include/linux/iio/common/inv_sensors_timestamp.h - linux - Git at Google

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

 #ifndef INV_SENSORS_TIMESTAMP_H_
 #define INV_SENSORS_TIMESTAMP_H_

 /**
  * struct inv_sensors_timestamp_chip - chip internal properties
  * @clock_period:	internal clock period in ns
  * @jitter:		acceptable jitter in per-mille
  * @init_period:	chip initial period at reset in ns
  */
 struct inv_sensors_timestamp_chip {
 	uint32_t clock_period;
 	uint32_t jitter;
 	uint32_t init_period;
 };

 /**
  * struct inv_sensors_timestamp_interval - timestamps interval
  * @lo:	interval lower bound
  * @up:	interval upper bound
  */
 struct inv_sensors_timestamp_interval {
 	int64_t lo;
 	int64_t up;
 };

 /**
  * struct inv_sensors_timestamp_acc - accumulator for computing an estimation
  * @val:	current estimation of the value, the mean of all values
  * @idx:	current index of the next free place in values table
  * @values:	table of all measured values, use for computing the mean
  */
 struct inv_sensors_timestamp_acc {
 	uint32_t val;
 	size_t idx;
 	uint32_t values[32];
 };

 /**
  * struct inv_sensors_timestamp - timestamp management states
  * @chip:		chip internal characteristics
  * @min_period:		minimal acceptable clock period
  * @max_period:		maximal acceptable clock period
  * @it:			interrupts interval timestamps
  * @timestamp:		store last timestamp for computing next data timestamp
  * @mult:		current internal period multiplier
  * @new_mult:		new set internal period multiplier (not yet effective)
  * @period:		measured current period of the sensor
  * @chip_period:	accumulator for computing internal chip period
  */
 struct inv_sensors_timestamp {
 	struct inv_sensors_timestamp_chip chip;
 	uint32_t min_period;
 	uint32_t max_period;
 	struct inv_sensors_timestamp_interval it;
 	int64_t timestamp;
 	uint32_t mult;
 	uint32_t new_mult;
 	uint32_t period;
 	struct inv_sensors_timestamp_acc chip_period;
 };

 void inv_sensors_timestamp_init(struct inv_sensors_timestamp *ts,
 				const struct inv_sensors_timestamp_chip *chip);

 int inv_sensors_timestamp_update_odr(struct inv_sensors_timestamp *ts,
 				     uint32_t period, bool fifo);

 void inv_sensors_timestamp_interrupt(struct inv_sensors_timestamp *ts,
 				     uint32_t fifo_period, size_t fifo_nb,
 				     size_t sensor_nb, int64_t timestamp);

 static inline int64_t inv_sensors_timestamp_pop(struct inv_sensors_timestamp *ts)
 {
 	ts->timestamp += ts->period;
 	return ts->timestamp;
 }

 void inv_sensors_timestamp_apply_odr(struct inv_sensors_timestamp *ts,
 				     uint32_t fifo_period, size_t fifo_nb,
 				     unsigned int fifo_no);

 static inline void inv_sensors_timestamp_reset(struct inv_sensors_timestamp *ts)
 {
 	const struct inv_sensors_timestamp_interval interval_init = {0LL, 0LL};

 	ts->it = interval_init;
 	ts->timestamp = 0;
 }

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

	#ifndef INV_SENSORS_TIMESTAMP_H_
	#define INV_SENSORS_TIMESTAMP_H_

	/**
	* struct inv_sensors_timestamp_chip - chip internal properties
	* @clock_period: internal clock period in ns
	* @jitter: acceptable jitter in per-mille
	* @init_period: chip initial period at reset in ns
	*/
	struct inv_sensors_timestamp_chip {
	uint32_t clock_period;
	uint32_t jitter;
	uint32_t init_period;
	};

	/**
	* struct inv_sensors_timestamp_interval - timestamps interval
	* @lo: interval lower bound
	* @up: interval upper bound
	*/
	struct inv_sensors_timestamp_interval {
	int64_t lo;
	int64_t up;
	};

	/**
	* struct inv_sensors_timestamp_acc - accumulator for computing an estimation
	* @val: current estimation of the value, the mean of all values
	* @idx: current index of the next free place in values table
	* @values: table of all measured values, use for computing the mean
	*/
	struct inv_sensors_timestamp_acc {
	uint32_t val;
	size_t idx;
	uint32_t values[32];
	};

	/**
	* struct inv_sensors_timestamp - timestamp management states
	* @chip: chip internal characteristics
	* @min_period: minimal acceptable clock period
	* @max_period: maximal acceptable clock period
	* @it: interrupts interval timestamps
	* @timestamp: store last timestamp for computing next data timestamp
	* @mult: current internal period multiplier
	* @new_mult: new set internal period multiplier (not yet effective)
	* @period: measured current period of the sensor
	* @chip_period: accumulator for computing internal chip period
	*/
	struct inv_sensors_timestamp {
	struct inv_sensors_timestamp_chip chip;
	uint32_t min_period;
	uint32_t max_period;
	struct inv_sensors_timestamp_interval it;
	int64_t timestamp;
	uint32_t mult;
	uint32_t new_mult;
	uint32_t period;
	struct inv_sensors_timestamp_acc chip_period;
	};

	void inv_sensors_timestamp_init(struct inv_sensors_timestamp *ts,
	const struct inv_sensors_timestamp_chip *chip);

	int inv_sensors_timestamp_update_odr(struct inv_sensors_timestamp *ts,
	uint32_t period, bool fifo);

	void inv_sensors_timestamp_interrupt(struct inv_sensors_timestamp *ts,
	uint32_t fifo_period, size_t fifo_nb,
	size_t sensor_nb, int64_t timestamp);

	static inline int64_t inv_sensors_timestamp_pop(struct inv_sensors_timestamp *ts)
	{
	ts->timestamp += ts->period;
	return ts->timestamp;
	}

	void inv_sensors_timestamp_apply_odr(struct inv_sensors_timestamp *ts,
	uint32_t fifo_period, size_t fifo_nb,
	unsigned int fifo_no);

	static inline void inv_sensors_timestamp_reset(struct inv_sensors_timestamp *ts)
	{
	const struct inv_sensors_timestamp_interval interval_init = {0LL, 0LL};

	ts->it = interval_init;
	ts->timestamp = 0;
	}

	#endif