drivers/iio/imu/inv_icm42600/inv_icm42600_timestamp.c - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0-or-later
 /*
  * Copyright (C) 2020 Invensense, Inc.
  */

 #include <linux/kernel.h>
 #include <linux/regmap.h>
 #include <linux/math64.h>

 #include "inv_icm42600.h"
 #include "inv_icm42600_timestamp.h"

 /* internal chip period is 32kHz, 31250ns */
 #define INV_ICM42600_TIMESTAMP_PERIOD		31250
 /* allow a jitter of +/- 2% */
 #define INV_ICM42600_TIMESTAMP_JITTER		2
 /* compute min and max periods accepted */
 #define INV_ICM42600_TIMESTAMP_MIN_PERIOD(_p)		\
 	(((_p) * (100 - INV_ICM42600_TIMESTAMP_JITTER)) / 100)
 #define INV_ICM42600_TIMESTAMP_MAX_PERIOD(_p)		\
 	(((_p) * (100 + INV_ICM42600_TIMESTAMP_JITTER)) / 100)

 /* Add a new value inside an accumulator and update the estimate value */
 static void inv_update_acc(struct inv_icm42600_timestamp_acc *acc, uint32_t val)
 {
 	uint64_t sum = 0;
 	size_t i;

 	acc->values[acc->idx++] = val;
 	if (acc->idx >= ARRAY_SIZE(acc->values))
 		acc->idx = 0;

 	/* compute the mean of all stored values, use 0 as empty slot */
 	for (i = 0; i < ARRAY_SIZE(acc->values); ++i) {
 		if (acc->values[i] == 0)
 			break;
 		sum += acc->values[i];
 	}

 	acc->val = div_u64(sum, i);
 }

 void inv_icm42600_timestamp_init(struct inv_icm42600_timestamp *ts,
 				 uint32_t period)
 {
 	/* initial odr for sensor after reset is 1kHz */
 	const uint32_t default_period = 1000000;

 	/* current multiplier and period values after reset */
 	ts->mult = default_period / INV_ICM42600_TIMESTAMP_PERIOD;
 	ts->period = default_period;
 	/* new set multiplier is the one from chip initialization */
 	ts->new_mult = period / INV_ICM42600_TIMESTAMP_PERIOD;

 	/* use theoretical value for chip period */
 	inv_update_acc(&ts->chip_period, INV_ICM42600_TIMESTAMP_PERIOD);
 }

 int inv_icm42600_timestamp_setup(struct inv_icm42600_state *st)
 {
 	unsigned int val;

 	/* enable timestamp register */
 	val = INV_ICM42600_TMST_CONFIG_TMST_TO_REGS_EN |
 	      INV_ICM42600_TMST_CONFIG_TMST_EN;
 	return regmap_update_bits(st->map, INV_ICM42600_REG_TMST_CONFIG,
 				  INV_ICM42600_TMST_CONFIG_MASK, val);
 }

 int inv_icm42600_timestamp_update_odr(struct inv_icm42600_timestamp *ts,
 				      uint32_t period, bool fifo)
 {
 	/* when FIFO is on, prevent odr change if one is already pending */
 	if (fifo && ts->new_mult != 0)
 		return -EAGAIN;

 	ts->new_mult = period / INV_ICM42600_TIMESTAMP_PERIOD;

 	return 0;
 }

 static bool inv_validate_period(uint32_t period, uint32_t mult)
 {
 	const uint32_t chip_period = INV_ICM42600_TIMESTAMP_PERIOD;
 	uint32_t period_min, period_max;

 	/* check that period is acceptable */
 	period_min = INV_ICM42600_TIMESTAMP_MIN_PERIOD(chip_period) * mult;
 	period_max = INV_ICM42600_TIMESTAMP_MAX_PERIOD(chip_period) * mult;
 	if (period > period_min && period < period_max)
 		return true;
 	else
 		return false;
 }

 static bool inv_compute_chip_period(struct inv_icm42600_timestamp *ts,
 				    uint32_t mult, uint32_t period)
 {
 	uint32_t new_chip_period;

 	if (!inv_validate_period(period, mult))
 		return false;

 	/* update chip internal period estimation */
 	new_chip_period = period / mult;
 	inv_update_acc(&ts->chip_period, new_chip_period);

 	return true;
 }

 void inv_icm42600_timestamp_interrupt(struct inv_icm42600_timestamp *ts,
 				      uint32_t fifo_period, size_t fifo_nb,
 				      size_t sensor_nb, int64_t timestamp)
 {
 	struct inv_icm42600_timestamp_interval *it;
 	int64_t delta, interval;
 	const uint32_t fifo_mult = fifo_period / INV_ICM42600_TIMESTAMP_PERIOD;
 	uint32_t period = ts->period;
 	int32_t m;
 	bool valid = false;

 	if (fifo_nb == 0)
 		return;

