include/zephyr/drivers/sensor.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /**
  * @file drivers/sensor.h
  *
  * @brief Public APIs for the sensor driver.
  */

 /*
  * Copyright (c) 2016 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */
 #ifndef ZEPHYR_INCLUDE_DRIVERS_SENSOR_H_
 #define ZEPHYR_INCLUDE_DRIVERS_SENSOR_H_

 /**
  * @brief Sensor Interface
  * @defgroup sensor_interface Sensor Interface
  * @ingroup io_interfaces
  * @{
  */

 #include <zephyr/types.h>
 #include <zephyr/device.h>
 #include <errno.h>

 #ifdef __cplusplus
 extern "C" {
 #endif

 /**
  * @brief Representation of a sensor readout value.
  *
  * The value is represented as having an integer and a fractional part,
  * and can be obtained using the formula val1 + val2 * 10^(-6). Negative
  * values also adhere to the above formula, but may need special attention.
  * Here are some examples of the value representation:
  *
  *      0.5: val1 =  0, val2 =  500000
  *     -0.5: val1 =  0, val2 = -500000
  *     -1.0: val1 = -1, val2 =  0
  *     -1.5: val1 = -1, val2 = -500000
  */
 struct sensor_value {
 	/** Integer part of the value. */
 	int32_t val1;
 	/** Fractional part of the value (in one-millionth parts). */
 	int32_t val2;
 };

 /**
  * @brief Sensor channels.
  */
 enum sensor_channel {
 	/** Acceleration on the X axis, in m/s^2. */
 	SENSOR_CHAN_ACCEL_X,
 	/** Acceleration on the Y axis, in m/s^2. */
 	SENSOR_CHAN_ACCEL_Y,
 	/** Acceleration on the Z axis, in m/s^2. */
 	SENSOR_CHAN_ACCEL_Z,
 	/** Acceleration on the X, Y and Z axes. */
 	SENSOR_CHAN_ACCEL_XYZ,
 	/** Angular velocity around the X axis, in radians/s. */
 	SENSOR_CHAN_GYRO_X,
 	/** Angular velocity around the Y axis, in radians/s. */
 	SENSOR_CHAN_GYRO_Y,
 	/** Angular velocity around the Z axis, in radians/s. */
 	SENSOR_CHAN_GYRO_Z,
 	/** Angular velocity around the X, Y and Z axes. */
 	SENSOR_CHAN_GYRO_XYZ,
 	/** Magnetic field on the X axis, in Gauss. */
 	SENSOR_CHAN_MAGN_X,
 	/** Magnetic field on the Y axis, in Gauss. */
 	SENSOR_CHAN_MAGN_Y,
 	/** Magnetic field on the Z axis, in Gauss. */
 	SENSOR_CHAN_MAGN_Z,
 	/** Magnetic field on the X, Y and Z axes. */
 	SENSOR_CHAN_MAGN_XYZ,
 	/** Device die temperature in degrees Celsius. */
 	SENSOR_CHAN_DIE_TEMP,
 	/** Ambient temperature in degrees Celsius. */
 	SENSOR_CHAN_AMBIENT_TEMP,
 	/** Pressure in kilopascal. */
 	SENSOR_CHAN_PRESS,
 	/**
 	 * Proximity.  Adimensional.  A value of 1 indicates that an
 	 * object is close.
 	 */
 	SENSOR_CHAN_PROX,
 	/** Humidity, in percent. */
 	SENSOR_CHAN_HUMIDITY,
 	/** Illuminance in visible spectrum, in lux. */
 	SENSOR_CHAN_LIGHT,
 	/** Illuminance in infra-red spectrum, in lux. */
 	SENSOR_CHAN_IR,
 	/** Illuminance in red spectrum, in lux. */
 	SENSOR_CHAN_RED,
 	/** Illuminance in green spectrum, in lux. */
 	SENSOR_CHAN_GREEN,
 	/** Illuminance in blue spectrum, in lux. */
 	SENSOR_CHAN_BLUE,
 	/** Altitude, in meters */
 	SENSOR_CHAN_ALTITUDE,

 	/** 1.0 micro-meters Particulate Matter, in ug/m^3 */
 	SENSOR_CHAN_PM_1_0,
 	/** 2.5 micro-meters Particulate Matter, in ug/m^3 */
 	SENSOR_CHAN_PM_2_5,
 	/** 10 micro-meters Particulate Matter, in ug/m^3 */
 	SENSOR_CHAN_PM_10,
 	/** Distance. From sensor to target, in meters */
 	SENSOR_CHAN_DISTANCE,

 	/** CO2 level, in parts per million (ppm) **/
 	SENSOR_CHAN_CO2,
 	/** VOC level, in parts per billion (ppb) **/
 	SENSOR_CHAN_VOC,
 	/** Gas sensor resistance in ohms. */
 	SENSOR_CHAN_GAS_RES,

 	/** Voltage, in volts **/
 	SENSOR_CHAN_VOLTAGE,
 	/** Current, in amps **/
 	SENSOR_CHAN_CURRENT,
 	/** Power in watts **/
 	SENSOR_CHAN_POWER,

 	/** Resistance , in Ohm **/
 	SENSOR_CHAN_RESISTANCE,

 	/** Angular rotation, in degrees */
 	SENSOR_CHAN_ROTATION,

 	/** Position change on the X axis, in points. */
 	SENSOR_CHAN_POS_DX,
 	/** Position change on the Y axis, in points. */
 	SENSOR_CHAN_POS_DY,
 	/** Position change on the Z axis, in points. */
 	SENSOR_CHAN_POS_DZ,

