Adding upstream version 4.5.upstream/4.5upstream

Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>

1 files changed, 1072 insertions, 0 deletions

diff --git a/rtc_linux.c b/rtc_linux.c
new file mode 100644
index 0000000..58b625b
--- /dev/null
+++ b/rtc_linux.c
@@ -0,0 +1,1072 @@
+/*
+  chronyd/chronyc - Programs for keeping computer clocks accurate.
+
+ **********************************************************************
+ * Copyright (C) Richard P. Curnow  1997-2003
+ * Copyright (C) Miroslav Lichvar  2012-2014
+ * 
+ * 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.
+ * 
+ **********************************************************************
+
+  =======================================================================
+
+  Real-time clock driver for linux.  This interfaces the program with
+  the clock that keeps time when the machine is turned off.
+
+  */
+
+#include "config.h"
+
+#include "sysincl.h"
+
+#include <linux/rtc.h>
+
+#include "logging.h"
+#include "sched.h"
+#include "local.h"
+#include "util.h"
+#include "sys_linux.h"
+#include "reference.h"
+#include "regress.h"
+#include "rtc.h"
+#include "rtc_linux.h"
+#include "conf.h"
+#include "memory.h"
+
+/* ================================================== */
+/* Forward prototypes */
+
+static void measurement_timeout(void *any);
+
+static void read_from_device(int fd_, int event, void *any);
+
+/* ================================================== */
+
+typedef enum {
+  OM_NORMAL,
+  OM_INITIAL,
+  OM_AFTERTRIM
+} OperatingMode;
+
+static OperatingMode operating_mode = OM_NORMAL;
+
+/* ================================================== */
+
+static int fd;
+
+#define LOWEST_MEASUREMENT_PERIOD 15
+#define HIGHEST_MEASUREMENT_PERIOD 480
+#define N_SAMPLES_PER_REGRESSION 1
+
+static int measurement_period = LOWEST_MEASUREMENT_PERIOD;
+
+static SCH_TimeoutID timeout_id = 0;
+
+static int skip_interrupts;
+
+/* ================================================== */
+
+/* Maximum number of samples held */
+#define MAX_SAMPLES 64
+
+/* Real time clock samples.  We store the seconds count as originally
+   measured. */
+static time_t *rtc_sec = NULL;
+
+/* Reference time, against which delta times on the RTC scale are measured */
+static time_t rtc_ref;
+
+/* System clock samples associated with the above samples. */
+static struct timespec *system_times = NULL;
+
+/* Number of samples currently stored. */
+static int n_samples;   
+
+/* Number of new samples since last regression */
+static int n_samples_since_regression;
+
+/* Number of runs of residuals in last regression (for logging) */
+static int n_runs;
+
+/* Coefficients */
+/* Whether they are valid */
+static int coefs_valid;
+
+/* Reference time */
+static time_t coef_ref_time;
+/* Number of seconds by which RTC was fast of the system time at coef_ref_time */
+static double coef_seconds_fast;
+
+/* Estimated number of seconds that RTC gains relative to system time
+   for each second of ITS OWN time */
+static double coef_gain_rate;
+
+/* Gain rate saved just before we step the RTC to correct it to the
+   nearest second, so that we can write a useful set of coefs to the
+   RTC data file once we have reacquired its offset after the step */
+static double saved_coef_gain_rate;
+
+/* Threshold for automatic RTC trimming in seconds, zero when disabled */
+static double autotrim_threshold;
+
+/* Filename supplied by config file where RTC coefficients are
+   stored. */
+static char *coefs_file_name;
+
+/* ================================================== */
+/* Coefficients read from file at start of run. */
+
+/* Whether we have tried to load the coefficients */
+static int tried_to_load_coefs = 0;
+
+/* Whether valid coefficients were read */
+static int valid_coefs_from_file = 0;
+
+/* Coefs read in */
+static time_t file_ref_time;
+static double file_ref_offset, file_rate_ppm;
+
+/* ================================================== */
+
+/* Flag to remember whether to assume the RTC is running on UTC */
+static int rtc_on_utc;
+
+/* ================================================== */
+
+static LOG_FileID logfileid;
+
+/* ================================================== */
+
+static void (*after_init_hook)(void *) = NULL;
+static void *after_init_hook_arg = NULL;
+
+/* ================================================== */
