chrony/local.c - chrony - Git at Google

 /*
   chronyd/chronyc - Programs for keeping computer clocks accurate.

  **********************************************************************
  * Copyright (C) Richard P. Curnow  1997-2003
  * Copyright (C) Miroslav Lichvar  2011, 2014-2015
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of version 2 of the GNU General Public License as
  * published by the Free Software Foundation.
  *
  * 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.
  *
  **********************************************************************

   =======================================================================

   The routines in this file present a common local (system) clock
   interface to the rest of the software.

   They interface with the system specific driver files in sys_*.c
   */

 #include "config.h"

 #include "sysincl.h"

 #include "conf.h"
 #include "local.h"
 #include "localp.h"
 #include "memory.h"
 #include "smooth.h"
 #include "util.h"
 #include "logging.h"

 /* ================================================== */

 /* Variable to store the current frequency, in ppm */
 static double current_freq_ppm;

 /* Maximum allowed frequency, in ppm */
 static double max_freq_ppm;

 /* Temperature compensation, in ppm */
 static double temp_comp_ppm;

 /* ================================================== */
 /* Store the system dependent drivers */

 static lcl_ReadFrequencyDriver drv_read_freq;
 static lcl_SetFrequencyDriver drv_set_freq;
 static lcl_AccrueOffsetDriver drv_accrue_offset;
 static lcl_ApplyStepOffsetDriver drv_apply_step_offset;
 static lcl_OffsetCorrectionDriver drv_offset_convert;
 static lcl_SetLeapDriver drv_set_leap;
 static lcl_SetSyncStatusDriver drv_set_sync_status;

 /* ================================================== */

 /* Types and variables associated with handling the parameter change
    list */

 typedef struct _ChangeListEntry {
   struct _ChangeListEntry *next;
   struct _ChangeListEntry *prev;
   LCL_ParameterChangeHandler handler;
   void *anything;
 } ChangeListEntry;

 static ChangeListEntry change_list;

 /* ================================================== */

 /* Types and variables associated with handling the parameter change
    list */

 typedef struct _DispersionNotifyListEntry {
   struct _DispersionNotifyListEntry *next;
   struct _DispersionNotifyListEntry *prev;
   LCL_DispersionNotifyHandler handler;
   void *anything;
 } DispersionNotifyListEntry;

 static DispersionNotifyListEntry dispersion_notify_list;

 /* ================================================== */

 static int precision_log;
 static double precision_quantum;

 static double max_clock_error;

 /* ================================================== */

 /* Define the number of increments of the system clock that we want
    to see to be fairly sure that we've got something approaching
    the minimum increment.  Even on a crummy implementation that can't
    interpolate between 10ms ticks, we should get this done in
    under 1s of busy waiting. */
 #define NITERS 100

 #define NSEC_PER_SEC 1000000000

 static double
 measure_clock_precision(void)
 {
   struct timespec ts, old_ts;
   int iters, diff, best;

   LCL_ReadRawTime(&old_ts);

   /* Assume we must be better than a second */
   best = NSEC_PER_SEC;
   iters = 0;

   do {
     LCL_ReadRawTime(&ts);

     diff = NSEC_PER_SEC * (ts.tv_sec - old_ts.tv_sec) + (ts.tv_nsec - old_ts.tv_nsec);

     old_ts = ts;
     if (diff > 0) {
       if (diff < best)
         best = diff;
       iters++;
     }
   } while (iters < NITERS);

   assert(best > 0);

   return 1.0e-9 * best;
 }

 /* ================================================== */

 void
 LCL_Initialise(void)
 {
   change_list.next = change_list.prev = &change_list;

   dispersion_notify_list.next = dispersion_notify_list.prev = &dispersion_notify_list;

   /* Null out the system drivers, so that we die
      if they never get defined before use */

   drv_read_freq = NULL;
   drv_set_freq = NULL;
   drv_accrue_offset = NULL;
   drv_offset_convert = NULL;

   /* This ought to be set from the system driver layer */
   current_freq_ppm = 0.0;
   temp_comp_ppm = 0.0;

   precision_quantum = CNF_GetClockPrecision();
   if (precision_quantum <= 0.0)
     precision_quantum = measure_clock_precision();

   precision_quantum = CLAMP(1.0e-9, precision_quantum, 1.0);
   precision_log = round(log(precision_quantum) / log(2.0));
   /* NTP code doesn't support smaller log than -30 */
   assert(precision_log >= -30);

   DEBUG_LOG("Clock precision %.9f (%d)", precision_quantum, precision_log);

   /* This is the maximum allowed frequency offset in ppm, the time must
      never stop or run backwards */
   max_freq_ppm = CNF_GetMaxDrift();
   max_freq_ppm = CLAMP(0.0, max_freq_ppm, 500000.0);

   max_clock_error = CNF_GetMaxClockError() * 1e-6;
 }

 /* ================================================== */

 void
 LCL_Finalise(void)
 {
   /* Make sure all handlers have been removed */
   if (change_list.next != &change_list)
     assert(0);
   if (dispersion_notify_list.next != &dispersion_notify_list)
     assert(0);
 }

 /* ================================================== */

 /* Routine to read the system precision as a log to base 2 value. */
 int
 LCL_GetSysPrecisionAsLog(void)
 {
   return precision_log;
 }

