:40:50]. Note that the date/time pair is expressed in UTC, not the local time zone. @item The measured offset between the system's real time clock and the system (@code{gettimeofday()}) time. In seconds, positive indicates that the RTC is fast of the system time. [-0.037360]. @item Flag indicating whether the regression has produced valid coefficients. (1 for yes, 0 for no). [1] @item Offset at the current time predicted by the regression process. A large difference between this value and the measured offset tends to indicate that the measurement is an outlier with a serious measurement error. [-0.037434]. @item The rate at which the RTC is losing or gaining time relative to the system clock. In ppm, with positive indicating that the RTC is gaining time. [-37.948] @item The number of measurements used in the regression. [12] @item The number of runs of regression residuals of the same sign. Low values indicate that a straight line is no longer a good model of the measured data and that older measurements should be discarded. [5] @item The measurement interval used prior to the measurement being made (in seconds). [120] @end enumerate A banner is periodically written to the log file to indicate the meanings of the columns. @c }}} @c {{{ refclocks.log @node refclocks log @subsubsection Refclocks log file format An example line (which actually appears as a single line in the file) from the refclocks log file is shown below. @example 2009-11-30 14:33:27.000000 PPS2 7 N 1 4.900000e-07 -6.741777e-07 1.000e-06 @end example The columns are as follows (the quantities in square brackets are the values from the example line above) : @enumerate 1 @item Date [2009-11-30] @item Hour:Minute:Second.Microsecond [14:33:27.000000]. Note that the date/time pair is expressed in UTC, not the local time zone. @item Reference ID of refclock from which measurement comes. [PPS2] @item Sequence number of driver poll within one polling interval for raw samples, or @code{-} for filtered samples. [7] @item Leap status (@code{N} means normal, @code{+} means that the last minute of the current month has 61 seconds, @code{-} means that the last minute of the month has 59 seconds). [N] @item Flag indicating whether the sample comes from PPS source. (1 for yes, 0 for no, or @code{-} for filtered sample). [1] @item Local clock error measured by refclock driver, or @code{-} for filtered sample. [4.900000e-07] @item Local clock error with applied corrections. Positive indicates that the local clock is slow. [-6.741777e-07] @item Assumed dispersion of the sample. [1.000e-06] @end enumerate A banner is periodically written to the log file to indicate the meanings of the columns. @c }}} @c {{{ tempcomp.log @node tempcomp log @subsubsection Tempcomp log file format An example line (which actually appears as a single line in the file) from the tempcomp log file is shown below. @example 2010-04-19 10:39:48 2.8000e+04 3.6600e-01 @end example The columns are as follows (the quantities in square brackets are the values from the example line above) : @enumerate 1 @item Date [2010-04-19] @item Hour:Minute:Second [10:39:48]. Note that the date/time pair is expressed in UTC, not the local time zone. @item Temperature read from tempcomp file. [2.8000e+04] @item Applied compensation in ppm, positive means the system clock is running faster than it would be without the compensation. [3.6600e-01] @end enumerate A banner is periodically written to the log file to indicate the meanings of the columns. @c }}} @c }}} @c {{{ logbanner @node logbanner directive @subsection logbanner A banner is periodically written to the log files enabled by the @code{log} directive to indicate the meanings of the columns. The @code{logbanner} directive specifies after how many entries in the log file should be the banner written. The default is 32, and 0 can be used to disable it entirely. @c }}} @c {{{ logchange @node logchange directive @subsection logchange This directive forces @code{chronyd} to send a message to syslog if it makes a system clock adjustment larger than a threshold value. An example of use is @example logchange 0.5 @end example which would cause a syslog message to be generated a system clock error of over 0.5 seconds starts to be compensated. Clock errors detected either via NTP packets or via timestamps entered via the @code{settime} command of @code{chronyc} are logged. This directive assumes that syslog messages are appearing where somebody can see them. This allows that person to see if a large error has arisen, e.g. because of a fault, or because of faulty timezone handling, for example when summer time (daylight saving) starts or ends. @c }}} @c {{{ logdir @node logdir directive @subsection logdir This directive allows the directory where log files are written to be specified. An example of the use of this directive is @example logdir /var/log/chrony @end example @c }}} @c {{{ mailonchange @node mailonchange directive @subsection mailonchange This directive defines an email address to which mail should be sent if chronyd applies a correction exceeding a particular threshold to the system clock. An example of use of this directive is @example mailonchange root@@localhost 0.5 @end example This would send a mail message to root if a change of more than 0.5 seconds were applied to the system clock. This directive can't be used when a system call filter is enabled by the @code{-F} option as the @code{chronyd} process will not be allowed to fork and execute the sendmail binary. @c }}} @c {{{ makestep @node makestep directive @subsection makestep Normally chronyd will cause the system to gradually correct any time offset, by slowing down or speeding up the clock as required. In certain situations, the system clock may be so far adrift that this slewing process would take a very long time to correct the system clock. This directive forces @code{chronyd} to step system clock if the adjustment is larger than a threshold value, but only if there were no more clock updates since @code{chronyd} was started than a specified limit (a negative value can be used to disable the limit). This is particularly useful when using reference clocks, because the @code{initstepslew} directive (@pxref{initstepslew directive}) works only with NTP sources. An example of the use of this directive is @example makestep 0.1 10 @end example This would step system clock if the adjustment is larger than 0.1 seconds, but only in the first ten clock updates. @c }}} @c {{{ manual @node manual directive @subsection manual The @code{manual} directive enables support at run-time for the @code{settime} command in chronyc (@pxref{settime command}). If no @code{manual} directive is included, any attempt to use the @code{settime} command in chronyc will be met with an error message. Note that the @code{settime} command can be enabled at run-time using the @code{manual} command in chronyc (@pxref{manual command}). (The idea of the two commands is that the @code{manual} command controls the manual clock driver's behaviour, whereas the @code{settime} command allows samples of manually entered time to be provided). @c }}} @c {{{ maxchange @node maxchange directive @subsection maxchange This directive sets the maximum allowed offset corrected on a clock update. The check is performed only after the specified number of updates to allow a large initial adjustment of the system clock. When an offset larger than the specified maximum occurs, it will be ignored for the specified number of times and then @code{chronyd} will give up and exit (a negative value can be used to never exit). In both cases a message is sent to syslog. An example of the use of this directive is @example maxchange 1000 1 2 @end example After the first clock update, @code{chronyd} will check the offset on every clock update, it will ignore two adjustments larger than 1000 seconds and exit on another one. @c }}} @c {{{ maxclockerror @node maxclockerror directive @subsection maxclockerror The @code{maxclockerror} directive sets the maximum assumed frequency error of the local clock. This is a frequency stability of the clock, not an absolute frequency error. By default, the maximum assumed error is set to 1 ppm. The syntax is @example maxclockerror @end example Typical values for might be 10 for a low quality clock to 0.1 for a high quality clock using a temperature compensated crystal oscillator. @c }}} @c {{{ maxdistance @node maxdistance directive @subsection maxdistance The @code{maxdistance} directive sets the maximum allowed root distance of the sources to not be rejected by the source selection algorithm. The distance includes the accumulated dispersion, which may be large when the source is no longer synchronised, and half of the total round-trip delay to the primary source. By default, the maximum root distance is 3 seconds. Setting @code{maxdistance} to a larger value can be useful to allow synchronisation with a server that only has a very infrequent connection to its sources and can accumulate a large dispersion between updates of its clock. The syntax is @example maxdistance @end example @c }}} @c {{{ maxsamples @node maxsamples directive @subsection maxsamples The @code{maxsamples} directive sets the default maximum number of samples @code{chronyd} should keep for each source. This setting can be overriden for individual sources in the @code{server} and @code{refclock} directives (@pxref{server directive}, @pxref{refclock directive}). The default value is 0, which disables the configurable limit. The useful range is 4 to 64. The syntax is @example maxsamples @end example @c }}} @c {{{ maxslewrate @node maxslewrate directive @subsection maxslewrate The @code{maxslewrate} directive sets the maximum rate at which @code{chronyd} is allowed to slew the time. It limits the slew rate controlled by the correction time ratio (@pxref{corrtimeratio directive}) and is effective only on systems where @code{chronyd} is able to control the rate (i.e. Linux, FreeBSD, NetBSD, Solaris). For each system there is a maximum frequency offset of the clock that can be set by the driver. On Linux it's 100000 ppm, on FreeBSD and NetBSD it's 5000 ppm and on Solaris it is 32500 ppm. Also, due to a kernel limitation, setting @code{maxslewrate} on FreeBSD and NetBSD to a value between 500 ppm and 5000 ppm will effectively set it to 500 ppm. By default, the maximum slew rate is set to 83333.333 ppm (one twelfth). The syntax is @example maxslewrate @end example @c }}} @c {{{ maxupdateskew @node maxupdateskew directive @subsection maxupdateskew One of @code{chronyd's} tasks is to work out how fast or slow the computer's clock runs relative to its reference sources. In addition, it computes an estimate of the error bounds around the estimated value. If the range of error is too large, it probably indicates that the measurements have not settled down yet, and that the estimated gain or loss rate is not very reliable. The @code{maxupdateskew} parameter allows the threshold for determining whether an estimate may be so unreliable that it should not be used. By default, the threshold is 1000 ppm. The syntax is @example maxupdateskew @end example Typical values for might be 100 for a dial-up connection to servers over a phone line, and 5 or 10 for a computer on a LAN. It should be noted that this is not the only means of protection against using unreliable estimates. At all times, @code{chronyd} keeps track of both the estimated gain or loss rate, and the error bound on the estimate. When a new estimate is generated following another measurement from one of the sources, a weighted combination algorithm is used to update the master estimate. So if @code{chronyd} has an existing highly-reliable master estimate and a new estimate is generated which has large error bounds, the existing master estimate will dominate in the new master estimate. @c }}} @c {{{ minsamples @node minsamples directive @subsection minsamples The @code{minsamples} directive sets the default minimum number of samples @code{chronyd} should keep for each source. This setting can be overriden for individual sources in the @code{server} and @code{refclock} directives (@pxref{server directive}, @pxref{refclock directive}). The default value is 0. The useful range is 4 to 64. The syntax is @example minsamples @end example @c }}} @c {{{ minsources @node minsources directive @subsection minsources The @code{minsources} directive sets the minimum number of sources that need to be considered as selectable in the source selection algorithm before the local clock is updated. The default value is 1. Setting this option to a larger number can be used to improve the reliability. More sources will have to agree with each other and the clock will not be updated when only one source (which could be serving wrong time) is reachable. The syntax is @example minsources @end example @c }}} @c {{{ noclientlog @node noclientlog directive @subsection noclientlog This directive, which takes no arguments, specifies that client accesses are not to be logged. Normally they are logged, allowing statistics to be reported using the @code{clients} command in @code{chronyc}. @c }}} @c {{{ peer @node peer directive @subsection peer The syntax of this directive is identical to that for the @code{server} directive (@pxref{server directive}), except that it is used to specify an NTP peer rather than an NTP server. Please note that NTP peers that are not configured with a key to enable authentication are vulnerable to a denial-of-service attack. An attacker knowing that NTP hosts A and B are peering with each other can send a packet with random timestamps to host A with source address of B which will set the NTP state variables on A to the values sent by the attacker. Host A will then send on its next poll to B a packet with originate timestamp that doesn't match the transmit timestamp of B and the packet will be dropped. If the attacker does this periodically for both