+
+static void
+discard_samples(int new_first)
+{
+  int n_to_save;
+
+  assert(new_first >= 0 && new_first < n_samples);
+
+  n_to_save = n_samples - new_first;
+
+  memmove(rtc_sec, rtc_sec + new_first, n_to_save * sizeof(time_t));
+  memmove(system_times, system_times + new_first, n_to_save * sizeof(struct timespec));
+
+  n_samples = n_to_save;
+}
+
+/* ================================================== */
+
+#define NEW_FIRST_WHEN_FULL 4
+
+static void
+accumulate_sample(time_t rtc, struct timespec *sys)
+{
+
+  if (n_samples == MAX_SAMPLES) {
+    /* Discard oldest samples */
+    discard_samples(NEW_FIRST_WHEN_FULL);
+  }
+
+  /* Discard all samples if the RTC was stepped back (not our trim) */
+  if (n_samples > 0 && rtc_sec[n_samples - 1] >= rtc) {
+    DEBUG_LOG("RTC samples discarded");
+    n_samples = 0;
+  }
+
+  /* Always use most recent sample as reference */
+  rtc_ref = rtc;
+  rtc_sec[n_samples] = rtc;
+  system_times[n_samples] = *sys;
+  ++n_samples_since_regression;
+  ++n_samples;
+}
+
+/* ================================================== */
+/* The new_sample flag is to indicate whether to adjust the
+   measurement period depending on the behaviour of the standard
+   deviation. */
+
+static void
+run_regression(int new_sample,
+               int *valid,
+               time_t *ref,
+               double *fast,
+               double *slope)
+{
+  double rtc_rel[MAX_SAMPLES]; /* Relative times on RTC axis */
+  double offsets[MAX_SAMPLES]; /* How much the RTC is fast of the system clock */
+  int i;
+  double est_intercept, est_slope;
+  int best_new_start;
+
+  if (n_samples > 0) {
+
+    for (i=0; i<n_samples; i++) {
+      rtc_rel[i] = (double)(rtc_sec[i] - rtc_ref);
+      offsets[i] = ((double) (rtc_ref - system_times[i].tv_sec) -
+                    (1.0e-9 * system_times[i].tv_nsec) +
+                    rtc_rel[i]);
+
+    }
+
+    if (RGR_FindBestRobustRegression
+        (rtc_rel, offsets,
+         n_samples, 1.0e-9,
+         &est_intercept, &est_slope,
+         &n_runs,
+         &best_new_start)) {
+
+      /* Calculate and store coefficients.  We don't do any error
+         bounds processing on any of these. */
+      *valid = 1;
+      *ref = rtc_ref;
+      *fast = est_intercept;
+      *slope = est_slope;
+
+      if (best_new_start > 0) {
+        discard_samples(best_new_start);
+      }
+
+
+    } else {
+      /* Keep existing coefficients. */
+    }
+  } else {
+    /* Keep existing coefficients. */
+  }
+
+}
+
+/* ================================================== */
+
+static void
+slew_samples
+(struct timespec *raw, struct timespec *cooked,
+ double dfreq,
+ double doffset,
+ LCL_ChangeType change_type,
+ void *anything)
+{
+  int i;
+  double delta_time;
+  double old_seconds_fast, old_gain_rate;
+
+  if (change_type == LCL_ChangeUnknownStep) {
+    /* Drop all samples. */
+    n_samples = 0;
+  }
+
+  for (i=0; i<n_samples; i++) {
+    UTI_AdjustTimespec(system_times + i, cooked, system_times + i, &delta_time,
+        dfreq, doffset);
+  }
+
+  old_seconds_fast = coef_seconds_fast;
+  old_gain_rate = coef_gain_rate;
+
+  if (coefs_valid) {
+    coef_seconds_fast += doffset;
+    coef_gain_rate += dfreq * (1.0 - coef_gain_rate);
+  }
+
+  DEBUG_LOG("dfreq=%.8f doffset=%.6f old_fast=%.6f old_rate=%.3f new_fast=%.6f new_rate=%.3f",
+      dfreq, doffset,
+      old_seconds_fast, 1.0e6 * old_gain_rate,
+      coef_seconds_fast, 1.0e6 * coef_gain_rate);
+}
+
+/* ================================================== */
+
+/* Function to convert from a time_t value represenging UTC to the
+   corresponding real time clock 'DMY HMS' form, taking account of
+   whether the user runs his RTC on the local time zone or UTC */
+
+static struct tm *
+rtc_from_t(const time_t *t)
+{
+  if (rtc_on_utc) {
+    return gmtime(t);
+  } else {
+    return localtime(t);
+  }
+}
+
+/* ================================================== */
+
+/* Inverse function to get back from RTC 'DMY HMS' form to time_t UTC
+   form.  This essentially uses mktime(), but involves some awful
+   complexity to cope with timezones.  The problem is that mktime's
+   behaviour with regard to the daylight saving flag in the 'struct
+   tm' does not seem to be reliable across all systems, unless that
+   flag is set to zero. 