 	/* update interrupt timestamp and compute chip and sensor periods */
 	it = &ts->it;
 	it->lo = it->up;
 	it->up = timestamp;
 	delta = it->up - it->lo;
 	if (it->lo != 0) {
 		/* compute period: delta time divided by number of samples */
 		period = div_s64(delta, fifo_nb);
 		valid = inv_compute_chip_period(ts, fifo_mult, period);
 		/* update sensor period if chip internal period is updated */
 		if (valid)
 			ts->period = ts->mult * ts->chip_period.val;
 	}

 	/* no previous data, compute theoritical value from interrupt */
 	if (ts->timestamp == 0) {
 		/* elapsed time: sensor period * sensor samples number */
 		interval = (int64_t)ts->period * (int64_t)sensor_nb;
 		ts->timestamp = it->up - interval;
 		return;
 	}

 	/* if interrupt interval is valid, sync with interrupt timestamp */
 	if (valid) {
 		/* compute measured fifo_period */
 		fifo_period = fifo_mult * ts->chip_period.val;
 		/* delta time between last sample and last interrupt */
 		delta = it->lo - ts->timestamp;
 		/* if there are multiple samples, go back to first one */
 		while (delta >= (fifo_period * 3 / 2))
 			delta -= fifo_period;
 		/* compute maximal adjustment value */
 		m = INV_ICM42600_TIMESTAMP_MAX_PERIOD(ts->period) - ts->period;
 		if (delta > m)
 			delta = m;
 		else if (delta < -m)
 			delta = -m;
 		ts->timestamp += delta;
 	}
 }

 void inv_icm42600_timestamp_apply_odr(struct inv_icm42600_timestamp *ts,
 				      uint32_t fifo_period, size_t fifo_nb,
 				      unsigned int fifo_no)
 {
 	int64_t interval;
 	uint32_t fifo_mult;

 	if (ts->new_mult == 0)
 		return;

 	/* update to new multiplier and update period */
 	ts->mult = ts->new_mult;
 	ts->new_mult = 0;
 	ts->period = ts->mult * ts->chip_period.val;

 	/*
 	 * After ODR change the time interval with the previous sample is
 	 * undertermined (depends when the change occures). So we compute the
 	 * timestamp from the current interrupt using the new FIFO period, the
 	 * total number of samples and the current sample numero.
 	 */
 	if (ts->timestamp != 0) {
 		/* compute measured fifo period */
 		fifo_mult = fifo_period / INV_ICM42600_TIMESTAMP_PERIOD;
 		fifo_period = fifo_mult * ts->chip_period.val;
 		/* computes time interval between interrupt and this sample */
 		interval = (int64_t)(fifo_nb - fifo_no) * (int64_t)fifo_period;
 		ts->timestamp = ts->it.up - interval;
 	}
 }
	// SPDX-License-Identifier: GPL-2.0-or-later
	/*
	* Copyright (C) 2020 Invensense, Inc.
	*/

	#include <linux/kernel.h>
	#include <linux/regmap.h>
	#include <linux/math64.h>

	#include "inv_icm42600.h"
	#include "inv_icm42600_timestamp.h"

	/* internal chip period is 32kHz, 31250ns */
	#define INV_ICM42600_TIMESTAMP_PERIOD 31250
	/* allow a jitter of +/- 2% */
	#define INV_ICM42600_TIMESTAMP_JITTER 2
	/* compute min and max periods accepted */
	#define INV_ICM42600_TIMESTAMP_MIN_PERIOD(_p) \
	(((_p) * (100 - INV_ICM42600_TIMESTAMP_JITTER)) / 100)
	#define INV_ICM42600_TIMESTAMP_MAX_PERIOD(_p) \
	(((_p) * (100 + INV_ICM42600_TIMESTAMP_JITTER)) / 100)

	/* Add a new value inside an accumulator and update the estimate value */
	static void inv_update_acc(struct inv_icm42600_timestamp_acc *acc, uint32_t val)
	{
	uint64_t sum = 0;
	size_t i;

	acc->values[acc->idx++] = val;
	if (acc->idx >= ARRAY_SIZE(acc->values))
	acc->idx = 0;

	/* compute the mean of all stored values, use 0 as empty slot */
	for (i = 0; i < ARRAY_SIZE(acc->values); ++i) {
	if (acc->values[i] == 0)
	break;
	sum += acc->values[i];
	}

	acc->val = div_u64(sum, i);
	}

	void inv_icm42600_timestamp_init(struct inv_icm42600_timestamp *ts,
	uint32_t period)
	{
	/* initial odr for sensor after reset is 1kHz */
	const uint32_t default_period = 1000000;

	/* current multiplier and period values after reset */
	ts->mult = default_period / INV_ICM42600_TIMESTAMP_PERIOD;
	ts->period = default_period;
	/* new set multiplier is the one from chip initialization */
	ts->new_mult = period / INV_ICM42600_TIMESTAMP_PERIOD;

	/* use theoretical value for chip period */
	inv_update_acc(&ts->chip_period, INV_ICM42600_TIMESTAMP_PERIOD);
	}

	int inv_icm42600_timestamp_setup(struct inv_icm42600_state *st)
	{
	unsigned int val;