hosts, they won't be able to synchronize to each other. This attack can be prevented by enabling authentication with the key option, or using the @code{server} directive on both sides to specify the other host as a server instead of peer, the only drawback is that it will double the network traffic between the two hosts. @c }}} @c {{{ pidfile @node pidfile directive @subsection pidfile chronyd always writes its process ID (pid) to a file, and checks this file on startup to see if another chronyd may already be running on the system. By default, the file used is @code{/var/run/chronyd.pid}. The @code{pidfile} directive allows the name to be changed, e.g. @example pidfile /var/tmp/chronyd.pid @end example @c }}} @c {{{ pool @node pool directive @subsection pool The syntax of this directive is similar to that for the @code{server} directive (@pxref{server directive}), except that it is used to specify a pool of NTP servers rather than a single NTP server. The pool name is expected to resolve to multiple addresses which may change over time. All options valid in the @code{server} directive can be used in this directive too. There is one option specific to @code{pool} directive: @code{maxsources} sets the maximum number of sources that can be used from the pool, the default value is 4. On start, when the pool name is resolved, @code{chronyd} will add up to 16 sources, one for each resolved address. When the number of sources from which at least one valid reply was received reaches @code{maxsources}, the other sources will be removed. When a pool source is unreachable or marked as falseticker, @code{chronyd} will try to replace the source with a newly resolved address of the pool. An example of the pool directive is @example pool pool.ntp.org iburst maxsources 3 @end example @c }}} @c {{{ port @node port directive @subsection port This option allows you to configure the port on which @code{chronyd} will listen for NTP requests. The port will be open only when an address is allowed by the @code{allow} directive or command, an NTP peer is configured, or the broadcast server mode is enabled. The compiled in default is udp/123, the standard NTP port. If set to 0, @code{chronyd} will never open the server port and will operate strictly in a client-only mode. The source port used in NTP client requests can be set by the @code{acquisitionport} directive. An example of the port command is @example port 11123 @end example This would change the NTP port served by @code{chronyd} on the computer to udp/11123. @c }}} @c {{{ refclock @node refclock directive @subsection refclock Reference clocks allows very accurate synchronisation and @code{chronyd} can function as a stratum 1 server. They are specified by the @code{refclock} directive. It has two mandatory parameters, a refclock driver name and a driver specific parameter. There are currently four drivers included: @table @code @item PPS PPSAPI (pulse per second) driver. The parameter is the path to a PPS device. Assert events are used by default. Driver option @code{:clear} can be appended to the path if clear events should be used instead. As PPS refclock gets only sub-second time information, it needs another source (NTP or non-PPS refclock) or local directive (@pxref{local directive}) enabled to work. For example: @example refclock PPS /dev/pps0 lock NMEA refclock SHM 0 offset 0.5 delay 0.2 refid NMEA noselect @end example @item SHM NTP shared memory driver. This driver uses a shared memory segment to receive data from another daemon which communicates with an actual reference clock. The parameter is the number of a shared memory segment, usually 0, 1, 2 or 3. For example: @example refclock SHM 1 poll 3 refid GPS1 @end example A driver option in form @code{:perm=NNN} can be appended to the segment number to create the segment with permissions other than the default @code{0600}. Some examples of applications that can be used as SHM sources are @uref{http://catb.org/gpsd/, @code{gpsd}}, @code{shmpps} and @uref{http://www.buzzard.me.uk/jonathan/radioclock.html, @code{radioclk}}. @item SOCK Unix domain socket driver. It is similar to the SHM driver, but uses a different format and uses a socket instead of shared memory. It does not require polling and it supports transmitting of PPS data. The parameter is a path to the socket which will be created by @code{chronyd} and used to receive the messages. The format of messages sent over the socket is described in the @code{refclock_sock.c} file. Recent versions of the @code{gpsd} daemon include support for the SOCK protocol. The path where the socket should be created is described in the @code{gpsd(8)} man page. For example: @example refclock SOCK /var/run/chrony.ttyS0.sock @end example @item PHC PTP hardware clock (PHC) driver. The parameter is the path to the device of the PTP clock, which can be synchronised by a PTP daemon (e.g. @code{ptp4l} from the @uref{http://linuxptp.sourceforge.net/, Linux PTP project}. The PTP clocks are typically kept in TAI instead of UTC. The @code{offset} option can be used to compensate for the current UTC/TAI offset. For example: @example refclock PHC /dev/ptp0 poll 3 dpoll -2 offset -35 @end example @end table The @code{refclock} command also supports a number of subfields (which may be defined in any order): @table @code @item poll Timestamps produced by refclock drivers are not used immediately, but they are stored and processed by a median filter in the polling interval specified by this option. This is defined as a power of 2 and may be negative to specify a sub-second interval. The default is 4 (16 seconds). A shorter interval allows @code{chronyd} to react faster to changes in clock frequency, but it may decrease the accuracy if the source is too noisy. @item dpoll Some drivers don't listen for external events and try to produce samples in their own polling interval. This is defined as a power of 2 and may be negative to specify a sub-second interval. The default is 0 (1 second). @item refid This option is used to specify a reference id of the refclock, as up to four ASCII characters. By default, first three characters from driver name and the number of the refclock are used as refid. Each refclock must have an unique refid. @item filter This option sets the length of the median filter which is used to reduce noise. With each poll about 40 percent of the stored samples is discarded and one final sample is calculated as average of the remaining samples. If the length is 4 or above, at least 4 samples have to be collected between polls. For lengths below 4, the filter has to be full. The default is 64. @item rate PPS signal frequency (in Hz). This option only controls how the received pulses are aligned. To actually receive more than one pulse per second, a negative @code{dpoll} has to be specified (-3 for 5Hz signal). The default is 1. @item lock This option can be used to lock a PPS refclock to another refclock whose reference id is specified by this option. In this mode received pulses are aligned directly to unfiltered samples from the refclock. By default, pulses are aligned to local clock, but only when it is well synchronised. @item offset This option can be used to compensate a constant error. The specified offset (in seconds) is applied to all samples produced by the refclock. The default is 0.0. @item delay This option sets the NTP delay of the source (in seconds). Half of this value is included in the maximum assumed error which is used in the source selection algorithm. Increasing the delay is useful to avoid having no majority in the algorithm or to make it prefer other sources. The default is 1e-9 (1 nanosecond). @item precision Refclock precision (in seconds). The default is 1e-6 (1 microsecond) for SHM refclock, and 1e-9 (1 nanosecond) for SOCK, PPS and PHC refclocks. @item maxdispersion Maximum allowed dispersion for filtered samples (in seconds). Samples with larger estimated dispersion are ignored. By default, this limit is disabled. @item prefer Prefer this source over sources without prefer option. @item noselect Never select this source. This is useful for monitoring or with sources which are not very accurate, but are locked with a PPS refclock. @item minsamples Set the minimum number of samples kept for this source. This overrides the @code{minsamples} directive (@pxref{minsamples directive}). @item maxsamples Set the maximum number of samples kept for this source. This overrides the @code{maxsamples} directive (@pxref{maxsamples directive}). @end table @c }}} @c {{{ reselectdist @node reselectdist directive @subsection reselectdist When @code{chronyd} selects synchronisation source from available sources, it will prefer the one with minimum synchronisation distance. However, to avoid frequent reselecting when there are sources with similar distance, a fixed distance is added to the distance for sources that are currently not selected. This can be set with the @code{reselectdist} option. By default, the distance is 100 microseconds. The syntax is @example reselectdist @end example @c }}} @c {{{ rtcautotrim @node rtcautotrim directive @subsection rtcautotrim The @code{rtcautotrim} directive is used to keep the real time clock (RTC) close to the system clock automatically. When the system clock is synchronized and the estimated error between the two clocks is larger than the specified threshold, @code{chronyd} will trim the RTC as if the @code{trimrtc} (@pxref{trimrtc command}) command was issued. This directive is effective only with the @code{rtcfile} directive. An example of the use of this directive is @example rtcautotrim 30 @end example This would set the threshold error to 30 seconds. @c }}} @c {{{ rtcdevice @node rtcdevice directive @subsection rtcdevice The @code{rtcdevice} directive defines the name of the device file for accessing the real time clock. By default this is @code{/dev/rtc}, unless the directive is used to set a different value. This applies to Linux systems with devfs. An example of use is @example rtcdevice /dev/misc/rtc @end example @c }}} @c {{{ rtcfile @node rtcfile directive @subsection rtcfile The @code{rtcfile} directive defines the name of the file in which @code{chronyd} can save parameters associated with tracking the accuracy of the system's real-time clock (RTC). The syntax is illustrated in the following example @example rtcfile @CHRONYVARDIR@/rtc @end example @code{chronyd} saves information in this file when it exits and when the @code{writertc} command is issued in @code{chronyc}. The information saved is the RTC's error at some epoch, that epoch (in seconds since January 1 1970), and the rate at which the RTC gains or loses time. So far, the support for real-time clocks is limited - their code is even more system-specific than the rest of the software. You can only use the real time clock facilities (the @code{rtcfile} directive and the @code{-s} command line option to @code{chronyd}) if the following three conditions apply: @enumerate 1 @item You are running Linux version 2.2.x or later. @item You have compiled the kernel with extended real-time clock support (i.e. the @file{/dev/rtc} device is capable of doing useful things). @item You don't have other applications that need to make use of @file{/dev/rtc} at all. @end enumerate @c }}} @c {{{ rtconutc @node rtconutc directive @subsection rtconutc @code{chronyd} assumes by default that the real time clock (RTC) keeps local time (including any daylight saving changes). This is convenient on PCs running Linux which are dual-booted with DOS or Windows. NOTE : IF YOU KEEP THE REAL TIME CLOCK ON LOCAL TIME AND YOUR COMPUTER IS OFF WHEN DAYLIGHT SAVING (SUMMER TIME) STARTS OR ENDS, THE COMPUTER'S SYSTEM TIME WILL BE ONE HOUR IN ERROR WHEN YOU NEXT BOOT AND START CHRONYD. An alternative is for the RTC to keep Universal Coordinated Time (UTC). This does not suffer from the 1 hour problem when daylight saving starts or ends. If the @code{rtconutc} directive appears, it means the RTC is required to keep UTC. The directive takes no arguments. It is equivalent to specifying the @code{-u} switch to the Linux @file{/sbin/hwclock} program. Note that this setting is overriden when the @code{hwclockfile} directive (@pxref{hwclockfile directive}) is used. @c }}} @c {{{ rtcsync @node rtcsync directive @subsection rtcsync The @code{rtcsync} directive will enable a kernel mode where the system time is copied to the real time clock (RTC) every 11 minutes. This directive is supported only on Linux and cannot be used when the normal RTC tracking is enabled, i.e. when the @code{rtcfile} directive is used. On other systems this directive does nothing. @c }}} @c {{{ sched_priority @node sched_priority directive @subsection sched_priority On Linux, the @code{sched_priority} directive will select the SCHED_FIFO real-time scheduler at the specified priority (which must be between 0 and 100). On Mac OS X, this option must have either a value of 0 (the default) to disable the thread time constraint policy or 1 for the policy to be enabled. Other systems do not support this option. On Linux, this directive uses the sched_setscheduler() system call to instruct the kernel to use the SCHED_FIFO first-in, first-out real-time scheduling policy for @code{chronyd} with the specified priority. This means that whenever @code{chronyd} is ready to run it will run, interrupting whatever else is running unless it is a higher priority real-time process. This should not impact performance as @code{chronyd's} resource requirements are modest, but it should result in lower and more consistent latency since @code{chronyd} will not need to wait for the scheduler to get around to running it. You should not use this unless you really need it. The sched_setscheduler man page has more details. On Mac OS X, this directive uses the thread_policy_set() kernel call to specify real-time scheduling. As noted for Linux, you should not use this directive unless you really need