 	/** Revolutions per minute, in RPM. */
 	SENSOR_CHAN_RPM,

 	/** Voltage, in volts **/
 	SENSOR_CHAN_GAUGE_VOLTAGE,
 	/** Average current, in amps **/
 	SENSOR_CHAN_GAUGE_AVG_CURRENT,
 	/** Standby current, in amps **/
 	SENSOR_CHAN_GAUGE_STDBY_CURRENT,
 	/** Max load current, in amps **/
 	SENSOR_CHAN_GAUGE_MAX_LOAD_CURRENT,
 	/** Gauge temperature  **/
 	SENSOR_CHAN_GAUGE_TEMP,
 	/** State of charge measurement in % **/
 	SENSOR_CHAN_GAUGE_STATE_OF_CHARGE,
 	/** Full Charge Capacity in mAh **/
 	SENSOR_CHAN_GAUGE_FULL_CHARGE_CAPACITY,
 	/** Remaining Charge Capacity in mAh **/
 	SENSOR_CHAN_GAUGE_REMAINING_CHARGE_CAPACITY,
 	/** Nominal Available Capacity in mAh **/
 	SENSOR_CHAN_GAUGE_NOM_AVAIL_CAPACITY,
 	/** Full Available Capacity in mAh **/
 	SENSOR_CHAN_GAUGE_FULL_AVAIL_CAPACITY,
 	/** Average power in mW **/
 	SENSOR_CHAN_GAUGE_AVG_POWER,
 	/** State of health measurement in % **/
 	SENSOR_CHAN_GAUGE_STATE_OF_HEALTH,
 	/** Time to empty in minutes **/
 	SENSOR_CHAN_GAUGE_TIME_TO_EMPTY,
 	/** Time to full in minutes **/
 	SENSOR_CHAN_GAUGE_TIME_TO_FULL,
 	/** Cycle count (total number of charge/discharge cycles) **/
 	SENSOR_CHAN_GAUGE_CYCLE_COUNT,
 	/** Design voltage of cell in V (max voltage)*/
 	SENSOR_CHAN_GAUGE_DESIGN_VOLTAGE,
 	/** Desired voltage of cell in V (nominal voltage) */
 	SENSOR_CHAN_GAUGE_DESIRED_VOLTAGE,
 	/** Desired charging current in mA */
 	SENSOR_CHAN_GAUGE_DESIRED_CHARGING_CURRENT,

 	/** All channels. */
 	SENSOR_CHAN_ALL,

 	/**
 	 * Number of all common sensor channels.
 	 */
 	SENSOR_CHAN_COMMON_COUNT,

 	/**
 	 * This and higher values are sensor specific.
 	 * Refer to the sensor header file.
 	 */
 	SENSOR_CHAN_PRIV_START = SENSOR_CHAN_COMMON_COUNT,

 	/**
 	 * Maximum value describing a sensor channel type.
 	 */
 	SENSOR_CHAN_MAX = INT16_MAX,
 };

 /**
  * @brief Sensor trigger types.
  */
 enum sensor_trigger_type {
 	/**
 	 * Timer-based trigger, useful when the sensor does not have an
 	 * interrupt line.
 	 */
 	SENSOR_TRIG_TIMER,
 	/** Trigger fires whenever new data is ready. */
 	SENSOR_TRIG_DATA_READY,
 	/**
 	 * Trigger fires when the selected channel varies significantly.
 	 * This includes any-motion detection when the channel is
 	 * acceleration or gyro. If detection is based on slope between
 	 * successive channel readings, the slope threshold is configured
 	 * via the @ref SENSOR_ATTR_SLOPE_TH and @ref SENSOR_ATTR_SLOPE_DUR
 	 * attributes.
 	 */
 	SENSOR_TRIG_DELTA,
 	/** Trigger fires when a near/far event is detected. */
 	SENSOR_TRIG_NEAR_FAR,
 	/**
 	 * Trigger fires when channel reading transitions configured
 	 * thresholds.  The thresholds are configured via the @ref
 	 * SENSOR_ATTR_LOWER_THRESH, @ref SENSOR_ATTR_UPPER_THRESH, and
 	 * @ref SENSOR_ATTR_HYSTERESIS attributes.
 	 */
 	SENSOR_TRIG_THRESHOLD,

 	/** Trigger fires when a single tap is detected. */
 	SENSOR_TRIG_TAP,

 	/** Trigger fires when a double tap is detected. */
 	SENSOR_TRIG_DOUBLE_TAP,

 	/** Trigger fires when a free fall is detected. */
 	SENSOR_TRIG_FREEFALL,

 	/** Trigger fires when motion is detected. */
 	SENSOR_TRIG_MOTION,

 	/** Trigger fires when no motion has been detected for a while. */
 	SENSOR_TRIG_STATIONARY,
 	/**
 	 * Number of all common sensor triggers.
 	 */
 	SENSOR_TRIG_COMMON_COUNT,

 	/**
 	 * This and higher values are sensor specific.
 	 * Refer to the sensor header file.
 	 */
 	SENSOR_TRIG_PRIV_START = SENSOR_TRIG_COMMON_COUNT,

 	/**
 	 * Maximum value describing a sensor trigger type.
 	 */
 	SENSOR_TRIG_MAX = INT16_MAX,
 };

 /**
  * @brief Sensor trigger spec.
  */
 struct sensor_trigger {
 	/** Trigger type. */
 	enum sensor_trigger_type type;
 	/** Channel the trigger is set on. */
 	enum sensor_channel chan;
 };

 /**
  * @brief Sensor attribute types.
  */
 enum sensor_attribute {
 	/**
 	 * Sensor sampling frequency, i.e. how many times a second the
 	 * sensor takes a measurement.
 	 */
 	SENSOR_ATTR_SAMPLING_FREQUENCY,
 	/** Lower threshold for trigger. */
 	SENSOR_ATTR_LOWER_THRESH,
 	/** Upper threshold for trigger. */
 	SENSOR_ATTR_UPPER_THRESH,
 	/** Threshold for any-motion (slope) trigger. */
 	SENSOR_ATTR_SLOPE_TH,
 	/**
 	 * Duration for which the slope values needs to be
 	 * outside the threshold for the trigger to fire.
 	 */
 	SENSOR_ATTR_SLOPE_DUR,
 	/* Hysteresis for trigger thresholds. */
 	SENSOR_ATTR_HYSTERESIS,
 	/** Oversampling factor */
 	SENSOR_ATTR_OVERSAMPLING,
 	/** Sensor range, in SI units. */
 	SENSOR_ATTR_FULL_SCALE,
 	/**
 	 * The sensor value returned will be altered by the amount indicated by
 	 * offset: final_value = sensor_value + offset.
 	 */
 	SENSOR_ATTR_OFFSET,
 	/**
 	 * Calibration target. This will be used by the internal chip's
 	 * algorithms to calibrate itself on a certain axis, or all of them.
 	 */
 	SENSOR_ATTR_CALIB_TARGET,
 	/** Configure the operating modes of a sensor. */
 	SENSOR_ATTR_CONFIGURATION,
 	/** Set a calibration value needed by a sensor. */
 	SENSOR_ATTR_CALIBRATION,
 	/** Enable/disable sensor features */
 	SENSOR_ATTR_FEATURE_MASK,
 	/** Alert threshold or alert enable/disable */
 	SENSOR_ATTR_ALERT,