+
+   tm_isdst = -1 does not seem to work with all libc's - it is treated
+   as meaning there is DST, or fails completely.  (It is supposed to
+   use the timezone info to work out whether summer time is active at
+   the specified epoch).
+
+   tm_isdst = 1 fails if the local timezone has no summer time defined.
+
+   The approach taken is as follows.  Suppose the RTC is on localtime.
+   We perform all mktime calls with the tm_isdst field set to zero.
+
+   Let y be the RTC reading in 'DMY HMS' form.  Let M be the mktime
+   function with tm_isdst=0 and L be the localtime function.
+
+   We seek x such that y = L(x).  Now there will exist a value Z(t)
+   such that M(L(t)) = t + Z(t) for all t, where Z(t) depends on
+   whether daylight saving is active at time t.
+
+   We want L(x) = y.  Therefore M(L(x)) = x + Z = M(y).  But
+   M(L(M(y))) = M(y) + Z.  Therefore x = M(y) - Z = M(y) - (M(L(M(y)))
+   - M(y)).
+
+   The case for the RTC running on UTC is identical but without the
+   potential complication that Z depends on t.
+*/
+
+static time_t
+t_from_rtc(struct tm *stm) {
+  struct tm temp1, temp2, *tm;
+  long diff;
+  time_t t1, t2;
+
+  temp1 = *stm;
+  temp1.tm_isdst = 0;
+  
+  t1 = mktime(&temp1);
+
+  tm = rtc_on_utc ? gmtime(&t1) : localtime(&t1);
+  if (!tm) {
+    DEBUG_LOG("gmtime()/localtime() failed");
+    return -1;
+  }
+
+  temp2 = *tm;
+  temp2.tm_isdst = 0;
+  t2 = mktime(&temp2);
+  diff = t2 - t1;
+
+  if (t1 - diff == -1)
+    DEBUG_LOG("Could not convert RTC time");
+
+  return t1 - diff;
+}
+
+/* ================================================== */
+
+static void
+read_hwclock_file(const char *hwclock_file)
+{
+  FILE *in;
+  char line[256];
+  int i;
+
+  if (!hwclock_file || !hwclock_file[0])
+    return;
+
+  in = UTI_OpenFile(NULL, hwclock_file, NULL, 'r', 0);
+  if (!in)
+    return;
+
+  /* Read third line from the file. */
+  for (i = 0; i < 3; i++) {
+    if (!fgets(line, sizeof(line), in))
+      break;
+  }
+
+  fclose(in);
+
+  if (i == 3 && !strncmp(line, "LOCAL", 5)) {
+    rtc_on_utc = 0;
+  } else if (i == 3 && !strncmp(line, "UTC", 3)) {
+    rtc_on_utc = 1;
+  } else {
+    LOG(LOGS_WARN, "Could not read RTC LOCAL/UTC setting from %s", hwclock_file);
+  }
+}
+
+/* ================================================== */
+
+static void
+setup_config(void)
+{
+  if (CNF_GetRtcOnUtc()) {
+    rtc_on_utc = 1;
+  } else {
+    rtc_on_utc = 0;
+  }
+
+  read_hwclock_file(CNF_GetHwclockFile());
+
+  autotrim_threshold = CNF_GetRtcAutotrim();
+}
+
+/* ================================================== */
+/* Read the coefficients from the file where they were saved
+   the last time the program was run. */
+
+static void
+read_coefs_from_file(void)
+{
+  double ref_time;
+  FILE *in;
+
+  if (!tried_to_load_coefs) {
+
+    valid_coefs_from_file = 0; /* only gets set true if we succeed */
+
+    tried_to_load_coefs = 1;
+
+    if (coefs_file_name &&
+        (in = UTI_OpenFile(NULL, coefs_file_name, NULL, 'r', 0))) {
+      if (fscanf(in, "%d%lf%lf%lf",
+                 &valid_coefs_from_file,
+                 &ref_time,
+                 &file_ref_offset,
+                 &file_rate_ppm) == 4) {
+        file_ref_time = ref_time;
