60xx/libsensors_iio/software/core/mllite/data_builder.h - platform/hardware/invensense - Git at Google

 /*
  $License:
     Copyright (C) 2011-2012 InvenSense Corporation, All Rights Reserved.
     See included License.txt for License information.
  $
  */
 #include "mltypes.h"

 #ifndef INV_DATA_BUILDER_H__
 #define INV_DATA_BUILDER_H__

 #ifdef __cplusplus
 extern "C" {
 #endif

 // Uncomment this flag to enable playback debug and record or playback scenarios
 //#define INV_PLAYBACK_DBG

 /** This is a new sample of accel data */
 #define INV_ACCEL_NEW 1
 /** This is a new sample of gyro data */
 #define INV_GYRO_NEW 2
 /** This is a new sample of compass data */
 #define INV_MAG_NEW 4
 /** This is a new sample of temperature data */
 #define INV_TEMP_NEW 8
 /** This is a new sample of quaternion data */
 #define INV_QUAT_NEW 16
 /** Set if quaternion is 6-axis from DMP */
 #define INV_QUAT_6AXIS 1024
 /** Set if quaternion is 3-axis from DMP */
 #define INV_QUAT_3AXIS 4096

 /** Set if the data is contiguous. Typically not set if a sample was skipped */
 #define INV_CONTIGUOUS 16
 /** Set if the calibrated data has been solved for */
 #define INV_CALIBRATED 32
 /* INV_NEW_DATA set for a new set of data, cleared if not available. */
 #define INV_NEW_DATA 64
 /* Set if raw data exists */
 #define INV_RAW_DATA 128
 /* Set if the sensor is on */
 #define INV_SENSOR_ON 256
 /* Set if quaternion has bias correction applied */
 #define INV_BIAS_APPLIED 512

 #define INV_PRIORITY_MOTION_NO_MOTION          100
 #define INV_PRIORITY_GYRO_TC                   150
 #define INV_PRIORITY_QUATERNION_GYRO_ACCEL     200
 #define INV_PRIORITY_QUATERNION_NO_GYRO        250
 #define INV_PRIORITY_MAGNETIC_DISTURBANCE      300
 #define INV_PRIORITY_HEADING_FROM_GYRO         350
 #define INV_PRIORITY_COMPASS_BIAS_W_GYRO       375
 #define INV_PRIORITY_COMPASS_VECTOR_CAL        400
 #define INV_PRIORITY_COMPASS_ADV_BIAS          500
 #define INV_PRIORITY_9_AXIS_FUSION             600
 #define INV_PRIORITY_QUATERNION_ADJUST_9_AXIS  700
 #define INV_PRIORITY_QUATERNION_ACCURACY       750
 #define INV_PRIORITY_RESULTS_HOLDER            800
 #define INV_PRIORITY_INUSE_AUTO_CALIBRATION    850
 #define INV_PRIORITY_HAL_OUTPUTS               900
 #define INV_PRIORITY_GLYPH                     950
 #define INV_PRIORITY_SHAKE                     975
 #define INV_PRIORITY_SM                        1000

 struct inv_single_sensor_t {
     /** Orientation Descriptor. Describes how to go from the mounting frame to the body frame when
     * the rotation matrix could be thought of only having elements of 0,1,-1.
     * 2 bits are used to describe the column of the 1 or -1 and the 3rd bit is used for the sign.
     * Bit 8 is sign of +/- 1 in third row. Bit 6-7 is column of +/-1 in third row.
     * Bit 5 is sign of +/- 1 in second row. Bit 3-4 is column of +/-1 in second row.
     * Bit 2 is sign of +/- 1 in first row. Bit 0-1 is column of +/-1 in first row.
     */
     int orientation;
     /** The raw data in raw data units in the mounting frame */
     short raw[3];
     /** Raw data in body frame */
     long raw_scaled[3];
     /** Calibrated data */
     long calibrated[3];
     long sensitivity;
     /** Sample rate in microseconds */
     long sample_rate_us;
     long sample_rate_ms;
     /** INV_CONTIGUOUS is set for contiguous data. Will not be set if there was a sample
     * skipped due to power savings turning off this sensor.
     * INV_NEW_DATA set for a new set of data, cleared if not available.
     * INV_CALIBRATED_SET if calibrated data has been solved for */
     int status;
     /** 0 to 3 for how well sensor data and biases are known. 3 is most accurate. */
     int accuracy;
     inv_time_t timestamp;
     inv_time_t timestamp_prev;
     /** Bandwidth in Hz */
     int bandwidth;
 };
 struct inv_quat_sensor_t {
     long raw[4];
     /** INV_CONTIGUOUS is set for contiguous data. Will not be set if there was a sample
     * skipped due to power savings turning off this sensor.
     * INV_NEW_DATA set for a new set of data, cleared if not available.
     * INV_CALIBRATED_SET if calibrated data has been solved for */
     int status;
     inv_time_t timestamp;
     inv_time_t timestamp_prev;
     long sample_rate_us;
     long sample_rate_ms;
 };

