adjtimex(8)


NAME

   adjtimex - display or set the kernel time variables

SYNOPSIS

   adjtimex [option]...

DESCRIPTION

   This program gives you raw access to the kernel time variables.  Anyone
   may print out the time variables, but only the superuser may change
   them.

   Your computer has two clocks - the "hardware clock" that runs all the
   time, and the system clock that runs only while the computer is on.
   Normally, "hwclock --hctosys" should be run at startup to initialize
   the system clock.  The system clock has much better precision
   (approximately 1 usec), but the hardware clock probably has better
   long-term stability.  There are three basic strategies for managing
   these clocks.

   For a machine connected to the Internet, or equipped with a precision
   oscillator or radio clock, the best way is to regulate the system clock
   with ntpd(8).  The kernel will automatically update the hardware clock
   every eleven minutes.

   In addition, hwclock(8) can be used to approximately correct for a
   constant drift in the hardware clock.  In this case, "hwclock --adjust"
   is run occasionally. hwclock notes how long it has been since the last
   adjustment, and nudges the hardware clock forward or back by the
   appropriate amount.  The user needs to set the time with "hwclock
   --set" several times over the course of a few days so hwclock can
   estimate the drift rate.  During that time, ntpd should not be running,
   or else hwclock will conclude the hardware clock does not drift at all.
   After you have run "hwclock --set" for the last time, it's okay to
   start ntpd.  Then, "hwclock --systohc" should be run when the machine
   is shut down.  (To see why, suppose the machine runs for a week with
   ntpd, is shut down for a day, is restarted, and "hwclock --adjust" is
   run by a startup script.  It should only correct for one day's worth of
   drift.  However, it has no way of knowing that ntpd has been adjusting
   the hardware clock, so it bases its adjustment on the last time hwclock
   was run.)

   For a standalone or intermittently connected machine, where it's not
   possible to run ntpd, you may use adjtimex instead to correct the
   system clock for systematic drift.

   There are several ways to estimate the drift rate.  If your computer
   can be connected to the net, you might run ntpd for at least several
   hours and run "adjtimex --print" to learn what values of tick and freq
   it settled on.  Alternately, you could estimate values using as a
   reference the CMOS clock (see the --compare and --adjust switches),
   another host (see --host and --review), or some other source of time
   (see --watch and --review).  You could then add a line to rc.local
   invoking adjtimex, or configure /etc/init.d/adjtimex or
   /etc/default/adjtimex, to set those parameters each time you reboot.

OPTIONS

   Options may be introduced by either - or --, and unique abbreviations
   may be used.

   Here is a summary of the options, grouped by type.  Explanations
   follow.

   Get/Set Kernel Time Parameters
          -p --print -t --tick val -f newfreq --frequency newfreq -o val
          --offset val -s adjustment --singleshot adjustment -S status
          --status status -m val -R --reset --maxerror val -e val
          --esterror val -T val --timeconstant val -a[count]
          --adjust[=count]

   Estimate Systematic Drifts
          -c[count] --compare[=count] -i tim --interval tim -l file
          --logfile file -h timeserver --host timeserver -w --watch
          -r[file] --review[=file] -u --utc -d --directisa -n
          --nointerrupt

   Informative Output
          --help -v --version -V --verbose

   -p, --print
          Print the current values of the kernel time variables.  NOTE:
          The time is "raw", and may be off by up to one timer tick (10
          msec).  "status" gives the value of the time_status variable in
          the kernel.  For Linux 1.0 and 1.2 kernels, the value is as
          follows:
                0   clock is synchronized (so the kernel should
                    periodically set the CMOS clock to match the
                    system clock)
                1   inserting a leap second at midnight
                2   deleting a leap second at midnight
                3   leap second in progress
                4   leap second has occurred
                5   clock not externally synchronized (so the
                    kernel should leave the CMOS clock alone)
          For Linux kernels 2.0 through 2.6, the value is a sum of these:
                1   PLL updates enabled
                2   PPS freq discipline enabled
                4   PPS time discipline enabled
                8   frequency-lock mode enabled
               16   inserting leap second
               32   deleting leap second
               64   clock unsynchronized
              128   holding frequency
              256   PPS signal present
              512   PPS signal jitter exceeded
             1024   PPS signal wander exceeded
             2048   PPS signal calibration error
             4096   clock hardware fault
           * The following status value are appended since 2.6.26 (July 2008):
             8192   resolution (0 = us, 8192 = ns)
            16384   mode (0 = PLL, 16384 = FLL)
            32768   clock source (0 = A, 32768 = B)