+      } else {
+        LOG(LOGS_WARN, "Could not read coefficients from %s", coefs_file_name);
+      }
+      fclose(in);
+    }
+  }
+}
+
+/* ================================================== */
+/* Write the coefficients to the file where they will be read
+   the next time the program is run. */
+
+static int
+write_coefs_to_file(int valid,time_t ref_time,double offset,double rate)
+{
+  FILE *out;
+
+  /* Create a temporary file with a '.tmp' extension. */
+  out = UTI_OpenFile(NULL, coefs_file_name, ".tmp", 'w', 0644);
+  if (!out)
+    return RTC_ST_BADFILE;
+
+  /* Gain rate is written out in ppm */
+  fprintf(out, "%1d %.0f %.6f %.3f\n", valid, (double)ref_time, offset, 1.0e6 * rate);
+  fclose(out);
+
+  /* Rename the temporary file to the correct location */
+  if (!UTI_RenameTempFile(NULL, coefs_file_name, ".tmp", NULL))
+    return RTC_ST_BADFILE;
+
+  return RTC_ST_OK;
+}
+
+/* ================================================== */
+
+static int
+switch_interrupts(int on_off)
+{
+  if (ioctl(fd, on_off ? RTC_UIE_ON : RTC_UIE_OFF, 0) < 0) {
+    LOG(LOGS_ERR, "Could not %s RTC interrupt : %s",
+        on_off ? "enable" : "disable", strerror(errno));
+    return 0;
+  }
+
+  if (on_off)
+    skip_interrupts = 1;
+
+  return 1;
+}
+
+/* ================================================== */
+/* file_name is the name of the file where we save the RTC params
+   between executions.  Return status is whether we could initialise
+   on this version of the system. */
+
+int
+RTC_Linux_Initialise(void)
+{
+  /* Try to open the device */
+  fd = open(CNF_GetRtcDevice(), O_RDWR);
+  if (fd < 0) {
+    LOG(LOGS_ERR, "Could not open RTC device %s : %s",
+        CNF_GetRtcDevice(), strerror(errno));
+    return 0;
+  }
+
+  /* Make sure the RTC supports interrupts */
+  if (!switch_interrupts(1) || !switch_interrupts(0)) {
+    close(fd);
+    return 0;
+  }
+
+  /* Close on exec */
+  UTI_FdSetCloexec(fd);
+
+  rtc_sec = MallocArray(time_t, MAX_SAMPLES);
+  system_times = MallocArray(struct timespec, MAX_SAMPLES);
+
+  /* Setup details depending on configuration options */
+  setup_config();
+
+  /* In case it didn't get done by pre-init */
+  coefs_file_name = CNF_GetRtcFile();
+
+  n_samples = 0;
+  n_samples_since_regression = 0;
+  n_runs = 0;
+  coefs_valid = 0;
+
+  measurement_period = LOWEST_MEASUREMENT_PERIOD;
+
+  operating_mode = OM_NORMAL;
+
+  /* Register file handler */
+  SCH_AddFileHandler(fd, SCH_FILE_INPUT, read_from_device, NULL);
+
+  /* Register slew handler */
+  LCL_AddParameterChangeHandler(slew_samples, NULL);
+
+  logfileid = CNF_GetLogRtc() ? LOG_FileOpen("rtc",
+      "   Date (UTC) Time   RTC fast (s) Val   Est fast (s)   Slope (ppm)  Ns  Nr Meas")
+    : -1;
+  return 1;
+}
+
+/* ================================================== */
+
+void
+RTC_Linux_Finalise(void)
+{
+  SCH_RemoveTimeout(timeout_id);
+  timeout_id = 0;
+
+  /* Remove input file handler */
+  if (fd >= 0) {
+    SCH_RemoveFileHandler(fd);
+    switch_interrupts(0);
+    close(fd);
+
+    /* Save the RTC data */
+    (void) RTC_Linux_WriteParameters();
+
+  }
+
+  if (rtc_sec)
+    LCL_RemoveParameterChangeHandler(slew_samples, NULL);
+
+  Free(rtc_sec);