 	/**
 	 * Number of all common sensor attributes.
 	 */
 	SENSOR_ATTR_COMMON_COUNT,

 	/**
 	 * This and higher values are sensor specific.
 	 * Refer to the sensor header file.
 	 */
 	SENSOR_ATTR_PRIV_START = SENSOR_ATTR_COMMON_COUNT,

 	/**
 	 * Maximum value describing a sensor attribute type.
 	 */
 	SENSOR_ATTR_MAX = INT16_MAX,
 };

 /**
  * @typedef sensor_trigger_handler_t
  * @brief Callback API upon firing of a trigger
  *
  * @param dev Pointer to the sensor device
  * @param trigger The trigger
  */
 typedef void (*sensor_trigger_handler_t)(const struct device *dev,
 					 const struct sensor_trigger *trigger);

 /**
  * @typedef sensor_attr_set_t
  * @brief Callback API upon setting a sensor's attributes
  *
  * See sensor_attr_set() for argument description
  */
 typedef int (*sensor_attr_set_t)(const struct device *dev,
 				 enum sensor_channel chan,
 				 enum sensor_attribute attr,
 				 const struct sensor_value *val);

 /**
  * @typedef sensor_attr_get_t
  * @brief Callback API upon getting a sensor's attributes
  *
  * See sensor_attr_get() for argument description
  */
 typedef int (*sensor_attr_get_t)(const struct device *dev,
 				 enum sensor_channel chan,
 				 enum sensor_attribute attr,
 				 struct sensor_value *val);

 /**
  * @typedef sensor_trigger_set_t
  * @brief Callback API for setting a sensor's trigger and handler
  *
  * See sensor_trigger_set() for argument description
  */
 typedef int (*sensor_trigger_set_t)(const struct device *dev,
 				    const struct sensor_trigger *trig,
 				    sensor_trigger_handler_t handler);
 /**
  * @typedef sensor_sample_fetch_t
  * @brief Callback API for fetching data from a sensor
  *
  * See sensor_sample_fetch() for argument description
  */
 typedef int (*sensor_sample_fetch_t)(const struct device *dev,
 				     enum sensor_channel chan);
 /**
  * @typedef sensor_channel_get_t
  * @brief Callback API for getting a reading from a sensor
  *
  * See sensor_channel_get() for argument description
  */
 typedef int (*sensor_channel_get_t)(const struct device *dev,
 				    enum sensor_channel chan,
 				    struct sensor_value *val);

 __subsystem struct sensor_driver_api {
 	sensor_attr_set_t attr_set;
 	sensor_attr_get_t attr_get;
 	sensor_trigger_set_t trigger_set;
 	sensor_sample_fetch_t sample_fetch;
 	sensor_channel_get_t channel_get;
 };

 /**
  * @brief Set an attribute for a sensor
  *
  * @param dev Pointer to the sensor device
  * @param chan The channel the attribute belongs to, if any.  Some
  * attributes may only be set for all channels of a device, depending on
  * device capabilities.
  * @param attr The attribute to set
  * @param val The value to set the attribute to
  *
  * @return 0 if successful, negative errno code if failure.
  */
 __syscall int sensor_attr_set(const struct device *dev,
 			      enum sensor_channel chan,
 			      enum sensor_attribute attr,
 			      const struct sensor_value *val);

 static inline int z_impl_sensor_attr_set(const struct device *dev,
 					 enum sensor_channel chan,
 					 enum sensor_attribute attr,
 					 const struct sensor_value *val)
 {
 	const struct sensor_driver_api *api =
 		(const struct sensor_driver_api *)dev->api;

 	if (api->attr_set == NULL) {
 		return -ENOSYS;
 	}

 	return api->attr_set(dev, chan, attr, val);
 }

 /**
  * @brief Get an attribute for a sensor
  *
  * @param dev Pointer to the sensor device
  * @param chan The channel the attribute belongs to, if any.  Some
  * attributes may only be set for all channels of a device, depending on
  * device capabilities.
  * @param attr The attribute to get
  * @param val Pointer to where to store the attribute
  *
  * @return 0 if successful, negative errno code if failure.
  */
 __syscall int sensor_attr_get(const struct device *dev,
 			      enum sensor_channel chan,
 			      enum sensor_attribute attr,
 			      struct sensor_value *val);

 static inline int z_impl_sensor_attr_get(const struct device *dev,
 					 enum sensor_channel chan,
 					 enum sensor_attribute attr,
 					 struct sensor_value *val)
 {
 	const struct sensor_driver_api *api =
 		(const struct sensor_driver_api *)dev->api;

 	if (api->attr_get == NULL) {
 		return -ENOSYS;
 	}

 	return api->attr_get(dev, chan, attr, val);
 }

 /**
  * @brief Activate a sensor's trigger and set the trigger handler
  *
  * The handler will be called from a thread, so I2C or SPI operations are
  * safe.  However, the thread's stack is limited and defined by the
  * driver.  It is currently up to the caller to ensure that the handler
  * does not overflow the stack.
  *
  * @funcprops \supervisor
  *
  * @param dev Pointer to the sensor device
  * @param trig The trigger to activate
  * @param handler The function that should be called when the trigger
  * fires
  *
  * @return 0 if successful, negative errno code if failure.
  */
 static inline int sensor_trigger_set(const struct device *dev,
 				     const struct sensor_trigger *trig,
 				     sensor_trigger_handler_t handler)
 {
 	const struct sensor_driver_api *api =
 		(const struct sensor_driver_api *)dev->api;