 /* ================================================== */
 /* Routine to read the system precision in terms of the actual time step */

 double
 LCL_GetSysPrecisionAsQuantum(void)
 {
   return precision_quantum;
 }

 /* ================================================== */

 double
 LCL_GetMaxClockError(void)
 {
   return max_clock_error;
 }

 /* ================================================== */

 void
 LCL_AddParameterChangeHandler(LCL_ParameterChangeHandler handler, void *anything)
 {
   ChangeListEntry *ptr, *new_entry;

   /* Check that the handler is not already registered */
   for (ptr = change_list.next; ptr != &change_list; ptr = ptr->next) {
     if (!(ptr->handler != handler || ptr->anything != anything)) {
       assert(0);
     }
   }

   new_entry = MallocNew(ChangeListEntry);

   new_entry->handler = handler;
   new_entry->anything = anything;

   /* Chain it into the list */
   new_entry->next = &change_list;
   new_entry->prev = change_list.prev;
   change_list.prev->next = new_entry;
   change_list.prev = new_entry;
 }

 /* ================================================== */

 /* Remove a handler */
 void LCL_RemoveParameterChangeHandler(LCL_ParameterChangeHandler handler, void *anything)
 {

   ChangeListEntry *ptr;
   int ok;

   ptr = NULL;
   ok = 0;

   for (ptr = change_list.next; ptr != &change_list; ptr = ptr->next) {
     if (ptr->handler == handler && ptr->anything == anything) {
       ok = 1;
       break;
     }
   }

   assert(ok);

   /* Unlink entry from the list */
   ptr->next->prev = ptr->prev;
   ptr->prev->next = ptr->next;

   Free(ptr);
 }

 /* ================================================== */

 int
 LCL_IsFirstParameterChangeHandler(LCL_ParameterChangeHandler handler)
 {
   return change_list.next->handler == handler;
 }

 /* ================================================== */

 static void
 invoke_parameter_change_handlers(struct timespec *raw, struct timespec *cooked,
                                  double dfreq, double doffset,
                                  LCL_ChangeType change_type)
 {
   ChangeListEntry *ptr;

   for (ptr = change_list.next; ptr != &change_list; ptr = ptr->next) {
     (ptr->handler)(raw, cooked, dfreq, doffset, change_type, ptr->anything);
   }
 }

 /* ================================================== */

 void
 LCL_AddDispersionNotifyHandler(LCL_DispersionNotifyHandler handler, void *anything)
 {
   DispersionNotifyListEntry *ptr, *new_entry;

   /* Check that the handler is not already registered */
   for (ptr = dispersion_notify_list.next; ptr != &dispersion_notify_list; ptr = ptr->next) {
     if (!(ptr->handler != handler || ptr->anything != anything)) {
       assert(0);
     }
   }

   new_entry = MallocNew(DispersionNotifyListEntry);

   new_entry->handler = handler;
   new_entry->anything = anything;

   /* Chain it into the list */
   new_entry->next = &dispersion_notify_list;
   new_entry->prev = dispersion_notify_list.prev;
   dispersion_notify_list.prev->next = new_entry;
   dispersion_notify_list.prev = new_entry;
 }

 /* ================================================== */

 /* Remove a handler */
 extern
 void LCL_RemoveDispersionNotifyHandler(LCL_DispersionNotifyHandler handler, void *anything)
 {

   DispersionNotifyListEntry *ptr;
   int ok;

   ptr = NULL;
   ok = 0;

   for (ptr = dispersion_notify_list.next; ptr != &dispersion_notify_list; ptr = ptr->next) {
     if (ptr->handler == handler && ptr->anything == anything) {
       ok = 1;
       break;
     }
   }

   assert(ok);

   /* Unlink entry from the list */
   ptr->next->prev = ptr->prev;
   ptr->prev->next = ptr->next;

   Free(ptr);
 }

 /* ================================================== */

 void
 LCL_ReadRawTime(struct timespec *ts)
 {
 #if HAVE_CLOCK_GETTIME
   if (clock_gettime(CLOCK_REALTIME, ts) < 0)
     LOG_FATAL("clock_gettime() failed : %s", strerror(errno));
 #else
   struct timeval tv;

   if (gettimeofday(&tv, NULL) < 0)
     LOG_FATAL("gettimeofday() failed : %s", strerror(errno));

   UTI_TimevalToTimespec(&tv, ts);
 #endif
 }

 /* ================================================== */

 void
 LCL_ReadCookedTime(struct timespec *result, double *err)
 {
   struct timespec raw;

   LCL_ReadRawTime(&raw);
   LCL_CookTime(&raw, result, err);
 }

 /* ================================================== */

 void
 LCL_CookTime(struct timespec *raw, struct timespec *cooked, double *err)
 {
   double correction;

   LCL_GetOffsetCorrection(raw, &correction, err);
   UTI_AddDoubleToTimespec(raw, correction, cooked);
 }

 /* ================================================== */

 void
 LCL_GetOffsetCorrection(struct timespec *raw, double *correction, double *err)
 {
   /* Call system specific driver to get correction */
   (*drv_offset_convert)(raw, correction, err);
 }

 /* ================================================== */
 /* Return current frequency */

 double
 LCL_ReadAbsoluteFrequency(void)
 {
   double freq;

   freq = current_freq_ppm;

