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1 /**
2  *   @defgroup  HAL_Outputs
3  *   @brief     Motion Library - HAL Outputs
4  *              Sets up common outputs for HAL
5  *
6  *   @{
7  *       @file  datalogger_outputs.c
8  *       @brief Windows 8 HAL outputs.
9  */
10 
11 #include <string.h>
12 
13 #include "datalogger_outputs.h"
14 #include "ml_math_func.h"
15 #include "mlmath.h"
16 #include "start_manager.h"
17 #include "data_builder.h"
18 #include "results_holder.h"
19 
20 /*
21     Defines
22 */
23 #define ACCEL_CONVERSION (0.000149637603759766f)
24 
25 /*
26     Types
27 */
28 struct datalogger_output_s {
29     int quat_accuracy;
30     inv_time_t quat_timestamp;
31     long quat[4];
32     struct inv_sensor_cal_t sc;
33 };
34 
35 /*
36     Globals and Statics
37 */
38 static struct datalogger_output_s dl_out;
39 
40 /*
41     Functions
42 */
43 
44 /**
45  *  Raw (uncompensated) angular velocity (LSB) in chip frame.
46  *  @param[out] values      raw angular velocity in LSB.
47  *  @param[out] timestamp   Time when sensor was sampled.
48  */
inv_get_sensor_type_gyro_raw_short(short * values,inv_time_t * timestamp)49 void inv_get_sensor_type_gyro_raw_short(short *values, inv_time_t *timestamp)
50 {
51     struct inv_single_sensor_t *pg = &dl_out.sc.gyro;
52 
53     if (values)
54         memcpy(values, &pg->raw, sizeof(short) * 3);
55     if (timestamp)
56         *timestamp = pg->timestamp;
57 }
58 
59 /**
60  *  Raw (uncompensated) angular velocity (degrees per second) in body frame.
61  *  @param[out] values      raw angular velocity in dps.
62  *  @param[out] timestamp   Time when sensor was sampled.
63  */
inv_get_sensor_type_gyro_raw_body_float(float * values,inv_time_t * timestamp)64 void inv_get_sensor_type_gyro_raw_body_float(float *values,
65         inv_time_t *timestamp)
66 {
67     struct inv_single_sensor_t *pg = &dl_out.sc.gyro;
68     long raw[3];
69     long raw_body[3];
70 
71     raw[0] = (long) pg->raw[0] * (1L << 16);
72     raw[1] = (long) pg->raw[1] * (1L << 16);
73     raw[2] = (long) pg->raw[2] * (1L << 16);
74     inv_convert_to_body_with_scale(pg->orientation, pg->sensitivity,
75                                    raw, raw_body);
76     if (values) {
77         values[0] = inv_q16_to_float(raw_body[0]);
78         values[1] = inv_q16_to_float(raw_body[1]);
79         values[2] = inv_q16_to_float(raw_body[2]);
80     }
81     if (timestamp)
82         *timestamp = pg->timestamp;
83 }
84 
85 /**
86  *  Angular velocity (degrees per second) in body frame.
87  *  @param[out] values      Angular velocity in dps.
88  *  @param[out] accuracy    0 (uncalibrated) to 3 (most accurate).
89  *  @param[out] timestamp   Time when sensor was sampled.
90  */
inv_get_sensor_type_gyro_float(float * values,int8_t * accuracy,inv_time_t * timestamp)91 void inv_get_sensor_type_gyro_float(float *values, int8_t *accuracy,
92         inv_time_t *timestamp)
93 {
94     long gyro[3];
95     inv_get_gyro_set(gyro, accuracy, timestamp);
96 
97     values[0] = (float)gyro[0] / 65536.f;
98     values[1] = (float)gyro[1] / 65536.f;
99     values[2] = (float)gyro[2] / 65536.f;
100 }
101 
102 /**
103  *  Raw (uncompensated) acceleration (LSB) in chip frame.
104  *  @param[out] values      raw acceleration in LSB.
105  *  @param[out] timestamp   Time when sensor was sampled.
106  */
inv_get_sensor_type_accel_raw_short(short * values,inv_time_t * timestamp)107 void inv_get_sensor_type_accel_raw_short(short *values, inv_time_t *timestamp)
108 {
109     struct inv_single_sensor_t *pa = &dl_out.sc.accel;
110 
111     if (values)
112         memcpy(values, &pa->raw, sizeof(short) * 3);
113     if (timestamp)
114         *timestamp = pa->timestamp;
115 }
116 
117 /**
118  *  Acceleration (g's) in body frame.