 	if (api->trigger_set == NULL) {
 		return -ENOSYS;
 	}

 	return api->trigger_set(dev, trig, handler);
 }

 /**
  * @brief Fetch a sample from the sensor and store it in an internal
  * driver buffer
  *
  * Read all of a sensor's active channels and, if necessary, perform any
  * additional operations necessary to make the values useful.  The user
  * may then get individual channel values by calling @ref
  * sensor_channel_get.
  *
  * Since the function communicates with the sensor device, it is unsafe
  * to call it in an ISR if the device is connected via I2C or SPI.
  *
  * @param dev Pointer to the sensor device
  *
  * @return 0 if successful, negative errno code if failure.
  */
 __syscall int sensor_sample_fetch(const struct device *dev);

 static inline int z_impl_sensor_sample_fetch(const struct device *dev)
 {
 	const struct sensor_driver_api *api =
 		(const struct sensor_driver_api *)dev->api;

 	return api->sample_fetch(dev, SENSOR_CHAN_ALL);
 }

 /**
  * @brief Fetch a sample from the sensor and store it in an internal
  * driver buffer
  *
  * Read and compute compensation for one type of sensor data (magnetometer,
  * accelerometer, etc). The user may then get individual channel values by
  * calling @ref sensor_channel_get.
  *
  * This is mostly implemented by multi function devices enabling reading at
  * different sampling rates.
  *
  * Since the function communicates with the sensor device, it is unsafe
  * to call it in an ISR if the device is connected via I2C or SPI.
  *
  * @param dev Pointer to the sensor device
  * @param type The channel that needs updated
  *
  * @return 0 if successful, negative errno code if failure.
  */
 __syscall int sensor_sample_fetch_chan(const struct device *dev,
 				       enum sensor_channel type);

 static inline int z_impl_sensor_sample_fetch_chan(const struct device *dev,
 						  enum sensor_channel type)
 {
 	const struct sensor_driver_api *api =
 		(const struct sensor_driver_api *)dev->api;

 	return api->sample_fetch(dev, type);
 }

 /**
  * @brief Get a reading from a sensor device
  *
  * Return a useful value for a particular channel, from the driver's
  * internal data.  Before calling this function, a sample must be
  * obtained by calling @ref sensor_sample_fetch or
  * @ref sensor_sample_fetch_chan. It is guaranteed that two subsequent
  * calls of this function for the same channels will yield the same
  * value, if @ref sensor_sample_fetch or @ref sensor_sample_fetch_chan
  * has not been called in the meantime.
  *
  * For vectorial data samples you can request all axes in just one call
  * by passing the specific channel with _XYZ suffix. The sample will be
  * returned at val[0], val[1] and val[2] (X, Y and Z in that order).
  *
  * @param dev Pointer to the sensor device
  * @param chan The channel to read
  * @param val Where to store the value
  *
  * @return 0 if successful, negative errno code if failure.
  */
 __syscall int sensor_channel_get(const struct device *dev,
 				 enum sensor_channel chan,
 				 struct sensor_value *val);

 static inline int z_impl_sensor_channel_get(const struct device *dev,
 					    enum sensor_channel chan,
 					    struct sensor_value *val)
 {
 	const struct sensor_driver_api *api =
 		(const struct sensor_driver_api *)dev->api;

 	return api->channel_get(dev, chan, val);
 }

 /**
  * @brief The value of gravitational constant in micro m/s^2.
  */
 #define SENSOR_G		9806650LL

 /**
  * @brief The value of constant PI in micros.
  */
 #define SENSOR_PI		3141592LL

 /**
  * @brief Helper function to convert acceleration from m/s^2 to Gs
  *
  * @param ms2 A pointer to a sensor_value struct holding the acceleration,
  *            in m/s^2.
  *
  * @return The converted value, in Gs.
  */
 static inline int32_t sensor_ms2_to_g(const struct sensor_value *ms2)
 {
 	int64_t micro_ms2 = ms2->val1 * 1000000LL + ms2->val2;

 	if (micro_ms2 > 0) {
 		return (micro_ms2 + SENSOR_G / 2) / SENSOR_G;
 	} else {
 		return (micro_ms2 - SENSOR_G / 2) / SENSOR_G;
 	}
 }

 /**
  * @brief Helper function to convert acceleration from Gs to m/s^2
  *
  * @param g The G value to be converted.
  * @param ms2 A pointer to a sensor_value struct, where the result is stored.
  */
 static inline void sensor_g_to_ms2(int32_t g, struct sensor_value *ms2)
 {
 	ms2->val1 = ((int64_t)g * SENSOR_G) / 1000000LL;
 	ms2->val2 = ((int64_t)g * SENSOR_G) % 1000000LL;
 }

 /**
  * @brief Helper function for converting radians to degrees.
  *
  * @param rad A pointer to a sensor_value struct, holding the value in radians.
  *
  * @return The converted value, in degrees.
  */
 static inline int32_t sensor_rad_to_degrees(const struct sensor_value *rad)
 {
 	int64_t micro_rad_s = rad->val1 * 1000000LL + rad->val2;

 	if (micro_rad_s > 0) {
 		return (micro_rad_s * 180LL + SENSOR_PI / 2) / SENSOR_PI;
 	} else {
 		return (micro_rad_s * 180LL - SENSOR_PI / 2) / SENSOR_PI;
 	}
 }

 /**
  * @brief Helper function for converting degrees to radians.
  *
  * @param d The value (in degrees) to be converted.
  * @param rad A pointer to a sensor_value struct, where the result is stored.
  */
 static inline void sensor_degrees_to_rad(int32_t d, struct sensor_value *rad)
 {
 	rad->val1 = ((int64_t)d * SENSOR_PI / 180LL) / 1000000LL;
 	rad->val2 = ((int64_t)d * SENSOR_PI / 180LL) % 1000000LL;
 }

 /**
  * @brief Helper function for converting struct sensor_value to double.
  *
  * @param val A pointer to a sensor_value struct.
  * @return The converted value.
  */
 static inline double sensor_value_to_double(const struct sensor_value *val)
 {
 	return (double)val->val1 + (double)val->val2 / 1000000;
 }