   /* Undo temperature compensation */
   if (temp_comp_ppm != 0.0) {
     freq = (freq + temp_comp_ppm) / (1.0 - 1.0e-6 * temp_comp_ppm);
   }

   return freq;
 }

 /* ================================================== */

 static double
 clamp_freq(double freq)
 {
   if (freq <= max_freq_ppm && freq >= -max_freq_ppm)
     return freq;

   LOG(LOGS_WARN, "Frequency %.1f ppm exceeds allowed maximum", freq);

   return CLAMP(-max_freq_ppm, freq, max_freq_ppm);
 }

 /* ================================================== */

 static int
 check_offset(struct timespec *now, double offset)
 {
   /* Check if the time will be still sane with accumulated offset */
   if (UTI_IsTimeOffsetSane(now, -offset))
       return 1;

   LOG(LOGS_WARN, "Adjustment of %.1f seconds is invalid", -offset);
   return 0;
 }

 /* ================================================== */

 /* This involves both setting the absolute frequency with the
    system-specific driver, as well as calling all notify handlers */

 void
 LCL_SetAbsoluteFrequency(double afreq_ppm)
 {
   struct timespec raw, cooked;
   double dfreq;

   afreq_ppm = clamp_freq(afreq_ppm);

   /* Apply temperature compensation */
   if (temp_comp_ppm != 0.0) {
     afreq_ppm = afreq_ppm * (1.0 - 1.0e-6 * temp_comp_ppm) - temp_comp_ppm;
   }

   /* Call the system-specific driver for setting the frequency */

   afreq_ppm = (*drv_set_freq)(afreq_ppm);

   dfreq = (afreq_ppm - current_freq_ppm) / (1.0e6 - current_freq_ppm);

   LCL_ReadRawTime(&raw);
   LCL_CookTime(&raw, &cooked, NULL);

   /* Dispatch to all handlers */
   invoke_parameter_change_handlers(&raw, &cooked, dfreq, 0.0, LCL_ChangeAdjust);

   current_freq_ppm = afreq_ppm;

 }

 /* ================================================== */

 void
 LCL_AccumulateDeltaFrequency(double dfreq)
 {
   struct timespec raw, cooked;
   double old_freq_ppm;

   old_freq_ppm = current_freq_ppm;

   /* Work out new absolute frequency.  Note that absolute frequencies
    are handled in units of ppm, whereas the 'dfreq' argument is in
    terms of the gradient of the (offset) v (local time) function. */

   current_freq_ppm += dfreq * (1.0e6 - current_freq_ppm);

   current_freq_ppm = clamp_freq(current_freq_ppm);

   /* Call the system-specific driver for setting the frequency */
   current_freq_ppm = (*drv_set_freq)(current_freq_ppm);
   dfreq = (current_freq_ppm - old_freq_ppm) / (1.0e6 - old_freq_ppm);

   LCL_ReadRawTime(&raw);
   LCL_CookTime(&raw, &cooked, NULL);

   /* Dispatch to all handlers */
   invoke_parameter_change_handlers(&raw, &cooked, dfreq, 0.0, LCL_ChangeAdjust);
 }

 /* ================================================== */

 int
 LCL_AccumulateOffset(double offset, double corr_rate)
 {
   struct timespec raw, cooked;

   /* In this case, the cooked time to be passed to the notify clients
      has to be the cooked time BEFORE the change was made */

   LCL_ReadRawTime(&raw);
   LCL_CookTime(&raw, &cooked, NULL);

   if (!check_offset(&cooked, offset))
     return 0;

   (*drv_accrue_offset)(offset, corr_rate);

   /* Dispatch to all handlers */
   invoke_parameter_change_handlers(&raw, &cooked, 0.0, offset, LCL_ChangeAdjust);

   return 1;
 }

 /* ================================================== */

 int
 LCL_ApplyStepOffset(double offset)
 {
   struct timespec raw, cooked;

   /* In this case, the cooked time to be passed to the notify clients
      has to be the cooked time BEFORE the change was made */

   LCL_ReadRawTime(&raw);
   LCL_CookTime(&raw, &cooked, NULL);

   if (!check_offset(&raw, offset))
       return 0;

   if (!(*drv_apply_step_offset)(offset)) {
     LOG(LOGS_ERR, "Could not step system clock");
     return 0;
   }

   /* Reset smoothing on all clock steps */
   SMT_Reset(&cooked);

   /* Dispatch to all handlers */
   invoke_parameter_change_handlers(&raw, &cooked, 0.0, offset, LCL_ChangeStep);

   return 1;
 }

 /* ================================================== */

 void
 LCL_NotifyExternalTimeStep(struct timespec *raw, struct timespec *cooked,
     double offset, double dispersion)
 {
   /* Dispatch to all handlers */
   invoke_parameter_change_handlers(raw, cooked, 0.0, offset, LCL_ChangeUnknownStep);

   lcl_InvokeDispersionNotifyHandlers(dispersion);
 }

 /* ================================================== */

 void
 LCL_NotifyLeap(int leap)
 {
   struct timespec raw, cooked;

   LCL_ReadRawTime(&raw);
   LCL_CookTime(&raw, &cooked, NULL);

   /* Smooth the leap second out */
   SMT_Leap(&cooked, leap);