	/* enable timestamp register */
	val = INV_ICM42600_TMST_CONFIG_TMST_TO_REGS_EN \|
	INV_ICM42600_TMST_CONFIG_TMST_EN;
	return regmap_update_bits(st->map, INV_ICM42600_REG_TMST_CONFIG,
	INV_ICM42600_TMST_CONFIG_MASK, val);
	}

	int inv_icm42600_timestamp_update_odr(struct inv_icm42600_timestamp *ts,
	uint32_t period, bool fifo)
	{
	/* when FIFO is on, prevent odr change if one is already pending */
	if (fifo && ts->new_mult != 0)
	return -EAGAIN;

	ts->new_mult = period / INV_ICM42600_TIMESTAMP_PERIOD;

	return 0;
	}

	static bool inv_validate_period(uint32_t period, uint32_t mult)
	{
	const uint32_t chip_period = INV_ICM42600_TIMESTAMP_PERIOD;
	uint32_t period_min, period_max;

	/* check that period is acceptable */
	period_min = INV_ICM42600_TIMESTAMP_MIN_PERIOD(chip_period) * mult;
	period_max = INV_ICM42600_TIMESTAMP_MAX_PERIOD(chip_period) * mult;
	if (period > period_min && period < period_max)
	return true;
	else
	return false;
	}

	static bool inv_compute_chip_period(struct inv_icm42600_timestamp *ts,
	uint32_t mult, uint32_t period)
	{
	uint32_t new_chip_period;

	if (!inv_validate_period(period, mult))
	return false;

	/* update chip internal period estimation */
	new_chip_period = period / mult;
	inv_update_acc(&ts->chip_period, new_chip_period);

	return true;
	}

	void inv_icm42600_timestamp_interrupt(struct inv_icm42600_timestamp *ts,
	uint32_t fifo_period, size_t fifo_nb,
	size_t sensor_nb, int64_t timestamp)
	{
	struct inv_icm42600_timestamp_interval *it;
	int64_t delta, interval;
	const uint32_t fifo_mult = fifo_period / INV_ICM42600_TIMESTAMP_PERIOD;
	uint32_t period = ts->period;
	int32_t m;
	bool valid = false;

	if (fifo_nb == 0)
	return;

	/* update interrupt timestamp and compute chip and sensor periods */
	it = &ts->it;
	it->lo = it->up;
	it->up = timestamp;
	delta = it->up - it->lo;
	if (it->lo != 0) {
	/* compute period: delta time divided by number of samples */
	period = div_s64(delta, fifo_nb);
	valid = inv_compute_chip_period(ts, fifo_mult, period);
	/* update sensor period if chip internal period is updated */
	if (valid)
	ts->period = ts->mult * ts->chip_period.val;
	}

	/* no previous data, compute theoritical value from interrupt */
	if (ts->timestamp == 0) {
	/* elapsed time: sensor period * sensor samples number */
	interval = (int64_t)ts->period * (int64_t)sensor_nb;
	ts->timestamp = it->up - interval;
	return;
	}

	/* if interrupt interval is valid, sync with interrupt timestamp */
	if (valid) {
	/* compute measured fifo_period */
	fifo_period = fifo_mult * ts->chip_period.val;
	/* delta time between last sample and last interrupt */
	delta = it->lo - ts->timestamp;
	/* if there are multiple samples, go back to first one */
	while (delta >= (fifo_period * 3 / 2))
	delta -= fifo_period;
	/* compute maximal adjustment value */
	m = INV_ICM42600_TIMESTAMP_MAX_PERIOD(ts->period) - ts->period;
	if (delta > m)
	delta = m;
	else if (delta < -m)
	delta = -m;
	ts->timestamp += delta;
	}
	}

	void inv_icm42600_timestamp_apply_odr(struct inv_icm42600_timestamp *ts,
	uint32_t fifo_period, size_t fifo_nb,
	unsigned int fifo_no)
	{
	int64_t interval;
	uint32_t fifo_mult;

	if (ts->new_mult == 0)
	return;

	/* update to new multiplier and update period */
	ts->mult = ts->new_mult;
	ts->new_mult = 0;
	ts->period = ts->mult * ts->chip_period.val;

	/*
	* After ODR change the time interval with the previous sample is
	* undertermined (depends when the change occures). So we compute the
	* timestamp from the current interrupt using the new FIFO period, the
	* total number of samples and the current sample numero.
	*/
	if (ts->timestamp != 0) {
	/* compute measured fifo period */
	fifo_mult = fifo_period / INV_ICM42600_TIMESTAMP_PERIOD;
	fifo_period = fifo_mult * ts->chip_period.val;
	/* computes time interval between interrupt and this sample */
	interval = (int64_t)(fifo_nb - fifo_no) * (int64_t)fifo_period;
	ts->timestamp = ts->it.up - interval;
	}
	}