 /**
  * @brief Helper function for converting double to struct sensor_value.
  *
  * @param val A pointer to a sensor_value struct.
  * @param inp The converted value.
  * @return 0 if successful, negative errno code if failure.
  */
 static inline int sensor_value_from_double(struct sensor_value *val, double inp)
 {
 	if (inp < INT32_MIN || inp > INT32_MAX) {
 		return -ERANGE;
 	}

 	double val2 = (inp - (int32_t)inp) * 1000000.0;

 	if (val2 < INT32_MIN || val2 > INT32_MAX) {
 		return -ERANGE;
 	}

 	val->val1 = (int32_t)inp;
 	val->val2 = (int32_t)val2;

 	return 0;
 }

 /**
  * @}
  */

 #ifdef __cplusplus
 }
 #endif

 #include <syscalls/sensor.h>

 #endif /* ZEPHYR_INCLUDE_DRIVERS_SENSOR_H_ */
	/**
	* @file drivers/sensor.h
	*
	* @brief Public APIs for the sensor driver.
	*/

	/*
	* Copyright (c) 2016 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/
	#ifndef ZEPHYR_INCLUDE_DRIVERS_SENSOR_H_
	#define ZEPHYR_INCLUDE_DRIVERS_SENSOR_H_

	/**
	* @brief Sensor Interface
	* @defgroup sensor_interface Sensor Interface
	* @ingroup io_interfaces
	* @{
	*/

	#include <zephyr/types.h>
	#include <zephyr/device.h>
	#include <errno.h>

	#ifdef __cplusplus
	extern "C" {
	#endif

	/**
	* @brief Representation of a sensor readout value.
	*
	* The value is represented as having an integer and a fractional part,
	* and can be obtained using the formula val1 + val2 * 10^(-6). Negative
	* values also adhere to the above formula, but may need special attention.
	* Here are some examples of the value representation:
	*
	* 0.5: val1 = 0, val2 = 500000
	* -0.5: val1 = 0, val2 = -500000
	* -1.0: val1 = -1, val2 = 0
	* -1.5: val1 = -1, val2 = -500000
	*/
	struct sensor_value {
	/** Integer part of the value. */
	int32_t val1;
	/** Fractional part of the value (in one-millionth parts). */
	int32_t val2;
	};

	/**
	* @brief Sensor channels.
	*/
	enum sensor_channel {
	/** Acceleration on the X axis, in m/s^2. */
	SENSOR_CHAN_ACCEL_X,
	/** Acceleration on the Y axis, in m/s^2. */
	SENSOR_CHAN_ACCEL_Y,
	/** Acceleration on the Z axis, in m/s^2. */
	SENSOR_CHAN_ACCEL_Z,
	/** Acceleration on the X, Y and Z axes. */
	SENSOR_CHAN_ACCEL_XYZ,
	/** Angular velocity around the X axis, in radians/s. */
	SENSOR_CHAN_GYRO_X,
	/** Angular velocity around the Y axis, in radians/s. */
	SENSOR_CHAN_GYRO_Y,
	/** Angular velocity around the Z axis, in radians/s. */
	SENSOR_CHAN_GYRO_Z,
	/** Angular velocity around the X, Y and Z axes. */
	SENSOR_CHAN_GYRO_XYZ,
	/** Magnetic field on the X axis, in Gauss. */
	SENSOR_CHAN_MAGN_X,
	/** Magnetic field on the Y axis, in Gauss. */
	SENSOR_CHAN_MAGN_Y,
	/** Magnetic field on the Z axis, in Gauss. */
	SENSOR_CHAN_MAGN_Z,
	/** Magnetic field on the X, Y and Z axes. */
	SENSOR_CHAN_MAGN_XYZ,
	/** Device die temperature in degrees Celsius. */
	SENSOR_CHAN_DIE_TEMP,
	/** Ambient temperature in degrees Celsius. */
	SENSOR_CHAN_AMBIENT_TEMP,
	/** Pressure in kilopascal. */
	SENSOR_CHAN_PRESS,
	/**
	* Proximity. Adimensional. A value of 1 indicates that an
	* object is close.
	*/
	SENSOR_CHAN_PROX,
	/** Humidity, in percent. */
	SENSOR_CHAN_HUMIDITY,
	/** Illuminance in visible spectrum, in lux. */
	SENSOR_CHAN_LIGHT,
	/** Illuminance in infra-red spectrum, in lux. */
	SENSOR_CHAN_IR,
	/** Illuminance in red spectrum, in lux. */
	SENSOR_CHAN_RED,
	/** Illuminance in green spectrum, in lux. */
	SENSOR_CHAN_GREEN,
	/** Illuminance in blue spectrum, in lux. */
	SENSOR_CHAN_BLUE,
	/** Altitude, in meters */
	SENSOR_CHAN_ALTITUDE,

	/** 1.0 micro-meters Particulate Matter, in ug/m^3 */
	SENSOR_CHAN_PM_1_0,
	/** 2.5 micro-meters Particulate Matter, in ug/m^3 */
	SENSOR_CHAN_PM_2_5,
	/** 10 micro-meters Particulate Matter, in ug/m^3 */
	SENSOR_CHAN_PM_10,
	/** Distance. From sensor to target, in meters */
	SENSOR_CHAN_DISTANCE,

	/ CO2 level, in parts per million (ppm) /
	SENSOR_CHAN_CO2,
	/ VOC level, in parts per billion (ppb) /
	SENSOR_CHAN_VOC,
	/** Gas sensor resistance in ohms. */
	SENSOR_CHAN_GAS_RES,

	/ Voltage, in volts /
	SENSOR_CHAN_VOLTAGE,
	/ Current, in amps /
	SENSOR_CHAN_CURRENT,
	/ Power in watts /
	SENSOR_CHAN_POWER,

	/ Resistance , in Ohm /
	SENSOR_CHAN_RESISTANCE,

	/** Angular rotation, in degrees */
	SENSOR_CHAN_ROTATION,

	/** Position change on the X axis, in points. */
	SENSOR_CHAN_POS_DX,
	/** Position change on the Y axis, in points. */
	SENSOR_CHAN_POS_DY,
	/** Position change on the Z axis, in points. */
	SENSOR_CHAN_POS_DZ,