it. @c }}} @c {{{ server @node server directive @subsection server The @code{server} directive allows NTP servers to be specified. The client/server relationship is strictly hierarchical : a client may synchronise its system time to that of the server, but the server's system time will never be influenced by that of a client. The @code{server} directive is immediately followed by either the name of the server, or its IP address. The server command also supports a number of subfields (which may be defined in any order): @table @code @item port This option allows the UDP port on which the server understands NTP requests to be specified. For normal servers this option should not be required (the default is 123, the standard NTP port). @item minpoll Although @code{chronyd} will trim the rate at which it samples the server during normal operation, the user may wish to constrain the minimum polling interval. This is always defined as a power of 2, so @code{minpoll 5} would mean that the polling interval cannot drop below 32 seconds. The default is 6 (64 seconds). @item maxpoll In a similar way, the user may wish to constrain the maximum polling interval. Again this is specified as a power of 2, @code{maxpoll 9} indicates that the polling interval must stay at or below 512 seconds. The default is 10 (1024 seconds). @item maxdelay @code{chronyd} uses the network round-trip delay to the server to determine how accurate a particular measurement is likely to be. Long round-trip delays indicate that the request, or the response, or both were delayed. If only one of the messages was delayed the measurement error is likely to be substantial. For small variations in round trip delay, @code{chronyd} uses a weighting scheme when processing the measurements. However, beyond a certain level of delay the measurements are likely to be so corrupted as to be useless. (This is particularly so on dial-up or other slow links, where a long delay probably indicates a highly asymmetric delay caused by the response waiting behind a lot of packets related to a download of some sort). If the user knows that round trip delays above a certain level should cause the measurement to be ignored, this level can be defined with the maxdelay command. For example, @code{maxdelay 0.3} would indicate that measurements with a round-trip delay of 0.3 seconds or more should be ignored. The default value is 3 seconds. @item maxdelayratio This option is similar to the maxdelay option above. @code{chronyd} keeps a record of the minimum round-trip delay amongst the previous measurements that it has buffered. If a measurement has a round trip delay that is greater than the maxdelayratio times the minimum delay, it will be rejected. @item maxdelaydevratio If a measurement has ratio of the increase in round-trip delay from the minimum delay amongst the previous measurements to the standard deviation of the previous measurements that is greater than maxdelaydevratio, it will be rejected. The default is 10.0. @item presend If the timing measurements being made by @code{chronyd} are the only network data passing between two computers, you may find that some measurements are badly skewed due to either the client or the server having to do an ARP lookup on the other party prior to transmitting a packet. This is more of a problem with long sampling intervals, which may be similar in duration to the lifetime of entries in the ARP caches of the machines. In order to avoid this problem, the @code{presend} option may be used. It takes a single integer argument, which is the smallest polling interval for which an extra pair of NTP packets will be exchanged between the client and the server prior to the actual measurement. For example, with the following option included in a @code{server} directive : @example presend 9 @end example when the polling interval is 512 seconds or more, an extra NTP client packet will be sent to the server a short time (currently 4 seconds) before making the actual measurement. @item key The NTP protocol supports the inclusion of checksums in the packets, to prevent computers having their system time upset by rogue packets being sent to them. The checksums are generated as a function of a password, using the cryptographic hash function set in the key file. The association between key numbers and passwords is contained in the keys file, defined by the keyfile command. If the key option is present, @code{chronyd} will attempt to use authenticated packets when communicating with this server. The key number used will be the single argument to the key option (an unsigned integer in the range 1 through 2**32-1). The server must have the same password for this key number configured, otherwise no relationship between the computers will be possible. @item offline If the server will not be reachable when @code{chronyd} is started, the offline option may be specified. @code{chronyd} will not try to poll the server until it is enabled to do so (by using the online option of @code{chronyc}). @item auto_offline If this option is set, the server will be assumed to have gone offline when 2 requests have been sent to it without receiving a response. This option avoids the need to run the @code{offline} (@pxref{offline command}) command from chrony when disconnecting the dial-up link. (It will still be necessary to use chronyc's @code{online} (@pxref{online command}) command when the link has been established, to enable measurements to start.) @item iburst On start, make four measurements over a short duration (rather than the usual periodic measurements). @item minstratum When the synchronisation source is selected from available sources, sources with lower stratum are normally preferred. This option can be used to increase stratum of the source to the specified minimum, so @code{chronyd} will avoid selecting that source. This is useful with low stratum sources that are known to be unrealiable or inaccurate and which should be used only when other sources are unreachable. @item polltarget Target number of measurements to use for the regression algorithm which @code{chronyd} will try to maintain by adjusting polling interval between @code{minpoll} and @code{maxpoll}. A higher target makes @code{chronyd} prefer shorter polling intervals. The default is 6 and a useful range is 6 to 60. @item version This option sets the NTP version number used in packets sent to the server. This can be useful when the server runs an old NTP implementation that doesn't respond to newer versions. The default version number is 4. @item prefer Prefer this source over sources without prefer option. @item noselect Never select this source. This is particularly useful for monitoring. @item minsamples Set the minimum number of samples kept for this source. This overrides the @code{minsamples} directive (@pxref{minsamples directive}). @item maxsamples Set the maximum number of samples kept for this source. This overrides the @code{maxsamples} directive (@pxref{maxsamples directive}). @end table @c }}} @c {{{ smoothtime @node smoothtime directive @subsection smoothtime The @code{smoothtime} directive can be used to enable smoothing of the time that @code{chronyd} serves to its clients to make it easier for them to track it and keep their clocks close together even when large offset or frequency corrections are applied to the server's clock, for example after being offline for a longer time. BE WARNED - the server is intentionally not serving its best estimate of the true time. If a large offset has been accumulated, it may take a very long time to smooth it out. This directive should be used only when the clients are not configured to poll also another NTP server, because they could reject this server as a falseticker or fail to select a source completely. The smoothing process is implemented with a quadratic spline function with two or three pieces. It's independent from any slewing applied to the local system clock, but the accumulated offset and frequency will be reset when the clock is corrected by stepping, e.g. by the @code{makestep} directive or command. The process can be reset without stepping the clock by the @code{smoothtime reset} command (@pxref{smoothtime command}). The first two arguments of the directive are the maximum frequency offset of the smoothed time to the tracked NTP time (in ppm) and the maximum rate at which the frequency offset is allowed to change (in ppm per second). @code{leaponly} is an optional third argument which enables a mode where only leap seconds are smoothed out and normal offset/frequency changes are ignored. The @code{leaponly} option is useful in a combination with the @code{leapsecmode slew} option (@pxref{leapsecmode directive}) to allow clients use multiple time smoothing servers safely. The smoothing process is activated automatically when 1/10000 of the estimated skew of the local clock falls below the maximum rate of frequency change. It can be also activated manually by the @code{smoothtime activate} command, which is particularly useful when the clock is synchronized only with manual input and the skew is always larger than the threshold. The @code{smoothing} command (@pxref{smoothing command}) can be used to monitor the process. An example suitable for clients using @code{ntpd} and 1024 second polling interval could be @example smoothtime 400 0.001 @end example An example suitable for clients using @code{chronyd} on Linux could be @example smoothtime 50000 0.01 @end example @c }}} @c {{{ stratumweight @node stratumweight directive @subsection stratumweight The @code{stratumweight} directive sets how much distance should be added per stratum to the synchronisation distance when @code{chronyd} selects the synchronisation source from available sources. The syntax is @example stratumweight @end example By default, the weight is 0.001 seconds. This means that stratum of the sources in the selection process matters only when the differences between the distances are in milliseconds. @c }}} @c {{{ tempcomp @node tempcomp directive @subsection tempcomp Normally, changes in the rate of drift of the system clock are caused mainly by changes in the temperature of the crystal oscillator on the mainboard. If there are temperature measurements available from a sensor close to the oscillator, the @code{tempcomp} directive can be used to compensate for the changes in the temperature and improve the stability and accuracy of the clock. The result depends on many factors, including the resolution of the sensor, the amount of noise in the measurements, the polling interval of the time source, the compensation update interval, how well is the compensation specified, and how close is the sensor to the oscillator. When it's working well, the frequency reported in the @file{tracking.log} file is more stable and the maximum reached offset is smaller. There are two forms of the directive. The first one has six parameters: a path to the file containing the current temperature from the sensor (in text format), the compensation update interval (in seconds), and temperature coefficients T0, k0, k1, k2. The frequency compensation is calculated (in ppm) as @code{k0 + (T - T0) * k1 + (T - T0)^2 * k2} The result has to be between -10 ppm and 10 ppm, otherwise the measurement is considered invalid and will be ignored. The k0 coefficient can be used to get the results in that range. An example of use is @example tempcomp /sys/class/hwmon/hwmon0/temp2_input 30 26000 0.0 0.000183 0.0 @end example The measured temperature will be read from the file in the Linux sysfs filesystem every 30 seconds. When the temperature is 26000 (26 degrees Celsius), the frequency correction will be zero. When it is 27000 (27 degrees Celsius), the clock will be set to run 0.183ppm faster, etc. The second form has three parameters, the path to the sensor file, the update interval and a path to a file containing a list of (temperature, compensation) points, from which the compensation is linearly interpolated or extrapolated. An example is @example tempcomp /sys/class/hwmon/hwmon0/temp2_input 30 /etc/chrony.tempcomp @end example where the @file{chrony.tempcomp} file could have @example 20000 1.0 21000 0.64 22000 0.36 23000 0.16 24000 0.04 25000 0.0 26000 0.04 27000 0.16 28000 0.36 29000 0.64 30000 1.0 @end example Valid measurements with corresponding compensations are logged to the @file{tempcomp.log} file if enabled by the @code{log tempcomp} directive. @c }}} @c {{{ user @node user directive @subsection user The @code{user} directive sets the name of the system user to which @code{chronyd} will switch after start in order to drop root privileges. It may be set to a non-root user only when @code{chronyd} is compiled with support for Linux capabilities (libcap) or on NetBSD with the @code{/dev/clockctl} device. The default value is @code{@DEFAULT_USER@}. @c }}} @c }}} @c {{{ S:Running chronyc @node Running chronyc @section Running chronyc @c {{{ Section top Chronyc is the program that can be used to reconfigure options within the @code{chronyd} program whilst it is running. Chronyc can also be used to generate status reports about the operation of @code{chronyd}. @menu * Chronyc basic use:: How to run chronyc * Chronyc command line options:: Chrony's command line options * Security with chronyc:: How chronyd restricts access * Chronyc command reference:: All the commands chronyc supports @end menu @c }}} @c {{{ SS:Chronyc basic use @node Chronyc basic use @subsection Basic use The program chronyc is run by entering @example chronyc @end example at the command line. The prompt @code{chronyc} is displayed whilst chronyc is expecting input from the user, when it is being run from a terminal. If chronyc's input or output are redirected from/to a file, the prompt is not shown. When you are finished entering commands, the commands @code{exit} or @code{quit} will terminate the program. (Entering @key{Control-D} will also terminate the