119  *  Microsoft defines gravity as positive acceleration pointing towards the
120  *  Earth.
121  *  @param[out] values      Acceleration in g's.
122  *  @param[out] accuracy    0 (uncalibrated) to 3 (most accurate).
123  *  @param[out] timestamp   Time when sensor was sampled.
124  */
inv_get_sensor_type_accel_float(float * values,int8_t * accuracy,inv_time_t * timestamp)125 void inv_get_sensor_type_accel_float(float *values, int8_t *accuracy,
126         inv_time_t *timestamp)
127 {
128     long accel[3];
129     inv_get_accel_set(accel, accuracy, timestamp);
130 
131     values[0] = (float) -accel[0] / 65536.f;
132     values[1] = (float) -accel[1] / 65536.f;
133     values[2] = (float) -accel[2] / 65536.f;
134 }
135 
136 /**
137  *  Raw (uncompensated) compass magnetic field  (LSB) in chip frame.
138  *  @param[out] values      raw magnetic field in LSB.
139  *  @param[out] timestamp   Time when sensor was sampled.
140  */
inv_get_sensor_type_compass_raw_short(short * values,inv_time_t * timestamp)141 void inv_get_sensor_type_compass_raw_short(short *values, inv_time_t *timestamp)
142 {
143     struct inv_single_sensor_t *pc = &dl_out.sc.compass;
144 
145     if (values)
146         memcpy(values, &pc->raw, sizeof(short) * 3);
147     if (timestamp)
148         *timestamp = pc->timestamp;
149 }
150 
151 /**
152  *  Magnetic heading/field strength in body frame.
153  *  TODO: No difference between mag_north and true_north yet.
154  *  @param[out] mag_north   Heading relative to magnetic north in degrees.
155  *  @param[out] true_north  Heading relative to true north in degrees.
156  *  @param[out] values      Field strength in milligauss.
157  *  @param[out] accuracy    0 (uncalibrated) to 3 (most accurate).
158  *  @param[out] timestamp   Time when sensor was sampled.
159  */
inv_get_sensor_type_compass_float(float * mag_north,float * true_north,float * values,int8_t * accuracy,inv_time_t * timestamp)160 void inv_get_sensor_type_compass_float(float *mag_north, float *true_north,
161         float *values, int8_t *accuracy, inv_time_t *timestamp)
162 {
163     long compass[3];
164     long q00, q12, q22, q03, t1, t2;
165 
166     /* 1 uT = 10 milligauss. */
167 #define COMPASS_CONVERSION  (10 / 65536.f)
168     inv_get_compass_set(compass, accuracy, timestamp);
169     if (values) {
170         values[0] = (float)compass[0]*COMPASS_CONVERSION;
171         values[1] = (float)compass[1]*COMPASS_CONVERSION;
172         values[2] = (float)compass[2]*COMPASS_CONVERSION;
173     }
174 
175     /* TODO: Stolen from euler angle computation. Calculate this only once per
176      * callback.
177      */
178     q00 = inv_q29_mult(dl_out.quat[0], dl_out.quat[0]);
179     q12 = inv_q29_mult(dl_out.quat[1], dl_out.quat[2]);
180     q22 = inv_q29_mult(dl_out.quat[2], dl_out.quat[2]);
181     q03 = inv_q29_mult(dl_out.quat[0], dl_out.quat[3]);
182     t1 = q12 - q03;
183     t2 = q22 + q00 - (1L << 30);
184     if (mag_north) {
185         *mag_north = atan2f((float) t1, (float) t2) * 180.f / (float) M_PI;
186         if (*mag_north < 0)
187             *mag_north += 360;
188     }
189     if (true_north) {
190         if (!mag_north) {
191             *true_north = atan2f((float) t1, (float) t2) * 180.f / (float) M_PI;
192             if (*true_north < 0)
193                 *true_north += 360;
194         } else {
195             *true_north = *mag_north;
196         }
197     }
198 }
199 
200 #if 0
201 // put it back when we handle raw temperature
202 /**
203  *  Raw temperature (LSB).
204  *  @param[out] value       raw temperature in LSB (1 element).
205  *  @param[out] timestamp   Time when sensor was sampled.