	/** Revolutions per minute, in RPM. */
	SENSOR_CHAN_RPM,

	/ Voltage, in volts /
	SENSOR_CHAN_GAUGE_VOLTAGE,
	/ Average current, in amps /
	SENSOR_CHAN_GAUGE_AVG_CURRENT,
	/ Standby current, in amps /
	SENSOR_CHAN_GAUGE_STDBY_CURRENT,
	/ Max load current, in amps /
	SENSOR_CHAN_GAUGE_MAX_LOAD_CURRENT,
	/ Gauge temperature /
	SENSOR_CHAN_GAUGE_TEMP,
	/ State of charge measurement in % /
	SENSOR_CHAN_GAUGE_STATE_OF_CHARGE,
	/ Full Charge Capacity in mAh /
	SENSOR_CHAN_GAUGE_FULL_CHARGE_CAPACITY,
	/ Remaining Charge Capacity in mAh /
	SENSOR_CHAN_GAUGE_REMAINING_CHARGE_CAPACITY,
	/ Nominal Available Capacity in mAh /
	SENSOR_CHAN_GAUGE_NOM_AVAIL_CAPACITY,
	/ Full Available Capacity in mAh /
	SENSOR_CHAN_GAUGE_FULL_AVAIL_CAPACITY,
	/ Average power in mW /
	SENSOR_CHAN_GAUGE_AVG_POWER,
	/ State of health measurement in % /
	SENSOR_CHAN_GAUGE_STATE_OF_HEALTH,
	/ Time to empty in minutes /
	SENSOR_CHAN_GAUGE_TIME_TO_EMPTY,
	/ Time to full in minutes /
	SENSOR_CHAN_GAUGE_TIME_TO_FULL,
	/ Cycle count (total number of charge/discharge cycles) /
	SENSOR_CHAN_GAUGE_CYCLE_COUNT,
	/** Design voltage of cell in V (max voltage)*/
	SENSOR_CHAN_GAUGE_DESIGN_VOLTAGE,
	/** Desired voltage of cell in V (nominal voltage) */
	SENSOR_CHAN_GAUGE_DESIRED_VOLTAGE,
	/** Desired charging current in mA */
	SENSOR_CHAN_GAUGE_DESIRED_CHARGING_CURRENT,

	/** All channels. */
	SENSOR_CHAN_ALL,

	/**
	* Number of all common sensor channels.
	*/
	SENSOR_CHAN_COMMON_COUNT,

	/**
	* This and higher values are sensor specific.
	* Refer to the sensor header file.
	*/
	SENSOR_CHAN_PRIV_START = SENSOR_CHAN_COMMON_COUNT,

	/**
	* Maximum value describing a sensor channel type.
	*/
	SENSOR_CHAN_MAX = INT16_MAX,
	};

	/**
	* @brief Sensor trigger types.
	*/
	enum sensor_trigger_type {
	/**
	* Timer-based trigger, useful when the sensor does not have an
	* interrupt line.
	*/
	SENSOR_TRIG_TIMER,
	/** Trigger fires whenever new data is ready. */
	SENSOR_TRIG_DATA_READY,
	/**
	* Trigger fires when the selected channel varies significantly.
	* This includes any-motion detection when the channel is
	* acceleration or gyro. If detection is based on slope between
	* successive channel readings, the slope threshold is configured
	* via the @ref SENSOR_ATTR_SLOPE_TH and @ref SENSOR_ATTR_SLOPE_DUR
	* attributes.
	*/
	SENSOR_TRIG_DELTA,
	/** Trigger fires when a near/far event is detected. */
	SENSOR_TRIG_NEAR_FAR,
	/**
	* Trigger fires when channel reading transitions configured
	* thresholds. The thresholds are configured via the @ref
	* SENSOR_ATTR_LOWER_THRESH, @ref SENSOR_ATTR_UPPER_THRESH, and
	* @ref SENSOR_ATTR_HYSTERESIS attributes.
	*/
	SENSOR_TRIG_THRESHOLD,

	/** Trigger fires when a single tap is detected. */
	SENSOR_TRIG_TAP,

	/** Trigger fires when a double tap is detected. */
	SENSOR_TRIG_DOUBLE_TAP,

	/** Trigger fires when a free fall is detected. */
	SENSOR_TRIG_FREEFALL,

	/** Trigger fires when motion is detected. */
	SENSOR_TRIG_MOTION,

	/** Trigger fires when no motion has been detected for a while. */
	SENSOR_TRIG_STATIONARY,
	/**
	* Number of all common sensor triggers.
	*/
	SENSOR_TRIG_COMMON_COUNT,

	/**
	* This and higher values are sensor specific.
	* Refer to the sensor header file.
	*/
	SENSOR_TRIG_PRIV_START = SENSOR_TRIG_COMMON_COUNT,

	/**
	* Maximum value describing a sensor trigger type.
	*/
	SENSOR_TRIG_MAX = INT16_MAX,
	};

	/**
	* @brief Sensor trigger spec.
	*/
	struct sensor_trigger {
	/** Trigger type. */
	enum sensor_trigger_type type;
	/** Channel the trigger is set on. */
	enum sensor_channel chan;
	};

	/**
	* @brief Sensor attribute types.
	*/
	enum sensor_attribute {
	/**
	* Sensor sampling frequency, i.e. how many times a second the
	* sensor takes a measurement.
	*/
	SENSOR_ATTR_SAMPLING_FREQUENCY,
	/** Lower threshold for trigger. */
	SENSOR_ATTR_LOWER_THRESH,
	/** Upper threshold for trigger. */
	SENSOR_ATTR_UPPER_THRESH,
	/** Threshold for any-motion (slope) trigger. */
	SENSOR_ATTR_SLOPE_TH,
	/**
	* Duration for which the slope values needs to be
	* outside the threshold for the trigger to fire.
	*/
	SENSOR_ATTR_SLOPE_DUR,
	/* Hysteresis for trigger thresholds. */
	SENSOR_ATTR_HYSTERESIS,
	/** Oversampling factor */
	SENSOR_ATTR_OVERSAMPLING,
	/** Sensor range, in SI units. */
	SENSOR_ATTR_FULL_SCALE,
	/**
	* The sensor value returned will be altered by the amount indicated by
	* offset: final_value = sensor_value + offset.
	*/
	SENSOR_ATTR_OFFSET,
	/**
	* Calibration target. This will be used by the internal chip's
	* algorithms to calibrate itself on a certain axis, or all of them.
	*/
	SENSOR_ATTR_CALIB_TARGET,
	/** Configure the operating modes of a sensor. */
	SENSOR_ATTR_CONFIGURATION,
	/** Set a calibration value needed by a sensor. */
	SENSOR_ATTR_CALIBRATION,
	/** Enable/disable sensor features */
	SENSOR_ATTR_FEATURE_MASK,
	/** Alert threshold or alert enable/disable */
	SENSOR_ATTR_ALERT,