+  Free(system_times);
+}
+
+/* ================================================== */
+
+static void
+measurement_timeout(void *any)
+{
+  timeout_id = 0;
+  switch_interrupts(1);
+}
+
+/* ================================================== */
+
+static void
+set_rtc(time_t new_rtc_time)
+{
+  struct tm rtc_tm;
+  struct rtc_time rtc_raw;
+  int status;
+
+  rtc_tm = *rtc_from_t(&new_rtc_time);
+
+  rtc_raw.tm_sec = rtc_tm.tm_sec;
+  rtc_raw.tm_min = rtc_tm.tm_min;
+  rtc_raw.tm_hour = rtc_tm.tm_hour;
+  rtc_raw.tm_mday = rtc_tm.tm_mday;
+  rtc_raw.tm_mon = rtc_tm.tm_mon;
+  rtc_raw.tm_year = rtc_tm.tm_year;
+  rtc_raw.tm_wday = rtc_tm.tm_wday;
+  rtc_raw.tm_yday = rtc_tm.tm_yday;
+  rtc_raw.tm_isdst = rtc_tm.tm_isdst;
+
+  status = ioctl(fd, RTC_SET_TIME, &rtc_raw);
+  if (status < 0) {
+    LOG(LOGS_ERR, "Could not set RTC time");
+  }
+
+}
+
+/* ================================================== */
+
+static void
+handle_initial_trim(void)
+{
+  double rate;
+  long delta_time;
+  double rtc_error_now, sys_error_now;
+
+    /* The idea is to accumulate some number of samples at 1 second
+       intervals, then do a robust regression fit to this.  This
+       should give a good fix on the intercept (=system clock error
+       rel to RTC) at a particular time, removing risk of any
+       particular sample being an outlier.  We can then look at the
+       elapsed interval since the epoch recorded in the RTC file,
+       and correct the system time accordingly. */
+    
+  run_regression(1, &coefs_valid, &coef_ref_time, &coef_seconds_fast, &coef_gain_rate);
+
+  n_samples_since_regression = 0;
+  n_samples = 0;
+
+  read_coefs_from_file();
+
+  if (valid_coefs_from_file) {
+    /* Can process data */
+    delta_time = coef_ref_time - file_ref_time;
+    rate = 1.0e-6 * file_rate_ppm;
+    rtc_error_now = file_ref_offset + rate * (double) delta_time;
+          
+    /* sys_error_now is positive if the system clock is fast */
+    sys_error_now = rtc_error_now - coef_seconds_fast;
+          
+    LCL_AccumulateOffset(sys_error_now, 0.0);
+    LOG(LOGS_INFO, "System clock off from RTC by %f seconds (slew)",
+        sys_error_now);
+  } else {
+    LOG(LOGS_WARN, "No valid rtcfile coefficients");
+  }
+  
+  coefs_valid = 0;
+  
+  (after_init_hook)(after_init_hook_arg);
+  
+  operating_mode = OM_NORMAL;
+}
+
+/* ================================================== */
+
+static void
+handle_relock_after_trim(void)
+{
+  int valid;
+  time_t ref;
+  double fast, slope;
+
+  valid = 0;
+  run_regression(1, &valid, &ref, &fast, &slope);
+
+  if (valid) {
+    write_coefs_to_file(1,ref,fast,saved_coef_gain_rate);
+  } else {
+    DEBUG_LOG("Could not do regression after trim");
+  }
+
+  coefs_valid = 0;
+  n_samples = 0;
+  n_samples_since_regression = 0;
+  operating_mode = OM_NORMAL;
+  measurement_period = LOWEST_MEASUREMENT_PERIOD;
+}
+
+/* ================================================== */
+
+static void
+maybe_autotrim(void)
+{
+  /* Trim only when in normal mode, the coefficients are fresh, the current
+     offset is above the threshold and the system clock is synchronized */
+
+  if (operating_mode != OM_NORMAL || !coefs_valid || n_samples_since_regression)