206  */
207 void inv_get_sensor_type_temp_raw_short(short *value, inv_time_t *timestamp)
208 {
209     struct inv_single_sensor_t *pt = &dl_out.sc.temp;
210     if (value) {
211         /* no raw temperature, temperature is only handled calibrated
212         *value = pt->raw[0];
213         */
214         *value = pt->calibrated[0];
215     }
216     if (timestamp)
217         *timestamp = pt->timestamp;
218 }
219 #endif
220 
221 /**
222  *  Temperature (degree C).
223  *  @param[out] values      Temperature in degrees C.
224  *  @param[out] timestamp   Time when sensor was sampled.
225  */
inv_get_sensor_type_temperature_float(float * value,inv_time_t * timestamp)226 void inv_get_sensor_type_temperature_float(float *value, inv_time_t *timestamp)
227 {
228     struct inv_single_sensor_t *pt = &dl_out.sc.temp;
229     long ltemp;
230     if (timestamp)
231         *timestamp = pt->timestamp;
232     if (value) {
233         /* no raw temperature, temperature is only handled calibrated
234         ltemp = pt->raw[0];
235         */
236         ltemp = pt->calibrated[0];
237         *value = (float) ltemp / (1L << 16);
238     }
239 }
240 
241 /**
242  *  Quaternion in body frame.
243  *  @e inv_get_sensor_type_quaternion_float outputs the data in the following
244  *  order: X, Y, Z, W.
245  *  TODO: Windows expects a discontinuity at 180 degree rotations. Will our
246  *  convention be ok?
247  *  @param[out] values      Quaternion normalized to one.
248  *  @param[out] accuracy    0 (uncalibrated) to 3 (most accurate).
249  *  @param[out] timestamp   Time when sensor was sampled.
250  */
inv_get_sensor_type_quat_float(float * values,int * accuracy,inv_time_t * timestamp)251 void inv_get_sensor_type_quat_float(float *values, int *accuracy,
252                                     inv_time_t *timestamp)
253 {
254     values[0] = dl_out.quat[0] / 1073741824.f;
255     values[1] = dl_out.quat[1] / 1073741824.f;
256     values[2] = dl_out.quat[2] / 1073741824.f;
257     values[3] = dl_out.quat[3] / 1073741824.f;
258     accuracy[0] = dl_out.quat_accuracy;
259     timestamp[0] = dl_out.quat_timestamp;
260 }
261 
262 /** Gravity vector (gee) in body frame.
263 * @param[out] values Gravity vector in body frame, length 3, (gee)
264 * @param[out] accuracy Accuracy of the measurment, 0 is least accurate,
265                        while 3 is most accurate.
266 * @param[out] timestamp The timestamp for this sensor. Derived from the
267                         timestamp sent to inv_build_accel().
268 */
inv_get_sensor_type_gravity_float(float * values,int * accuracy,inv_time_t * timestamp)269 void inv_get_sensor_type_gravity_float(float *values, int *accuracy,
270                                        inv_time_t * timestamp)
271 {
272     struct inv_single_sensor_t *pa = &dl_out.sc.accel;
273 
274     if (values) {
275         long lgravity[3];
276         (void)inv_get_gravity(lgravity);
277         values[0] = (float) lgravity[0] / (1L << 16);
278         values[1] = (float) lgravity[1] / (1L << 16);
279         values[2] = (float) lgravity[2] / (1L << 16);
280     }
281     if (accuracy)
282         *accuracy = pa->accuracy;
283     if (timestamp)
284         *timestamp = pa->timestamp;
285 }
286 
287 /**
288 * This corresponds to Sensor.TYPE_ROTATION_VECTOR.
289 * The rotation vector represents the orientation of the device as a combination
290 * of an angle and an axis, in which the device has rotated through an angle @f$\theta@f$
291 * around an axis {x, y, z}. <br>
292 * The three elements of the rotation vector are
293 * {x*sin(@f$\theta@f$/2), y*sin(@f$\theta@f$/2), z*sin(@f$\theta@f$/2)}, such that the magnitude of the rotation
294 * vector is equal to sin(@f$\theta@f$/2), and the direction of the rotation vector is
295 * equal to the direction of the axis of rotation.
296 *
297 * The three elements of the rotation vector are equal to the last three components of a unit quaternion
298 * {x*sin(@f$\theta@f$/2), y*sin(@f$\theta@f$/2), z*sin(@f$\theta@f$/2)>.