program.) @c }}} @c {{{ SS:Command line options @node Chronyc command line options @subsection Command line options Chronyc supports the following command line options. @table @code @item -v Displays the version number of chronyc on the terminal, and exists. @item -h This option allows the user to specify which host (or comma-separated list of addresses) running the @code{chronyd} program is to be contacted. This allows for remote monitoring, without having to ssh to the other host first. The default is to contact @code{chronyd} running on the same host as that where chronyc is being run. @item -p This option allows the user to specify the UDP port number which the target @code{chronyd} is using for its command & monitoring connections. This defaults to the compiled-in default; there would rarely be a need to change this. @item -n This option disables resolving IP addresses to hostnames. @item -d This option enables printing of debugging messages (if compiled with debugging support). @item -4 With this option hostnames will be resolved only to IPv4 addresses. @item -6 With this option hostnames will be resolved only to IPv6 addresses. @item -m With this option multiple commands can be specified on the command line. Each argument will be interpreted as a whole command. @item -f This option is ignored and is provided only for compatibility. @item -a This option is ignored and is provided only for compatibility. @end table @c }}} @c {{{ SS:Security with chronyc @node Security with chronyc @subsection Security with chronyc Many of the commands available through chronyc have a fair amount of power to reconfigure the run-time behaviour of @code{chronyd}. Consequently, @code{chronyc} is quite dangerous for the integrity of the target system's clock performance. Having access to @code{chronyd} via @code{chronyc} is more or less equivalent to being able to modify @code{chronyd's} configuration file (typically @file{@SYSCONFDIR@/chrony.conf}) and to restart @code{chronyd}. @code{chronyc} also provides a number of monitoring (as opposed to commanding or configuration) commands, which will not affect the behaviour of @code{chronyd}. However, you may still want to restrict access to these commands. There are two ways how @code{chronyc} can access @code{chronyd}. One is the Internet Protocol (IPv4 or IPv6) and the other is a Unix domain socket, which is accessible only locally by the root or chrony user (by default @code{@CHRONYSOCKDIR@/chronyd.sock}). Only the following monitoring commands are allowed from the internet: @itemize @bullet @item @code{activity} @item @code{manual list} @item @code{rtcdata} @item @code{smoothing} @item @code{sources} @item @code{sourcestats} @item @code{tracking} @item @code{waitsync}. @end itemize The set of hosts from which @code{chronyd} will accept these commands can be restricted. By default, the commands will be accepted only from the localhost (127.0.0.1 or ::1). All other commands are allowed only through the Unix domain socket. When sent over the internet, @code{chronyd} will respond with a @code{Not authorised} error, even if it's from the localhost. In @code{chrony} versions before 2.2 the commands had to be authenticated with a password and they were allowed from the internet, but that is no longer supported. By default, @code{chronyc} tries to connect to the Unix domain socket first. If that fails (e.g. because @code{chronyc} is running under a non-root user), it will try to connect to 127.0.0.1 and then ::1. @c }}} @c {{{ SS:Chronyc command reference @node Chronyc command reference @subsection Command reference @c {{{ Top/menu This section describes each of the commands available within the chronyc program. Chronyc offers the user a simple command-line driven interface. @menu * accheck command:: Verifying NTP client access * activity command:: Check how many NTP servers/peers are online/offline * add peer command:: Add a new NTP peer * add server command:: Add a new NTP server * allow all command:: Allowing NTP client access * allow command:: Allowing NTP client access * burst command:: Initiating a rapid set of measurements * clients command:: Show clients that have accessed the server * cmdaccheck command:: Verifying monitoring client access * cmdallow all command:: Allowing monitoring client access * cmdallow command:: Allowing monitoring client access * cmddeny all command:: Denying monitoring client access * cmddeny command:: Denying monitoring client access * cyclelogs command:: Close and re-open open log files * delete command:: Remove an NTP server or peer * deny all command:: Denying NTP client access * deny command :: Denying NTP client access * dns command:: Configure how are hostnames and IP addresses resolved * dump command:: Dump measurement histories to files * exit command:: Exit from chronyc * help command:: Generate help summary * local command:: Let computer be a server when it is unsynchronised * makestep command:: Correct the system clock by stepping instead of slewing * manual command:: Enable/disable/configure options for settime * maxdelay command:: Set max measurement delay for a source * maxdelaydevratio command:: Set max measurement delay for a source as ratio to deviation * maxdelayratio command:: Set max measurement delay for a source as ratio * maxpoll command:: Set maximum polling interval for a source * maxupdateskew command:: Set safety threshold for clock gain/loss rate * minpoll command:: Set minimum polling interval for a source * minstratum command:: Set minimum stratum for a source * offline command:: Warn that connectivity to a source will be lost * online command:: Warn that connectivity to a source has been restored * polltarget command:: Set poll target for a source * quit command:: Exit from chronyc * refresh command:: Refresh IP addresses * reselect command:: Reselect synchronisation source * reselectdist command:: Set improvement in distance needed to reselect a source * retries command:: Set maximum number of retries * rtcdata command:: Display RTC parameters * settime command:: Provide a manual input of the current time * smoothing command:: Display current time smoothing state * smoothtime command:: Reset/activate server time smoothing * sources command:: Display information about the current set of sources * sourcestats command:: Display the rate & offset estimation performance of sources * timeout command:: Set initial response timeout * tracking command:: Display system clock performance * trimrtc command:: Correct the RTC time to the current system time * waitsync command:: Wait until synchronised * writertc command:: Write the RTC parameters to file @end menu @c }}} @c {{{ accheck @node accheck command @subsubsection accheck This command allows you to check whether client NTP access is allowed from a particular host. Examples of use, showing a named host and a numeric IP address, are as follows: @example accheck foo.example.net accheck 1.2.3.4 accheck 2001:db8::1 @end example This command can be used to examine the effect of a series of @code{allow}, @code{allow all}, @code{deny} and @code{deny all} commands specified either via chronyc, or in @code{chronyd's} configuration file. @c }}} @c {{{ activity command @node activity command @subsubsection activity This command reports the number of servers/peers that are online and offline. If the auto_offline option is used in specifying some of the servers/peers, the @code{activity} command may be useful for detecting when all of them have entered the offline state after the PPP link has been disconnected. The report shows the number of servers/peers in 5 states: @itemize @item @code{online} : the server/peer is currently online (i.e. assumed by chronyd to be reachable) @item @code{offline} : the server/peer is currently offline (i.e. assumed by chronyd to be unreachable, and no measurements from it will be attempted.) @item @code{burst_online} : a burst command has been initiated for the server/peer and is being performed; after the burst is complete, the server/peer will be returned to the online state. @item @code{burst_offline} : a burst command has been initiated for the server/peer and is being performed; after the burst is complete, the server/peer will be returned to the offline state. @item @code{unresolved} : the name of the server/peer wasn't resolved to an address yet; this server is not visible in the @code{sources} and @code{sourcestats} reports. @end itemize @c }}} @c {{{ add peer @node add peer command @subsubsection add peer The @code{add peer} command allows a new NTP peer to be added whilst @code{chronyd} is running. Following the words @code{add peer}, the syntax of the following parameters and options is similar to that for the @code{peer} directive in the configuration file (@pxref{peer directive}). The following peer options can be set in the command: @code{port}, @code{minpoll}, @code{maxpoll}, @code{presend}, @code{maxdelayratio}, @code{maxdelay}, @code{key} An example of using this command is shown below. @example add peer foo.example.net minpoll 6 maxpoll 10 key 25 @end example @c }}} @c {{{ add server @node add server command @subsubsection add server The @code{add server} command allows a new NTP server to be added whilst @code{chronyd} is running. Following the words @code{add server}, the syntax of the following parameters and options is similar to that for the @code{server} directive in the configuration file (@pxref{server directive}). The following server options can be set in the command: @code{port}, @code{minpoll}, @code{maxpoll}, @code{presend}, @code{maxdelayratio}, @code{maxdelay}, @code{key} An example of using this command is shown below. @example add server foo.example.net minpoll 6 maxpoll 10 key 25 @end example @c }}} @c {{{ allow all @node allow all command @subsubsection allow all The effect of the allow command is identical to the @code{allow all} directive in the configuration file (@pxref{allow directive}). @c }}} @c {{{ allow @node allow command @subsubsection allow The effect of the allow command is identical to the @code{allow} directive in the configuration file (@pxref{allow directive}). The syntax is illustrated in the following examples: @example allow foo.example.net allow 1.2 allow 3.4.5 allow 6.7.8/22 allow 6.7.8.9/22 allow 2001:db8:789a::/48 allow 0/0 allow ::/0 allow @end example The effect of each of these examples is the same as that of the @code{allow} directive in the configuration file. @c }}} @c {{{ burst @node burst command @subsubsection burst The @code{burst} command tells @code{chronyd} to make a set of measurements to each of its NTP sources over a short duration (rather than the usual periodic measurements that it makes). After such a burst, @code{chronyd} will revert to the previous state for each source. This might be either online, if the source was being periodically measured in the normal way, or offline, if the source had been indicated as being offline. (Switching a source between the online and offline states is described in @ref{online command}, @ref{offline command}). The syntax of the burst command is as follows @example burst / [/] burst / [/] burst / [
] @end example The mask and masked-address arguments are optional, in which case @code{chronyd} will initiate a burst for all of its currently defined sources. The arguments have the following meaning and format. @table @code @item n-good-measurements This defines the number of good measurements that @code{chronyd} will want to obtain from each source. A measurement is good if it passes certain tests, for example, the round trip time to the source must be acceptable. (This allows @code{chronyd} to reject measurements that are likely to be bogus.) @item max-measurements This defines the maximum number of measurements that @code{chronyd} will attempt to make, even if the required number of good measurements has not been obtained. @item mask This is an IP address with which the IP address of each of @code{chronyd}'s sources is to be masked. @item masked-address This is an IP address. If the masked IP address of a source matches this value then the burst command is applied to that source. @item masked-bits This can be used with @code{masked-address} for CIDR notation, which is a shorter alternative to the form with mask. @item address This is an IP address or a hostname. The burst command is applied only to that source. @end table If no mask or masked address arguments are provided, every source will be matched. An example of the two-argument form of the command is @example burst 2/10 @end example This will cause @code{chronyd} to attempt to get two good measurements from each source, stopping after two have been obtained, but in no event will it try more than ten probes to the source. Examples of the four-argument form of the command are @example burst 2/10 255.255.0.0/1.2.0.0 burst 2/10 2001:db8:789a::/48 @end example In the first case, the two out of ten sampling will only be applied to sources whose IPv4 addresses are of the form @code{1.2.x.y}, where x and y are arbitrary. In the second case, the sampling will be applied to sources whose IPv6 addresses have first 48 bits equal to @code{2001:db8:789a}. Example of the three-argument form of the command is @example burst 2/10 foo.example.net @end example @c }}} @c {{{ clients @node clients command @comment node-name, next, previous, up @subsubsection clients This command shows a list of all clients that have accessed the server, through either the NTP or command/monitoring ports. It doesn't include access to the Unix domain comamnd socket. There are no arguments. An example of the output is @example Hostname Client Peer CmdAuth CmdNorm CmdBad LstN LstC ========================= ====== ====== ====== ====== ====== ==== ==== localhost 0 0 0 1 0 29y 0 aardvark.xxx 4 0 0 0 0 49 29y badger.xxx 4 0 0 0 0 6 29y @end example Each row shows the data for a single host. Only hosts that have passed the host access checks (set with the @code{allow}, @code{deny}, @code{cmdallow} and @code{cmddeny} commands or configuration file directives) are logged. The columns are as follows: @enumerate 1 @item The hostname of the client @item The number of times the client has accessed the server using an NTP client mode packet. @item The number of times the client has accessed the server using an NTP symmetric active mode packet. @item The number of authenticated command packets that have been processed from the client. Authentication is no longer supported in command packets, so the number should be always zero. @item The number of unauthenticated command packets that have been processed from the client. @item The number of bad command packets received from the client (not all forms of bad packet are logged). @item Time since the last NTP packet was received @item Time since the last command packet was received @end enumerate The last two entries will be shown as the time since 1970 if no packet of that type has ever been received. @c }}} @c {{{ cmdaccheck @node cmdaccheck command @subsubsection cmdaccheck This command is similar to the @code{accheck} command, except that it is used to check whether monitoring access is permitted from a named host. Examples of use are as follows: @example cmdaccheck foo.example.net cmdaccheck 1.2.3.4 cmdaccheck 2001:db8::1 @end example @c }}} @c {{{ cmdallow all @node cmdallow all command @subsubsection cmdallow all This is similar to the @code{allow all} command, except that it is used to allow particular hosts or subnets to use @code{chronyc} to monitor with @code{chronyd} on the current host. @c }}} @c {{{ cmdallow @node cmdallow command @subsubsection cmdallow This is similar to the @code{allow} command, except that it is used to allow particular hosts or subnets to use @code{chronyc} to monitor with @code{chronyd} on the current host. @c }}} @c {{{ cmddeny all @node cmddeny all command @subsubsection cmddeny all This is similar to the @code{deny all} command, except that it is used to allow particular hosts or subnets to use @code{chronyc} to monitor @code{chronyd} on the current host. @c }}} @c {{{ cmddeny @node cmddeny command @subsubsection cmddeny This is similar to the @code{deny} command, except that it is used to allow particular hosts or subnets to use @code{chronyc} to monitor @code{chronyd} on the current host. @c }}} @c {{{ cyclelogs @node cyclelogs command @subsubsection cyclelogs The @code{cyclelogs} command causes all of @code{chronyd's} open log files to be closed and re-opened. This allows them to be renamed so that they can be periodically purged. An example of how to do this is shown below. @example % mv /var/log/chrony/measurements.log /var/log/chrony/measurements1.log % chronyc cyclelogs % ls -l /var/log/chrony -rw-r--r-- 1 root root 0 Jun 8 18:17 measurements.log -rw-r--r-- 1 root root 12345 Jun 8 18:17 measurements1.log % rm -f measurements1.log @end example @c }}} @c {{{ delete @node delete command @subsubsection delete The @code{delete} command allows an NTP server or peer to be removed from the current set of sources. The syntax is illustrated in the examples below. @example delete foo.example.net delete 1.2.3.4 delete 2001:db8::1 @end example There is one parameter, the name or IP address of the server or peer to be deleted. @c }}} @c {{{ deny all @node deny all command @subsubsection deny all The effect of the allow command is identical to the @code{deny all} directive in the configuration file (@pxref{deny directive}). @c }}} @c {{{ deny @node deny command @subsubsection deny The effect of the allow command is identical to the @code{deny} directive in the configuration file (@pxref{deny directive}). The syntax is illustrated in the following examples: @example deny foo.example.net deny 1.2 deny 3.4.5 deny 6.7.8/22 deny 6.7.8.9/22 deny 2001:db8:789a::/48 deny 0/0 deny ::/0 deny @end example @c }}} @c {{{ dns @node dns command @subsubsection dns The @code{dns} command configures how are hostnames and IP addresses resolved in @code{chronyc}. IP addresses can be resolved to hostnames when printing results of @code{sources}, @code{sourcestats}, @code{tracking} and @code{clients} commands. Hostnames are resolved in commands that take an address as argument. There are five forms of the command: @table @code @item dns -n Disables resolving IP addresses to hostnames. Raw IP addresses will be displayed. @item dns +n Enables resolving IP addresses to hostnames. This is the default unless @code{chronyc} was started with @code{-n} option. @item dns -4 Resolves hostnames only to IPv4 addresses. @item dns -6 Resolves hostnames only to IPv6 addresses. @item dns -46 Resolves hostnames to both address families. This is the default unless @code{chronyc} was started with @code{-4} or @code{-6} option. @end table @c }}} @c {{{ dump @node dump command @subsubsection dump The @code{dump} command causes @code{chronyd} to write its current history of measurements for each of its sources to dump files, either for inspection or to support the @code{-r} option when @code{chronyd} is restarted. The @code{dump} command is somewhat equivalent to the @code{dumponexit} directive in the chrony configuration file. @xref{dumponexit directive}. To use the @code{dump}, you probably want to configure the name of the directory into which the dump files will be written. This can only be done in the configuration file, see @ref{dumpdir directive}. @c }}} @c {{{ exit @node exit command @subsubsection exit The exit command exits from chronyc and returns the user to the shell (same as the quit command). @c }}} @c {{{ help @node help command @subsubsection help The help command displays a summary of the commands and their arguments. @c }}} @c {{{ local @node local command @subsubsection local The @code{local} command allows @code{chronyd} to be told that it is to appear as a reference source, even if it is not itself properly synchronised to an external source. (This can be used on isolated networks, to allow one computer to be a master time server with the other computers slaving to it.) The @code{local} command is somewhat equivalent to the @code{local} directive in the configuration file, see @ref{local directive}. The syntax is as shown in the following examples. @example local stratum 10 local off @end example The first example enables the local reference mode on the host, and sets the stratum at which it should claim to be synchronised. The second example disables the local reference mode. @c }}} @c {{{ makestep @node makestep command @subsubsection makestep Normally chronyd will cause the system to gradually correct any time offset, by slowing down or speeding up the clock as required. In certain situations, the system clock may be so far adrift that this slewing process would take a very long time to correct the system clock. The @code{makestep} command can be used in this situation. There are two forms of the command. The first form has no parameters. It tells @code{chronyd} to cancel any remaining correction that was being slewed and jump the system clock by the equivalent amount, making it correct immediately. The second form configures the automatic stepping, similarly to the @code{makestep} directive (@pxref{makestep directive}). It has two parameters, stepping threshold (in seconds) and number of future clock updates for which will be the threshold active. This can be used with the @code{burst} command to quickly make a new measurement and correct the clock by stepping if needed, without waiting for @code{chronyd} to complete the measurement and update the clock. @example makestep 0.1 1 burst 1/2 @end example BE WARNED - certain software will be seriously affected by such jumps to the system time. (That is the reason why chronyd uses slewing normally.) @c }}} @c {{{ manual @node manual command @subsubsection manual The manual command enables and disables use of the @code{settime} command (@pxref{settime command}), and is used to modify the behaviour of the manual clock driver. Examples of the command are shown below. @example manual on manual off manual delete 1 manual list manual reset @end example The @code{on} form of the command enables use of the @code{settime} command. The @code{off} form of the command disables use of the @code{settime} command. The @code{list} form of the command lists all the samples currently stored in @code{chronyd}. The output is illustrated below. @example 210 n_samples = 1 # Date Time(UTC) Slewed Original Residual ==================================================== 0 27Jan99 22:09:20 0.00 0.97 0.00 @end example The columns as as follows : @enumerate 1 @item The sample index (used for the @code{manual delete} command) @item The date and time of the sample @item The system clock error when the timestamp was entered, adjusted to allow for changes made to the system clock since. @item The system clock error when the timestamp was entered, as it originally was (without allowing for changes to the system clock since). @item The regression residual at this point, in seconds. This allows 'outliers' to be easily spotted, so that they can be deleted using the @code{manual delete} command. @end enumerate The @code{delete} form of the command deletes a single sample. The parameter is the index of the sample, as shown in the first column of the output from @code{manual list}. Following deletion of the data point, the current error and drift rate are re-estimated from the remaining data points and the system clock trimmed if necessary. This option is intended to allow 'outliers' to be discarded, i.e. samples where the administrator realises he/she has entered a very poor timestamp. The @code{reset} form of the command deletes all samples at once. The system clock is left running as it was before the command was entered. @c }}} @c {{{ maxdelay @node maxdelay command @subsubsection maxdelay This allows the @code{maxdelay} option for one of the sources to be modified, in the same way as specifying the @code{maxdelay} option for the @code{server} directive in the configuration file (@pxref{server directive}). The following examples illustrate the syntax @example maxdelay foo.example.net 0.3 maxdelay 1.2.3.4 0.0015 maxdelay 2001:db8::1 0.0015 @end example The first example sets the maximum network delay allowed for a measurement to the host @code{foo.example.net} to 0.3 seconds. The second and third examples set the maximum network delay for a measurement to the host with IPv4 address @code{1.2.3.4} and the host with IPv6 address @code{2001:db8::1} to 1.5 milliseconds. (Any measurement whose network delay exceeds the specified value is discarded.) @c }}} @c {{{ maxdelaydevratio @node maxdelaydevratio command @subsubsection maxdelaydevratio This allows the @code{maxdelaydevratio} option for one of the sources to be modified, in the same way as specifying the @code{maxdelaydevratio} option for the @code{server} directive in the configuration file (@pxref{server directive}). The following examples illustrate the syntax @example maxdelaydevratio foo.example.net 0.1 maxdelaydevratio 1.2.3.4 1.0 maxdelaydevratio 2001:db8::1 100.0 @end example @c }}} @c {{{ maxdelayratio @node maxdelayratio command @subsubsection maxdelayratio This allows the @code{maxdelayratio} option for one of the sources to be modified, in the same way as specifying the @code{maxdelayratio} option for the @code{server} directive in the configuration file (@pxref{server directive}). The following examples illustrate the syntax @example maxdelayratio foo.example.net 1.5 maxdelayratio 1.2.3.4 2.0 maxdelayratio 2001:db8::1 2.0 @end example The first example sets the maximum network delay for a measurement to the host @code{foo.example.net} to be 1.5 times the minimum delay found amongst the previous measurements that have been retained. The second and third examples set the maximum network delay for a measurement to the host with IPv4 address @code{1.2.3.4} and the host with IPv6 address @code{2001:db8::1} to be double the retained minimum. As for @code{maxdelay}, any measurement whose network delay is too large will be discarded. @c }}} @c {{{ maxpoll @node maxpoll command @subsubsection maxpoll The @code{maxpoll} command is used to modify the minimum polling interval for one of the current set of sources. It is equivalent to the @code{maxpoll} option in the @code{server} directive in the configuration file (@pxref{server directive}). The syntax is as follows @example maxpoll @end example where the host can be specified as either a machine name or IP address. The new minimum poll is specified as a base-2 logarithm of the number of seconds between polls (e.g. specify 6 for 64 second sampling). An example is @example maxpoll foo.example.net 10 @end example which sets the maximum polling interval for the host @code{foo.example.net} to 1024 seconds. Note that the new maximum polling interval only takes effect after the next measurement has been made. @c }}} @c {{{ maxupdateskew @node maxupdateskew command @subsubsection maxupdateskew This command has the same effect as the @code{maxupdateskew} directive in the configuration file, see @ref{maxupdateskew directive}. @c }}} @c {{{ minpoll @node minpoll command @subsubsection minpoll The @code{minpoll} command is used to modify the minimum polling interval for one of the current set of sources. It is equivalent to the @code{minpoll} option in the @code{server} directive in the configuration file (@pxref{server directive}). The syntax is as follows @example minpoll @end example where the host can be specified as either a machine name or IP address. The new minimum poll is specified as a base-2 logarithm of the number of seconds between polls (e.g. specify 6 for 64 second sampling). An example is @example minpoll foo.example.net 5 @end example which sets the minimum polling interval for the host @code{foo.example.net} to 32 seconds. Note that the new minimum polling interval only takes effect after the next measurement has been made. @c }}} @c {{{ minstratum @node minstratum command @subsubsection minstratum The @code{minstratum} command is used to modify the minimum stratum for one of the current set of sources. It is equivalent to the @code{minstratum} option in the @code{server} directive in the configuration file (@pxref{server directive}). The syntax is as follows @example minstratum @end example where the host can be specified as either a machine name or IP address. An example is @example minpoll foo.example.net 5 @end example which sets the minimum stratum for the host @code{foo.example.net} to 5. Note that the new minimum stratum only takes effect after the next measurement has been made. @c }}} @c {{{ offline @node offline command @subsubsection offline The @code{offline} command is used to warn @code{chronyd} that the network connection to a particular host or hosts is about to be lost. It should be used on computers with a dial-up or similar connection to their time sources, to warn @code{chronyd} that the connection is about to be broken. An example of how to use @code{offline} in this case is shown in @ref{Advising chronyd of internet availability}. Another case where @code{offline} could be used is where a computer serves time to a local group of computers, and has a permanant connection to true time servers outside the organisation. However, the external connection is heavily loaded at certain times of the day and the measurements obtained are less reliable at those times. In this case, it is probably most useful to determine the gain/loss rate during the quiet periods and let the whole network coast through the loaded periods. The @code{offline} and @code{online} commands can be used to achieve this. The situation is shown in the figure below. @example @group +----------+ |Ext source| +----------+ | | |/| <-- Link with variable | reliability | +-------------------+ |Local master server| +-------------------+ | +---+---+-----+-----+----+----+ | | | | | | | Local clients @end group @end example If the source to which @code{chronyd} is currently synchronised is indicated offline in this way, @code{chronyd} will continue to treat it as the synchronisation source. If the network connection were broken without the @code{offline} command being used, @code{chronyd} would assume that the source had failed and would attempt to pick another synchronisation source. There are four forms of the @code{offline} command. The first form is a wildcard, meaning all sources. The second form allows an IP address mask and a masked address to be specified. The third form uses the CIDR notation. The fourth form uses an IP address or a hostname. These forms are illustrated below. @example offline offline 255.255.255.0/1.2.3.0 offline 2001:db8:789a::/48 offline foo.example.net @end example The second form means that the @code{offline} command is to be applied to any source whose IPv4 address is in the @code{1.2.3} subnet. (The host's address is logically and-ed with the mask, and if the result matches the masked-address the host is processed). The third form means that the command is to be applied to all sources whose IPv6 addresses have first 48 bits equal to @code{2001:db8:789a}. The fourth form means that the command is to be applied only to that one source. The wildcard form of the address is actually equivalent to @example offline 0.0.0.0/0.0.0.0 offline ::/0 @end example @c }}} @c {{{ online @node online command @subsubsection online The @code{online} command is opposite in function to the @code{offline} command. It is used to advise @code{chronyd} that network connectivity to a particular source or sources has been restored. The syntax is identical to that of the @code{offline} command, see @ref{offline command}. @c }}} @c {{{ polltarget @node polltarget command @subsubsection polltarget The @code{polltarget} command is used to modify the poll target for one of the current set of sources. It is equivalent to the @code{polltarget} option in the @code{server} directive in the configuration file (@pxref{server directive}). The syntax is as follows @example polltarget @end example where the host can be specified as either a machine name or IP address. An example is @example polltarget foo.example.net 12 @end example which sets the poll target for the host @code{foo.example.net} to 12. @c }}} @c {{{ quit @node quit command @subsubsection quit The quit command exits from chronyc and returns the user to the shell (same as the exit command). @c }}} @c {{{ refresh command @node refresh command @subsubsection refresh The @code{refresh} command can be used to force @code{chronyd} to resolve the names of configured sources to IP addresses again, e.g. after suspending and resuming the machine in a different network. Sources that stop responding will be replaced with newly resolved addresses automatically after 8 polling intervals, but this command may still be useful to replace them immediately and not wait until they are marked as unreachable. @c }}} @c {{{ reselect command @node reselect command @subsubsection reselect To avoid excessive switching between sources, @code{chronyd} may stay synchronised to a source even when it is not currently the best one among the available sources. The @code{reselect} command can be used to force @code{chronyd} to reselect the best synchronisation source. @c }}} @c {{{ reselectdist command @node reselectdist command @subsubsection reselectdist The @code{reselectdist} command sets the reselect distance. It is equivalent to the @code{reselectdist} directive in the configuration file (@pxref{reselectdist directive}). @c }}} @c {{{ retries @node retries command @subsubsection retries The @code{retries} command sets the maximum number of retries for @code{chronyc} requests before giving up. The response timeout is controlled by @code{timeout} command (@pxref{timeout command}). The default is 2. @c }}} @c {{{ rtcdata @node rtcdata command @subsubsection rtcdata The @code{rtcdata} command displays the current real time clock RTC parameters. An example output is shown below. @example RTC ref time (GMT) : Sat May 30 07:25:56 1998 Number of samples : 10 Number of runs : 5 Sample span period : 549 RTC is fast by : -1.632736 seconds RTC gains time at : -107.623 ppm @end example The fields have the following meaning @table @code @item RTC ref time (GMT) This is the RTC reading the last time its error was measured. @item Number of samples This is the number of previous measurements being used to determine the RTC gain/loss rate. @item Number of runs This is the number of runs of residuals of the same sign following the regression fit for (RTC error) versus (RTC time). A value which is small indicates that the measurements are not well approximated by a linear model, and that the algorithm will tend to delete the older measurements to improve the fit. @item Sample span period This is the period that the measurements span (from the oldest to the newest). Without a unit the value is in seconds; suffixes `m' for minutes, `h' for hours, `d' for days or `y' for years may be used. @item RTC is fast by This is the estimate of how many seconds fast the RTC when it thought the time was at the reference time (above). If this value is large, you may (or may not) want to use the @code{trimrtc} command to bring the RTC into line with the system clock. (Note, a large error will not affect @code{chronyd's} operation, unless it becomes so big as to start causing rounding errors. @item RTC gains time at This is the amount of time gained (positive) or lost (negative) by the real time clock for each second that it ticks. It is measured in parts per million. So if the value shown was +1, suppose the RTC was exactly right when it crosses a particular second boundary. Then it would be 1 microsecond fast when it crosses its next second boundary. @end table @c }}} @c {{{ settime @node settime command @subsubsection settime The @code{settime} command allows the current time to be entered manually, if this option has been configured into @code{chronyd}. (It may be configured either with the @code{manual} directive in the configuration file (@pxref{manual directive}), or with the @code{manual} command of chronyc (@pxref{manual command}). It should be noted that the computer's sense of time will only be as accurate as the reference you use for providing this input (e.g. your watch), as well as how well you can time the press of the return key. Providing your computer's time zone is set up properly, you will be able to enter a local time (rather than UTC). The response to a successful @code{settime} command indicates the amount that the computer's clock was wrong. It should be apparent from this if you have entered the time wrongly, e.g. with the wrong time zone. The rate of drift of the system clock is estimated by a regression process using the entered measurement and all previous measurements entered during the present run of @code{chronyd}. However, the entered measurement is used for adjusting the current clock offset (rather than the estimated intercept from the regression, which is ignored). Contrast what happens with the @code{manual delete} command, where the intercept is used to set the current offset (since there is no measurement that has just been typed in in that case). The time is parsed by the public domain @file{getdate} algorithm. Consequently, you can only specify time to the nearest second. Examples of inputs that are valid are shown below. @example settime 16:30 settime 16:30:05 settime Nov 21, 1997 16:30:05 @end example For a full description of @code{getdate}, get hold of the getdate documentation (bundled, for example, with the source for GNU tar). @c }}} @c {{{ smoothing @node smoothing command @subsubsection smoothing The @code{smoothing} command displays the current state of the NTP server time smoothing. An example of the output is shown below. @example Active : Yes Offset : +1.000268817 seconds Frequency : -0.142859 ppm Wander : -0.010000 ppm per second Last update : 17.8 seconds ago Remaining time : 19988.4 seconds @end example The fields are explained as follows. @table @code @item Active This shows if the server time smoothing is currently active. Possible values are @code{Yes} and @code{No}. If the @code{leaponly} option is included in the @code{smoothtime} directive, @code{(leap second only)} will be shown on the line. @item Offset This is the current offset applied to the time sent to NTP clients. Positive value means the clients are getting time that's ahead of true time. @item Frequency The current frequency offset of the served time. Negative value means the time observed by clients is running slower than true time. @item Wander The current frequency wander of the served time. Negative value means the time observed by clients is slowing down. @item Last update This field shows how long ago was the time smoothing process updated, e.g. @code{chronyd} accumulated a new measurement. @item Remaining time The time it would take for the smoothing process to get to zero offset and frequency if there were no more updates. @end table @c }}} @c {{{ smoothtime @node smoothtime command @subsubsection smoothtime The @code{smoothtime} command can be used to reset or activate the server time smoothing process if it is configured with the @code{smoothtime} directive (@pxref{smoothtime directive}). The syntax is as follows @example smoothtime reset smoothtime activate @end example @c }}} @c {{{ sources @node sources command @subsubsection sources This command displays information about the current time sources that @code{chronyd} is accessing. The optional argument @code{-v} can be specified, meaning @emph{verbose}. In this case, extra caption lines are shown as a reminder of the meanings of the columns. @example @group 210 Number of sources = 3 MS Name/IP address Stratum Poll Reach LastRx Last sample =============================================================================== #* GPS0 0 4 377 11 -479ns[ -621ns] +/- 134ns ^? foo.example.net 2 6 377 23 -923us[ -924us] +/- 43ms ^+ bar.example.net 1 6 377 21 -2629us[-2619us] +/- 86ms @end group @end example The columns are as follows: @table @code @item M This indicates the mode of the source. @code{^} means a server, @code{=} means a peer and @code{#} indicates a locally connected reference clock. @item S This column indicates the state of the sources. @code{*} indicates the source to which @code{chronyd} is currently synchronised. @code{+} indicates acceptable sources which are combined with the selected source. @code{-} indicates acceptable sources which are excluded by the combining algorithm. @code{?} indicates sources to which connectivity has been lost or whose packets don't pass all tests. @code{x} indicates a clock which @code{chronyd} thinks is is a falseticker (i.e. its time is inconsistent with a majority of other sources). @code{~} indicates a source whose time appears to have too much variability. The @code{?