	/**
	* Number of all common sensor attributes.
	*/
	SENSOR_ATTR_COMMON_COUNT,

	/**
	* This and higher values are sensor specific.
	* Refer to the sensor header file.
	*/
	SENSOR_ATTR_PRIV_START = SENSOR_ATTR_COMMON_COUNT,

	/**
	* Maximum value describing a sensor attribute type.
	*/
	SENSOR_ATTR_MAX = INT16_MAX,
	};

	/**
	* @typedef sensor_trigger_handler_t
	* @brief Callback API upon firing of a trigger
	*
	* @param dev Pointer to the sensor device
	* @param trigger The trigger
	*/
	typedef void (sensor_trigger_handler_t)(const struct device dev,
	const struct sensor_trigger *trigger);

	/**
	* @typedef sensor_attr_set_t
	* @brief Callback API upon setting a sensor's attributes
	*
	* See sensor_attr_set() for argument description
	*/
	typedef int (sensor_attr_set_t)(const struct device dev,
	enum sensor_channel chan,
	enum sensor_attribute attr,
	const struct sensor_value *val);

	/**
	* @typedef sensor_attr_get_t
	* @brief Callback API upon getting a sensor's attributes
	*
	* See sensor_attr_get() for argument description
	*/
	typedef int (sensor_attr_get_t)(const struct device dev,
	enum sensor_channel chan,
	enum sensor_attribute attr,
	struct sensor_value *val);

	/**
	* @typedef sensor_trigger_set_t
	* @brief Callback API for setting a sensor's trigger and handler
	*
	* See sensor_trigger_set() for argument description
	*/
	typedef int (sensor_trigger_set_t)(const struct device dev,
	const struct sensor_trigger *trig,
	sensor_trigger_handler_t handler);
	/**
	* @typedef sensor_sample_fetch_t
	* @brief Callback API for fetching data from a sensor
	*
	* See sensor_sample_fetch() for argument description
	*/
	typedef int (sensor_sample_fetch_t)(const struct device dev,
	enum sensor_channel chan);
	/**
	* @typedef sensor_channel_get_t
	* @brief Callback API for getting a reading from a sensor
	*
	* See sensor_channel_get() for argument description
	*/
	typedef int (sensor_channel_get_t)(const struct device dev,
	enum sensor_channel chan,
	struct sensor_value *val);

	__subsystem struct sensor_driver_api {
	sensor_attr_set_t attr_set;
	sensor_attr_get_t attr_get;
	sensor_trigger_set_t trigger_set;
	sensor_sample_fetch_t sample_fetch;
	sensor_channel_get_t channel_get;
	};

	/**
	* @brief Set an attribute for a sensor
	*
	* @param dev Pointer to the sensor device
	* @param chan The channel the attribute belongs to, if any. Some
	* attributes may only be set for all channels of a device, depending on
	* device capabilities.
	* @param attr The attribute to set
	* @param val The value to set the attribute to
	*
	* @return 0 if successful, negative errno code if failure.
	*/
	__syscall int sensor_attr_set(const struct device *dev,
	enum sensor_channel chan,
	enum sensor_attribute attr,
	const struct sensor_value *val);

	static inline int z_impl_sensor_attr_set(const struct device *dev,
	enum sensor_channel chan,
	enum sensor_attribute attr,
	const struct sensor_value *val)
	{
	const struct sensor_driver_api *api =
	(const struct sensor_driver_api *)dev->api;

	if (api->attr_set == NULL) {
	return -ENOSYS;
	}

	return api->attr_set(dev, chan, attr, val);
	}

	/**
	* @brief Get an attribute for a sensor
	*
	* @param dev Pointer to the sensor device
	* @param chan The channel the attribute belongs to, if any. Some
	* attributes may only be set for all channels of a device, depending on
	* device capabilities.
	* @param attr The attribute to get
	* @param val Pointer to where to store the attribute
	*
	* @return 0 if successful, negative errno code if failure.
	*/
	__syscall int sensor_attr_get(const struct device *dev,
	enum sensor_channel chan,
	enum sensor_attribute attr,
	struct sensor_value *val);

	static inline int z_impl_sensor_attr_get(const struct device *dev,
	enum sensor_channel chan,
	enum sensor_attribute attr,
	struct sensor_value *val)
	{
	const struct sensor_driver_api *api =
	(const struct sensor_driver_api *)dev->api;

	if (api->attr_get == NULL) {
	return -ENOSYS;
	}

	return api->attr_get(dev, chan, attr, val);
	}

	/**
	* @brief Activate a sensor's trigger and set the trigger handler
	*
	* The handler will be called from a thread, so I2C or SPI operations are
	* safe. However, the thread's stack is limited and defined by the
	* driver. It is currently up to the caller to ensure that the handler
	* does not overflow the stack.
	*
	* @funcprops \supervisor
	*
	* @param dev Pointer to the sensor device
	* @param trig The trigger to activate
	* @param handler The function that should be called when the trigger
	* fires
	*
	* @return 0 if successful, negative errno code if failure.
	*/
	static inline int sensor_trigger_set(const struct device *dev,
	const struct sensor_trigger *trig,
	sensor_trigger_handler_t handler)
	{
	const struct sensor_driver_api *api =
	(const struct sensor_driver_api *)dev->api;

	if (api->trigger_set == NULL) {
	return -ENOSYS;
	}

	return api->trigger_set(dev, trig, handler);
	}

	/**
	* @brief Fetch a sample from the sensor and store it in an internal
	* driver buffer
	*
	* Read all of a sensor's active channels and, if necessary, perform any
	* additional operations necessary to make the values useful. The user
	* may then get individual channel values by calling @ref
	* sensor_channel_get.
	*
	* Since the function communicates with the sensor device, it is unsafe
	* to call it in an ISR if the device is connected via I2C or SPI.
	*
	* @param dev Pointer to the sensor device
	*
	* @return 0 if successful, negative errno code if failure.
	*/
	__syscall int sensor_sample_fetch(const struct device *dev);