+    return;
+  
+  if (autotrim_threshold <= 0.0 || fabs(coef_seconds_fast) < autotrim_threshold)
+    return;
+
+  if (REF_GetOurStratum() >= 16)
+    return;
+
+  RTC_Linux_Trim();
+}
+
+/* ================================================== */
+
+static void
+process_reading(time_t rtc_time, struct timespec *system_time)
+{
+  double rtc_fast;
+
+  accumulate_sample(rtc_time, system_time);
+
+  switch (operating_mode) {
+    case OM_NORMAL:
+
+      if (n_samples_since_regression >= N_SAMPLES_PER_REGRESSION) {
+        run_regression(1, &coefs_valid, &coef_ref_time, &coef_seconds_fast, &coef_gain_rate);
+        n_samples_since_regression = 0;
+        maybe_autotrim();
+      }
+      
+      break;
+    case OM_INITIAL:
+      if (n_samples_since_regression >= 8) {
+        handle_initial_trim();
+      }
+      break;
+    case OM_AFTERTRIM:
+      if (n_samples_since_regression >= 8) {
+        handle_relock_after_trim();
+      }
+      break;
+    default:
+      assert(0);
+      break;
+  }  
+
+
+  if (logfileid != -1) {
+    rtc_fast = (rtc_time - system_time->tv_sec) - 1.0e-9 * system_time->tv_nsec;
+
+    LOG_FileWrite(logfileid, "%s %14.6f %1d  %14.6f  %12.3f  %2d  %2d %4d",
+            UTI_TimeToLogForm(system_time->tv_sec),
+            rtc_fast,
+            coefs_valid,
+            coef_seconds_fast, coef_gain_rate * 1.0e6, n_samples, n_runs, measurement_period);
+  }    
+
+}
+
+/* ================================================== */
+
+static void
+read_from_device(int fd_, int event, void *any)
+{
+  int status;
+  unsigned long data;
+  struct timespec sys_time;
+  struct rtc_time rtc_raw;
+  struct tm rtc_tm;
+  time_t rtc_t;
+  int error = 0;
+
+  status = read(fd, &data, sizeof(data));
+
+  if (status < 0) {
+    /* This looks like a bad error : the file descriptor was indicating it was
+     * ready to read but we couldn't read anything.  Give up. */
+    LOG(LOGS_ERR, "Could not read flags %s : %s", CNF_GetRtcDevice(), strerror(errno));
+    SCH_RemoveFileHandler(fd);
+    switch_interrupts(0); /* Likely to raise error too, but just to be sure... */
+    close(fd);
+    fd = -1;
+    return;
+  }    
+
+  if (skip_interrupts > 0) {
+    /* Wait for the next interrupt, this one may be bogus */
+    skip_interrupts--;
+    return;
+  }
+
+  if ((data & RTC_UF) == RTC_UF) {
+    /* Update interrupt detected */
+    
+    /* Read RTC time, sandwiched between two polls of the system clock
+       so we can bound any error. */
+
+    SCH_GetLastEventTime(&sys_time, NULL, NULL);
+
+    status = ioctl(fd, RTC_RD_TIME, &rtc_raw);
+    if (status < 0) {
+      LOG(LOGS_ERR, "Could not read time from %s : %s", CNF_GetRtcDevice(), strerror(errno));
+      error = 1;
+      goto turn_off_interrupt;
+    }
+
+    /* Convert RTC time into a struct timespec */
+    rtc_tm.tm_sec = rtc_raw.tm_sec;
+    rtc_tm.tm_min = rtc_raw.tm_min;
+    rtc_tm.tm_hour = rtc_raw.tm_hour;
+    rtc_tm.tm_mday = rtc_raw.tm_mday;
+    rtc_tm.tm_mon = rtc_raw.tm_mon;
+    rtc_tm.tm_year = rtc_raw.tm_year;
+
+    rtc_t = t_from_rtc(&rtc_tm);
+
+    if (rtc_t == (time_t)(-1)) {
+      error = 1;
+      goto turn_off_interrupt;
+    }      
+
+    process_reading(rtc_t, &sys_time);