} condition is also shown at start-up, until at least 3 samples have been gathered from it. @item Name/IP address This shows the name or the IP address of the source, or refid for reference clocks. @item Stratum This shows the stratum of the source, as reported in its most recently received sample. Stratum 1 indicates a computer with a locally attached reference clock. A computer that is synchronised to a stratum 1 computer is at stratum 2. A computer that is synchronised to a stratum 2 computer is at stratum 3, and so on. @item Poll This shows the rate at which the source is being polled, as a base-2 logarithm of the interval in seconds. Thus, a value of 6 would indicate that a measurement is being made every 64 seconds. @code{chronyd} automatically varies the polling rate in response to prevailing conditions. @item Reach This shows the source's reachability register printed as octal number. The register has 8 bits and is updated on every received or missed packet from the source. A value of 377 indicates that a valid reply was received for all from the last eight transmissions. @item LastRx This column shows how long ago the last sample was received from the source. This is normally in seconds. The letters @code{m}, @code{h}, @code{d} or @code{y} indicate minutes, hours, days or years. A value of 10 years indicates there were no samples received from this source yet. @item Last sample This column shows the offset between the local clock and the source at the last measurement. The number in the square brackets shows the actual measured offset. This may be suffixed by @code{ns} (indicating nanoseconds), @code{us} (indicating microseconds), @code{ms} (indicating milliseconds), or @code{s} (indicating seconds). The number to the left of the square brackets shows the original measurement, adjusted to allow for any slews applied to the local clock since. The number following the @code{+/-} indicator shows the margin of error in the measurement. Positive offsets indicate that the local clock is fast of the source. @end table @c }}} @c {{{ sourcestats @node sourcestats command @subsubsection sourcestats The @code{sourcestats} command displays information about the drift rate and offset estimatation process for each of the sources currently being examined by @code{chronyd}. The optional argument @code{-v} can be specified, meaning @emph{verbose}. In this case, extra caption lines are shown as a reminder of the meanings of the columns. An example report is @example @group 210 Number of sources = 1 Name/IP Address NP NR Span Frequency Freq Skew Offset Std Dev =============================================================================== abc.def.ghi 11 5 46m -0.001 0.045 1us 25us @end group @end example The columns are as follows @table @code @item Name/IP Address This is the name or IP address of the NTP server (or peer) or refid of the refclock to which the rest of the line relates. @item NP This is the number of sample points currently being retained for the server. The drift rate and current offset are estimated by performing a linear regression through these points. @item NR This is the number of runs of residuals having the same sign following the last regression. If this number starts to become too small relative to the number of samples, it indicates that a straight line is no longer a good fit to the data. If the number of runs is too low, @code{chronyd} discards older samples and re-runs the regression until the number of runs becomes acceptable. @item Span This is the interval between the oldest and newest samples. If no unit is shown the value is in seconds. In the example, the interval is 46 minutes. @item Frequency This is the estimated residual frequency for the server, in parts per million. In this case, the computer's clock is estimated to be running 1 part in 10**9 slow relative to the server. @item Freq Skew This is the estimated error bounds on @code{Freq} (again in parts per million). @item Offset This is the estimated offset of the source. @item Std Dev This is the estimated sample standard deviation. @end table @c }}} @c {{{ timeout @node timeout command @subsubsection timeout The @code{timeout} command sets the initial timeout for @code{chronyc} requests in milliseconds. If no response is received from @code{chronyd}, the timeout is doubled and the request is resent. The maximum number of retries is configured with the @code{retries} command (@pxref{retries command}). By default, the timeout is 1000 milliseconds. @c }}} @c {{{ tracking @node tracking command @subsubsection tracking The @code{tracking} command displays parameters about the system's clock performance. An example of the output is shown below. @example Reference ID : 1.2.3.4 (foo.example.net) Stratum : 3 Ref time (UTC) : Fri Feb 3 15:00:29 2012 System time : 0.000001501 seconds slow of NTP time Last offset : -0.000001632 seconds RMS offset : 0.000002360 seconds Frequency : 331.898 ppm fast Residual freq : 0.004 ppm Skew : 0.154 ppm Root delay : 0.373169 seconds Root dispersion : 0.024780 seconds Update interval : 64.2 seconds Leap status : Normal @end example The fields are explained as follows. @table @code @item Reference ID This is the refid and name (or IP address) if available, of the server to which the computer is currently synchronised. If this is @code{127.127.1.1} it means the computer is not synchronised to any external source and that you have the `local' mode operating (via the @code{local} command in @code{chronyc} (@pxref{local command}), or the @code{local} directive in the @file{@SYSCONFDIR@/chrony.conf} file (@pxref{local directive})). @item Stratum The stratum indicates how many hops away from a computer with an attached reference clock we are. Such a computer is a stratum-1 computer, so the computer in the example is two hops away (i.e. @code{foo.example.net} is a stratum-2 and is synchronised from a stratum-1). @item Ref time This is the time (UTC) at which the last measurement from the reference source was processed. @item System time In normal operation, @code{chronyd} @emph{never} steps the system clock, because any jump in the timescale can have adverse consequences for certain application programs. Instead, any error in the system clock is corrected by slightly speeding up or slowing down the system clock until the error has been removed, and then returning to the system clock's normal speed. A consequence of this is that there will be a period when the system clock (as read by other programs using the @code{gettimeofday()} system call, or by the @code{date} command in the shell) will be different from @code{chronyd's} estimate of the current true time (which it reports to NTP clients when it is operating in server mode). The value reported on this line is the difference due to this effect. @item Last offset This is the estimated local offset on the last clock update. @item RMS offset This is a long-term average of the offset value. @item Frequency The `frequency' is the rate by which the system's clock would be would be wrong if @code{chronyd} was not correcting it. It is expressed in ppm (parts per million). For example, a value of 1ppm would mean that when the system's clock thinks it has advanced 1 second, it has actually advanced by 1.000001 seconds relative to true time. As you can see in the example, the clock in the computer is not a very good one - it gains about 30 seconds per day! @item Residual freq This shows the `residual frequency' for the currently selected reference source. This reflects any difference between what the measurements from the reference source indicate the frequency should be and the frequency currently being used. The reason this is not always zero is that a smoothing procedure is applied to the frequency. Each time a measurement from the reference source is obtained and a new residual frequency computed, the estimated accuracy of this residual is compared with the estimated accuracy (see `skew' next) of the existing frequency value. A weighted average is computed for the new frequency, with weights depending on these accuracies. If the measurements from the reference source follow a consistent trend, the residual will be driven to zero over time. @item Skew This is the estimated error bound on the the frequency. @item Root delay This is the total of the network path delays to the stratum-1 computer from which the computer is ultimately synchronised. @item Root dispersion This is the total dispersion accumulated through all the computers back to the stratum-1 computer from which the computer is ultimately synchronised. Dispersion is due to system clock resolution, statistical measurement variations etc. An absolute bound on the computer's clock accuracy (assuming the stratum-1 computer is correct) is given by @example clock_error <= root_dispersion + (0.5 * |root_delay|) @end example @item Update interval This is the interval between the last two clock updates. @item Leap status This is the leap status, which can be @code{Normal}, @code{Insert second}, @code{Delete second} or @code{Not synchronised}. @end table @c }}} @c {{{ trimrtc @node trimrtc command @subsubsection trimrtc The @code{trimrtc} command is used to correct the system's real time clock (RTC) to the main system clock. It has no effect if the error between the two clocks is currently estimated at less than a second (the resolution of the RTC is only 1 second). The command takes no arguments. It performs the following steps (if the RTC is more than 1 second away from the system clock): @enumerate 1 @item Remember the currently estimated gain/loss rate of the RTC and flush the previous measurements. @item Step the real time clock to bring it within a second of the system clock. @item Make several measurements to accurately determine the new offset between the RTC and the system clock (i.e. the remaining fraction of a second error) @item Save the RTC parameters to the RTC file (specified with the @code{rtcfile} directive in the configuration file (@pxref{rtcfile directive}). @end enumerate The last step is done as a precaution against the computer suffering a power failure before either the daemon exits or the @code{writertc} command is issued. @code{chronyd} will still work perfectly well both whilst operating and across machine reboots even if the @code{trimrtc} command is never used (and the RTC is allowed to drift away from true time). The @code{trimrtc} command is provided as a method by which it can be corrected, in a manner compatible with @code{chronyd} using it to maintain accurate time across machine reboots. The @code{trimrtc} command can be executed automatically by @code{chronyd} with the @code{rtcautotrim} directive (@pxref{rtcautotrim directive}). @c }}} @c {{{ waitsync @node waitsync command @subsubsection waitsync The @code{waitsync} command waits for @code{chronyd} to synchronise. Up to four optional arguments can be specified, the first is the maximum number of tries before giving up and returning a non-zero error code. When 0 is specified, or there are no arguments, the number of tries will not be limited. The second and third arguments are the maximum allowed remaining correction of the system clock and the maximum allowed skew (in ppm) as reported by the @code{tracking} command (@pxref{tracking command}) in the @code{System time} and @code{Skew} fields. If not specified or zero, the value will not be checked. The fourth argument is the interval in which the check is repeated. The interval is 10 seconds by default. An example is @example waitsync 60 0.01 @end example which will wait up to about 10 minutes (60 times 10 seconds) for @code{chronyd} to synchronise to a source and the remaining correction to be less than 10 milliseconds. @c }}} @c {{{ writertc @node writertc command @subsubsection writertc The @code{writertc} command writes the currently estimated error and gain/loss rate parameters for the RTC to the RTC file (specified with the @code{rtcfile} directive (@pxref{rtcfile directive})). This information is also written automatically when @code{chronyd} is killed (with SIGHUP, SIGINT, SIGQUIT or SIGTERM) or when the @code{trimrtc} command is issued. @c }}} @c }}} @c }}} @c }}} @c {{{ apx:GNU General Public License @node GPL @appendix GNU General Public License @center GNU GENERAL PUBLIC LICENSE @center Version 2, June 1991 Copyright (C) 1989, 1991 Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA Everyone is permitted to copy and distribute verbatim copies of this license document, but changing it is not allowed. Preamble The licenses for most software are designed to take away your freedom to share and change it. By contrast, the GNU General Public License is intended to guarantee your freedom to share and change free software--to make sure the software is free for all its users. This General Public License applies to most of the Free Software Foundation's software and to any other program whose authors commit to using it. (Some other Free Software Foundation software is covered by the GNU Lesser General Public License instead.) You can apply it to your programs, too. When we speak of free software, we are referring to freedom, not price. Our General Public Licenses are designed to make sure that you have the freedom to distribute copies of free software (and charge for this service if you wish), that you receive source code or can get it if you want it, that you can change the software or use pieces of it in new free programs; and that you know you can do these things. To protect your rights, we need to make restrictions that forbid anyone to deny you these rights or to ask you to surrender the rights. These restrictions translate to certain responsibilities for you if you distribute copies of the software, or if you modify it. For example, if you distribute copies of such a program, whether gratis or for a fee, you must give the recipients all the rights that you have. You must make sure that they, too, receive or can get the source code. And you must show them these terms so they know their rights. We protect your rights with two steps: (1) copyright the software, and (2) offer you this license which gives you legal permission to copy, distribute and/or modify the software. Also, for each author's protection and ours, we want to make certain that everyone understands that there is no warranty for this free software. If the software is modified by someone else and passed on, we want its recipients to know that what they have is not the original, so that any problems introduced by others will not reflect on the original authors' reputations. Finally, any free program is threatened constantly by software patents. We wish to avoid the danger that redistributors of a free program will individually obtain patent licenses, in effect making the program proprietary. To prevent this, we have made it clear that any patent must be licensed for everyone's free use or not licensed at all. The precise terms and conditions for