 struct inv_sensor_cal_t {
     struct inv_single_sensor_t gyro;
     struct inv_single_sensor_t accel;
     struct inv_single_sensor_t compass;
     struct inv_single_sensor_t temp;
     struct inv_quat_sensor_t quat;
     /** Combinations of INV_GYRO_NEW, INV_ACCEL_NEW, INV_MAG_NEW to indicate
     * which data is a new sample as these data points may have different sample rates.
     */
     int status;
 };

 // Useful for debug record and playback
 typedef enum {
     RD_NO_DEBUG,
     RD_RECORD,
     RD_PLAYBACK
 } rd_dbg_mode;

 typedef enum {
     PLAYBACK_DBG_TYPE_GYRO,
     PLAYBACK_DBG_TYPE_ACCEL,
     PLAYBACK_DBG_TYPE_COMPASS,
     PLAYBACK_DBG_TYPE_TEMPERATURE,
     PLAYBACK_DBG_TYPE_EXECUTE,
     PLAYBACK_DBG_TYPE_A_ORIENT,
     PLAYBACK_DBG_TYPE_G_ORIENT,
     PLAYBACK_DBG_TYPE_C_ORIENT,
     PLAYBACK_DBG_TYPE_A_SAMPLE_RATE,
     PLAYBACK_DBG_TYPE_C_SAMPLE_RATE,
     PLAYBACK_DBG_TYPE_G_SAMPLE_RATE,
     PLAYBACK_DBG_TYPE_GYRO_OFF,
     PLAYBACK_DBG_TYPE_ACCEL_OFF,
     PLAYBACK_DBG_TYPE_COMPASS_OFF,
     PLAYBACK_DBG_TYPE_Q_SAMPLE_RATE,
     PLAYBACK_DBG_TYPE_QUAT

 } inv_rd_dbg_states;

 /** Maximum number of data callbacks that are supported. Safe to increase if needed.*/
 #define INV_MAX_DATA_CB 20

 #ifdef INV_PLAYBACK_DBG
 #include <stdio.h>
 void inv_turn_on_data_logging(FILE *file);
 void inv_turn_off_data_logging();
 #endif

 void inv_set_gyro_orientation_and_scale(int orientation, long sensitivity);
 void inv_set_accel_orientation_and_scale(int orientation,
         long sensitivity);
 void inv_set_compass_orientation_and_scale(int orientation,
         long sensitivity);
 void inv_set_gyro_sample_rate(long sample_rate_us);
 void inv_set_compass_sample_rate(long sample_rate_us);
 void inv_set_quat_sample_rate(long sample_rate_us);
 void inv_set_accel_sample_rate(long sample_rate_us);
 void inv_set_gyro_bandwidth(int bandwidth_hz);
 void inv_set_accel_bandwidth(int bandwidth_hz);
 void inv_set_compass_bandwidth(int bandwidth_hz);

 void inv_get_gyro_sample_rate_ms(long *sample_rate_ms);
 void inv_get_accel_sample_rate_ms(long *sample_rate_ms);
 void inv_get_compass_sample_rate_ms(long *sample_rate_ms);

 inv_error_t inv_register_data_cb(inv_error_t (*func)
                                  (struct inv_sensor_cal_t * data), int priority,
                                  int sensor_type);
 inv_error_t inv_unregister_data_cb(inv_error_t (*func)
                                    (struct inv_sensor_cal_t * data));

 inv_error_t inv_build_gyro(const short *gyro, inv_time_t timestamp);
 inv_error_t inv_build_compass(const long *compass, int status,
                                   inv_time_t timestamp);
 inv_error_t inv_build_accel(const long *accel, int status,
                             inv_time_t timestamp);
 inv_error_t inv_build_temp(const long temp, inv_time_t timestamp);
 inv_error_t inv_build_quat(const long *quat, int status, inv_time_t timestamp);
 inv_error_t inv_execute_on_data(void);