299 *
300 * Elements of the rotation vector are unitless. The x,y and z axis are defined in the same way as the acceleration sensor.
301 * The reference coordinate system is defined as a direct orthonormal basis, where:
302 
303     -X is defined as the vector product Y.Z (It is tangential to the ground at the device's current location and roughly points East).
304     -Y is tangential to the ground at the device's current location and points towards the magnetic North Pole.
305     -Z points towards the sky and is perpendicular to the ground.
306 * @param[out] values
307 * @param[out] accuracy Accuracy 0 to 3, 3 = most accurate
308 * @param[out] timestamp Timestamp. In (ns) for Android.
309 */
inv_get_sensor_type_rotation_vector_float(float * values,int * accuracy,inv_time_t * timestamp)310 void inv_get_sensor_type_rotation_vector_float(float *values, int *accuracy,
311         inv_time_t * timestamp)
312 {
313     if (accuracy)
314         *accuracy = dl_out.quat_accuracy;
315     if (timestamp)
316         *timestamp = dl_out.quat_timestamp;
317     if (values) {
318         if (dl_out.quat[0] >= 0) {
319             values[0] = dl_out.quat[1] * INV_TWO_POWER_NEG_30;
320             values[1] = dl_out.quat[2] * INV_TWO_POWER_NEG_30;
321             values[2] = dl_out.quat[3] * INV_TWO_POWER_NEG_30;
322         } else {
323             values[0] = -dl_out.quat[1] * INV_TWO_POWER_NEG_30;
324             values[1] = -dl_out.quat[2] * INV_TWO_POWER_NEG_30;
325             values[2] = -dl_out.quat[3] * INV_TWO_POWER_NEG_30;
326         }
327     }
328 }
329 
330 /** Main callback to generate HAL outputs. Typically not called by library users. */
inv_generate_datalogger_outputs(struct inv_sensor_cal_t * sensor_cal)331 inv_error_t inv_generate_datalogger_outputs(struct inv_sensor_cal_t *sensor_cal)
332 {
333     memcpy(&dl_out.sc, sensor_cal, sizeof(struct inv_sensor_cal_t));
334     inv_get_quaternion_set(dl_out.quat, &dl_out.quat_accuracy,
335                            &dl_out.quat_timestamp);
336     return INV_SUCCESS;
337 }
338 
339 /** Turns off generation of HAL outputs. */
inv_stop_datalogger_outputs(void)340 inv_error_t inv_stop_datalogger_outputs(void)
341 {
342     return inv_unregister_data_cb(inv_generate_datalogger_outputs);
343 }
344 
345 /** Turns on generation of HAL outputs. This should be called after inv_stop_dl_outputs()
346 * to turn generation of HAL outputs back on. It is automatically called by inv_enable_dl_outputs().*/
inv_start_datalogger_outputs(void)347 inv_error_t inv_start_datalogger_outputs(void)
348 {
349     return inv_register_data_cb(inv_generate_datalogger_outputs,
350         INV_PRIORITY_HAL_OUTPUTS, INV_GYRO_NEW | INV_ACCEL_NEW | INV_MAG_NEW);
351 }
352 
353 /** Initializes hal outputs class. This is called automatically by the
354 * enable function. It may be called any time the feature is enabled, but
355 * is typically not needed to be called by outside callers.
356 */
inv_init_datalogger_outputs(void)357 inv_error_t inv_init_datalogger_outputs(void)
358 {
359     memset(&dl_out, 0, sizeof(dl_out));
360     return INV_SUCCESS;
361 }
362 
363 /** Turns on creation and storage of HAL type results.
364 */
inv_enable_datalogger_outputs(void)365 inv_error_t inv_enable_datalogger_outputs(void)
366 {
367     inv_error_t result;
368     result = inv_init_datalogger_outputs();
369     if (result)
370         return result;
371     return inv_register_mpl_start_notification(inv_start_datalogger_outputs);
372 }
373 
374 /** Turns off creation and storage of HAL type results.
375 */
inv_disable_datalogger_outputs(void)376 inv_error_t inv_disable_datalogger_outputs(void)
377 {
378     inv_stop_datalogger_outputs();
379     return inv_unregister_mpl_start_notification(inv_start_datalogger_outputs);
380 }
381 
382 /**
383  * @}
384  */
385