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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-07 16:09:41 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-07 16:09:41 +0000 |
commit | 3271d1ac389d2ec93db9c5b9ce0991ce478476cf (patch) | |
tree | 35ff7d180e1ccc061f28535d7435b5ba1789e734 /hwclock.c | |
parent | Initial commit. (diff) | |
download | chrony-upstream.tar.xz chrony-upstream.zip |
Adding upstream version 4.3.upstream/4.3upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'hwclock.c')
-rw-r--r-- | hwclock.c | 334 |
1 files changed, 334 insertions, 0 deletions
diff --git a/hwclock.c b/hwclock.c new file mode 100644 index 0000000..86c7e51 --- /dev/null +++ b/hwclock.c @@ -0,0 +1,334 @@ +/* + chronyd/chronyc - Programs for keeping computer clocks accurate. + + ********************************************************************** + * Copyright (C) Miroslav Lichvar 2016-2018, 2022 + * + * 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. + * + ********************************************************************** + + ======================================================================= + + Tracking of hardware clocks (e.g. RTC, PHC) + */ + +#include "config.h" + +#include "sysincl.h" + +#include "array.h" +#include "hwclock.h" +#include "local.h" +#include "logging.h" +#include "memory.h" +#include "quantiles.h" +#include "regress.h" +#include "util.h" + +/* Minimum and maximum number of samples per clock */ +#define MIN_SAMPLES 2 +#define MAX_SAMPLES 64 + +/* Maximum acceptable frequency offset of the clock */ +#define MAX_FREQ_OFFSET (2.0 / 3.0) + +/* Quantiles for filtering readings by delay */ +#define DELAY_QUANT_MIN_K 1 +#define DELAY_QUANT_MAX_K 2 +#define DELAY_QUANT_Q 10 +#define DELAY_QUANT_REPEAT 7 +#define DELAY_QUANT_MIN_STEP 1.0e-9 + +struct HCL_Instance_Record { + /* HW and local reference timestamp */ + struct timespec hw_ref; + struct timespec local_ref; + + /* Samples stored as intervals (uncorrected for frequency error) + relative to local_ref and hw_ref */ + double *x_data; + double *y_data; + + /* Minimum, maximum and current number of samples */ + int min_samples; + int max_samples; + int n_samples; + + /* Maximum error of the last sample */ + double last_err; + + /* Minimum interval between samples */ + double min_separation; + + /* Expected precision of readings */ + double precision; + + /* Flag indicating the offset and frequency values are valid */ + int valid_coefs; + + /* Estimated offset and frequency of HW clock relative to local clock */ + double offset; + double frequency; + + /* Estimated quantiles of reading delay */ + QNT_Instance delay_quants; +}; + +/* ================================================== */ + +static void +handle_slew(struct timespec *raw, struct timespec *cooked, double dfreq, + double doffset, LCL_ChangeType change_type, void *anything) +{ + HCL_Instance clock; + double delta; + + clock = anything; + + if (clock->n_samples) + UTI_AdjustTimespec(&clock->local_ref, cooked, &clock->local_ref, &delta, dfreq, doffset); + if (clock->valid_coefs) + clock->frequency /= 1.0 - dfreq; +} + +/* ================================================== */ + +HCL_Instance +HCL_CreateInstance(int min_samples, int max_samples, double min_separation, double precision) +{ + HCL_Instance clock; + + min_samples = CLAMP(MIN_SAMPLES, min_samples, MAX_SAMPLES); + max_samples = CLAMP(MIN_SAMPLES, max_samples, MAX_SAMPLES); + max_samples = MAX(min_samples, max_samples); + + clock = MallocNew(struct HCL_Instance_Record); + clock->x_data = MallocArray(double, max_samples); + clock->y_data = MallocArray(double, max_samples); + clock->x_data[max_samples - 1] = 0.0; + clock->y_data[max_samples - 1] = 0.0; + clock->min_samples = min_samples; + clock->max_samples = max_samples; + clock->n_samples = 0; + clock->valid_coefs = 0; + clock->min_separation = min_separation; + clock->precision = precision; + clock->delay_quants = QNT_CreateInstance(DELAY_QUANT_MIN_K, DELAY_QUANT_MAX_K, + DELAY_QUANT_Q, DELAY_QUANT_REPEAT, + DELAY_QUANT_MIN_STEP); + + LCL_AddParameterChangeHandler(handle_slew, clock); + + return clock; +} + +/* ================================================== */ + +void HCL_DestroyInstance(HCL_Instance clock) +{ + LCL_RemoveParameterChangeHandler(handle_slew, clock); + QNT_DestroyInstance(clock->delay_quants); + Free(clock->y_data); + Free(clock->x_data); + Free(clock); +} + +/* ================================================== */ + +int +HCL_NeedsNewSample(HCL_Instance clock, struct timespec *now) +{ + if (!clock->n_samples || + fabs(UTI_DiffTimespecsToDouble(now, &clock->local_ref)) >= clock->min_separation) + return 1; + + return 0; +} + +/* ================================================== */ + +int +HCL_ProcessReadings(HCL_Instance clock, int n_readings, struct timespec tss[][3], + struct timespec *hw_ts, struct timespec *local_ts, double *err) +{ + double delay, raw_delay, min_delay, low_delay, high_delay, e, pred_err; + double delay_sum, hw_sum, local_sum, local_prec, freq; + int i, min_reading, combined; + struct timespec ts1, ts2; + + if (n_readings < 1) + return 0; + + /* Work out the current correction multiplier needed to get cooked delays */ + LCL_CookTime(&tss[0][0], &ts1, NULL); + LCL_CookTime(&tss[n_readings - 1][2], &ts2, NULL); + if (UTI_CompareTimespecs(&tss[0][0], &tss[n_readings - 1][2]) < 0) + freq = UTI_DiffTimespecsToDouble(&ts1, &ts2) / + UTI_DiffTimespecsToDouble(&tss[0][0], &tss[n_readings - 1][2]); + else + freq = 1.0; + + for (i = 0; i < n_readings; i++) { + delay = freq * UTI_DiffTimespecsToDouble(&tss[i][2], &tss[i][0]); + + if (delay < 0.0) { + /* Step in the middle of a reading? */ + DEBUG_LOG("Bad reading delay=%e", delay); + return 0; + } + + if (i == 0 || min_delay > delay) { + min_delay = delay; + min_reading = i; + } + + QNT_Accumulate(clock->delay_quants, delay); + } + + local_prec = LCL_GetSysPrecisionAsQuantum(); + + low_delay = QNT_GetQuantile(clock->delay_quants, DELAY_QUANT_MIN_K); + high_delay = QNT_GetQuantile(clock->delay_quants, DELAY_QUANT_MAX_K); + low_delay = MIN(low_delay, high_delay); + high_delay = MAX(high_delay, low_delay + local_prec); + + /* Combine readings with delay in the expected interval */ + for (i = combined = 0, delay_sum = hw_sum = local_sum = 0.0; i < n_readings; i++) { + raw_delay = UTI_DiffTimespecsToDouble(&tss[i][2], &tss[i][0]); + delay = freq * raw_delay; + + if (delay < low_delay || delay > high_delay) + continue; + + delay_sum += delay; + hw_sum += UTI_DiffTimespecsToDouble(&tss[i][1], &tss[0][1]); + local_sum += UTI_DiffTimespecsToDouble(&tss[i][0], &tss[0][0]) + raw_delay / 2.0; + combined++; + } + + DEBUG_LOG("Combined %d readings lo=%e hi=%e", combined, low_delay, high_delay); + + if (combined > 0) { + UTI_AddDoubleToTimespec(&tss[0][1], hw_sum / combined, hw_ts); + UTI_AddDoubleToTimespec(&tss[0][0], local_sum / combined, local_ts); + *err = MAX(delay_sum / combined / 2.0, clock->precision); + return 1; + } + + /* Accept the reading with minimum delay if its interval does not contain + the current offset predicted from previous samples */ + + *hw_ts = tss[min_reading][1]; + UTI_AddDoubleToTimespec(&tss[min_reading][0], min_delay / freq / 2.0, local_ts); + *err = MAX(min_delay / 2.0, clock->precision); + + pred_err = 0.0; + LCL_CookTime(local_ts, &ts1, NULL); + if (!HCL_CookTime(clock, hw_ts, &ts2, &e) || + ((pred_err = UTI_DiffTimespecsToDouble(&ts1, &ts2)) > *err)) { + DEBUG_LOG("Accepted reading err=%e prerr=%e", *err, pred_err); + return 1; + } + + return 0; +} + +/* ================================================== */ + +void +HCL_AccumulateSample(HCL_Instance clock, struct timespec *hw_ts, + struct timespec *local_ts, double err) +{ + double hw_delta, local_delta, local_freq, raw_freq; + int i, n_runs, best_start; + + local_freq = 1.0 - LCL_ReadAbsoluteFrequency() / 1.0e6; + + /* Shift old samples */ + if (clock->n_samples) { + if (clock->n_samples >= clock->max_samples) + clock->n_samples--; + + hw_delta = UTI_DiffTimespecsToDouble(hw_ts, &clock->hw_ref); + local_delta = UTI_DiffTimespecsToDouble(local_ts, &clock->local_ref) / local_freq; + + if (hw_delta <= 0.0 || local_delta < clock->min_separation / 2.0) { + clock->n_samples = 0; + DEBUG_LOG("HW clock reset interval=%f", local_delta); + } + + for (i = clock->max_samples - clock->n_samples; i < clock->max_samples; i++) { + clock->y_data[i - 1] = clock->y_data[i] - hw_delta; + clock->x_data[i - 1] = clock->x_data[i] - local_delta; + } + } + + clock->n_samples++; + clock->hw_ref = *hw_ts; + clock->local_ref = *local_ts; + clock->last_err = err; + + /* Get new coefficients */ + clock->valid_coefs = + RGR_FindBestRobustRegression(clock->x_data + clock->max_samples - clock->n_samples, + clock->y_data + clock->max_samples - clock->n_samples, + clock->n_samples, 1.0e-10, &clock->offset, &raw_freq, + &n_runs, &best_start); + + if (!clock->valid_coefs) { + DEBUG_LOG("HW clock needs more samples"); + return; + } + + clock->frequency = raw_freq / local_freq; + + /* Drop unneeded samples */ + if (clock->n_samples > clock->min_samples) + clock->n_samples -= MIN(best_start, clock->n_samples - clock->min_samples); + + /* If the fit doesn't cross the error interval of the last sample, + or the frequency is not sane, drop all samples and start again */ + if (fabs(clock->offset) > err || + fabs(clock->frequency - 1.0) > MAX_FREQ_OFFSET) { + DEBUG_LOG("HW clock reset"); + clock->n_samples = 0; + clock->valid_coefs = 0; + } + + DEBUG_LOG("HW clock samples=%d offset=%e freq=%e raw_freq=%e err=%e ref_diff=%e", + clock->n_samples, clock->offset, clock->frequency - 1.0, raw_freq - 1.0, err, + UTI_DiffTimespecsToDouble(&clock->hw_ref, &clock->local_ref)); +} + +/* ================================================== */ + +int +HCL_CookTime(HCL_Instance clock, struct timespec *raw, struct timespec *cooked, double *err) +{ + double offset, elapsed; + + if (!clock->valid_coefs) + return 0; + + elapsed = UTI_DiffTimespecsToDouble(raw, &clock->hw_ref); + offset = elapsed / clock->frequency - clock->offset; + UTI_AddDoubleToTimespec(&clock->local_ref, offset, cooked); + + /* Fow now, just return the error of the last sample */ + if (err) + *err = clock->last_err; + + return 1; +} |