   /* Dispatch to all handlers as if the clock was stepped */
   invoke_parameter_change_handlers(&raw, &cooked, 0.0, -leap, LCL_ChangeStep);
 }

 /* ================================================== */

 int
 LCL_AccumulateFrequencyAndOffset(double dfreq, double doffset, double corr_rate)
 {
   struct timespec raw, cooked;
   double old_freq_ppm;

   LCL_ReadRawTime(&raw);
   /* Due to modifying the offset, this has to be the cooked time prior
      to the change we are about to make */
   LCL_CookTime(&raw, &cooked, NULL);

   if (!check_offset(&cooked, doffset))
     return 0;

   old_freq_ppm = current_freq_ppm;

   /* Work out new absolute frequency.  Note that absolute frequencies
    are handled in units of ppm, whereas the 'dfreq' argument is in
    terms of the gradient of the (offset) v (local time) function. */
   current_freq_ppm += dfreq * (1.0e6 - current_freq_ppm);

   current_freq_ppm = clamp_freq(current_freq_ppm);

   DEBUG_LOG("old_freq=%.3fppm new_freq=%.3fppm offset=%.6fsec",
       old_freq_ppm, current_freq_ppm, doffset);

   /* Call the system-specific driver for setting the frequency */
   current_freq_ppm = (*drv_set_freq)(current_freq_ppm);
   dfreq = (current_freq_ppm - old_freq_ppm) / (1.0e6 - old_freq_ppm);

   (*drv_accrue_offset)(doffset, corr_rate);

   /* Dispatch to all handlers */
   invoke_parameter_change_handlers(&raw, &cooked, dfreq, doffset, LCL_ChangeAdjust);

   return 1;
 }

 /* ================================================== */

 void
 lcl_InvokeDispersionNotifyHandlers(double dispersion)
 {
   DispersionNotifyListEntry *ptr;

   for (ptr = dispersion_notify_list.next; ptr != &dispersion_notify_list; ptr = ptr->next) {
     (ptr->handler)(dispersion, ptr->anything);
   }

 }

 /* ================================================== */

 void
 lcl_RegisterSystemDrivers(lcl_ReadFrequencyDriver read_freq,
                           lcl_SetFrequencyDriver set_freq,
                           lcl_AccrueOffsetDriver accrue_offset,
                           lcl_ApplyStepOffsetDriver apply_step_offset,
                           lcl_OffsetCorrectionDriver offset_convert,
                           lcl_SetLeapDriver set_leap,
                           lcl_SetSyncStatusDriver set_sync_status)
 {
   drv_read_freq = read_freq;
   drv_set_freq = set_freq;
   drv_accrue_offset = accrue_offset;
   drv_apply_step_offset = apply_step_offset;
   drv_offset_convert = offset_convert;
   drv_set_leap = set_leap;
   drv_set_sync_status = set_sync_status;

   current_freq_ppm = (*drv_read_freq)();

   DEBUG_LOG("Local freq=%.3fppm", current_freq_ppm);
 }

 /* ================================================== */
 /* Look at the current difference between the system time and the NTP
    time, and make a step to cancel it. */

 int
 LCL_MakeStep(void)
 {
   struct timespec raw;
   double correction;

   LCL_ReadRawTime(&raw);
   LCL_GetOffsetCorrection(&raw, &correction, NULL);

   if (!check_offset(&raw, -correction))
       return 0;

   /* Cancel remaining slew and make the step */
   LCL_AccumulateOffset(correction, 0.0);
   if (!LCL_ApplyStepOffset(-correction))
     return 0;

   LOG(LOGS_WARN, "System clock was stepped by %.6f seconds", correction);

   return 1;
 }

 /* ================================================== */

 void
 LCL_CancelOffsetCorrection(void)
 {
   struct timespec raw;
   double correction;

   LCL_ReadRawTime(&raw);
   LCL_GetOffsetCorrection(&raw, &correction, NULL);
   LCL_AccumulateOffset(correction, 0.0);
 }

 /* ================================================== */

 int
 LCL_CanSystemLeap(void)
 {
   return drv_set_leap ? 1 : 0;
 }

 /* ================================================== */

 void
 LCL_SetSystemLeap(int leap, int tai_offset)
 {
   if (drv_set_leap) {
     (drv_set_leap)(leap, tai_offset);
   }
 }

 /* ================================================== */

 double
 LCL_SetTempComp(double comp)
 {
   double uncomp_freq_ppm;

   if (temp_comp_ppm == comp)
     return comp;

   /* Undo previous compensation */
   current_freq_ppm = (current_freq_ppm + temp_comp_ppm) /
     (1.0 - 1.0e-6 * temp_comp_ppm);

   uncomp_freq_ppm = current_freq_ppm;

   /* Apply new compensation */
   current_freq_ppm = current_freq_ppm * (1.0 - 1.0e-6 * comp) - comp;

   /* Call the system-specific driver for setting the frequency */
   current_freq_ppm = (*drv_set_freq)(current_freq_ppm);

   temp_comp_ppm = (uncomp_freq_ppm - current_freq_ppm) /
     (1.0e-6 * uncomp_freq_ppm + 1.0);

   return temp_comp_ppm;
 }

 /* ================================================== */

 void
 LCL_SetSyncStatus(int synchronised, double est_error, double max_error)
 {
   if (drv_set_sync_status) {
     (drv_set_sync_status)(synchronised, est_error, max_error);
   }
 }

 /* ================================================== */
	/*
	chronyd/chronyc - Programs for keeping computer clocks accurate.