+
+    if (n_samples < 4) {
+      measurement_period = LOWEST_MEASUREMENT_PERIOD;
+    } else if (n_samples < 6) {
+      measurement_period = LOWEST_MEASUREMENT_PERIOD << 1;
+    } else if (n_samples < 10) {
+      measurement_period = LOWEST_MEASUREMENT_PERIOD << 2;
+    } else if (n_samples < 14) {
+      measurement_period = LOWEST_MEASUREMENT_PERIOD << 3;
+    } else {
+      measurement_period = LOWEST_MEASUREMENT_PERIOD << 4;
+    }
+
+  }
+
+turn_off_interrupt:
+
+  switch (operating_mode) {
+    case OM_INITIAL:
+      if (error) {
+        DEBUG_LOG("Could not complete initial step due to errors");
+        operating_mode = OM_NORMAL;
+        (after_init_hook)(after_init_hook_arg);
+
+        switch_interrupts(0);
+    
+        timeout_id = SCH_AddTimeoutByDelay((double) measurement_period, measurement_timeout, NULL);
+      }
+
+      break;
+
+    case OM_AFTERTRIM:
+      if (error) {
+        DEBUG_LOG("Could not complete after trim relock due to errors");
+        operating_mode = OM_NORMAL;
+
+        switch_interrupts(0);
+    
+        timeout_id = SCH_AddTimeoutByDelay((double) measurement_period, measurement_timeout, NULL);
+      }
+      
+      break;
+
+    case OM_NORMAL:
+      switch_interrupts(0);
+    
+      timeout_id = SCH_AddTimeoutByDelay((double) measurement_period, measurement_timeout, NULL);
+
+      break;
+    default:
+      assert(0);
+      break;
+  }
+
+}
+
+/* ================================================== */
+
+void
+RTC_Linux_TimeInit(void (*after_hook)(void *), void *anything)
+{
+  after_init_hook = after_hook;
+  after_init_hook_arg = anything;
+
+  operating_mode = OM_INITIAL;
+  timeout_id = 0;
+  switch_interrupts(1);
+}
+
+/* ================================================== */
+
+void
+RTC_Linux_StartMeasurements(void)
+{
+  measurement_timeout(NULL);
+}
+
+/* ================================================== */
+
+int
+RTC_Linux_WriteParameters(void)
+{
+  int retval;
+
+  if (fd < 0) {
+    return RTC_ST_NODRV;
+  }
+  
+  if (coefs_valid) {
+    retval = write_coefs_to_file(1,coef_ref_time, coef_seconds_fast, coef_gain_rate);
+  } else {
+   /* Don't change the existing file, it may not be 100% valid but is our
+      current best guess. */
+    retval = RTC_ST_OK; /*write_coefs_to_file(0,0,0.0,0.0); */
+  }
+
+  return(retval);
+}
+
+/* ================================================== */
+/* Try to set the system clock from the RTC, in the same manner as
+   /sbin/hwclock -s would do.  We're not as picky about OS version
+   etc in this case, since we have fewer requirements regarding the
+   RTC behaviour than we do for the rest of the module. */
+
+int
+RTC_Linux_TimePreInit(time_t driftfile_time)
+{
+  int fd, status;
+  struct rtc_time rtc_raw, rtc_raw_retry;
+  struct tm rtc_tm;
+  time_t rtc_t;
+  double accumulated_error, sys_offset;
+  struct timespec new_sys_time, old_sys_time;
+
+  coefs_file_name = CNF_GetRtcFile();
+
+  setup_config();
+  read_coefs_from_file();
+
+  fd = open(CNF_GetRtcDevice(), O_RDONLY);
+
+  if (fd < 0) {
+    return 0; /* Can't open it, and won't be able to later */
+  }
+
+  /* Retry reading the rtc until both read attempts give the same sec value.