   -t val, --tick val
          Set the number of microseconds that should be added to the
          system time for each kernel tick interrupt.  For a kernel with
          USER_HZ=100, there are supposed to be 100 ticks per second, so
          val should be close to 10000.  Increasing val by 1 speeds up the
          system clock by about 100 ppm, or 8.64 sec/day.  tick must be in
          the range 900000/USER_HZ...1100000/USER_HZ.  If val is rejected
          by the kernel, adjtimex will determine the acceptable range
          through trial and error and print it.  (After completing the
          search, it will restore the original value.)

   -f newfreq, --frequency newfreq
          Set the system clock frequency offset to newfreq.  newfreq can
          be negative or positive, and gives a much finer adjustment than
          the --tick switch.  When USER_HZ=100, the value is scaled such
          that newfreq = 65536 speeds up the system clock by about 1 ppm,
          or .0864 sec/day.  Thus, all of these are about the same:
               --tick  9995 --frequency  32768000
               --tick 10000 --frequency         0
               --tick 10001 --frequency  -6553600
               --tick 10002 --frequency -13107200
               --tick 10005 --frequency -32768000
          To see the acceptable range for newfreq, use --print and look at
          "tolerance", or try an illegal value (e.g. --tick 0).

   -s adj, --singleshot adj
          Slew the system clock by adj usec.  (Its rate is changed
          temporarily by about 1 part in 2000.)

   -o adj, --offset adj
          Add a time offset of adj usec.  The kernel code adjusts the time
          gradually by adj, notes how long it has been since the last time
          offset, and then adjusts the frequency offset to correct for the
          apparent drift.  adj must be in the range -512000...512000.

   -S status, --status status
          Set kernel system clock status register to value status. Look
          here above at the --print switch section for the meaning of
          status, depending on your kernel.

   -R, --reset
          Reset clock status after setting a clock parameter.  For early
          Linux kernels, using the adjtimex(2) system call to set any time
          parameter the kernel think the clock is synchronized with an
          external time source, so it sets the kernel variable time_status
          to TIME_OK.  Thereafter, at 11 minute intervals, it will adjust
          the CMOS clock to match.  We prevent this "eleven minute mode"
          by setting the clock, because that has the side effect of
          resetting time_status to TIME_BAD.  We try not to actually
          change the clock setting.  Kernel versions 2.0.40 and later
          apparently don't need this.  If your kernel does require it, use
          this option with: -t -T -t -e -m -f -s -o -c -r.

   -m val, --maxerror val
          Set maximum error (usec).

   -e val, --esterror val
          Set estimated error (usec).  The maximum and estimated error are
          not used by the kernel.  They are merely made available to user
          processes via the adjtimex(2) system call.

   -T val, --timeconstant val
          Set phase locked loop (PLL) time constant.  val determines the
          bandwidth or "stiffness" of the PLL.  The effective PLL time
          constant will be a multiple of (2^val).  For room-temperature
          quartz oscillators, David Mills recommends the value 2, which
          corresponds to a PLL time constant of about 900 sec and a
          maximum update interval of about 64 sec.  The maximum update
          interval scales directly with the time constant, so that at the
          maximum time constant of 6, the update interval can be as large
          as 1024 sec.

          Values of val between zero and 2 give quick convergence; values
          between 2 and 6 can be used to reduce network load, but at a
          modest cost in accuracy.

   -c[count], --compare[=count]
          Periodically compare the system clock with the CMOS clock.
          After the first two calls, print values for tick and frequency
          offset that would bring the system clock into approximate
          agreement with the CMOS clock.  CMOS clock readings are adjusted
          for systematic drift using using the correction in /etc/adjtime
          --- see hwclock(8).  The interval between comparisons is 10
          seconds, unless changed by the --interval switch.  The optional
          argument is the number of comparisons.  (If the argument is
          supplied, the "=" is required.)  If the CMOS clock and the
          system clock differ by more than six minutes, adjtimex will try
          shifting the time from the CMOS clock by some multiple of one
          hour, up to plus or minus 13 hours in all.  This should allow
          correct operation, including logging, if the --utc switch was
          used when the CMOS clock is set to local time (or vice-versa),
          or if summer time has started or stopped since the CMOS clock
          was last set.