	**********************************************************************
	* Copyright (C) Richard P. Curnow 1997-2003
	* Copyright (C) Miroslav Lichvar 2011, 2014-2015
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of version 2 of the GNU General Public License as
	* published by the Free Software Foundation.
	*
	* 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.
	*
	**********************************************************************

	=======================================================================

	The routines in this file present a common local (system) clock
	interface to the rest of the software.

	They interface with the system specific driver files in sys_*.c
	*/

	#include "config.h"

	#include "sysincl.h"

	#include "conf.h"
	#include "local.h"
	#include "localp.h"
	#include "memory.h"
	#include "smooth.h"
	#include "util.h"
	#include "logging.h"

	/* ================================================== */

	/* Variable to store the current frequency, in ppm */
	static double current_freq_ppm;

	/* Maximum allowed frequency, in ppm */
	static double max_freq_ppm;

	/* Temperature compensation, in ppm */
	static double temp_comp_ppm;

	/* ================================================== */
	/* Store the system dependent drivers */

	static lcl_ReadFrequencyDriver drv_read_freq;
	static lcl_SetFrequencyDriver drv_set_freq;
	static lcl_AccrueOffsetDriver drv_accrue_offset;
	static lcl_ApplyStepOffsetDriver drv_apply_step_offset;
	static lcl_OffsetCorrectionDriver drv_offset_convert;
	static lcl_SetLeapDriver drv_set_leap;
	static lcl_SetSyncStatusDriver drv_set_sync_status;

	/* ================================================== */

	/* Types and variables associated with handling the parameter change
	list */

	typedef struct _ChangeListEntry {
	struct _ChangeListEntry *next;
	struct _ChangeListEntry *prev;
	LCL_ParameterChangeHandler handler;
	void *anything;
	} ChangeListEntry;

	static ChangeListEntry change_list;

	/* ================================================== */

	/* Types and variables associated with handling the parameter change
	list */

	typedef struct _DispersionNotifyListEntry {
	struct _DispersionNotifyListEntry *next;
	struct _DispersionNotifyListEntry *prev;
	LCL_DispersionNotifyHandler handler;
	void *anything;
	} DispersionNotifyListEntry;

	static DispersionNotifyListEntry dispersion_notify_list;

	/* ================================================== */

	static int precision_log;
	static double precision_quantum;

	static double max_clock_error;

	/* ================================================== */

	/* Define the number of increments of the system clock that we want
	to see to be fairly sure that we've got something approaching
	the minimum increment. Even on a crummy implementation that can't
	interpolate between 10ms ticks, we should get this done in
	under 1s of busy waiting. */
	#define NITERS 100

	#define NSEC_PER_SEC 1000000000

	static double
	measure_clock_precision(void)
	{
	struct timespec ts, old_ts;
	int iters, diff, best;

	LCL_ReadRawTime(&old_ts);

	/* Assume we must be better than a second */
	best = NSEC_PER_SEC;
	iters = 0;

	do {
	LCL_ReadRawTime(&ts);

	diff = NSEC_PER_SEC * (ts.tv_sec - old_ts.tv_sec) + (ts.tv_nsec - old_ts.tv_nsec);

	old_ts = ts;
	if (diff > 0) {
	if (diff < best)
	best = diff;
	iters++;
	}
	} while (iters < NITERS);

	assert(best > 0);

	return 1.0e-9 * best;
	}

	/* ================================================== */

	void
	LCL_Initialise(void)
	{
	change_list.next = change_list.prev = &change_list;

	dispersion_notify_list.next = dispersion_notify_list.prev = &dispersion_notify_list;

	/* Null out the system drivers, so that we die
	if they never get defined before use */

	drv_read_freq = NULL;
	drv_set_freq = NULL;
	drv_accrue_offset = NULL;
	drv_offset_convert = NULL;

	/* This ought to be set from the system driver layer */
	current_freq_ppm = 0.0;
	temp_comp_ppm = 0.0;

	precision_quantum = CNF_GetClockPrecision();
	if (precision_quantum <= 0.0)
	precision_quantum = measure_clock_precision();

	precision_quantum = CLAMP(1.0e-9, precision_quantum, 1.0);
	precision_log = round(log(precision_quantum) / log(2.0));
	/* NTP code doesn't support smaller log than -30 */
	assert(precision_log >= -30);

	DEBUG_LOG("Clock precision %.9f (%d)", precision_quantum, precision_log);

	/* This is the maximum allowed frequency offset in ppm, the time must
	never stop or run backwards */
	max_freq_ppm = CNF_GetMaxDrift();
	max_freq_ppm = CLAMP(0.0, max_freq_ppm, 500000.0);

	max_clock_error = CNF_GetMaxClockError() * 1e-6;
	}

	/* ================================================== */

	void
	LCL_Finalise(void)
	{
	/* Make sure all handlers have been removed */
	if (change_list.next != &change_list)
	assert(0);
	if (dispersion_notify_list.next != &dispersion_notify_list)
	assert(0);
	}

	/* ================================================== */

	/* Routine to read the system precision as a log to base 2 value. */
	int
	LCL_GetSysPrecisionAsLog(void)
	{
	return precision_log;
	}