 void inv_get_compass_bias(long *bias);

 void inv_set_compass_bias(const long *bias, int accuracy);
 void inv_set_compass_disturbance(int dist);
 void inv_set_gyro_bias(const long *bias, int accuracy);
 void inv_set_accel_bias(const long *bias, int accuracy);
 void inv_set_accel_accuracy(int accuracy);
 void inv_set_accel_bias_mask(const long *bias, int accuracy, int mask);

 void inv_get_gyro_bias(long *bias, long *temp);
 void inv_get_accel_bias(long *bias, long *temp);

 void inv_gyro_was_turned_off(void);
 void inv_accel_was_turned_off(void);
 void inv_compass_was_turned_off(void);
 void inv_quaternion_sensor_was_turned_off(void);
 inv_error_t inv_init_data_builder(void);
 long inv_get_gyro_sensitivity(void);
 long inv_get_accel_sensitivity(void);
 long inv_get_compass_sensitivity(void);

 void inv_get_accel_set(long *data, int8_t *accuracy, inv_time_t * timestamp);
 void inv_get_gyro_set(long *data, int8_t *accuracy, inv_time_t * timestamp);
 void inv_get_gyro_set_raw(long *data, int8_t *accuracy, inv_time_t * timestamp);
 void inv_get_compass_set(long *data, int8_t *accuracy, inv_time_t * timestamp);

 void inv_get_gyro(long *gyro);

 int inv_get_gyro_accuracy(void);
 int inv_get_accel_accuracy(void);
 int inv_get_mag_accuracy(void);

 int inv_get_compass_on(void);
 int inv_get_gyro_on(void);
 int inv_get_accel_on(void);

 inv_time_t inv_get_last_timestamp(void);
 int inv_get_compass_disturbance(void);

 //New DMP Cal Functions
 inv_error_t inv_get_gyro_orient(int *orient);
 inv_error_t inv_get_accel_orient(int *orient);

 // internal
 int inv_get_6_axis_gyro_accel_timestamp(long sample_rate_us, inv_time_t *ts);

 #ifdef __cplusplus
 }
 #endif

 #endif  /* INV_DATA_BUILDER_H__ */
	/*
	$License:
	Copyright (C) 2011-2012 InvenSense Corporation, All Rights Reserved.
	See included License.txt for License information.
	$
	*/
	#include "mltypes.h"

	#ifndef INV_DATA_BUILDER_H__
	#define INV_DATA_BUILDER_H__

	#ifdef __cplusplus
	extern "C" {
	#endif

	// Uncomment this flag to enable playback debug and record or playback scenarios
	//#define INV_PLAYBACK_DBG

	/** This is a new sample of accel data */
	#define INV_ACCEL_NEW 1
	/** This is a new sample of gyro data */
	#define INV_GYRO_NEW 2
	/** This is a new sample of compass data */
	#define INV_MAG_NEW 4
	/** This is a new sample of temperature data */
	#define INV_TEMP_NEW 8
	/** This is a new sample of quaternion data */
	#define INV_QUAT_NEW 16
	/** Set if quaternion is 6-axis from DMP */
	#define INV_QUAT_6AXIS 1024
	/** Set if quaternion is 3-axis from DMP */
	#define INV_QUAT_3AXIS 4096

	/** Set if the data is contiguous. Typically not set if a sample was skipped */
	#define INV_CONTIGUOUS 16
	/** Set if the calibrated data has been solved for */
	#define INV_CALIBRATED 32
	/* INV_NEW_DATA set for a new set of data, cleared if not available. */
	#define INV_NEW_DATA 64
	/* Set if raw data exists */
	#define INV_RAW_DATA 128
	/* Set if the sensor is on */
	#define INV_SENSOR_ON 256
	/* Set if quaternion has bias correction applied */
	#define INV_BIAS_APPLIED 512