+     This way the race condition is prevented that the RTC has updated itself
+     during the first read operation. */
+  do {
+    status = ioctl(fd, RTC_RD_TIME, &rtc_raw);
+    if (status >= 0) {
+      status = ioctl(fd, RTC_RD_TIME, &rtc_raw_retry);
+    }
+  } while (status >= 0 && rtc_raw.tm_sec != rtc_raw_retry.tm_sec);
+
+  /* Read system clock */
+  LCL_ReadCookedTime(&old_sys_time, NULL);
+
+  close(fd);
+
+  if (status >= 0) {
+    /* Convert to seconds since 1970 */
+    rtc_tm.tm_sec = rtc_raw.tm_sec;
+    rtc_tm.tm_min = rtc_raw.tm_min;
+    rtc_tm.tm_hour = rtc_raw.tm_hour;
+    rtc_tm.tm_mday = rtc_raw.tm_mday;
+    rtc_tm.tm_mon = rtc_raw.tm_mon;
+    rtc_tm.tm_year = rtc_raw.tm_year;
+    
+    rtc_t = t_from_rtc(&rtc_tm);
+
+    if (rtc_t != (time_t)(-1)) {
+
+      /* Work out approximatation to correct time (to about the
+         nearest second) */
+      if (valid_coefs_from_file) {
+        accumulated_error = file_ref_offset +
+          (rtc_t - file_ref_time) * 1.0e-6 * file_rate_ppm;
+      } else {
+        accumulated_error = 0.0;
+      }
+
+      /* Correct time */
+
+      new_sys_time.tv_sec = rtc_t;
+      /* Average error in the RTC reading */
+      new_sys_time.tv_nsec = 500000000;
+
+      UTI_AddDoubleToTimespec(&new_sys_time, -accumulated_error, &new_sys_time);
+
+      if (new_sys_time.tv_sec < driftfile_time) {
+        LOG(LOGS_WARN, "RTC time before last driftfile modification (ignored)");
+        return 0;
+      }
+
+      sys_offset = UTI_DiffTimespecsToDouble(&old_sys_time, &new_sys_time);
+
+      /* Set system time only if the step is larger than 1 second */
+      if (fabs(sys_offset) >= 1.0) {
+        if (LCL_ApplyStepOffset(sys_offset))
+          LOG(LOGS_INFO, "System time set from RTC");
+      }
+    } else {
+      return 0;
+    }
+  } else {
+    return 0;
+  }
+
+  return 1;
+}
+
+/* ================================================== */
+
+int
+RTC_Linux_GetReport(RPT_RTC_Report *report)
+{
+  report->ref_time.tv_sec = coef_ref_time;
+  report->ref_time.tv_nsec = 0;
+  report->n_samples = n_samples;
+  report->n_runs = n_runs;
+  if (n_samples > 1) {
+    report->span_seconds = rtc_sec[n_samples - 1] - rtc_sec[0];
+  } else {
+    report->span_seconds = 0;
+  }
+  report->rtc_seconds_fast = coef_seconds_fast;
+  report->rtc_gain_rate_ppm = 1.0e6 * coef_gain_rate;
+  return 1;
+}
+
+/* ================================================== */
+
+int
+RTC_Linux_Trim(void)
+{
+  struct timespec now;
+
+  /* Remember the slope coefficient - we won't be able to determine a
+     good one in a few seconds when we determine the new offset! */
+  saved_coef_gain_rate = coef_gain_rate;
+
+  if (fabs(coef_seconds_fast) > 1.0) {
+
+    LOG(LOGS_INFO, "RTC wrong by %.3f seconds (step)",
+        coef_seconds_fast);
+
+    /* Do processing to set clock.  Let R be the value we set the
+       RTC to, then in 500ms the RTC ticks (R+1) (see comments in
+       arch/i386/kernel/time.c about the behaviour of the real time
+       clock chip).  If S is the system time now, the error at the
+       next RTC tick is given by E = (R+1) - (S+0.5).  Ideally we
+       want |E| <= 0.5, which implies R <= S <= R+1, i.e. R is just
+       the rounded down part of S, i.e. the seconds part. */
+
+    LCL_ReadCookedTime(&now, NULL);
+    
+    set_rtc(now.tv_sec);
+
+    /* All old samples will now look bogus under the new
+           regime. */
+    n_samples = 0;
+    operating_mode = OM_AFTERTRIM;
+
+    /* Estimate the offset in case writertc is called or chronyd
+       is terminated during rapid sampling */
+    coef_seconds_fast = -now.tv_nsec / 1.0e9 + 0.5;
+    coef_ref_time = now.tv_sec;
+
+    /* And start rapid sampling, interrupts on now */
+    SCH_RemoveTimeout(timeout_id);
+    timeout_id = 0;
+    switch_interrupts(1);
+  }
+
+  return 1;
+  
+}