	/* ================================================== */
	/* Routine to read the system precision in terms of the actual time step */

	double
	LCL_GetSysPrecisionAsQuantum(void)
	{
	return precision_quantum;
	}

	/* ================================================== */

	double
	LCL_GetMaxClockError(void)
	{
	return max_clock_error;
	}

	/* ================================================== */

	void
	LCL_AddParameterChangeHandler(LCL_ParameterChangeHandler handler, void *anything)
	{
	ChangeListEntry ptr, new_entry;

	/* Check that the handler is not already registered */
	for (ptr = change_list.next; ptr != &change_list; ptr = ptr->next) {
	if (!(ptr->handler != handler \|\| ptr->anything != anything)) {
	assert(0);
	}
	}

	new_entry = MallocNew(ChangeListEntry);

	new_entry->handler = handler;
	new_entry->anything = anything;

	/* Chain it into the list */
	new_entry->next = &change_list;
	new_entry->prev = change_list.prev;
	change_list.prev->next = new_entry;
	change_list.prev = new_entry;
	}

	/* ================================================== */

	/* Remove a handler */
	void LCL_RemoveParameterChangeHandler(LCL_ParameterChangeHandler handler, void *anything)
	{

	ChangeListEntry *ptr;
	int ok;

	ptr = NULL;
	ok = 0;

	for (ptr = change_list.next; ptr != &change_list; ptr = ptr->next) {
	if (ptr->handler == handler && ptr->anything == anything) {
	ok = 1;
	break;
	}
	}

	assert(ok);

	/* Unlink entry from the list */
	ptr->next->prev = ptr->prev;
	ptr->prev->next = ptr->next;

	Free(ptr);
	}

	/* ================================================== */

	int
	LCL_IsFirstParameterChangeHandler(LCL_ParameterChangeHandler handler)
	{
	return change_list.next->handler == handler;
	}

	/* ================================================== */

	static void
	invoke_parameter_change_handlers(struct timespec raw, struct timespec cooked,
	double dfreq, double doffset,
	LCL_ChangeType change_type)
	{
	ChangeListEntry *ptr;

	for (ptr = change_list.next; ptr != &change_list; ptr = ptr->next) {
	(ptr->handler)(raw, cooked, dfreq, doffset, change_type, ptr->anything);
	}
	}

	/* ================================================== */

	void
	LCL_AddDispersionNotifyHandler(LCL_DispersionNotifyHandler handler, void *anything)
	{
	DispersionNotifyListEntry ptr, new_entry;

	/* Check that the handler is not already registered */
	for (ptr = dispersion_notify_list.next; ptr != &dispersion_notify_list; ptr = ptr->next) {
	if (!(ptr->handler != handler \|\| ptr->anything != anything)) {
	assert(0);
	}
	}

	new_entry = MallocNew(DispersionNotifyListEntry);

	new_entry->handler = handler;
	new_entry->anything = anything;

	/* Chain it into the list */
	new_entry->next = &dispersion_notify_list;
	new_entry->prev = dispersion_notify_list.prev;
	dispersion_notify_list.prev->next = new_entry;
	dispersion_notify_list.prev = new_entry;
	}

	/* ================================================== */

	/* Remove a handler */
	extern
	void LCL_RemoveDispersionNotifyHandler(LCL_DispersionNotifyHandler handler, void *anything)
	{

	DispersionNotifyListEntry *ptr;
	int ok;

	ptr = NULL;
	ok = 0;

	for (ptr = dispersion_notify_list.next; ptr != &dispersion_notify_list; ptr = ptr->next) {
	if (ptr->handler == handler && ptr->anything == anything) {
	ok = 1;
	break;
	}
	}

	assert(ok);

	/* Unlink entry from the list */
	ptr->next->prev = ptr->prev;
	ptr->prev->next = ptr->next;

	Free(ptr);
	}

	/* ================================================== */

	void
	LCL_ReadRawTime(struct timespec *ts)
	{
	#if HAVE_CLOCK_GETTIME
	if (clock_gettime(CLOCK_REALTIME, ts) < 0)
	LOG_FATAL("clock_gettime() failed : %s", strerror(errno));
	#else
	struct timeval tv;

	if (gettimeofday(&tv, NULL) < 0)
	LOG_FATAL("gettimeofday() failed : %s", strerror(errno));

	UTI_TimevalToTimespec(&tv, ts);
	#endif
	}

	/* ================================================== */

	void
	LCL_ReadCookedTime(struct timespec result, double err)
	{
	struct timespec raw;

	LCL_ReadRawTime(&raw);
	LCL_CookTime(&raw, result, err);
	}

	/* ================================================== */

	void
	LCL_CookTime(struct timespec raw, struct timespec cooked, double *err)
	{
	double correction;

	LCL_GetOffsetCorrection(raw, &correction, err);
	UTI_AddDoubleToTimespec(raw, correction, cooked);
	}

	/* ================================================== */

	void
	LCL_GetOffsetCorrection(struct timespec raw, double correction, double *err)
	{
	/* Call system specific driver to get correction */
	(*drv_offset_convert)(raw, correction, err);
	}

	/* ================================================== */
	/* Return current frequency */

	double
	LCL_ReadAbsoluteFrequency(void)
	{
	double freq;

	freq = current_freq_ppm;