	#define INV_PRIORITY_MOTION_NO_MOTION 100
	#define INV_PRIORITY_GYRO_TC 150
	#define INV_PRIORITY_QUATERNION_GYRO_ACCEL 200
	#define INV_PRIORITY_QUATERNION_NO_GYRO 250
	#define INV_PRIORITY_MAGNETIC_DISTURBANCE 300
	#define INV_PRIORITY_HEADING_FROM_GYRO 350
	#define INV_PRIORITY_COMPASS_BIAS_W_GYRO 375
	#define INV_PRIORITY_COMPASS_VECTOR_CAL 400
	#define INV_PRIORITY_COMPASS_ADV_BIAS 500
	#define INV_PRIORITY_9_AXIS_FUSION 600
	#define INV_PRIORITY_QUATERNION_ADJUST_9_AXIS 700
	#define INV_PRIORITY_QUATERNION_ACCURACY 750
	#define INV_PRIORITY_RESULTS_HOLDER 800
	#define INV_PRIORITY_INUSE_AUTO_CALIBRATION 850
	#define INV_PRIORITY_HAL_OUTPUTS 900
	#define INV_PRIORITY_GLYPH 950
	#define INV_PRIORITY_SHAKE 975
	#define INV_PRIORITY_SM 1000

	struct inv_single_sensor_t {
	/** Orientation Descriptor. Describes how to go from the mounting frame to the body frame when
	* the rotation matrix could be thought of only having elements of 0,1,-1.
	* 2 bits are used to describe the column of the 1 or -1 and the 3rd bit is used for the sign.
	* Bit 8 is sign of +/- 1 in third row. Bit 6-7 is column of +/-1 in third row.
	* Bit 5 is sign of +/- 1 in second row. Bit 3-4 is column of +/-1 in second row.
	* Bit 2 is sign of +/- 1 in first row. Bit 0-1 is column of +/-1 in first row.
	*/
	int orientation;
	/** The raw data in raw data units in the mounting frame */
	short raw[3];
	/** Raw data in body frame */
	long raw_scaled[3];
	/** Calibrated data */
	long calibrated[3];
	long sensitivity;
	/** Sample rate in microseconds */
	long sample_rate_us;
	long sample_rate_ms;
	/** INV_CONTIGUOUS is set for contiguous data. Will not be set if there was a sample
	* skipped due to power savings turning off this sensor.
	* INV_NEW_DATA set for a new set of data, cleared if not available.
	* INV_CALIBRATED_SET if calibrated data has been solved for */
	int status;
	/** 0 to 3 for how well sensor data and biases are known. 3 is most accurate. */
	int accuracy;
	inv_time_t timestamp;
	inv_time_t timestamp_prev;
	/** Bandwidth in Hz */
	int bandwidth;
	};
	struct inv_quat_sensor_t {
	long raw[4];
	/** INV_CONTIGUOUS is set for contiguous data. Will not be set if there was a sample
	* skipped due to power savings turning off this sensor.
	* INV_NEW_DATA set for a new set of data, cleared if not available.
	* INV_CALIBRATED_SET if calibrated data has been solved for */
	int status;
	inv_time_t timestamp;
	inv_time_t timestamp_prev;
	long sample_rate_us;
	long sample_rate_ms;
	};

	struct inv_sensor_cal_t {
	struct inv_single_sensor_t gyro;
	struct inv_single_sensor_t accel;
	struct inv_single_sensor_t compass;
	struct inv_single_sensor_t temp;
	struct inv_quat_sensor_t quat;
	/** Combinations of INV_GYRO_NEW, INV_ACCEL_NEW, INV_MAG_NEW to indicate
	* which data is a new sample as these data points may have different sample rates.
	*/
	int status;
	};

	// Useful for debug record and playback
	typedef enum {
	RD_NO_DEBUG,
	RD_RECORD,
	RD_PLAYBACK
	} rd_dbg_mode;

	typedef enum {
	PLAYBACK_DBG_TYPE_GYRO,
	PLAYBACK_DBG_TYPE_ACCEL,
	PLAYBACK_DBG_TYPE_COMPASS,
	PLAYBACK_DBG_TYPE_TEMPERATURE,
	PLAYBACK_DBG_TYPE_EXECUTE,
	PLAYBACK_DBG_TYPE_A_ORIENT,
	PLAYBACK_DBG_TYPE_G_ORIENT,
	PLAYBACK_DBG_TYPE_C_ORIENT,
	PLAYBACK_DBG_TYPE_A_SAMPLE_RATE,
	PLAYBACK_DBG_TYPE_C_SAMPLE_RATE,
	PLAYBACK_DBG_TYPE_G_SAMPLE_RATE,
	PLAYBACK_DBG_TYPE_GYRO_OFF,
	PLAYBACK_DBG_TYPE_ACCEL_OFF,
	PLAYBACK_DBG_TYPE_COMPASS_OFF,
	PLAYBACK_DBG_TYPE_Q_SAMPLE_RATE,
	PLAYBACK_DBG_TYPE_QUAT