copying, distribution and modification follow. GNU GENERAL PUBLIC LICENSE TERMS AND CONDITIONS FOR COPYING, DISTRIBUTION AND MODIFICATION 0. This License applies to any program or other work which contains a notice placed by the copyright holder saying it may be distributed under the terms of this General Public License. The "Program", below, refers to any such program or work, and a "work based on the Program" means either the Program or any derivative work under copyright law: that is to say, a work containing the Program or a portion of it, either verbatim or with modifications and/or translated into another language. (Hereinafter, translation is included without limitation in the term "modification".) Each licensee is addressed as "you". Activities other than copying, distribution and modification are not covered by this License; they are outside its scope. The act of running the Program is not restricted, and the output from the Program is covered only if its contents constitute a work based on the Program (independent of having been made by running the Program). Whether that is true depends on what the Program does. 1. You may copy and distribute verbatim copies of the Program's source code as you receive it, in any medium, provided that you conspicuously and appropriately publish on each copy an appropriate copyright notice and disclaimer of warranty; keep intact all the notices that refer to this License and to the absence of any warranty; and give any other recipients of the Program a copy of this License along with the Program. You may charge a fee for the physical act of transferring a copy, and you may at your option offer warranty protection in exchange for a fee. 2. You may modify your copy or copies of the Program or any portion of it, thus forming a work based on the Program, and copy and distribute such modifications or work under the terms of Section 1 above, provided that you also meet all of these conditions: a) You must cause the modified files to carry prominent notices stating that you changed the files and the date of any change. b) You must cause any work that you distribute or publish, that in whole or in part contains or is derived from the Program or any part thereof, to be licensed as a whole at no charge to all third parties under the terms of this License. c) If the modified program normally reads commands interactively when run, you must cause it, when started running for such interactive use in the most ordinary way, to print or display an announcement including an appropriate copyright notice and a notice that there is no warranty (or else, saying that you provide a warranty) and that users may redistribute the program under these conditions, and telling the user how to view a copy of this License. (Exception: if the Program itself is interactive but does not normally print such an announcement, your work based on the Program is not required to print an announcement.) These requirements apply to the modified work as a whole. If identifiable sections of that work are not derived from the Program, and can be reasonably considered independent and separate works in themselves, then this License, and its terms, do not apply to those sections when you distribute them as separate works. But when you distribute the same sections as part of a whole which is a work based on the Program, the distribution of the whole must be on the terms of this License, whose permissions for other licensees extend to the entire whole, and thus to each and every part regardless of who wrote it. Thus, it is not the intent of this section to claim rights or contest your rights to work written entirely by you; rather, the intent is to exercise the right to control the distribution of derivative or collective works based on the Program. In addition, mere aggregation of another work not based on the Program with the Program (or with a work based on the Program) on a volume of a storage or distribution medium does not bring the other work under the scope of this License. 3. You may copy and distribute the Program (or a work based on it, under Section 2) in object code or executable form under the terms of Sections 1 and 2 above provided that you also do one of the following: a) Accompany it with the complete corresponding machine-readable source code, which must be distributed under the terms of Sections 1 and 2 above on a medium customarily used for software interchange; or, b) Accompany it with a written offer, valid for at least three years, to give any third party, for a charge no more than your cost of physically performing source distribution, a complete machine-readable copy of the corresponding source code, to be distributed under the terms of Sections 1 and 2 above on a medium customarily used for software interchange; or, c) Accompany it with the information you received as to the offer to distribute corresponding source code. (This alternative is allowed only for noncommercial distribution and only if you received the program in object code or executable form with such an offer, in accord with Subsection b above.) The source code for a work means the preferred form of the work for making modifications to it. For an executable work, complete source code means all the source code for all modules it contains, plus any associated interface definition files, plus the scripts used to control compilation and installation of the executable. However, as a special exception, the source code distributed need not include anything that is normally distributed (in either source or binary form) with the major components (compiler, kernel, and so on) of the operating system on which the executable runs, unless that component itself accompanies the executable. If distribution of executable or object code is made by offering access to copy from a designated place, then offering equivalent access to copy the source code from the same place counts as distribution of the source code, even though third parties are not compelled to copy the source along with the object code. 4. You may not copy, modify, sublicense, or distribute the Program except as expressly provided under this License. Any attempt otherwise to copy, modify, sublicense or distribute the Program is void, and will automatically terminate your rights under this License. However, parties who have received copies, or rights, from you under this License will not have their licenses terminated so long as such parties remain in full compliance. 5. You are not required to accept this License, since you have not signed it. However, nothing else grants you permission to modify or distribute the Program or its derivative works. These actions are prohibited by law if you do not accept this License. Therefore, by modifying or distributing the Program (or any work based on the Program), you indicate your acceptance of this License to do so, and all its terms and conditions for copying, distributing or modifying the Program or works based on it. 6. Each time you redistribute the Program (or any work based on the Program), the recipient automatically receives a license from the original licensor to copy, distribute or modify the Program subject to these terms and conditions. You may not impose any further restrictions on the recipients' exercise of the rights granted herein. You are not responsible for enforcing compliance by third parties to this License. 7. If, as a consequence of a court judgment or allegation of patent infringement or for any other reason (not limited to patent issues), conditions are imposed on you (whether by court order, agreement or otherwise) that contradict the conditions of this License, they do not excuse you from the conditions of this License. If you cannot distribute so as to satisfy simultaneously your obligations under this License and any other pertinent obligations, then as a consequence you may not distribute the Program at all. For example, if a patent license would not permit royalty-free redistribution of the Program by all those who receive copies directly or indirectly through you, then the only way you could satisfy both it and this License would be to refrain entirely from distribution of the Program. If any portion of this section is held invalid or unenforceable under any particular circumstance, the balance of the section is intended to apply and the section as a whole is intended to apply in other circumstances. It is not the purpose of this section to induce you to infringe any patents or other property right claims or to contest validity of any such claims; this section has the sole purpose of protecting the integrity of the free software distribution system, which is implemented by public license practices. Many people have made generous contributions to the wide range of software distributed through that system in reliance on consistent application of that system; it is up to the author/donor to decide if he or she is willing to distribute software through any other system and a licensee cannot impose that choice. This section is intended to make thoroughly clear what is believed to be a consequence of the rest of this License. 8. If the distribution and/or use of the Program is restricted in certain countries either by patents or by copyrighted interfaces, the original copyright holder who places the Program under this License may add an explicit geographical distribution limitation excluding those countries, so that distribution is permitted only in or among countries not thus excluded. In such case, this License incorporates the limitation as if written in the body of this License. 9. The Free Software Foundation may publish revised and/or new versions of the General Public License from time to time. Such new versions will be similar in spirit to the present version, but may differ in detail to address new problems or concerns. Each version is given a distinguishing version number. If the Program specifies a version number of this License which applies to it and "any later version", you have the option of following the terms and conditions either of that version or of any later version published by the Free Software Foundation. If the Program does not specify a version number of this License, you may choose any version ever published by the Free Software Foundation. 10. If you wish to incorporate parts of the Program into other free programs whose distribution conditions are different, write to the author to ask for permission. For software which is copyrighted by the Free Software Foundation, write to the Free Software Foundation; we sometimes make exceptions for this. Our decision will be guided by the two goals of preserving the free status of all derivatives of our free software and of promoting the sharing and reuse of software generally. NO WARRANTY 11. BECAUSE THE PROGRAM IS LICENSED FREE OF CHARGE, THERE IS NO WARRANTY FOR THE PROGRAM, TO THE EXTENT PERMITTED BY APPLICABLE LAW. EXCEPT WHEN OTHERWISE STATED IN WRITING THE COPYRIGHT HOLDERS AND/OR OTHER PARTIES PROVIDE THE PROGRAM "AS IS" WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE PROGRAM IS WITH YOU. SHOULD THE PROGRAM PROVE DEFECTIVE, YOU ASSUME THE COST OF ALL NECESSARY SERVICING, REPAIR OR CORRECTION. 12. IN NO EVENT UNLESS REQUIRED BY APPLICABLE LAW OR AGREED TO IN WRITING WILL ANY COPYRIGHT HOLDER, OR ANY OTHER PARTY WHO MAY MODIFY AND/OR REDISTRIBUTE THE PROGRAM AS PERMITTED ABOVE, BE LIABLE TO YOU FOR DAMAGES, INCLUDING ANY GENERAL, SPECIAL, INCIDENTAL OR CONSEQUENTIAL DAMAGES ARISING OUT OF THE USE OR INABILITY TO USE THE PROGRAM (INCLUDING BUT NOT LIMITED TO LOSS OF DATA OR DATA BEING RENDERED INACCURATE OR LOSSES SUSTAINED BY YOU OR THIRD PARTIES OR A FAILURE OF THE PROGRAM TO OPERATE WITH ANY OTHER PROGRAMS), EVEN IF SUCH HOLDER OR OTHER PARTY HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. END OF TERMS AND CONDITIONS How to Apply These Terms to Your New Programs If you develop a new program, and you want it to be of the greatest possible use to the public, the best way to achieve this is to make it free software which everyone can redistribute and change under these terms. To do so, attach the following notices to the program. It is safest to attach them to the start of each source file to most effectively convey the exclusion of warranty; and each file should have at least the "copyright" line and a pointer to where the full notice is found. Copyright (C) This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. Also add information on how to contact you by electronic and paper mail. If the program is interactive, make it output a short notice like this when it starts in an interactive mode: Gnomovision version 69, Copyright (C) year name of author Gnomovision comes with ABSOLUTELY NO WARRANTY; for details type `show w'. This is free software, and you are welcome to redistribute it under certain conditions; type `show c' for details. The hypothetical commands `show w' and `show c' should show the appropriate parts of the General Public License. Of course, the commands you use may be called something other than `show w' and `show c'; they could even be mouse-clicks or menu items--whatever suits your program. You should also get your employer (if you work as a programmer) or your school, if any, to sign a "copyright disclaimer" for the program, if necessary. Here is a sample; alter the names: Yoyodyne, Inc., hereby disclaims all copyright interest in the program `Gnomovision' (which makes passes at compilers) written by James Hacker. , 1 April 1989 Ty Coon, President of Vice This General Public License does not permit incorporating your program into proprietary programs. If your program is a subroutine library, you may consider it more useful to permit linking proprietary applications with the library. If this is what you want to do, use the GNU Lesser General Public License instead of this License. @c }}} @contents @bye @c vim:cms=@c\ %s:fdm=marker:fdc=5:syntax=off