	/* Undo temperature compensation */
	if (temp_comp_ppm != 0.0) {
	freq = (freq + temp_comp_ppm) / (1.0 - 1.0e-6 * temp_comp_ppm);
	}

	return freq;
	}

	/* ================================================== */

	static double
	clamp_freq(double freq)
	{
	if (freq <= max_freq_ppm && freq >= -max_freq_ppm)
	return freq;

	LOG(LOGS_WARN, "Frequency %.1f ppm exceeds allowed maximum", freq);

	return CLAMP(-max_freq_ppm, freq, max_freq_ppm);
	}

	/* ================================================== */

	static int
	check_offset(struct timespec *now, double offset)
	{
	/* Check if the time will be still sane with accumulated offset */
	if (UTI_IsTimeOffsetSane(now, -offset))
	return 1;

	LOG(LOGS_WARN, "Adjustment of %.1f seconds is invalid", -offset);
	return 0;
	}

	/* ================================================== */

	/* This involves both setting the absolute frequency with the
	system-specific driver, as well as calling all notify handlers */

	void
	LCL_SetAbsoluteFrequency(double afreq_ppm)
	{
	struct timespec raw, cooked;
	double dfreq;

	afreq_ppm = clamp_freq(afreq_ppm);

	/* Apply temperature compensation */
	if (temp_comp_ppm != 0.0) {
	afreq_ppm = afreq_ppm * (1.0 - 1.0e-6 * temp_comp_ppm) - temp_comp_ppm;
	}

	/* Call the system-specific driver for setting the frequency */

	afreq_ppm = (*drv_set_freq)(afreq_ppm);

	dfreq = (afreq_ppm - current_freq_ppm) / (1.0e6 - current_freq_ppm);

	LCL_ReadRawTime(&raw);
	LCL_CookTime(&raw, &cooked, NULL);

	/* Dispatch to all handlers */
	invoke_parameter_change_handlers(&raw, &cooked, dfreq, 0.0, LCL_ChangeAdjust);

	current_freq_ppm = afreq_ppm;

	}

	/* ================================================== */

	void
	LCL_AccumulateDeltaFrequency(double dfreq)
	{
	struct timespec raw, cooked;
	double old_freq_ppm;

	old_freq_ppm = current_freq_ppm;

	/* Work out new absolute frequency. Note that absolute frequencies
	are handled in units of ppm, whereas the 'dfreq' argument is in
	terms of the gradient of the (offset) v (local time) function. */

	current_freq_ppm += dfreq * (1.0e6 - current_freq_ppm);

	current_freq_ppm = clamp_freq(current_freq_ppm);

	/* Call the system-specific driver for setting the frequency */
	current_freq_ppm = (*drv_set_freq)(current_freq_ppm);
	dfreq = (current_freq_ppm - old_freq_ppm) / (1.0e6 - old_freq_ppm);

	LCL_ReadRawTime(&raw);
	LCL_CookTime(&raw, &cooked, NULL);

	/* Dispatch to all handlers */
	invoke_parameter_change_handlers(&raw, &cooked, dfreq, 0.0, LCL_ChangeAdjust);
	}

	/* ================================================== */

	int
	LCL_AccumulateOffset(double offset, double corr_rate)
	{
	struct timespec raw, cooked;

	/* In this case, the cooked time to be passed to the notify clients
	has to be the cooked time BEFORE the change was made */

	LCL_ReadRawTime(&raw);
	LCL_CookTime(&raw, &cooked, NULL);

	if (!check_offset(&cooked, offset))
	return 0;

	(*drv_accrue_offset)(offset, corr_rate);

	/* Dispatch to all handlers */
	invoke_parameter_change_handlers(&raw, &cooked, 0.0, offset, LCL_ChangeAdjust);

	return 1;
	}

	/* ================================================== */

	int
	LCL_ApplyStepOffset(double offset)
	{
	struct timespec raw, cooked;

	/* In this case, the cooked time to be passed to the notify clients
	has to be the cooked time BEFORE the change was made */

	LCL_ReadRawTime(&raw);
	LCL_CookTime(&raw, &cooked, NULL);

	if (!check_offset(&raw, offset))
	return 0;

	if (!(*drv_apply_step_offset)(offset)) {
	LOG(LOGS_ERR, "Could not step system clock");
	return 0;
	}

	/* Reset smoothing on all clock steps */
	SMT_Reset(&cooked);

	/* Dispatch to all handlers */
	invoke_parameter_change_handlers(&raw, &cooked, 0.0, offset, LCL_ChangeStep);

	return 1;
	}

	/* ================================================== */

	void
	LCL_NotifyExternalTimeStep(struct timespec raw, struct timespec cooked,
	double offset, double dispersion)
	{
	/* Dispatch to all handlers */
	invoke_parameter_change_handlers(raw, cooked, 0.0, offset, LCL_ChangeUnknownStep);

	lcl_InvokeDispersionNotifyHandlers(dispersion);
	}

	/* ================================================== */

	void
	LCL_NotifyLeap(int leap)
	{
	struct timespec raw, cooked;

	LCL_ReadRawTime(&raw);
	LCL_CookTime(&raw, &cooked, NULL);

	/* Smooth the leap second out */
	SMT_Leap(&cooked, leap);

	/* Dispatch to all handlers as if the clock was stepped */
	invoke_parameter_change_handlers(&raw, &cooked, 0.0, -leap, LCL_ChangeStep);
	}