	static inline int z_impl_sensor_sample_fetch(const struct device *dev)
	{
	const struct sensor_driver_api *api =
	(const struct sensor_driver_api *)dev->api;

	return api->sample_fetch(dev, SENSOR_CHAN_ALL);
	}

	/**
	* @brief Fetch a sample from the sensor and store it in an internal
	* driver buffer
	*
	* Read and compute compensation for one type of sensor data (magnetometer,
	* accelerometer, etc). The user may then get individual channel values by
	* calling @ref sensor_channel_get.
	*
	* This is mostly implemented by multi function devices enabling reading at
	* different sampling rates.
	*
	* Since the function communicates with the sensor device, it is unsafe
	* to call it in an ISR if the device is connected via I2C or SPI.
	*
	* @param dev Pointer to the sensor device
	* @param type The channel that needs updated
	*
	* @return 0 if successful, negative errno code if failure.
	*/
	__syscall int sensor_sample_fetch_chan(const struct device *dev,
	enum sensor_channel type);

	static inline int z_impl_sensor_sample_fetch_chan(const struct device *dev,
	enum sensor_channel type)
	{
	const struct sensor_driver_api *api =
	(const struct sensor_driver_api *)dev->api;

	return api->sample_fetch(dev, type);
	}

	/**
	* @brief Get a reading from a sensor device
	*
	* Return a useful value for a particular channel, from the driver's
	* internal data. Before calling this function, a sample must be
	* obtained by calling @ref sensor_sample_fetch or
	* @ref sensor_sample_fetch_chan. It is guaranteed that two subsequent
	* calls of this function for the same channels will yield the same
	* value, if @ref sensor_sample_fetch or @ref sensor_sample_fetch_chan
	* has not been called in the meantime.
	*
	* For vectorial data samples you can request all axes in just one call
	* by passing the specific channel with _XYZ suffix. The sample will be
	* returned at val[0], val[1] and val[2] (X, Y and Z in that order).
	*
	* @param dev Pointer to the sensor device
	* @param chan The channel to read
	* @param val Where to store the value
	*
	* @return 0 if successful, negative errno code if failure.
	*/
	__syscall int sensor_channel_get(const struct device *dev,
	enum sensor_channel chan,
	struct sensor_value *val);

	static inline int z_impl_sensor_channel_get(const struct device *dev,
	enum sensor_channel chan,
	struct sensor_value *val)
	{
	const struct sensor_driver_api *api =
	(const struct sensor_driver_api *)dev->api;

	return api->channel_get(dev, chan, val);
	}

	/**
	* @brief The value of gravitational constant in micro m/s^2.
	*/
	#define SENSOR_G 9806650LL

	/**
	* @brief The value of constant PI in micros.
	*/
	#define SENSOR_PI 3141592LL

	/**
	* @brief Helper function to convert acceleration from m/s^2 to Gs
	*
	* @param ms2 A pointer to a sensor_value struct holding the acceleration,
	* in m/s^2.
	*
	* @return The converted value, in Gs.
	*/
	static inline int32_t sensor_ms2_to_g(const struct sensor_value *ms2)
	{
	int64_t micro_ms2 = ms2->val1 * 1000000LL + ms2->val2;

	if (micro_ms2 > 0) {
	return (micro_ms2 + SENSOR_G / 2) / SENSOR_G;
	} else {
	return (micro_ms2 - SENSOR_G / 2) / SENSOR_G;
	}
	}

	/**
	* @brief Helper function to convert acceleration from Gs to m/s^2
	*
	* @param g The G value to be converted.
	* @param ms2 A pointer to a sensor_value struct, where the result is stored.
	*/
	static inline void sensor_g_to_ms2(int32_t g, struct sensor_value *ms2)
	{
	ms2->val1 = ((int64_t)g * SENSOR_G) / 1000000LL;
	ms2->val2 = ((int64_t)g * SENSOR_G) % 1000000LL;
	}

	/**
	* @brief Helper function for converting radians to degrees.
	*
	* @param rad A pointer to a sensor_value struct, holding the value in radians.
	*
	* @return The converted value, in degrees.
	*/
	static inline int32_t sensor_rad_to_degrees(const struct sensor_value *rad)
	{
	int64_t micro_rad_s = rad->val1 * 1000000LL + rad->val2;

	if (micro_rad_s > 0) {
	return (micro_rad_s * 180LL + SENSOR_PI / 2) / SENSOR_PI;
	} else {
	return (micro_rad_s * 180LL - SENSOR_PI / 2) / SENSOR_PI;
	}
	}

	/**
	* @brief Helper function for converting degrees to radians.
	*
	* @param d The value (in degrees) to be converted.
	* @param rad A pointer to a sensor_value struct, where the result is stored.
	*/
	static inline void sensor_degrees_to_rad(int32_t d, struct sensor_value *rad)
	{
	rad->val1 = ((int64_t)d * SENSOR_PI / 180LL) / 1000000LL;
	rad->val2 = ((int64_t)d * SENSOR_PI / 180LL) % 1000000LL;
	}

	/**
	* @brief Helper function for converting struct sensor_value to double.
	*
	* @param val A pointer to a sensor_value struct.
	* @return The converted value.
	*/
	static inline double sensor_value_to_double(const struct sensor_value *val)
	{
	return (double)val->val1 + (double)val->val2 / 1000000;
	}

	/**
	* @brief Helper function for converting double to struct sensor_value.
	*
	* @param val A pointer to a sensor_value struct.
	* @param inp The converted value.
	* @return 0 if successful, negative errno code if failure.
	*/
	static inline int sensor_value_from_double(struct sensor_value *val, double inp)
	{
	if (inp < INT32_MIN \|\| inp > INT32_MAX) {
	return -ERANGE;
	}

	double val2 = (inp - (int32_t)inp) * 1000000.0;

	if (val2 < INT32_MIN \|\| val2 > INT32_MAX) {
	return -ERANGE;
	}

	val->val1 = (int32_t)inp;
	val->val2 = (int32_t)val2;

	return 0;
	}

	/**
	* @}
	*/

	#ifdef __cplusplus
	}
	#endif

	#include <syscalls/sensor.h>

	#endif /* ZEPHYR_INCLUDE_DRIVERS_SENSOR_H_ */