	} inv_rd_dbg_states;

	/** Maximum number of data callbacks that are supported. Safe to increase if needed.*/
	#define INV_MAX_DATA_CB 20

	#ifdef INV_PLAYBACK_DBG
	#include <stdio.h>
	void inv_turn_on_data_logging(FILE *file);
	void inv_turn_off_data_logging();
	#endif

	void inv_set_gyro_orientation_and_scale(int orientation, long sensitivity);
	void inv_set_accel_orientation_and_scale(int orientation,
	long sensitivity);
	void inv_set_compass_orientation_and_scale(int orientation,
	long sensitivity);
	void inv_set_gyro_sample_rate(long sample_rate_us);
	void inv_set_compass_sample_rate(long sample_rate_us);
	void inv_set_quat_sample_rate(long sample_rate_us);
	void inv_set_accel_sample_rate(long sample_rate_us);
	void inv_set_gyro_bandwidth(int bandwidth_hz);
	void inv_set_accel_bandwidth(int bandwidth_hz);
	void inv_set_compass_bandwidth(int bandwidth_hz);

	void inv_get_gyro_sample_rate_ms(long *sample_rate_ms);
	void inv_get_accel_sample_rate_ms(long *sample_rate_ms);
	void inv_get_compass_sample_rate_ms(long *sample_rate_ms);

	inv_error_t inv_register_data_cb(inv_error_t (*func)
	(struct inv_sensor_cal_t * data), int priority,
	int sensor_type);
	inv_error_t inv_unregister_data_cb(inv_error_t (*func)
	(struct inv_sensor_cal_t * data));

	inv_error_t inv_build_gyro(const short *gyro, inv_time_t timestamp);
	inv_error_t inv_build_compass(const long *compass, int status,
	inv_time_t timestamp);
	inv_error_t inv_build_accel(const long *accel, int status,
	inv_time_t timestamp);
	inv_error_t inv_build_temp(const long temp, inv_time_t timestamp);
	inv_error_t inv_build_quat(const long *quat, int status, inv_time_t timestamp);
	inv_error_t inv_execute_on_data(void);

	void inv_get_compass_bias(long *bias);

	void inv_set_compass_bias(const long *bias, int accuracy);
	void inv_set_compass_disturbance(int dist);
	void inv_set_gyro_bias(const long *bias, int accuracy);
	void inv_set_accel_bias(const long *bias, int accuracy);
	void inv_set_accel_accuracy(int accuracy);
	void inv_set_accel_bias_mask(const long *bias, int accuracy, int mask);

	void inv_get_gyro_bias(long bias, long temp);
	void inv_get_accel_bias(long bias, long temp);

	void inv_gyro_was_turned_off(void);
	void inv_accel_was_turned_off(void);
	void inv_compass_was_turned_off(void);
	void inv_quaternion_sensor_was_turned_off(void);
	inv_error_t inv_init_data_builder(void);
	long inv_get_gyro_sensitivity(void);
	long inv_get_accel_sensitivity(void);
	long inv_get_compass_sensitivity(void);

	void inv_get_accel_set(long data, int8_t accuracy, inv_time_t * timestamp);
	void inv_get_gyro_set(long data, int8_t accuracy, inv_time_t * timestamp);
	void inv_get_gyro_set_raw(long data, int8_t accuracy, inv_time_t * timestamp);
	void inv_get_compass_set(long data, int8_t accuracy, inv_time_t * timestamp);

	void inv_get_gyro(long *gyro);

	int inv_get_gyro_accuracy(void);
	int inv_get_accel_accuracy(void);
	int inv_get_mag_accuracy(void);

	int inv_get_compass_on(void);
	int inv_get_gyro_on(void);
	int inv_get_accel_on(void);

	inv_time_t inv_get_last_timestamp(void);
	int inv_get_compass_disturbance(void);

	//New DMP Cal Functions
	inv_error_t inv_get_gyro_orient(int *orient);
	inv_error_t inv_get_accel_orient(int *orient);

	// internal
	int inv_get_6_axis_gyro_accel_timestamp(long sample_rate_us, inv_time_t *ts);

	#ifdef __cplusplus
	}
	#endif

	#endif /* INV_DATA_BUILDER_H__ */