	/* ================================================== */

	int
	LCL_AccumulateFrequencyAndOffset(double dfreq, double doffset, double corr_rate)
	{
	struct timespec raw, cooked;
	double old_freq_ppm;

	LCL_ReadRawTime(&raw);
	/* Due to modifying the offset, this has to be the cooked time prior
	to the change we are about to make */
	LCL_CookTime(&raw, &cooked, NULL);

	if (!check_offset(&cooked, doffset))
	return 0;

	old_freq_ppm = current_freq_ppm;

	/* Work out new absolute frequency. Note that absolute frequencies
	are handled in units of ppm, whereas the 'dfreq' argument is in
	terms of the gradient of the (offset) v (local time) function. */
	current_freq_ppm += dfreq * (1.0e6 - current_freq_ppm);

	current_freq_ppm = clamp_freq(current_freq_ppm);

	DEBUG_LOG("old_freq=%.3fppm new_freq=%.3fppm offset=%.6fsec",
	old_freq_ppm, current_freq_ppm, doffset);

	/* Call the system-specific driver for setting the frequency */
	current_freq_ppm = (*drv_set_freq)(current_freq_ppm);
	dfreq = (current_freq_ppm - old_freq_ppm) / (1.0e6 - old_freq_ppm);

	(*drv_accrue_offset)(doffset, corr_rate);

	/* Dispatch to all handlers */
	invoke_parameter_change_handlers(&raw, &cooked, dfreq, doffset, LCL_ChangeAdjust);

	return 1;
	}

	/* ================================================== */

	void
	lcl_InvokeDispersionNotifyHandlers(double dispersion)
	{
	DispersionNotifyListEntry *ptr;

	for (ptr = dispersion_notify_list.next; ptr != &dispersion_notify_list; ptr = ptr->next) {
	(ptr->handler)(dispersion, ptr->anything);
	}

	}

	/* ================================================== */

	void
	lcl_RegisterSystemDrivers(lcl_ReadFrequencyDriver read_freq,
	lcl_SetFrequencyDriver set_freq,
	lcl_AccrueOffsetDriver accrue_offset,
	lcl_ApplyStepOffsetDriver apply_step_offset,
	lcl_OffsetCorrectionDriver offset_convert,
	lcl_SetLeapDriver set_leap,
	lcl_SetSyncStatusDriver set_sync_status)
	{
	drv_read_freq = read_freq;
	drv_set_freq = set_freq;
	drv_accrue_offset = accrue_offset;
	drv_apply_step_offset = apply_step_offset;
	drv_offset_convert = offset_convert;
	drv_set_leap = set_leap;
	drv_set_sync_status = set_sync_status;

	current_freq_ppm = (*drv_read_freq)();

	DEBUG_LOG("Local freq=%.3fppm", current_freq_ppm);
	}

	/* ================================================== */
	/* Look at the current difference between the system time and the NTP
	time, and make a step to cancel it. */

	int
	LCL_MakeStep(void)
	{
	struct timespec raw;
	double correction;

	LCL_ReadRawTime(&raw);
	LCL_GetOffsetCorrection(&raw, &correction, NULL);

	if (!check_offset(&raw, -correction))
	return 0;

	/* Cancel remaining slew and make the step */
	LCL_AccumulateOffset(correction, 0.0);
	if (!LCL_ApplyStepOffset(-correction))
	return 0;

	LOG(LOGS_WARN, "System clock was stepped by %.6f seconds", correction);

	return 1;
	}

	/* ================================================== */

	void
	LCL_CancelOffsetCorrection(void)
	{
	struct timespec raw;
	double correction;

	LCL_ReadRawTime(&raw);
	LCL_GetOffsetCorrection(&raw, &correction, NULL);
	LCL_AccumulateOffset(correction, 0.0);
	}

	/* ================================================== */

	int
	LCL_CanSystemLeap(void)
	{
	return drv_set_leap ? 1 : 0;
	}

	/* ================================================== */

	void
	LCL_SetSystemLeap(int leap, int tai_offset)
	{
	if (drv_set_leap) {
	(drv_set_leap)(leap, tai_offset);
	}
	}

	/* ================================================== */

	double
	LCL_SetTempComp(double comp)
	{
	double uncomp_freq_ppm;

	if (temp_comp_ppm == comp)
	return comp;

	/* Undo previous compensation */
	current_freq_ppm = (current_freq_ppm + temp_comp_ppm) /
	(1.0 - 1.0e-6 * temp_comp_ppm);

	uncomp_freq_ppm = current_freq_ppm;

	/* Apply new compensation */
	current_freq_ppm = current_freq_ppm * (1.0 - 1.0e-6 * comp) - comp;

	/* Call the system-specific driver for setting the frequency */
	current_freq_ppm = (*drv_set_freq)(current_freq_ppm);

	temp_comp_ppm = (uncomp_freq_ppm - current_freq_ppm) /
	(1.0e-6 * uncomp_freq_ppm + 1.0);

	return temp_comp_ppm;
	}

	/* ================================================== */

	void
	LCL_SetSyncStatus(int synchronised, double est_error, double max_error)
	{
	if (drv_set_sync_status) {
	(drv_set_sync_status)(synchronised, est_error, max_error);
	}
	}

	/* ================================================== */