   -a[count], --adjust[=count]
          By itself, same as --compare, except the recommended values are
          actually installed after every third comparison.  With --review,
          the tick and frequency are set to the least-squares estimates.
          (In the latter case, any count value is ignored.)

   --force-adjust
          Override the sanity check that prevents changing the clock rate
          by more than 500 ppm.

   -i tim, --interval tim
          Set the interval in seconds between clock comparisons for the
          --compare and --adjust options.

   -u, --utc
          The CMOS clock is set to UTC (universal time) rather than local
          time.

   -d, --directisa
          To read the CMOS clock accurately, adjtimex usually accesses the
          clock via the /dev/rtc device driver of the kernel, and makes
          use of its CMOS update-ended interrupt to detect the beginning
          of seconds. It will also try /dev/rtc0 (for udev), /dev/misc/rtc
          (for the obsolete devfs) and possibly others.  When the /dev/rtc
          driver is absent, or when the interrupt is not available,
          adjtimex can sometimes automatically fallback to a direct access
          method. This method detects the start of seconds by polling the
          update-in-progress (UIP) flag of the CMOS clock. You can force
          this direct access to the CMOS chip with the --directisa switch.

          Note that the /dev/rtc interrupt method is more accurate, less
          sensible to perturbations due to system load, cleaner, cheaper,
          and is generally better than the direct access method. It is
          advisable to not use the --directisa switch, unless the CMOS
          chip or the motherboard don't properly provide the necessary
          interrupt.

   -n, --nointerrupt
          Force immediate use of busywait access method, without first
          waiting for the interrupt timeout.

   -l[file], --log[=file]
          Save the current values of the system and CMOS clocks, and
          optionally a reference time, to file (default
          /var/log/clocks.log).  The reference time is taken from a
          network timeserver (see the --host switch) or supplied by the
          user (see the --watch switch).

   -h timeserver, --host timeserver
          Use ntpdate to query the given timeserver for the current time.
          This will fail if timeserver is not running a Network Time
          Protocol (NTP) server, or if that server is not synchronized.
          Implies --log.

   -w, --watch
          Ask for a keypress when the user knows the time, then ask what
          that time was, and its approximate accuracy.  Implies --log.

   -r[file], --review[=file]
          Review the clock log file (default /var/log/clocks.log) and
          estimate, if possible, the rates of the CMOS and system clocks.
          Calculate least-squares rates using all suitable log entries.
          Suggest corrections to adjust for systematic drift.  With
          --adjust, the frequency and tick are set to the suggested
          values.  (The CMOS clock correction is not changed.)

   -V, --verbose
          Increase verbosity.

   --help Print the program options.

   -v, --version
          Print the program version.

EXAMPLES

   If your system clock gained 8 seconds in 24 hours, you could set the
   tick to 9999, and then it would lose 0.64 seconds a day (that is, 1
   tick unit = 8.64 seconds per day).  To correct the rest of the error,
   you could set the frequency offset to (2^16)*0.64/.0864 = 485452.
   Thus, putting the following in rc.local would approximately correct the
   system clock:

        adjtimex  --tick 9999  --freq 485452

NOTES

   adjtimex adjusts only the system clock --- the one that runs while the
   computer is powered up.  To set or regulate the CMOS clock, see
   hwclock(8).

AUTHORS

   Steven S. Dick <ssd at nevets.oau.org>, Jim Van Zandt <jrv at
   comcast.net>.

SEE ALSO

   date(1L), gettimeofday(2), settimeofday(2), hwclock(8), ntpdate(8),
   ntpd(8), /usr/src/linux/include/linux/timex.h,
   /usr/src/linux/include/linux/sched.h, /usr/src/linux/kernel/time.c,
   /usr/src/linux/kernel/sched.c

                            March 11, 2009                     ADJTIMEX(8)





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